VICTOR G. SPRINGE Revision of the
: Fish Genus Ecsenius
(Blenniidae, Blenniinae,
Salariini)
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SMITHSONIAN CONTRIBUTIONS TO
ZOOLOGY
NUMBER 72
victor G. springer Revision of the
Fish Genus Ecsenius
(Blenniidae, Blenniinae,
Salariini)
SMITHSONIAN INSTITUTION PRESS
CITY OF WASHINGTON
1971
ABSTRACT
Springer, Victor G. Revision of the Fish Genus Ecsenius (Blenniidae, Blenniinae,
Salariini). Smithsonian Contributions to Zoology, 72:1-74, I971.-The genus
Ecsenius comprises 18 species of Indo-Pacific reef-dwelling fishes. The species are
generally characterized by a high degree of sexual dimorphism and geographic
variation as indicated by statistically significant differences in average numbers
of various meristic and proportional characters and color pattern types.
Keys, illustrations and diagnoses, and nomenclatural and zoogeographical dis-
cussions are provided. Four new species are described: E. aroni from the Gulf of
Aqaba, E. oculus from the western Pacific, E. bimaculatus from Borneo, and
E. bandanus from Banda Island.
A discussion is given of a particularly complex taxonomic problem involving
three nominal species occurring in the Red Sea and Gulf of Aqaba. E. nigrovittatus
is known only from the southern Red Sea, E. frontalis is known from the northern
Gulf of Aqaba to the Bay of Tadjoura (Gulf of Aden), and E. albicaudatus is
known from the northern Gulf of Aqaba to the southern Red Sea. Except for
color pattern all three forms are very similar morphologically, have been collected
together from one small rock, and are very different from any other species of
Ecsenius. The problem of whether the three forms constitute one or more species
is not solvable presently, but the three nominal species are treated here as color
pattern forms of single species, E. frontalis.
Official publication date is handstamped in a limited number of initial copies and is recorded
in the Institution's annual report, Smithsonian Year.
UNITED STATES GOVERNMENT PRINTING OFFICE
WASHINGTON : 1971
For sale by the Superintendent of Documents, U.S. Government Printing Office
Washington, D.C. 20402 - Price tl.25
Victor G. Springer Revision of the
Fish Genus Ecsenius
(Blenniidae, Blenniinae,
Salariini)
Introduction
Chapman and Schultz (1952), with seventy speci-
mens for study, last reviewed the Indo-Pacific genus
Ecsenius. They recognized eleven species, including
two species for which they had examined no speci-
mens. Since their review five additional species of
Ecsenius have been described (not all properly al-
located to genus). Intensive collecting in recent years
has made available well over one thousand speci-
mens of Ecsenius, including material of all the
described species and additional material of unde-
scribed species. The new material enables the revi-
sion of Ecsenius presented here.
I recognize eighteen species of Ecsenius, of which
four are new. Since some species of Ecsenius are re-
stricted to poorly collected, relatively deep water,
and because several of the species appear to be
restricted in their geographic distribution, I believe
that there will be a large increase in the number of
species over that which I report when more thor-
ough collecting has taken place. The faunistically
rich Indo-Malayan region is one of the most poorly
sampled for fishes, and it is therefore probable that
this region will provide most of the new Ecsenius
species collected in the future.
The species of Ecsenius are relatively small, not
exceeding 83 mm standard length, and are known,
with rare exceptions, only from coraliferous areas.
Victor G. Springer, Department of Vertebrate Zoology, Na-
tional Museum of Natural History, Smithsonian Institution,
Washington, D.C. 20560.
They live at depths from about one meter down
to at least 39 meters, although most species seem
to have a relatively restricted depth range. The
species may occur in the surge zone, tide pools, or
the relatively quiet lagoons of atolls.
The genus is a highly specialized one, exhibiting
anatomical peculiarities not found elsewhere among
the blenniids (see generic discussion). Some of the
species apparently are mimics, many are very color-
ful, while others are very somber in tone. One spe-
cies, Ecsenius bicolor, has been maintained and bred
in the laboratory (Wickler, 1965a), although it was
not possible to rear the young.
Chapman and Schultz (1952) believed that the
species of Ecsenius formed a close-knit group. I can-
not agree with this. While their generic affiliation is
more clear-cut than it is for the species of many
blenny genera, there seems to have been an unus-
ually high degree of adaptive radiation among the
species of Ecsenius. Although I can recognize small
groups of species within the genus, I am unable to
relate the groups.
Methods
MEASUREMENTS.?When possible, I made all meas-
urements on the left side of each specimen, using a
set of needlepoint dial calipers reading directly to
the nearest tenth of a millimeter. Measurements
were converted to percent of standard length.
Standard length (SL): This measurement was
1
2 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
taken from the midtip of the upper lip to the mid-
lateral posterior margin of the hypural vertebra as
indicated externally on the specimen. Variably, the
anteriormost point of the head is in advance of the
upper lip, but this portion of the head was ignored
in measurements.
Nasal cirrus length (Table 10): Most species have
a single, simple cirrus on the posterior rim of the
anterior nostril; two species, bicolor and namiyei,
also have a shorter, simple cirrus on the anterior rim
of the anterior nostril. On occasion any of these cirri
may bear a short secondary branch. The length of
the posterior cirrus was measured as the greatest dis-
tance from the point where the cirrus joined the
nostril to the distal tip of the cirrus.
Dorsal fin spine and ray lengths (Tables 5, 7, 8):
These measurements were taken from the proximal-
most point of the posterior axil formed by the ele-
ment with the dorsal body contour to the distal tip
of the element, disregarding the normal curvature
of the element. In a few instances (specimens of E.
namiyei and E. midas and some specimens of E.
frontalis) the lengths of the dorsal rays and spines
were taken from radiographs. This was necessary
because the dark skin overlying the fin elements
obscured them from view.
Longest caudal ray (Table 9): This measurement
was taken from the proximalmost point of the ray,
which overlaps the upper hypural plate, to the
distal tip of the ray.
Dorsal fin notch (Table 5): The notch, if present,
was measured as the greatest distance from the
distal tip of the first dorsal ray to the distal edge of
the fin membrane between the last dorsal spine
and first dorsal ray. This distance was divided by
the length of the first dorsal ray and the resulting
proportion recorded as the nearest one-ninth of the
length of the first dorsal ray. Occasionally the distal
tip of the penultimate dorsal spine extended over
the ultimate spine and attached to the first dorsal
ray. In such instances the notch depth was meas-
ured from the point of attachment of the penulti-
mate spine to the tip of the first ray.
Lateral line: The dorsal fin element under which
the lateral line terminated was recorded (Table 6).
Fin elements were numbered consecutively from the
anteriormost to the posteriormost without distin-
guishing spines from rays. If the lateral line ter-
minated below the space between two elements, the
nearest even-numbered element was recorded. With
few exceptions the lateral line terminates below the
spinous portion of the dorsal fin.
MERISTIC AND OTHER COUNTABLE CHARACTERS
(Tables 1-4, 6, 11, 12, 15-18).?All specimens were
radiographed and counts of the dorsal, anal and
caudal fin elements, caudal and precaudal vertebrae,
and epipleurals were taken from radiographs. Occa-
sionally a dorsal or anal fin ray was absent but its
proximal pterygiophore was present. In such in-
stances the ray was counted as if present. No counts
of caudal vertebrae were recorded for specimens
with apparent vertebral fusions. Pectoral and pelvic
ray counts were made on the specimens. Counts for
bilaterally paired characters are for one side only
(the left, when possible, unless otherwise noted.
Dorsal spines: In some species the terminal dorsal
spine is so reduced that it can be seen only on radio-
graphs or after osteological preparation.
Dorsal rays: Each segmented element was counted
separately (the last two counted as two).
Anal spines: There are invariably two, but the
first in females is frequently not visible externally.
Anal rays: Each segmented element was counted
separately (the last two counted as two); the ter-
minal pterygeophore always supports a single seg-
mented ray (unlike some other blenniids; see
Springer, 1967).
Segmented caudal rays: Except for certain small
specimens (see below) each segmented ray was
counted, including, where they occur, the single
dorsal and ventral rays with a single segmental
joint. I noted that occasional specimens less than
about 25 mm had one or two more segmented caudal
rays than larger specimens. These additional seg-
mented rays were usually the ventralmost and, sec-
ondarily, the dorsalmost of the segmented rays, and
they never had more than two segments; they were
either paired structures with right and left halves
or were paired for most of their length and fused
at their tips. I believe that such rays lose their
segmentations with growth and become fused for
much of their length. Counts for specimens under
25 mm SL are not included in Table 3 or the
species descriptions.
Procurrent caudal rays: These are the unseg-
mented elements described by Springer (1968). As
they are not bilaterally paired structures, they could
be called spines. As they appear to be serially homol-
ogous with the segmented rays discussed above and
usually have a bilaterally forked base, they give
NUMBER 72
evidence of having gone through a raylike stage in
ontogeny. In the posterior-most procurrent ray the
base may be cleft for almost half the length of the
element, but the distal portion is always fused and
spinelike with no evidence of a joint line extending
distally from the cleft. Procurrent ray counts for
specimens under 25 mm are not included in the
species descriptions. In Table 3, however, total
caudal element counts do include data from these
specimens.
Total caudal elements: This is the sum of the
dorsal and ventral procurrent caudal rays and the
segmented caudal rays.
Pelvic fins: A spine and three segmented rays are
always present, but the spine is imbedded, closely
applied to the first pelvic ray, and not visible ex-
ternally. In addition, the innermost pelvic ray is
reduced and often impossible to see externally.
Vertebrae: Precaudal vertebrae are those lacking
a hemal spine; the caudal vertebrae all bear a hemal
spine, although that of the hypural (last) vertebra
is fused with the ventral hypurals.
Epipleural ribs: The anterior epipleural ribs are
not possible to count on radiographs, but from ex-
amination of cleared and stained specimens are
known to begin invariably on the first vertebra (the
pleural ribs begin invariably on the third vertebra).
The epipleural rib count is actually a count of the
number of vertebrae from the anteriormost to the
posteriormost bearing an epipleural rib, regardless
of whether it bears a pair or only one, and that on
the right or left side. Thus, occasional vertebrae
lacking epipleural ribs, that occur between verte-
brae bearing epipleural ribs, are counted as if they
had these ribs.
Dentary teeth (Table 4): Ecsenius is unique
among blenniids in having two sets of canines-
anterior and posterior. The anterior canines, us-
ually a single tooth on each side, occur in line with
the incisoritorm, comblike teeth of the dental plate
(Springer, 1968). They are usually only slightly
larger than the adjacent incisor teeth and are fre-
quently blunted and difficult to distinguish from the
incisors, but in E. midas, and occasional specimens
of other species, they are quite large, pointed, and
distinct. The posterior canines (usually one or,
rarely, two, in all but one species) are posterior,
slightly medial to, and well separated from the an-
terior teeth. They are small and frequently blunted.
In one species, E. mandibularis, there is a series of
up to eight of these posterior canines on each side.
In making the dentary tooth counts the anterior
canines and all the incisors are included. The pos-
terior canines were counted separately. The pos-
terior canines frequently are not developed in speci-
mens below 25 mm SL.
Premaxillary teeth: All the teeth in the premaxil-
lary dental plate were counted. These counts are
difficult and were made on only a relatively few
specimens.
Gill-rakers and pseudobranchial filaments: All the
gill-rakers on the first arch and the pseudobranchial
filaments of one side were counted.
Color pattern: Unless otherwise stated, color pat-
tern descriptions are based on preserved specimens.
Statistical tests: Student's Mest, two sided (Simp
son, Roe and Lewontin, 1960), was employed to test
the difference between means of some samples. Dif-
ferences were considered to be significant when
p = .01 or less.
Synonymies: The synonymies under each species
include only references to original species descrip-
tions.
Much of the data concerning each species is to be
found under the general accounts of meristics, sex-
ual dimorphism, etc., and is not always repeated
under the individual species accounts.
Institutional abbreviations: In the material lists
and acknowledgments the following abbreviations
are used:
AMS?Australian Museum, Sydney; ANSP?Acad-
emy of Natural Sciences of Philadelphia; BMNH?
British Museum (Natural History); BPBM?Bernice
P. Bishop Museum, Honolulu; CAS?California
Academy of Sciences, San Francisco (also GVF for
those specimens in the George Vanderbilt Founda-
tion collections at CAS); FMRI?Central Fisheries
Marine Research Institute, Mandapam Camp, In-
dia; HUI?Hebrew University, Israel (some HUI
numbers include "HUJ" as part of the catalogue
number); ISZZ?Institut fur Spezielle Zoologie und
Zoologisches Museum, Berlin; MNHN?Museum
National d'Histoire Naturelle, Paris; NFIS?Natur-
Museum und Forschungs-Institut Senckenberg,
Frankfurt; RU?Rhodes University, Department of
Ichthyology, South Africa; UMML?University of
Miami Rosenstiel School of Marine and Atmos-
pheric Sciences; USNM?United States National
Museum of Natural History; UTAI?University of
Tel Aviv, Israel; UW?University of Washington,
SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
Seattle; ZMA?Zoologisch Museum, Amsterdam;
ZITH?Zoological Institute, University of Tokyo.
Full locality citations have usually not been in-
cluded in the material lists.
Ecsenius McCulloch
Ecsenius McCulloch, 1923, p. 121 [type-species: Ecsenius man-
dibularis McCulloch, 1923, by original designation].
Pescadorichthys Tomiyama, 1955, p. 8 [type-species: Salarias
namiyei Jordan and Evermann, 1902, by original designa-
tion].
DIAGNOSIS.?Fishes of the tribe Salariini (Springer,
1968), subfamily Blenniinae, (1) lacking an ossi-
fied median ethmoidl, (2) having the lateral extra-
scapulars fused with the pterotics, (3) four cir-
cumorbital bones, (4) both anterior and posterior
canines in the lower jaw (the anterior frequently
difficult to distinguish from the adjacent incisors
except in osteological preparations), (5) dorsomes-
ially extending processes arising from the proximal
ends of at least the third to fifth epipleural ribs, (6)
all fin rays unbranched, (7) upper and/or lower
caudal lobes of most mature males and many females
elongated.
Characters (1), (4), and (5) distinguish Ecsenius
from all other Blenniidae. In addition character (2)
distinguishes Ecsenius from all blenniids except a
few species in the subfamily Nemophidinae, and
character (7) distinguishes Ecsenius from all other
Salariini and Blenniini.
Further characterization: Dorsal spines 10 to 14
(rarely 10 or 11); dorsal rays 12 to 21 (rarely 12);
anal elements II, 13 to 23; pectoral rays 12 to 16;
pelvic elements I, 3 (but obvious pelvic rays 2 or 3);
segmented caudal rays 13 or 14 (rarely 15); verte-
brae 10 or 11 (9 and 12 in one specimen each) -f-
19 to 29 = 29 to 40; dentary incisor teeth (including
anterior canines) 13 to 64; premaxillary incisor
teeth 26 to 148, (usually 2 to 3 times as many upper
incisors as lower incisors).
Lateral line extending posteriorly to beneath level
of seventh dorsal spine to first dorsal ray. Dorsal
11 (Springer, 1968) erroneously reported that Ecsenius had
a median ethmoid that was encapsulated by the lateral eth-
moids and that projected into the orbital region of the skull.
I have reexamined my material and additional material and
find only a small amount of cartilage in the area where an
ossified median ethmoid would be expected. The structure
labelled as the median ethmoid in Springer (1968, plate 10,
center) is actually a process on the parasphenoid.
fin varying from entire to deeply notched between
dorsal spines and rays. Last dorsal and anal fin rays
attached by membrane to caudal peduncle. Cirri
present on anterior nostril; none on eye or nape.
Distinct occipital fleshy crest absent. Circumorbital
and preoperculomandibular pores in simple series
(no paired pores); one mid-predorsal, supra temporal
pore. Lips entire (no crenulae).
Eighteen species occurring in coraliferous areas
of the Indian and western Pacific oceans and their
associated seas and gulfs.
Subgenera: Ecsenius comprising 17 species, and
Anthiiblennius, monotypic, differentiated in the key.
NOMENCLATURE.?Tomiyama compared Pescado-
richthys only to the type-species of Ecsenius, E.
mandibularis. All the characters, except one, that
he used to differentiate the two genera vanish when
all the species treated here are considered. The one
character, presence of a series of canines posteriorly
in each jaw, is distinctive of E. mandibularis. I do
not believe that Pescadorichthys should be main-
tained, however, in view of the great number of
pecularities exhibited by E. mandibularis in com-
mon with the other species here included in
Ecsenius. Indeed, a few specimens of E. man-
dibularis have only two posterior canines on one
side of the jaw, as do a few specimens of the other
species, and so there is a degree of overlap in the
character.
RELATIONSHIPS.?Ecsenius is such a highly special-
ized genus that it is not possible to select another
genus of blenniids as its nearest relative. It is only
with reluctance that I do not recognize Ecsenius
as constituting a separate tribe of blenniids. The
excavation of the premaxillaries and dentaries, the
high number of premaxillary teeth, and the floating
nature (Springer, 1968) of the incisor teeth of
Ecsenius place it with the Salariini.
SEXUAL DIMORPHISM.?The species of Ecsenius ex-
hibit a number of diverse morphological features
that are associated with sex and, in males, with
presumed degree of maturity. The primary sexual
dimorphism of Ecsenius is that typical of all
blenniids: the first anal spine in females is usually
greatly reduced, not visible externally and com-
pletely included in a somewhat triangular fleshy
lobe embodying a large urogenital opening and a
papilla. In males the anal spines are distinct and
the urogenital opening is a minute orifice at the
tip of a short, slender, or truncate tube.
NUMBER 72
In at least several species of Ecsenius there is a
tendency for males to exceed females in standard
length attained. In E. gravieri the largest male
was 61 mm and the largest female was 46 mm (12
of 29 males over 24 mm exceeded 46 mm, but only
1 of 24 females over 24 mm attained that size). In
E. bicolor the largest male was 77 mm and the
largest female was 59 mm (40 of 128 males over
24 mm exceeded 55 mm, but only 2 of 110 females
over 24 mm exceeded 55 mm). In E. mandibularis
the largest male was 51 mm and the largest female
was 39 mm (23 of 45 males over 24 mm exceeded
39 mm; there were 40 females over 24 mm). In
E. yaeyamaensis the largest male was 51 mm and
the largest female was 42 mm (15 of 84 males over
24 mm exceeded 42 mm; there were 71 females
over 24 mm). In E. nalolo the largest male was
51 mm and the largest female was 43 mm (15 of
81 males over 24 mm exceeded 43 mm; there were
68 females over 24 mm). In E. oculus, E. namiyei,
E. midas, and E. lividinalis, of which there were
relatively few specimens, the largest specimen was
a male. In E. lineatus, of which I had only 13
specimens (6 were males), the largest specimen was
a female. In E. frontalis large males and females
were relatively common in all three color pattern
forms (see discussion under species account), but
the largest female was larger than the largest male
in the nigrovittatus form. The sexes attained about
equal size in E. aroni, E. pulcher, and E. opsi-
frontalis. The list on this page gives the sizes of the
largest specimen examined for each sex of each
species.
These sexual differences are possibly associated
with territoriality. It has been noted for freshwater
fishes (Collette and Yerger, 1962, p. 220, for sig-
nificant reference citations) that in those species
with a well-developed territory, the males are larger.
During field observations on nine different species
of Ecsenius I noted that all appeared to have a
very limited range of movement. Individuals were
occasionally seen to drive off fishes (nonblenniids)
that approached them, although most often the
Ecsenius retreated. An individual Ecsenius occupy-
ing a hole in a rock in an aquarium would success-
fully drive off another attacking Ecsenius whether
or not of the same species or of larger size. If the
occupant left the hole and another individual
midas
frontalis
frontalis form
albicaudatus form
nigrovittatus form
pulcher
gravieri
aroni
bicolor
namiyei
lineatus
stigmatura
lividinalis
yaeyamaensis
nalolo
oculus
opsifrontalis
prooculis
bimaculatus
bandanus
mandibularis
female
56.0
505
50.5
48.3
58.0
465
40.8
59.6
665
65.9
44.9
305
42.6
43.2
493
54.8
?
_
?
39.0
male
83.1
58.6
51.6
44.0
58.4
60.8
40.8
77.6
81.8
60.1
37.7
33.0
51.9
51.3
53.8
35.8
395
31.7
31.4
51.1
entered it, however, the new occupant could not
be driven out by the previous occupant.
In E. bicolor (Table 15) and Taiwan specimens
of E. namiyei (Table 16) males have significantly
(p = less than .001) higher average numbers of
dorsal and anal rays and caudal vertebrae than
females. Ethiopian males of E. frontaris (frontalis
form color pattern) had significantly higher average
numbers of anal rays (p = less than .001) and
vertebrae (p = between .02 and .01) than Ethiopian
females (frontalis form color pattern). The other
E. frontalis color pattern forms from Ethiopia and
the frontalis and albicaudatus color pattern forms
from the Gulf of Aqaba did not exhibit sexual
dimorphism in these two characters. In those other
species for which there were large numbers of
specimens, there did not appear to be sexual
dimorphism in these meristics except for numbers
of dorsal rays in E. pulcher, where males had a
significantly higher average number than females
(Table 16; p = .001).
Mandibular (dentary) tooth counts were examined
for sexual dimorphism. Most of the species ex-
hibited none for this character, but in three species,
E. bicolor, E. yaeyamaensis (both Table 4), and
E. nalolo (Table 17), females had significantly
higher average numbers of teeth (p = less than
.001). Gulf of Aqaba and northern Red Sea speci-
SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
mens of E. nalolo were considered in one test,
southern Red Sea and Indian Ocean specimens in
another test. Both tests were significant.
In E. mandibularis the third dorsal spine (Table
7) is considerably longer in males than females
(only the southern Queensland specimens were
checked). Though few specimens were available, it
seems that the same type sexual dimorphism may
also occur in E. opsifrontalis, E. nalolo, and E.
lineatus.
In E. mandibularis, E. yaeyamaensis, E. nalolo,
non-Australian E. bicolor, and E. argus the males
tend to have a higher average fifth dorsal ray length
than females (Table 8). There did not appear to
be much difference between males and females of
Australian E. bicolor in regard to fifth dorsal ray
lengths.
Either the upper and/or lower lobes of the
caudal fin in males (less so in females) of Ecsenius
species generally become increasingly longer with
increase in SL, and males of most species tend to
have longer caudal fins than females (Table 9);
but the two sexes are about the same in E. gravieri
(Figure 11). In E. mandibularis and E. bicolor males
and E. aroni females the caudal fins may reach a
peak relative length well below the maximum SL
and then begin to decrease in relative size with
increase in SL.
Nasal cirrus lengths (Table 10) tend to be longer
in males of E. oculus, E. opsifrontalis, E. yaeya-
maensis, E. nalolo, and E. mandibularis than in
females.
In addition to the above features the males of
most, if not all, species of Ecsenius tend to develop
thick fleshy tips on most of the anal rays (Figures
19, 33, 35, 36). Such developments may accompany
sexual maturity as males of similar size within a
species may or may not show such development.
The fleshy ray tips appear to be a parallel of the
condition found in many blenniids where the anal
spines and anterior anal rays may be enveloped in
rugose folds in presumably mature males.
Finally, the color pattern of preserved males is
in general darker or more contrasty than that of
females.
Many of the features discussed above are similarly
and variously exhibited by other species of the
Blenniidae. I am unable to explain why there
should be meristic sexual dimorphism, especially
so as there is usually a broad overlap in meristics
between males and females and the average differ-
ences are frequently one element or less in a par-
ticular character. On the other hand, the longer
fin elements and cirri of males are probably of
importance in sex recognition and courtship.
MIMICRY.?At least two species of Ecsenius bear
a strong, but superficial, resemblance to species of
the nemophidinine genus Meiacanthus Norman.
E. bicolor resembles M. atrodorsalis (Giinther) in
both color and morphology. G. Losey (in litteris)
has observed the two species together at Eniwetok,
where it appeared to him that E. bicolor was the
mimic as it was the rarer of the two species. He
described both species as being dark gray-blue
anteriorly and bright yellow-orange posteriorly. My
observations of E. bicolor offer some contrast to
those of Losey's. At One Tree Island on the
southern end of the Great Barrier Reef, I collected
over 100 E. bicolor and only one M. atrodorsalis,
and that one was taken in a collection where no
E. bicolor were seen or collected. The color patterns
were somewhat different also. The E. bicolor were
bright blue anteriorly and red-orange posteriorly.
The M. atrodorsalis was gray-blue anteriorly and
yellow posteriorly. It is possible that there is pop-
ulation variation or that different species of Meia-
canthus were involved.
Both E. gravieri and M. nigrolineatus Smith-Vaniz
have been collected together often and are very
similar in morphology and color pattern, both in
life and in preserved material. There is good cir-
cumstantial evidence supporting the idea of a
mimic-model relationship between these two species.
In the Gulf of Aqaba the two species are repre-
sented only by pale forms; that is, with relatively
little black pigment. In the southern Red Sea both
species are represented only by melanistic forms.
Further considerations of possible mimicry involv-
ing these two species will be discussed elsewhere
(Springer and Smith-Vaniz, ms).
Starck (1969) discussed mimicry between E. midas
and the anthiine Anthias squamipinnis Peters. He
believed that E. midas was the mimic because it was
much less abundant than the anthiine. He was not
able to establish the basis for the mimicry but be-
lieved that the blenny, when occurring in aggrega-
tions of the anthiid, probably was protected from
predation because of the difficulty a predator has in
singling out a prey from a large group. My observa-
tions in the Red Sea also indicate that E. midas was
NUMBER 72
exceedingly rare and that A. squamipinnis was one
of the dominant species, but I saw no predation of
or interaction between these two species.
Among the blennies, the only other species re-
ported to be involved in mimicry are the aggressive
nemophidinines Aspidontus taeniatus Quoy and
Gaimard, which mimics the cleaner wrasse Labroides
dimidiatus (Cuvier and Valenciennes)?see Randall
and Randall (I960)?and Runula azalea Jordan
and Bollman, which aggregates with the wrasse
Thalassoma lucasanum (Gill) where mimicry as
such was not specified (see Hobson, 1969).
Zoogeography
Ecsenius occurs from the Red Sea and east African
coast as far west as the Tonga Islands, as far north
as the Ryukyu Islands, and as far south as the
southern end of the Great Barrier Reef. It has
been reported questionably from the Hawaiian
Islands (I doubt its occurrence there; see discussion
under E. bicolor species account). The genus is
unreported from the central and eastern Pacific
and Atlantic oceans. While most of the species are
inhabitants of shallow waters, they are not taken
along shore. With only exceptional individuals, the
species are known only from coraliferous areas.
Over half the species of Ecsenius are relatively
restricted geographically, or form identifiable pop-
ulations in different areas. Of the five species occur-
ring in the Red Sea, E. aroni (Figure 2), E. gravieri
(Figure 1), and E. frontalis (Figures 1 and 5) occur
only there (the latter two species also occur in the
contiguous Gulf of Aden). Of the other two Red
Sea species, the E. nalolo (Figure 2) population
from the Gulf of Aqaba is recognizable from the
southern Red Sea and Indian Ocean populations
in having more teeth, and the four Red Sea speci-
mens of E. midas (Figure 2), which species is
known from only 12 specimens altogether, have
slightly lower vertebral counts than the six Indian
Ocean specimens. However, the two specimens of
E. midas from the Great Barrier Reef are inter-
mediate in these counts.
Only one species of Ecsenius, E. pulcher (Figure
1), is known from the Persian Gulf and Arabian
Sea, and it is not found elsewhere. Of the four
species known from Australia (all from the Great
Barrier Reef), E. mandibularis (Figure 3) is endemic,
E. yaeyamaensis (Figure 2) is represented by a
unique color pattern population, and the popula-
tion of E. bicolor (Figure 2) has higher average
numbers of dorsal and anal rays and caudal verte-
brae than populations of the species from any other
"W bicolor
A frwrtali*
? flrovitri
? namiyai
O pulch?r
n
FIGURE 1 .?Distribution of certain species of Ecsenius. Irregular broken line indicates approximate
position of andesite line (see zoogeography section).
SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
O lineatus
A midat
nalolo
opsifrontalis
yaeyamaensis
FICURE 2.?Distribution of certain species of Ecsenius. Irregular hroken line indicates approximate
position of andesite line (see zoogeography section).
locality except the South China Sea. E. prooculis,
E. bimaculatus, and E. bandanus (all Figure 4)
appear to be highly restricted in their ranges, and
E. oculus (Figure 3) comprises several recognizable
color pattern populations in the Pacific.
Only three species occur in both the Indian and
Pacific oceans. E. bicolor (Figure 1), which is wide-
spread in the Pacific, reaches as far west as the
Maldives in the central Indian Ocean. E. oculus
(Figure 3), also moderately widespread in the Pa-
cific, occurs along the Indian Ocean side of Sumatra,
and E. lineatus occurs from northern Taiwan and
the South China Sea to the Maldives. One might
place among these species a fourth, which I have
recognized as two species: E. yaeyamaensis (Figure
2), Pacific Ocean, and E. nalolo (Figure 2), Indian
Ocean, which at the least are completely distin-
guishable based on color pattern. There is a con-
siderable distance between the nearest known pop-
ulations of these last two species.
While it is difficult to explain and may only be
an artifact of collecting, only 3 of the 12 species
occurring in the Pacific, E. bicolor (Figure 1), E.
yaeyamaensis (Figure 2) and E. opsifrontalis (Figure
2) have been collected east of the andesite line
(Macdonald, 1949), which separates the continental
from the noncontinental rocks. The approximate
position of the line, based on Menard's (1964, fig.
4.21) delineation, is indicated in Figures 1-4. Of
these three species, E. opsifrontalis occurs only from
the line eastward and E. yaeyamaensis has its eastern
limits at or just beyond the line. The nearest rela-
tive of E. opsifrontalis, E. oculus (Figure 3), has its
eastern limit on the line. The last two species have
not been collected together.
It would appear that in the Pacific, at least,
Ecsenius had its evolutionary origin in the older
continental areas and has not been too successful
in invading the more recent oceanic islands. Thus,
E. opsifrontalis is probably a recently evolved
species, perhaps a derivative of E. oculus, and the
presence of E. bicolor east of the andesite line
indicates a relatively recent invasion.
It is interesting to compare the distributions of
the species of Ecsenius with those of the only other
recently revised large genus of salariinine blennies,
NUMBER 72
._ MARSHALL IS
? .Wot/o
' ".Maturo?
 ;. ..v.; .? ? -./w?
CALEPONIA _4j
lividinalis
O mandibularis
A oculus
stigmatura
|OO
FIGURE 3.?Distribution of certain species of Ecsenius. Irregular broken line indicates approximate
position of andesite line (see zoogeography section).
l8Oe
Entomacrodus (Springer, 1967). Entomacrodus oc-
curs in waters close to rocky shores (right up to
the shore line). The species are most often taken
in areas where corals are sparsely or not at all
present (although the corals may abound in areas
adjacent to where the species occur). Species of the
two genera are not often collected together, and
where they are, one genus or the other usually pre-
dominates. Presumably where they are collected
together, by poisoning, the poison has entered
different habitats. Collectors rarely restrict them-
selves to a single habitat when collecting, but pick
up everything killed, thus mixing the specimens
so taken.
In general, the species of Entomacrodus are
more abundant in collections and more widely
distributed geographically, occurring circumtropi-
cally, than are the species of Ecsenius, but no species
of Entomacrodus has been taken in the Red Sea
or Persian Gulf. I collected only one specimen of
Entomacrodus (E. thalassinus) at One Tree Island,
Great Barrier Reef, whereas I collected hundreds
10
of specimens of the three species of Ecsenius occur-
ring there. I collected seven species of Entromacro-
dus and four species of Ecsenius in Taiwan, and
none were very abundant.
The overall geographic picture presented by the
two genera has two parallels and several differences.
Indian Ocean-Pacific Ocean species pairs are present
in both genera: Ecsenius nalolo-E. yaeyamaensis,
Entomacrodus epalzeocheilus-E. niuafoouensis, En-
tomacrodus vermiculatus-E. decussatus. Two species
of Entomacrodus, E. sealei and E. cymatobiotus, do
not occur west of the andesite line and one species,
E. stellifer, does not occur east of it. The wide-
spread species of Entomacrodus are more wide-
spread than those of Ecsenius, and Entomacrodus
is circumtropical. This may be the result of the
pelagic ophioblennius larva characteristic of Ento-
macrodus. The larvae of Ecsenius have not been
collected in the field and nothing is known of their
behavior. Entomacrodus has eight island endemic
species (22 species in the genus), whereas Ecsenius
has only one or two (18 species in the genus), and
these may be found to be more widespread when
more collections are available. Two species of
Entomacrodus have recognizable South China Sea
subspecies, but none of the species of Ecsenius are
so represented (there are few specimens of Ecsenius
from that area). Springer (1967) noted that several
species of Entomacrodus were peripherally distrib-
uted in the tropical western and central Pacific;
only Ecsenius mandibularis is so limited in its
distribution. Entomacrodus occurs in Hawaii where
SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
Ecsenius has been reported only once, under pe-
culiar circumstances.
It would seem that the distributional pattern
differences shown by the two genera are probably
the result of their different ecological preferences
and early life history. But these facts alone are
insufficient to explain, on the surface, at least, why
Entomacrodus does not occur in the Red Sea or
Arabian Sea and Persian Gulf. Its absence from the
latter two areas could be an artifact of collecting,
but seems unlikely in view of the fact that many
collections have been made in those areas and that
Entomacrodus is an easier genus to obtain than
Ecsenius where the two co-occur generally. The
absences of Entomacrodus from the Red Sea and
Ecsenius from Hawaii seem real as there has been
a great collecting effort made in those areas in
recent years.
Because they are more difficult to obtain, I feel
certain that the ranges of the species and the
number of species of Ecsenius reported on here
will increase significantly in the course of a few
years. I believe this, in part, because Ecsenius
species frequently occur at greater depths than
have usually been collected in the past; there has
been relatively little collecting at depths over three
meters along the coasts of the Indo-Pacific. On the
other hand, I do not feel that there are many, if
any, species of the shallow-dwelling genus Ento-
macrodus yet undiscovered, and the ranges of only
a few of those known will increase to any significant
degree with more collecting.
Key to the Subgenera and Species of Ecsenius
1. Anterior canines in lower jaw obvious, more than twice size of adjacent incisoriform teeth;
total incisoriform teeth -)- anterior canines in lower jaw 13-16; total teeth in upper jaw
26-34; caudal forked (Figure 12); mid-predorsal pore of supratemporal series in advance
of level of posterior orbital margin; pseudobranchial filaments 6-12; dorsal -f ventral
procurrent caudal rays 18-20; epipleural ribs 22-25; postcleithra consisting of two well-
separated ossifications, dorsalmost much reduced (subgenus Anthiiblennius)
tnidas (Red Sea, Indian Ocean, eastern Australia)
Anterior canines in lower jaw rarely obvious, when obvious only slightly larger than adjacent
incisoriform teeth; total incisoriform teeth + anterior canines in lower jaw 30-64; total
teeth in upper jaw 97-148; caudal not forked, but often with produced rays on dorsal and
ventral lobes (for instance, Figures 15, 19, 20); mid-predorsal pore of supratemporal series
well posterior to level of posterior orbital margin; pseudobranchial filaments 5-8 (rarely
8); dorsal -f. ventral procurrent rays 10-18; epipleural ribs 11-17; postcleithra consisting
of two subequal articulating ossifications (subgenus Ecsenius) 2
2. Total posterior canines in lower jaw 7-15 (2-8 on each side)
mandibularis (eastern Australia)
Total posterior canines in lower jaw 0-3 (usually 1 on each side) 3
NUMBER 72
3. Segmented dorsal rays 12-15; segmented anal rays 13-17; vertebrae 29-33 4
Segmented dorsal rays 15-20 (only 2 of 252 specimens of bicolor with 15); segmented anal
rays 17-23 (only 1 of 258 specimens of bicolor with 17); vertebrae 33-39 (2 of 4 specimens
of stigmatura and 9 of 234 specimens of bicolor with 33) 11
4. Dark spot extending well anteriorly from anus (Figure 26); dorsal fin notched three-ninths
to five-ninths length of first dorsal ray; last dorsal spine 6 to 10 percent SL; incisoriform
teeth in lower jaw 30-37; segmented anal rays 13-14; caudal vertebrae 19-20; total verte-
brae 29-30 lividinalis (Pacific)
No dark spot extending anteriorly from anus (occasionally black lining of gut protrudes
slightly through anus giving appearance of dark ring); dorsal fin notched seven-ninths
to nine-ninths length of first dorsal ray; last dorsal spine 0.4-3.1 percent SL (one specimen
of 35 of E. oculus had length 4.6 percent); incisoriform teeth in lower jaw 41-64; seg-
mented anal rays 14-17 (1 of 42 specimens of opsifrontalis with 14); caudal vertebrae
21-23; total vertebrae 31-33 5
5. Two large, distinct dark spots at caudal base extending posteriorly well out on caudal fin
(Figure 31) oculus (Pacific)
Dark spots, if present at caudal base, small, scarcely encroaching on caudal fin 6
6. Distinct dark stripe, stripes, or spots present on fleshy pectoral base (Figures 27-30); pseudo-
branchial filaments 5-8 (rarely 5) 7
Fleshy pectoral base not noticeably marked; pseudobranchial filaments 5-6 8
7. Fleshy pectoral base with at least a forked dark stripe, the arms of which extend pos-
teriorly yaeyamaensis (Pacific)
Fleshy pectoral base with an unforked dark stripe (and usually other dark marks)
nalolo (Indian Ocean; Red Sea)
8. Lateral line extending posteriorly to below level of llth-12th (usually 12th) dorsal spine;
segmented dorsal rays 13-14 (14 in only 6 of 42 specimens); segmented anal rays 14 to
16 (usually 15); nasal cirrus 2.3-5.9 percent SL opsifrontalis (Pacific)
Lateral line extending posteriorly to below level of 8th-9th dorsal spine; segmented dorsal
rays 14; segmented anal rays 15-16 (usually 16); nasal cirrus 1.1-2.3 percent SL 9
9. Two large dark spots on side of body in area covered by appressed pectoral fin (Figure 34)
bimaculatus (Pacific)
Body without large dark spots 10
10. Side of body with alternating dark and pale longitudinal stripes (Figure 33)
prooculis (Pacific)
Side of body without distinct marks (Figure 35) bandanus (Pacific)
11. Dark spot extending anteriorly from anus (Figures 24-25); dark stripe originating at ventral
margin of orbit extending posteriorly across head atigmatura (Pacific)
No dark spot in region of anus; dark stripe extending posteriorly across head, if present,
originating at mid-postorbital level 12
12. Anterior nostril with cirri on both anterior and posterior margins; segmented caudal rays
14 (rarely 13); lateral line usually with several vertical pairs of pores beginning ante-
riorly IS
Anterior nostril with cirrus on posterior margin only; segmented caudal rays 13 (rarely 14
in E. frontalis and in some juveniles of other species under 25 mm SL); lateral line of
simple pores only (rarely with a vertical pair at origin) 14
13. Dorsal rays 15-18; dorsal fin notched two-ninths to seven-ninths length of first dorsal ray
(usually four-ninths or more); last dorsal spine 2.5-6.9 percent SL; lateral line with ver-
tical pairs of pores for one-third to all its length (rarely less than one-half); a dark spot
on paler background on anterior dorsal fin; pseudobranchial filaments usually 6; upper
nasal cirrus length usually more than 4.9 percent SL. bicolor (Pacific and Indian Oceans)
Dorsal rays 18-20 (rarely 18); dorsal fin unnotched; last dorsal spine 11.0-15.9 percent SL;
lateral line with vertical pairs of pores, if present, rarely occupying more than anterior
two-fifths its length; dorsal fin entirely black, occasionally with some obscure longitudinal
stripes anteriorly; pseudobranchial filaments usually 7; upper nasal cirrus length not
more than 4.8 percent SL namiyei (Pacific)
14. Dorsal fin without a notch; last dorsal spine 10.7-20.8 percent SL; pectoral rays 14-16 (14
in 5 or 89 specimens) frontalit (Red Sea;
Gulf of Tadjourah; see discussion under species account for distinct color pattern forms.)
12 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
Dorsal fin with a notch; last dorsal spine 2.2-7.0 percent SL; pectoral rays 13-15 (15 in 5
of 87 specimens) ^
15. Dorsal spines 12; pectoral rays 13 (14 in 1 of 12 specimens); body at about midlevel with a
longitudinal dark stripe, either continuous or as a series of dark bars, extending length
of body and entering caudal fin basally lineatus (Pacific and Indian Oceans)
Dorsal spines 12-14 (12 in 9 of 201 specimens); pectoral rays 13-15 (13 in 2 of 176 speci-
mens) ; body without a broad dark stripe (occasionally with a slender stripe on dorsal
fourth of body, ceasing well anterior to caudal base) 16
16. Mid-distal half of at least spinous dorsal fin black or with black spots in interradial mem-
brane; dorsal and ventral lobes of caudal fin darker than remainder; usually several small
dark spots on posterior third of body; usually a narrow, black longitudinal stripe on
dorsoanterior portion of body gravieri (Red Sea; Bay of Tadjourah)
Mid-distal half of dorsal fin not noticeably marked; dorsal and ventral lobes of caudal not
darker than remainder of caudal; no black spots or longitudinal stripes on body (body
uniformly dark, with a dark spot at caudal base, or with posterior half pale with irregular,
vertical dark bars) 17
17. Dorsal rays 17 or 18; anal rays 19 or 20; nasal cirrus 1.0-3.9 percent SL; dorsal fin notched
seven-ninths to nine-ninths (usually eight-ninths) length of first dorsal ray, body uni-
formly dark with a darker spot at caudal base E. aroni (Red Sea)
Dorsal rays 18-20; anal rays 19-23 (rarely 19 or 20); nasal cirrus 3.0-7.9 percent SL; dorsal
fin notched five-ninths to eight-ninths (rarely eight-ninths) length of first dorsal ray;
body uniformly dark or posterior half pale with vertical dark bars
E. pulcher (Persian Gulf and northern Arabian Sea)
The Species Groups of Ecsenius
The 18 species of Ecsenius fall into eight groups.
Four of these groups are monotypic, E. midas, E.
frontalis, E. lineatus, and E. mandibularis, and with
the exception of E. lineatus, I hesitate to relate
them closely to each other or to any other group.
E. lineatus may be an offshoot of the yaeyamaensis
group.
Ecsenius midas, as the monotypic member of the
subgenus Anthiiblennius, is well differentiated (see
key, couplet 1). It is also the most specialized of
the species of the genus as evidenced by its extreme
reduction in number of teeth, the increased size of
the anterior canines, the reduced nature of the
postcleithra, and the great anterior displacement
of its dorsal fin origin. E. frontalis has an unnotched
dorsal fin and the highest pectoral ray counts in
the genus. The albicaudatus form of E. frontalis
(see discussion of color pattern under species ac-
count) is reminiscent of that found in E. bicolor
and E. namiyei. E. frontalis is separated from the
latter two species, however, in having only a single
nasal cirrus, 13 segmented caudal rays, and no
paired lateral line pores. E. lineatus has no note-
worthy peculiarities as found in many of the other
species. Its general robustness, relatively high fin
ray and vertebral counts, large size attained, and
moderately notched dorsal fin separate it from the
yaeyamaensis species group, to which it otherwise
might belong. E. mandibularis is unique in its large
numbers of posterior canine teeth and long third
dorsal spine and fifth dorsal ray lengths. In addi-
tion, males of E. mandibularis develop prolonga-
tions of all the caudal rays, which in the other
species are primarily restricted to the upper and
lower extremities of the fin.
The pulcher species group comprises E. pulcher,
E. gravieri, and E. aroni. These three species are
morphologically quite similar and differ from each
other primarily in color pattern, depth of the
dorsal fin notch, development of caudal fin lobes,
and the slightly higher meristics of E. pulcher.
They share the pecularity of having typically 14
pectoral rays (otherwise found typically only in
E. stigmatura), and with E. midas and E. frontalis
are the only species with typically 11 precaudal
vertebrae.
The bicolor species group comprises E. bicolor
and E. namiyei, which are distinct from all other
Ecsenius species in having nasal cirri on both the
anterior and posterior margins of the anterior
nostril and paired pores in the lateral line. They
both have typically 14 segmented caudal rays.
The stigmatura species group comprises E. stig-
matura and E. lividinalis. The Bornean specimen
allocated to E. stigmatura may be recognizable as
NUMBER 72 13
a separate species when more specimens are known.
The two species are united here in having a black
spot in the anal region (found otherwise only in
E. midas) and typically 14 segmented caudal rays,
but are considerably different in other characters.
E. lividinalis has the lowest tooth, dorsal and anal
fin and vertebral counts, and the highest fin ray
proportions (as percent SL) in the subgenus
Ecsenius. The relationship of E. lividinalis with
E. pulcher is questionable and possibly each should
be placed in its own group.
The yaeyamaensis species group comprises E.
yaeyamaensis, E. nalolo, E. oculus, E. opsifrontalis,
E. prooculis, E. bimaculatus, and E. bandanus. This
group comprises the more or less nondescript, small
species with relatively deep dorsal fin notches and,
for the most part, low vertebral and vertical fin
ray counts. Within this group, there are three sub-
groups comprising the first two, second two, and
last three species listed. The subgroups are dis-
tinguished from each other on color pattern and
slight meristic or proportional differences. Each
group presents certain problems.
The two species of the yaeyamaensis subgroup
might, by some systematists, be considered to com-
prise a single species. The two species I recognize
are completely differentiated by a color marking
(key couplet 7) and occur in different oceans (Figure
2). In the Pacific Ocean there are also easily recog-
nizable color pattern populations of one species. If
the two species were combined the problem of what
to do with these recognizable populations would
remain, as the situation would then exist of having
two recognizable taxa differing in color pattern
with at least one of these taxa also having popula-
tions completely recognizable on the basis of color
pattern (see color pattern description under E.
yaeyamaensis species account).
The two species of the oculus subgroup are dis-
tinguished from each other on the basis of color
pattern and the slightly lower meristics of one
species. The two species occupy essentially allopatric
ranges (Figures 2 and 3). There are indications that
some recognizable populations of E. oculus may
occur (see under species account).
The three species of the prooculis subgroup are
known from 5, 3, and 1 specimens, all males. These
species are distinguished from each other only by
their strikingly different color patterns. They have
not been collected from the same locality (Figure 4).
Whether the three species comprise one highly
variable species will require much more material
than is available.
Species Accounts
Ecsenius (Anthiihlennius) midas Starck
FlCURE 12
Ecsenius (Anthiiblennius) midas Starck, 1969, p. 1 [D'Arros
Island, Amirante Islands].
DESCRIPTION.?Dorsal spines 13-14 (usually 13);
dorsal rays 19-21; segmented anal rays 20-23; pec-
toral rays 13 (12 on one side only of one specimen);
segmented caudal rays 13-15 (usually 14); dorsal
procurrent caudal rays 9-10; ventral procurrent
caudal rays 9-10; total caudal elements 31-34; gill-
rakers 10-15; pseudobranchial filaments 6-12; lower
incisor teeth 13 to 16; lower jaw posterior canines 1;
total lower jaw posterior canines 2; upper incisor
teeth 26-34; precaudal vertebrae 11; caudal verte-
brae 27-29; total vertebrae 38-40; epipleural ribs
22-25. Lateral line with no paired pores, extending
posteriorly to beneath level of 7th-9th dorsal spine.
Dorsal fin without notch. Third (innermost) pelvic
ray obvious. One cirrus on each anterior nostril.
Color pattern: The Red Sea and Indian Ocean
specimens of this species are generally dusky, dark-
est anteriorly, and paling on the caudal peduncle
of some specimens. The lower side of the head is
darker anteriorly and on some specimens a dusky
stripe occurs on each side proceeding dorsopos-
teriorly from the side of the lower jaw and curving
upward along the membranous margin of the
branch iostegal membrane. A few specimens exhibit
a diffusely dusky stripe beginning just behind the
ventroposterior border of the eye and extending
back across the opercle. One specimen had some
diffuse vertical bands on the body. The most con-
spicuous mark is a dark spot enveloping the anus
and extending anteriorly for a short distance. The
dorsal fin bears a narrow, dark distal stripe begin-
ning anteriorly on the spinous portion and extend-
ing to the anterior dorsal rays. This fin is usually
dark anteriorly, making it difficult or impossible
to count the spines externally. The anal fin is pale
dusky, slightly darker on the spines and, in some
specimens, along its distal edge. The caudal fin
varies from immaculate to evenly dusky with its
dorsal and ventral margins narrowly, darkly pig-
14
\ZO?
SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
?4O? 160*
bandanus
A bimaculatus
# prooculjszo
120 140* 160*
FIGURE 4.?Distribution of certain species of Ecsenius. Irregular broken line indicates approximate
position of andesite line (see zoogeography section).
mented. The pectorals are generally pale with the
rays sometimes narrowly and darkly pigmented.
The pelvics are dusky. The two small Great Barrier
Reef specimens differed from the others most no-
ticeably in having the dorsal fin dusky, but with
the distal portion of the segmented ray part of the
fin unmarked and the edge of the dusky area much
darker than the remainder in the region below the
unmarked part.
Starck (1969) reported the life color to be golden
yellow, darker dorsally except for a fine black
marginal line on the dorsal fin and a black blotch
around the anus. The color of a freshly killed
female (USNM 204550) I collected in the Red Sea
was somewhat different. The head was pale orange-
dusky with a narrow, pale yellow-green stripe
extending posteriorly from the orbit to the opercle
margin. The underside of the head was pale white
except for the dark dusky lower jaw. The sides of
the body were pale purple-dusky overlying orange.
The venter was chartreuse. The dorsal, anal, and
caudal fins were orange-yellow. The pectoral fins
were pale yellow-green.
GEOGRAPHIC VARIATION.?There are too few speci-
mens of E. mi das to draw firm conclusions, but it
appears from the fact that the four Red Sea speci-
mens have 27 caudal vertebrae and the six Indian
Ocean specimens have 28 or 29 caudal vertebrae,
that population differences occur. The two Great
Barrier Reef specimens have 27 and 28 caudal
vertebrae and are thus intermediate between the
specimens from the other two areas.
MATERIAL.?Gulf of Aqaba, Sinai coast, Dahab,
UTAI 4221 (71.2) and USNM 204707 (77.1); Ras
Muhammad, southern tip of Sinai Peninsula,
USNM 204550 (45.1) and 204551 (68.9); Amirantes
Islands, D'Arros Island, ANSP 111148 (74.4, holo-
type of E. midas), 111149 (48.7), 111854 (33.5,
cleared and stained), and USNM 202422 (56.0);
Nicobar Islands, NFIS 9579 (83.1); Nicobar Islands,
Tillanchong, NFIS 9577 (44.4); Australia, Queens-
land, Escape Reef, ANSP 109686 (2:28.5-29.0).
Ecsenius (Ecsenius) frontalis Ehrenberg
FIGURES 13-15
Salarias frontalis Ehrenberg in Cuvier and Valenciennes, 1836,
p. 328 [Massawa, Red Sea].
NUMBER 72 15
Salarias nigrovittatus Ruppell, 1838, p. 136 [Massawa, Red
Sea].
Ecsenius albicaudatus Lotan, 1969, p. 372 [Marsa Murach,
Gulf of Aqaba].
DESCRIPTION.?Dorsal spines 10-13 (rarely 10, 11,
or 13); dorsal rays 17-21 (rarely 17 or 21); seg-
mented anal rays 17-22 (rarely 17, 18, or 22); pec-
toral rays 14-16 (usually 15); segmented caudal
rays 13 (rarely 14); dorsal procurrent caudal rays
6-8; ventral procurrent caudal rays 6-9 (rarely 9);
total caudal elements 25-30 (rarely 25 or 30); gill-
rakers 11-17 (rarely 11, 12, or 17); pseudobranchial
filaments 5-7 (usually 6); lower incisor teeth 40-53;
lower jaw posterior canines 0-1; total lower jaw
posterior canines 0-2 (usually 2); upper incisor
teeth 124-130 (4 counts); precaudal vertebrae 10-12
(rarely 10 or 12); caudal vertebrae 23-26 (rarely
23); total vertebrae 34-37 (rarely 34); epipleural
ribs 11-16 (usually 12-14). Lateral line without
paired pores, extending to below level of 8th-12th
dorsal element (usually 9th-llth). Dorsal fin without
notch (one of several hundred specimens had dorsal
fin notched two-ninths length of first dorsal ray).
Third (innermost) pelvic ray varying from obvious
to not obvious (usually not obvious). One cirrus
on each anterior nostril, each cirrus occasionally
forked.
Color pattern: There are three basic color pat-
terns found in E. frontalis. See discussion following,
concerning the systematic status of these patterns.
The smallest specimen examined was a postlarva,
15.0 mm SL, from the Gulf of Aqaba. It was not
possible to assign this specimen to one of the three
color pattern types. The specimen was pale with
several irregular vertical bands composed of spots.
A few small bright yellow individuals of E. frontalis
were also seen in the Gulf of Aqaba. It may be that
the banded and yellow forms represent the preadult
color of the two color pattern forms found in the
Gulf of Aqaba (more below).
The Problem of Ecsenius frontalis, E. albicauda-
tus, and E. nigrovittatus
Although I have placed E. albicaudatus and E.
nigrovittatus in the synonymy of E. frontalis, I am
uncertain that my action is correct. In the discussion
that follows I treat the three nominal species as
color pattern forms of a single species, E. frontalis,
and present the evidence on which my action is
based.
Ecsenius frontalis and E. nigrovittatus were de-
scribed from Massawa, Ethiopia, and E. albicaudatus
was described from the Gulf of Aqaba, each from
a single specimen. While the types of E. frontalis
and E. nigrovittatus are in poor condition, data
from these types, together with the distinctive color
patterns given in the original descriptions, make
it possible to identify recently collected specimens
from Massawa with both these nominal species.
The holotype of E. albicaudatus is in excellent
condition. Its distinctive color pattern has been
found in numerous recently collected specimens
from near the type locality.
The morphology and meristics of the three nomi-
nal species are very similar, but the species differ
consistently in color pattern. (In Figures 13-15 the
apparent morphological differences exhibited in
these illustrations are individual variations; when
series of each color form are examined complete
morphological overlap is encountered.) I have ob-
served all three color pattern forms alive in their
natural habitat. The frontalis form is generally
brown, darkest anteriorly, grading into yellow-
orange posteriorly, with a bright yellow-orange
caudal fin. The head and body of the albicaudatus
form are black with a narrow area of variable width
at the caudal peduncle completely unmarked and
pale (sometimes the pale area extends onto the
dorsal fin); the caudal fin is immaculate except
for a faint pink tinge observable only in freshly
preserved specimens. The nigrovittatus form is usu-
ally brown with a black stripe on the body bordered
by pale dorsal and ventral margins; the caudal fin
is slightly tinged with orange. Occasional individ-
uals of the nigrovittatus form have yellow-orange
heads.
Two individuals, I believed at the time of capture
to be the frontalis form, were brought to the lab-
oratory alive. When the individuals were placed in
an aquarium there appeared one frontalis form and
one albicaudatus form, which was dark brown with
a yellow-orange caudal?the only albicaudatus form
I have collected with these colors. These and other
individuals of both color pattern forms held in the
aquarium paled considerably after several days,
and it was not possible to tell one form from the
other.
383-026 O - 71 - 2
16
The geographical distributions of the albicau-
datus and frontalis forms are nearly identical
(Figure 5). The frontalis form has been taken
widely in the Gulf of Aqaba, in the southern Gulf
of Suez, widely in the Red Sea and in the Bay of
Tadjoura (Gulf of Aden, just outside the southern
entrance to the Red Sea). The albicaudatus form
has a similar distribution to that of the frontalis
form, but it has not been taken outside of the
Red Sea or in the Gulf of Suez. It was observed by
me in the Gulf of Suez, however. The nigrovittatus
form has been taken only in the southern Red Sea,
on and off the coast of Ethiopia.
FIGURE 5.?Distribution of the three color pattern forms of
Ecsenius frontalis: ?% ? frontalis form, -ft = albicaudatus
form, % ? nigrovittatus form.
SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
I obtained all three forms in the same collection
(poison) from a coral rock outcrop estimated to be
about 3 meters in height and 8-10 meters in cir-
cumference; water depth was about 4 meters. The
specimens in this collection included 55 frontalis
forms, 25 nigrovittatus forms, and 6 albicaudatus
forms. My six collections (all made at depths of
7 meters or less) in Ethiopian waters, where the
frontalis and nigrovittatus forms were always taken
together, yielded three times as many frontalis
forms as nigrovittatus forms, and the frontalis forms
were always more abundant. The six albicaudatus
forms mentioned are the only ones known from
Ethiopian waters.
In the Gulf of Aqaba and Gulf of Suez collec-
tions, where only the frontalis and albicaudatus
forms were seen or taken, the frontalis form was
generally dominant in the shallower waters and
the albicaudatus form was generally dominant in
the deeper waters. The depth of each collection and
the number of specimens of each form taken in the
poison collections that I made in Israeli waters are
listed below. Because the poison spread, it was not
possible to limit collections to a particular depth.
The collections were all made during the day,
July-September 1969.
Frontalis
form
37
3
9
2
0
1
31
8
1
0
9 (seen commonly)
I observed both the frontalis and albicaudatus
forms together and common at depths of about 3-12
meters on the coral reef preserve at Eilat, Israel.
I cannot say whether one form was much more
dominant than the other; my impressions varied
from day to day.
The frontalis and albicaudatus forms were com-
monly observed together in the Gulf of Aqaba,
and the frontalis and nigrovittatus forms were
Approximate
depth
(meters)
0-3
0-18
0-15
0-16
0-7.5
0-105
0-10
0-3.5
9-12
21-27
0-9
Albicaudatus
form
10
11
5
14
3
4
1
1
18
3
one seen
NUMBER 72 17
commonly observed together at Massawa, Ethiopia.
I have not seen all three forms together, although
as noted above, I have collected all three from the
same rock. The three forms inhabit live and dead
coral and are not found over the sandy bottom.
They are frequently out from under cover, on top
of the coral. They dart, but only rarely swim
freely, and then for only a few centimeters. Their
movements are only moderately jerky. They feed
by nipping at the rocky substrate. Gut contents
consist of unidentifiable calcareous granules less
than 0.3 mm in diameter, paniculate organic
matter, ostracods, and foraminifera. I noted no
differences in behavior of the three forms, which
appeared to be identical and different from the
behavior of the other species of Ecsenius that occur
together with them in the same general area. For
instance, E. gravieri spends much of its time swim-
ming freely over sandy bottom, where it feeds by
nipping into the sand; E. nalolo was never seen out
from under cover or swimming freely, and its
22
20 -
movements are very jerky; E. aroni is somewhat
similar in behavior (but not morphology or color
pattern) to E. frontalis, but it usually occurs at
greater depths and spends more time under cover;
E. midas, which was not seen alive, was reported
by Starck (1969) to swim with other fishes and to
feed on plankton.
Certain morphological and meristic characters
are given with frequency distributions in Tables
11 and 12 for each of the three forms for the
different localities where they occur. Examination
of the data indicates the possibility of sexual
dimorphism and also that Israeli specimens of the
color forms have higher numbers of certain meristic
characters than Ethiopian specimens of the same
forms. To determine if the differences noted are
statistically significant it is, therefore, necessary to
test the data for the same forms, sexes separated,
from the two areas, and for different forms from
the same area, sexes separated.
15 -
10
-
?
? E3 "
Q
Q ? ?
? ?
?
?
<O o O
o
**?* e 9*
? ? ? ?
o
1
M
?
?
1
 o
8
?
?
H
?3
?
?
D
D
O
0
O
D
ffl ?
a ?
0
?
i
D
?
? ?
?
O
o
?
1
Israeli frontalis form
Israeli albicaudatus form
Ethiopian frontalis form
Ethiopian albicaudatus form
Ethiopian nigrovittatus form
D
a
?
f ?
? ?
i
female male
? D
m E3
? o
o ?
? ?
D
o
o
1
2 2 30 40
Standard Length mm
50 6 0
FIGURE 6.?Graph showing relationship of last dorsal spine length to standard length in the three
color pattern forms of Ecsenius frontalis.
18 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
Data for specimens of the frontalis form from
Sanganib Reef (Sudan) and the Gulf of Aden and
for specimens of the albicaudatus form from Ethi-
opian waters were not included in the tests because
the numbers of specimens were small and the
localities were well removed from Israel or Ethiopia.
The following significant differences were found:
Israeli frontalis form males and females have
higher average numbers of teeth, segmented dorsal
rays, segmented anal rays, and caudal vertebrae
than Ethiopian frontalis form males and females.
Ethiopian frontalis form males have higher aver-
age numbers of segmented anal rays than Ethiopian
frontalis form females.
Ethiopian frontalis form males have a close to
significantly (p = between .02 and .01) higher aver-
age number of caudal vertebrae than Ethiopian
frontalis form females.
Grouped data (Tables 13 and 14) of proportional
characters also indicate differences among the three
forms. These data were also graphed and the fol-
lowing differences noted:
Israeli frontalis form males have a relatively
longer caudal fin than Israeli frontalis form females
(Figure 10).
Israeli albicaudatus form males have a relatively
longer caudal fin than Israeli albicaudatus form
females (Figure 10).
Israeli frontalis form males have a relatively
longer caudal fin than Ethiopian frontalis form
males (Figure 10).
Ethiopian nigrovittatus form males have a rela-
tively longer caudal fin than Ethiopian nigrovittatus
form females (Figure 9).
Ethiopian nigrovittatus form males have a rela-
tively longer caudal fin than Ethiopian frontalis
form males or females (Figure 9).
Specimens of less than 30 mm SL of the Israeli
frontalis and albicaudatus forms have relatively
longer nasal cirri than specimens of any of the
three Ethiopian forms (Figures 7 and 8).
Specimens of the Israeli frontalis and albicau-
datus forms have a relatively longer last dorsal
spine than any of the three Ethiopian forms
5
10
5
-
-
o
-
?
?
D
-
1
O
o
?
o
.
D8
?
a
a
* ?
?" ? D
?
? *
- 0 "
a
?
?m
1
?
D
#
? ?
0
?
i
0
D *
O
a
 mr
? ?
?
?
Q
D O
?
a
Ethiopian
Ethiopian
Ethiopian
0
? 0
0
? ? o
?
a
frontalis form
albicaudatus form
nigrovittatus form
o
0
o
m
I 0
?
o
f t m a l t
?
*
?
o
o
0
o
? o
mal*
o
*
a
o
20 30 40
Standard Length mm
50 60
FIGURE 7.?Graph showing relationship of nasal cirrus length to standard length in the three-
color pattern forms of Ecsenius frontalis from Ethiopian coastal waters.
NUMBER 72 19
(Figure 6). The same relationship exists between
the relative lengths of the third dorsal spine and
fifth dorsal ray of the Israeli frontalis and albicau-
datus forms compared with the lengths of these
elements for the three Ethiopian forms (study
graphs).
There is some indication that Israeli frontalis
form males have a relatively longer caudal fin than
Israeli albicaudatus males (Figure 10).
Aside from the fact that there are differences
between the Israeli and Ethiopian populations of
the frontalis form, the above data provide only
limited support for the concept that the three color
pattern forms are different species: The nigro-
vittatus form exhibits sexual dimorphism in the
length of the caudal fin, which the sympatric
frontalis form does not (but the allopatric Israeli
frontalis form does); nigrovittatus form males have
a longer caudal fin than sympatric males of the
Ethiopian frontalis form (but not longer than the
allopatric Israeli frontalis and albicaudatus form
males), and possibly the Israeli frontalis form males
have longer caudal fins than Israeli albicaudatus
form males. (This does not seem to be true of
Ethiopian frontalis form males versus Ethiopian
albicaudatus form males even though there are
only a few specimens of the latter.)
The fact that the Gulf of Aqaba populations of
the frontalis and albicaudatus color pattern forms
have higher average numbers of each meristic char-
acter than their Ethiopian counterparts is probably
due to the cooler water temperatures of the Gulf
of Aqaba relative to those of the Ethiopian coast
(Oren, 1962). The same type variation has been
reported for other Gulf of Aqaba-Red Sea blenniids
(Smith-Vaniz and Springer, in press).
There is, then, no consistent basis other than
color pattern on which to recognize E. frontalis and
E. albicaudatus as separate species. One might
recognize E. nigrovittatus as a separate species,
based on the small differences noted and the fact
that it does not occur at the northern end of the
Red Sea (Gulf of Aqaba).
There are other data that influence the recogni-
tion of the three forms as one species. There are
no other species of Ecsenius that appear to be
closely related to the three forms and speciation,
if such occurred, would seem of necessity to have
taken place in the Red Sea. The Red Sea is a
relatively small body of water with a limited amount
of coral reef habitat. It is difficult to postulate how
three species so similar as the three color pattern
forms could have evolved sympatrically, especially
when there does not appear to be a difference in
feeding habits or microhabitat preference.
There are other species of Ecsenius that have
apparently evolved different color pattern forms
that occur sympatrically. These forms are, however,
more obviously derivative of the same basic form
than are the Red Sea color pattern forms of E.
frontalis. Ecsenius pulcher has a solid color form
and one in which the melanophores have been
suppressed in portions of the posterior region of
the body, thus forming vertical dark and pale
stripes (Figure 16). This form is somewhat similar
to the albicaudatus form in which the melanophores
on the caudal peduncle have been suppressed.
Ecsenius bicolor has three basic color pattern forms:
one that is completely dark, one that is paler
(either gradually or abruptly, Figures 20 and 21),
and one that has a diffuse, dark stripe on its side.
Although these three forms duplicate the forms
found in Ecsenius frontalis, they generally are not
so strikingly different from each other, and the
striped form is very rare. The life colors of the
three E. bicolor forms are very much the same as
opposed to the differences noted in the frontalis
forms. It seems, therefore, that the tendency for
species of Ecsenius to exhibit different color pattern
forms is a trait of the genus.
Information on breeding behavior and the color
patterns of the offspring are necessary for reaching
a final solution to the problem of the taxonomic
level that should be accorded the three color pattern
forms of E. frontalis.
I know of no situation involving fishes that is
exactly comparable with that reported here for E.
frontalis. Although only slightly similar, the cir-
cumstances Stephens (1963) reported for Acanthem-
blemaria crockeri Beebe and Tee-Van (Chaenop-
sidae) is of interest. A. crockeri is represented by
two color pattern forms in the Gulf of California,
the only area where the species occurs. Only one
form was found in the northern end of the Gulf,
and its relative abundance gradually decreased
toward the south until it was not found to occur
in the southern end of the Gulf. The other form
was the only one at the southern end of the Gulf
and it decreased in relative abundance toward the
northern end of the Gulf. The two forms occurred
20
together in the midportion of the Gulf. Stephens
was unable to explain the basis for these circum-
stances. The situation is somewhat paralleled by
two of the E. frontalis color forms. The albicaudatus
form is abundant at the northern end of the Red
Sea (Gulf of Aqaba) and rare at the southern end.
The nigrovittatus form is common at the southern
end of the Red Sea but absent from the northern
end. I hesitate to place much emphasis on these
similarities.
MATERIAL (localities abbreviated).?Gulf of
Aqaba: USNM 204535 (3 albicaudatus, 25.4-30.5),
USNM 204536 (3 albicaudatus, 19.8-24.2; 1 post
larva, 15.5), USNM 204685 (1 albicaudatus, 51.6;
8 frontalis, 29.2-44.8), USNM 204684 (9 albicau-
datus, 18.0-44.4; 37 frontalis, 16.8-43.7), USNM
204534 (18 albicaudatus, 16.6-36.1; 1 frontalis, 36.7),
USNM 204650 (11 albicaudatus, 18.0-37.7; 3 fron-
talis, 18.7-48.4), USNM 204533 (14 albicaudatus,
19.5-37.5; 2 frontalis, 19.5-21.7), HUI HUJ-F-3540
(holotype of E. albicaudatus, 43.0), HUI E-60/96.16
(albicaudatus, 46.9), HUI HUJ-F-4375 (2 albicau-
datus, 19.1-21.4), HUI HUJ-F-3544 (2 frontalis,
40.2-42.1), HUI E-64/34 (4 frontalis, 32.0-41.0),
HUI E-64/3013 (frontalis, 40.0), UTAI NS-3582
(albicaudatus, 43.8); Gulf of Suez, Et Tor: USNM
204651 (9 frontalis, 29.5-44.7); Egypt, Strait of
Jubal: USNM 200613 (1 albicaudatus, 50.5; 6 fron-
talis, including one cleared and stained, 23.9-58.6);
Egypt, Al Ghardaqa: NFIS 5118 (frontalis, 43.9);
Sudan, Sanganeb Reef: NFIS 8236 (3 frontalis,
40.6-47.4); Ethiopia, Massawa: ISZZ 1947 (5 dam-
aged syntypes of Salarias frontalis), NFIS 1680
(holotype of Salarias nigrovittatus, 29.0), USNM
204517 (4 nigrovittatus, 24.2-36.0; 8 frontalis, 21.2-
34.6); Ethiopia, Harat Island: USNM 204490 (6
albicaudatus, 29.2-46.5; 25 nigrovittatus, 20.4-48.3;
55 frontalis, 21.9-61.4); Ethiopia, Dahlak Islands:
HUI E-62/424A (21 frontalis, 16.3-47.3), HUI
E-62/1280 (2 nigrovittatus, 32.5-34.2), HUI E-62/
428 (2 nigrovittatus, 18.9-40.2), HUI E62/604
(nigrovittatus, 39.2), HUI E-62/3678A (nigro-
vittatus, 39.5), HUI E-62/1280A (8 frontalis, 30.8-
48.3), HUI E-62/417H (18 nigrovittatus, 16.7-38.5),
NFIS 8757 (7 nigrovittatus, 23.8-44.0); Ethiopia,
Zubair Island: HUI HUJ-F-4628 (4 frontalis 29.4-
35.0); Gulf of Aden, Bay of Djibouti, French Somali-
land: MNHN 04-318 (3 frontalis, 37.8-47.3).
Numerous other uncataloged specimens from the
SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
Gulf of Aqaba and Ethiopia in the USNM collec-
tions were examined in order to obtain data on
frequencies of occurrence of the color pattern forms.
In Ethiopian waters, the following localities for
this material are as follows: Isola Delemme (35?54'E,
15?30.5'N), Sciumma Island (40? 0 0 W E; 15?32'
31"N); Melita Bay (39?49'E; 15?15'N); Difnein
Island (39?20'E, 16?36'N). The frontalis and nigro-
vittatus forms were present in all these collections.
Ecsenius (Ecsenius) pulcher (Murray)
FIGURE 16
Salarias pulcher Murray, 1887, p. 23 [Manora Rocks, Karachi].
Salarias phntasticus Boulenger, 1897, p. 422 [Mekran Coast,
Persia].
Salarias anomalus Regan, 1905, p. 327 [Mekran Coast, Persian
Gulf].
DESCRIPTION.?Dorsal spines 12-14 (usually 13);
dorsal rays 18-20; segmented anal rays 19-23 (usu-
ally 21-22); pectoral rays 14-15 (usually 14); seg-
mented caudal rays 13 (rarely 14 in specimens over
25 mm SL; when 14, lowermost ray has only one
segmental line); dorsal procurrent caudal rays 7-8;
ventral procurrent caudal rays 5-8 (usually 7-8);
total caudal elements 26-29 (rarely 26); gill-rakers
13-17 (usually 14-15); pseudobranchial filaments
6-7; lower incisor teeth 44-53; lower jaw posterior
canines 0-1 (rarely 0); total lower jaw posterior
canines 0-2 (usually 2); upper incisor teeth 107-116
(three counts); precaudal vertebrae 11, caudal verte-
brae 26-28; total vertebrae 37-39; epipleural ribs
13-14. Lateral line with no paired pores, extending
to below level of 8th to 12th dorsal spine (usually
9th or 10th). Dorsal fin notched five-ninths to eight-
ninths (rarely eight-ninths) length first dorsal ray.
Third (innermost) pelvic ray varying from not
obvious to obvious (usually not obvious). One cirrus
on each anterior nostril, rarely forked.
Color pattern: There are two basic color patterns
found in adult and young adult specimens. These
two patterns are so strikingly different as to have
been the basis for species descriptions, and the
uninformed worker sorts collections containing both
types into different lots. Chapman and Schultz (1952)
believed that the two color patterns were sex linked,
but I find that both sexes exhibit both types of
color pattern.
NUMBER 72 21
The most common color pattern, based on mu-
seum specimens, is that in which the head and
body are uniformly dark or dusky brown. Occasional
specimens of this form are paler posteriorly on the
body. A marking slightly darker than the ground
color frequently occurs behind the eye. The under-
side of the head may also be slightly darker
anteriorly.
In the other color pattern (Figure 8) the head
and anterior half of the body are similar to that
of the form described above, but the posterior half
of the body bears separated pigmentless areas setting
off dark vertical bars of different sizes and intensi-
ties. The number of dark bars ranges from 5 to 8
on each side of the body. The smallest specimen
exhibiting this pattern was 32.9 mm SL.
Below about 20 mm SL, specimens may be uni-
formly dark or bear 7 or 8 pairs of diffuse vertical
bands on each side and irregular dark marks on
the head. Both uniform and banded small speci-
mens occurred in the same collections.
In both adult type color patterns the spinous
dorsal bears a dusky stripe basally and an immacu-
late area distally. The dusky stripe extends onto
the soft dorsal where it becomes separated into a
darker area suprabasally and a paler area basally.
The distal portion of the rayed dorsal is mostly
unmarked. The anal fin is uniformly pale dusky.
The other fins are variably marked with immaculate
and pale dusky areas.
A color photograph of a living specimen of E.
pulcher, barred form, appears in Axelrod and
Emmens (1969).
NOMENCLATURE.?Salarias phntasticus was not
compared with any other species. I have examined
the two syntypes and find them to be the striped
form of E. pulcher. (An obvious typographical
error is involved in the specific epithet and the
name is usually spelled phantasticus.)
Salarias anomalus was not compared with any
other species. I have examined the syntypes and
find them to be the uniformly dark form of E.
pulcher.
MATERIAL (localities abbreviated).?Persian Gulf:
USNM 201572 (36.5, cleared and stained), 201571
1 O
10
5
-
*
?
?
-
-
-
1
*
?
?
o
*
0
0
?
*
*
* *
*
?
0
Q O
I
*
* *
?
*
0
?
?
o
?
*
?
?
t
m
o
a*
m
0
*
*
 a
*
*
o eoo o
en
D
Ethiopian
Israeli
Israeli
D
? 0
*
o
? o
frontalis
frontalis
form
form
albicaudatus form
0
o
o
m
o
1
female
?
?
*
o
o
o
o
0
 0
?
male
o
D
*
o
D
20 30 40
Standard Length mm
50 60
FIGURE 8.?Graph showing relationship of nasal cirrus length to standard length in the two
color pattern forms of Ecsenius frontalis from Israeli coastal waters and one of these forms from
Ethiopian coastal waters.
22 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
(32.9), 196505 (2: 42.2-52.1), 196506 (52.3), BMNH
1900.5.9.47-56 (16: 31.4-46.3, syntypes of Salaries
anomalus), 1898.6.29.163 (57.4), 1932.2.18.43 (39.7);
Gulf of Oman: BMNH 1912.11.26.1 (51.2), 1899.5.
8.94 (2: 28.7-34.0); Mekran Coast, Persia: BMNH
1897.9.22.20-21 (2: 54.5-57.9, syntypes of Salarias
phntasticus); Karachi, Pakistan: BMNH 1887.9.22.
59-60 (2: 44.3-44.5, syntypes of Salarias pulcher),
USNM 201867 (3: 38.9-58.0), 201816 (48.3), NFIS
8239 (37.3); Rupan Coast, India; FMRI uncata-
loged (4: 18.4-30.6, in two lots); Gulf of Kutch,
India: USNM 201863 (16.6); India: NFIS 5120 (9:
21.7-54.6).
Ecsenius (Ecsenius) gravieri (Pellegrin)
FIGURES 17, 18
Salarias gravieri Pellegrin, 1906, p. 5 [Bay of Tadjourah].
Ecsenius klausewitzi Lotan, 1969, p. 371 [Entedebir, Dahlak
Archipelago].
DESCRIPTION.?Dorsal spines 12-14 (usually 13);
dorsal rays 16-19 (rarely 16 or 19); segmented anal
rays 18-21 (rarely 18 or 21); pectoral rays 13-15
(rarely 13); segmented caudal rays 13; dorsal pro-
current caudal rays 7-9 (usually 8); ventral pro-
current caudal rays 7-9 (usually 8); total caudal
elements 27-31; gill rakers 12-16; pseudobranchial
filaments 6-8 (rarely 8); lower incisor teeth 44-54;
3 8
3 5
3 0
25
20 -
female
Ethiopian frontoli* form
Ethiopian albicaudatus form
Ethiopian nigrovittotus form
male
O
a
* ?
a
? ? o ^ o
?
o ?
D
20 30 4 0
Standard Length mm
50 60
FIGURE 9.-Graph showing relationship of longest caudal ray length to standard length in the three
color pattern forms of Ecsenius frontalis from Ethiopian coastal waters.
NUMBER 72 23
lower jaw posterior canines 0-1; total lower jaw
posterior canines 0-2 (usually 2); precaudal verte-
brae 10-11 (rarely 10); caudal vertebrae 24-26
(rarely 24); total vertebrae 35-37 (rarely 35); epi-
pleural ribs 12-15. Lateral line with no paired
pores, extending posteriorly to below level of 8th
to 10th (rarely 8th) dorsal spine. Dorsal fin notched
two-ninths to six-ninths length of first dorsal ray.
Third (innermost) pelvic ray not obvious in speci-
mens over 25 mm SL. One cirrus on each anterior
nostril.
Color pattern: This is a distinctively marked
species. In Gulf of Aqaba, Gulf of Suez, and north-
ern Red Sea specimens, 17.5-60.8 mm SL, the head
is relatively dark with the intensity of the pigment
decreasing gradually on the body and becoming
quite pale posteriorly. At about the midposterior
margin of the orbit of most specimens there is a
dark stripe, or diffuse evidence of one, that extends
posteriorly across the head, darkens greatly on the
body, and usually extends to below at least the
middle of the spinous dorsal fin, but terminates
anterior to the caudal peduncle. At its termination
the stripe continues as a row of variably spaced
dark spots to the base of the dorsal caudal rays.
There are also a variable number of dark spots
posteriorly on the body. In a few specimens the
dark stripe or the spots (but not both) may be
absent.
The spinous dorsal fin bears a jet black row of
dark spots, restricted mostly to the interspinous fin
membranes. These spots decrease in size and in-
tensity posteriorly and may extend onto the inter-
radial membrane of the rayed dorsal for a varying
distance. There is no pigment distally on the rayed
dorsal or anal fins. The upper and lower lobes of
the caudal are dusky.
Specimens from the southern Red Sea and the
Bay of Tadjourah, outside the entrance to the Red
Sea, differ from those described above in having
the dark pigment generally blacker and covering
more area. The stripe on the body may be almost
completely obscured anteriorly by the surrounding
body pigment, but the stripe is absent in the holo-
type (see Smith, 1959, fig. 12, for an illustration of
the holotype). In addition, some specimens exhibit
dark pigment at the tips of some of the dorsal and
anal rays. Specimens from the northern and south-
ern Red Sea (including the Bay of Tadjourah, type
locality) are easily distinguishable (Figures 17 and
18). I do not believe that the northern populations
merit nomenclatural distinction, however, as there
is a good possibility that the two forms gradually
merge somewhere in the midportion of the Red Sea.
There are no specimens available from the approxi-
mately 1500 km between the southernmost collec-
tions of the northern form and the northernmost
collections of the southern form.
The two types of color pattern described here
are paralleled in the unrelated blenniid genus
Meiacanthus, which co-occurs with E. gravieri (see
discussion of mimicry on page 6).
In life, E. gravieri is generally slate blue anteriorly
grading into pale yellow posteriorly. The black
markings are black.
REMARKS (see also discussion under E. aroni).?In
the northern Red Sea and Gulf of Aqaba, E. gravieri
occurs commonly in depths of 2 to 10 meters, but
is rarely seen at greater depths. The species is fre-
quently seen swimming freely, but such activity is
punctuated by long periods of rest on the bottom.
E. gravieri is apparently territorial and during
several periods of observation, individuals were
noticed to have a few favorite perching spots. An
individual might leave one of these spots and swim
around, up to about 5 meters distance from such
a spot, but it always returned to one of the favored
spots to perch.
Klausewitz (1960) illustrated E. gravieri but iden-
tified the specimen as E. nigrovittatus, a synonym
of ?. frontalis.
Lotan (1969) compared E. klausewitzi with E.
gravieri, differentiating E. klausewitzi by its having
a black line on the body, which the holotype of
E. gravieri lacked. The presence or absence of such
a dark line is variable, as noted in the color pattern
description above. The holotype of E. klausewitzi
is a small specimen of the southern Red Sea dark
form of E. gravieri.
MATERIAL (localities abbreviated).?(Pale form)
Gulf of Aqaba: UTAI NS-3580 (3: 20.4-48.1), HUI
HUJ-F-4382 (38.6), HUJ-F-4377 (2: 20.4-21.0),
E-64/30A (2: 20.0-32.4), USNM 204542 (9: 32.1-
55.9), 204555 (15: 19.3-33.2), 204546 (9: 17.5-23.3),
204544 (22: 20.2-52.7), 204543 (3: 19.5-60.8); Ras
Muhammad, southern tip of Sinai Peninsula, Red
Sea: USNM 204545 (9: 27.8-44.1), 204547 (2: 27.8-
41.3); Et Tur, Sinai Peninsula, Gulf of Suez: USNM
204548 (3: 50.1-54.7); Al Ghardaqa, Egypt, northern
Red Sea: NFIS 5122-23 (2: 29.6-34.6).
24 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
3 8
35
30 -
25 -
20 -
?
* * *
D
 . * "J 9
* ? C
? *
 
?
m
" i
c
o ?
o
?*? *
>
?
1
?
?
*
?
*
a
a
M
*
?
a
? ? o
?et'i o
4 ?
? *
D
O
n
o
?
?
?P
D
D
1
O
?
1
Ethiopian
Israeli
Israeli
a
o o
D
D
 D
o o
O
?
o
*
? * o
? *
1
female
frontalis form ?
frontalis form ?
albicaudatus form *
o
?
* o
o
o
* 0
o
o
? ? o
1
male
o
D
*
O
1
2 0 30 4 0
Standard Length mm
50 60
FIGURE 10.?Graph showing relationship of longest caudal ray length to standard length in the
two color pattern forms of Ecsenius frontalis from Israeli coastal waters and one of these forms
from Ethiopian coastal waters.
(Dark form) Dahlak Archipelago, Red Sea: HUI
E-62/3708 15.1, holotype of Ecsenius klausewitzi);
Isola Delemme (15?30.5' N, 39?54' E), Red Sea:
USNM 204479 (56.5); Sheikh el Abu (16?06" N,
39?36.5' E), Red Sea: USNM 204480 (3: 30.5-40.1);
Bay of Tadjourah: MNHN 04-319 (54.2, holotype
of Salarias gravieri).
In addition to the above, a large number of
uncataloged USNM specimens I collected in the
Gulf of Aqaba were examined for color pattern
and ecological data.
Ecsenius (Ecsenius) aroni, new species
FIGURE 19
DESCRIPTION.?Dorsal spines 12-14 (usually 13);
dorsal rays 17-18; segmented anal rays 19-20; pec-
toral rays 13-15 (usually 14); segmented caudal rays
13; dorsal procurrent caudal rays 6-9 (usually 7 or
8); ventral procurrent caudal rays 6-9 (usually 7
or 8); total caudal elements 25-30; gill-rakers 12-15;
pseudobranchial filaments 6-7; lower incisor teeth
46-57; lower jaw posterior canines 0-1; total lower
NUMBER 72 25
jaw posterior canines 0-2 (usually 2); upper incisor
teeth 130-132 (three counts); precaudal vertebrae
10 or 11 (rarely 10); caudal vertebrae 23-26 (rarely
23); total vertebrae 34-37 (rarely 34); epipleural
ribs 11-14. Lateral line with no paired pores, ex-
tending to below level of 8th to 10th dorsal spine
(usually 9th or 10th). Dorsal fin notched six-ninths
to nine-ninths length first dorsal ray. Third (inner-
most) pelvic ray barely or not obvious. One cirrus
on each anterior nostril.
Color pattern: The color pattern of preserved
specimens is not very variable. The head is dark
brown, but pale underneath. The body is generally
dusky brown with a dark spot on the caudal
peduncle that extends well onto the caudal fin.
For most of its length, the dorsal fin bears a narrow
suprabasal dusky stripe, but is otherwise scarcely
marked. The anal fin is generally dusky and in
mature males the tips of the rays are pale. The
other fins are pale or unmarked.
In life the body is generally dark tan with a
black spot with blue overtones at the base of and
on the caudal fin. Some individuals exhibited a
bright orange stripe along the dorsal body contour.
The head and anal fin are dark brown. The other
fins are pale or unmarked.
HABITAT AND DISTRIBUTION.? Ecsenius aroni is
known only from the Red Sea and Gulf of Aqaba
coasts of the Sinai Peninsula. It occurs in coral
areas only and is commonest at depths greater than
10 meters. It was only rarely seen or taken at depths
as shallow as 3 meters. The species was seen (but
not collected) at the nature preserve in Eilat at
depths as great as 36.6 meters, but was not found
at greater depths, down to 45.7 meters (two dives
planned primarily to search for the species). It
prefers the undersides of ledges and pockets in
the reefs and was not seen in the open areas above
or about the reefs.
RELATIONSHIPS.?Ecsenius aroni is closely related
to E. gravieri, with which it generally occurs in
the Gulf of Aqaba, and E. pulcher, which occurs in
the Persian Gulf and northern Arabian Sea. With
these two species it shares the following unique
combination of characters: typically 13 dorsal spines,
a notched dorsal fin, 11 precaudal vertebrae, typi-
cally 14 pectoral rays, and 13 segmented caudal
rays. It differs from these two species primarily in
color pattern, proportions and meristics as indicated
in key couplets 16 and 17. In addition it differs
from the sympatric E. gravieri in that caudal fila-
ments are primarily restricted to males (well devel-
oped in both sexes in E. gravieri), and in males the
longest caudal ray tends to increase in relative
length regularly with increase in standard length
(Figure 11). In general, for either sex, E. aroni has
a relatively shorter caudal than E. gravieri (Figure
11). E. aroni attains a much smaller maximum size
than either E. gravieri or E. pulcher (Figure 11).
E. aroni occurs more commonly in greater depths
than the sympatric E. gravieri, which is usually
found in less than 10 meters depth. The two species
behave quite differently. E. gravieri is an obvious
species on the reef and is frequently seen swimming
above the bottom over open sandy areas closely
adjacent to the reef. E. aroni is secretive and was
seen (rarely) free swimming only within small holes
in the reef.
ETYMOLOGY.?This species is named for Dr. Wil-
liam Aron of the Smithsonian Institution in appre-
ciation for his making possible my field work in the
Red Sea. The results of that work form an invalu-
able contribution to this and other of my studies.
HOLOTYPE.-USNM 204468, male, 36.8 mm SL,
bay at El Himeira, Sinai Peninsula, Gulf of Aqaba.
Depth of collection, to 18 meters. Collected by
V. G. Springer et al., 16 July 1969. Original field
number, VGS 69-2.
PARATYPES (all Sinai Peninsula).-USNM 204690
(12:18.5-40.8), collected with the holotype; USNM
204560 (21:19.4-31.5), 204550 (2:21.4-27.0), 204558
(24.7), all collected in same vicinity as holotype
but on different dates and at different depths;
USNM 204557 (2:21.3-35.4), Marsa Muqabila, Gulf
of Aqaba; USNM 204556 (33.1), bay between Marsa
Mokrakh and El Himeira; USNM 204561 (40.8)
and 204562 (7:25.8-40.5), Ras Muhammad, Red Sea.
Some paratypes will be deposited with the Hebrew
University after publication of this paper.
Ecsenius (Ecsenius) bicolor (Day)
FIGURES 20, 21
Salarias bicolor Day, 1888, p. 798 [Saddle Island, off Kyouk-
phyoo, Arakan, Burma].
Salarias furcatus Johnstone [not of De Vis], 1904, p. 213
[Chilaw Paar, Ceylon].
Salarias burmanicus Hora and Mukerji, 1936, p. 34 [Maung-
magan, Tavoy District, Lower Burma].
Salarias melanosoma Regan, 1909, p. 406 [Christmas Island,
Indian Ocean].
26 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
50
40
30
20
E. aroni
E. gravieri
E. pulcher
*
? it
I *
?
' * *
 #
_
? i i i i i
female male
? o
? *
? D
?
?
?
it ? ?
?
-ir
it
#
O
#o o
o .
?
. 1 1 1 1
?
i i
i
?
it
?
it
O
. I .
?
* *
*
it
* it
it
O D
? C?)
? o
? i i i i i
* * *
?
it
it
it
?
? . I . .
*
?
?
?
?
? ?
* a
. i . . .
?
D
? *
?
?
a
? i . . . . i .
20 30 40
Standard Length mm
50 60
FIGURE 11 .?Graph showing relationship of longest caudal ray length to standard length in spedes
of the E. pulcher species group.
Ecsenius hawaiiensis Chapman and Schultz, 1952, p. 526
[Pearl Harbor, Oahu, Hawaii; a possible introduction from
Guam].
DESCRIPTION.?Dorsal spines 11-12 (rarely 11);
dorsal rays 15-18 (rarely 15); segmented anal rays
17-21 (rarely 17 or 21); pectoral rays 12-14 (rarely
12 or 14); segmented caudal rays 13-14 (rarely 13;
15 in one specimen 20.7 mm. SL); dorsal procurrent
caudal rays 6-9 (rarely 6 or 9); ventral procurrent
caudal rays 6-8; total caudal elements 26-31 (rarely
26 or 31); gill rakers 12-18 (rarely 12 or 18); pseudo-
branchial filaments 5-8 (rarely 5 or 8); lower incisor
teeth 36-46 (one of 243 specimens with 32); lower
jaw posterior canines 0-1; total lower jaw posterior
canines 0-2 (usually 2); upper incisor teeth 114-129
(11 counts); precaudal vertebrae 10 (one specimen
of 233 with 11); caudal vertebrae 23-25; total verte-
brae 33-35; epipleural ribs 12-17 (rarely 12 or 17).
Lateral line with vertically paired pores for one-
quarter to all its length (rarely less than one-half
length), extending posteriorly to beneath level of
10th-13th dorsal fin element (rarely to 13th). Dorsal
fin notched two-ninths to seven-ninths (rarely less
than four-ninths) length first dorsal ray. Third
(innermost) pelvic ray varying from obvious to not
obvious (usually obvious). Two cirri on anterior
nostril, one each arising from anterior and posterior
margins.
NUMBER 72 27
Color pattern: Ecenius bicolor is one of the more
variably pigmented species of Ecsenius. Three of
the nominal species referable to the synonymy of
E. bicolor are merely color pattern variants. There
are, however, two basic color patterns found in
preserved specimens, which, with modifications,
grade into each other. On the basis of life color
variations exhibited by a single individual reported
by Wickler (1965A) and in a group of specimens
reported by Strasburg (1967), it appears that life
color variations may be fixed at the time of preserva-
tion. Of the two basic patterns, either one or the
other greatly predominates in individual collections
from any locality. While either type may occur as
the predominant form in individual collections
from the same general locality, collections indicate
that one form or the other is much more often
collected.
In one of the basic patterns the head and body
are, for the most part, completely dark dusky, oc-
casionally slightly less intensely so on the posterior
half of the body. There may be a dark spot just
posterior to the eye. The spinous dorsal fin is dusky
or bears a dusky band on its ventral half with a
black spot between the first and third spines. The
black spot is rarely absent. The rayed dorsal is
more faintly dusky than the spinous dorsal and
slightly darker basally. The anal is dusky, frequently
paler basally and on the tips of the rays. The caudal
bears a faint to dark dusky triangular mark cen-
trally, the base of the triangle vertically aligned
with the caudal base. The uniformly dark color
pattern is the type exhibited by the holotype of
S. melanosoma. A variation of this pattern, wherein
there are several vertical, pale streaks tm the body
and the corners of the mouth are pale, was the
basis for the description of E. hawaiiensis. In some
specimens there is a broad, dark dusky longitudinal
stripe extending from the level of the pectoral axil
posteriorly to some point anterior to the caudal
peduncle. The stripe may be broken into as many
as five portions.
The other basic color pattern is similar to the
first in that the head and body anteriorly are more
or less uniformly dark, but at some point no further
anteriorly than below the level of the third or
fourth dorsal ray, the body gradually or abruptly
becomes paler or completely lacks melanophores.
A colored photograph of a freshly dead specimen
of this color pattern type occurs in Axelrod and
Emmens (1969). In many specimens there are one
to three narrow, vertical, diffusely dusky bars in
the pale area on the body. (One of these is slightly
apparent in figure 21.) A number of specimens
examined also exhibited the longitudinal dark stripe
on the body as described above.
Wickler (1965A) illustrated and discussed life
color variations in E. bicolor, based on aquarium
specimens presumably from Ceylon. He ascertained
that these patterns reflected emotional states. He
described life color generally as dark gray-brown
anteriorly and yellow or orange-red posteriorly.
Strasburg (1967) reported on life coloration and
noted that the lengthwise stripe (described above)
was two toned, black and white, with the white
color turning black in preservative. Strasburg re-
ported that E. bicolor from Eniwetok was bright
ultramarine, sometimes tinged with violet anteriorly,
and orange-yellow posteriorly. G. Losey (in litteris)
described E. bicolor, also from Eniwetok, as blue-
gray anteriorly and yellow-orange posteriorly. At
One Tree Island, Great Barrier Reef, specimens I
saw in life were electric blue anteriorly and yellow-
orange posteriorly. One individual was seen with
a rose-colored area posterior to the eye. (Such rose-
colored marks are found in excited specimens, ac-
cording to Wickler.) The illustration in the Tickell
manuscript of the Zoological Society of London,
upon which Day based his description of S. bicolor,
is rich blue anteriorly and red-orange posteriorly.
GEOGRAPHIC VARIATION.?Average numbers of dor-
sal and anal rays and caudal vertebrae (usually
correlated characters) tend to vary from one locality
to another (Table 15). In general, the highest
averages occur in the Australian specimens. Aus-
tralian specimens also appeared to have average
longer posterior nasal cirri and shorter fifth dorsal
rays (Tables 8 and 10) than specimens from other
localities. The nasal cirri were sexually dimorphic
in size in the Australian specimens but not in the
others. The length of the fifth dorsal ray was
sexually dimorphic in non-Australian specimens but
was either not dimorphic or only slightly so in
Australian specimens.
REMARKS.?In Figure 1 the acceptable literature
records for E. bicolor entered on the map were
those reported in Day (1888), Hora and Mukerji
(1936), and Kamohara and Yamakawa (1965).
Wickler (1965A, B, C, D) has given a detailed
discussion on the behavior and biology of E. bicolor,
28
including a list of moving picture films deposited
with the Encyclopedia Cinematographies.
Strasburg (1967) reported that E. bicolor occurred
in the lagoon at Eniwetok at depths from about
1 to 7.5 meters, being more common at the latter
depth. In contrast, I collected the species at One
Tree Island only on the ocean side of the island
at depths of about 4 and 12 meters and found the
species common at both depths. Most collections
of the species, however, appear to have come from
the lagoon side of atolls in shallow depths, although
Randall collected a specimen in Guam from a
depth of 21.3 meters.
Chapman and Schultz (1952) mentioned that E.
bicolor (as E. hawaiiensis) might have been intro-
duced into Hawaiian waters from Guam, where
the species is known to occur, as its collection in
Hawaii was made under peculiar circumstances.
They discarded the possibility, however, as they
believed the species to be endemic to Hawaii.
Strasburg (1956) believed that the species probably
was brought to Hawaii from Guam in the fouling
on the bottom of a barge, and thus was not a
Hawaiian endemic, but possibly had become estab-
lished in Hawaiian waters as a consequence of its
introduction. Strasburg did not recognize the species
as E. bicolor, but accepted the name E. hawaiiensis.
Considerable collecting in Hawaiian waters in
recent years has produced no additional material
of E. bicolor other than that reported by Chapman
and Schultz. In view of this and the fact that
Hawaii is considerably removed from the nearest
known locality where E. bicolor occurs, I believe
that the Hawaiian specimens were introductions
and that the species has not become established in
Hawaii.
NOMENCLATURE.?The description of Salarias bi-
color was based on a short description and colored
illustration in a handwritten manuscript by Colonel
S. R. Tickell, dated 1875, and titled: "Fishes col-
lected in the seas and fresh waters of British Burma
from 1851 to 1864, vol. 1." The manuscript is
housed in the library of the Zoological Society of
London. Many of the descriptions contained in
the manuscript are the sole bases of many of F.
Day's new species descriptions. The specimens on
which Tickell based his descriptions were evidently
not retained as can be inferred from comments in
the manuscript.
The colored illustration of S. bicolor in the
SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
manuscript is of a fish 1% (35 mm) inches long.
The specimen is rich blue anteriorly below the
rayed portion of the dorsal fin; thence it is red-
orange. The species is portrayed as having a deep
notch in the dorsal fin between the spinous and
rayed portions, somewhat deeper than for any
specimen I have seen. The species is described as
having no tentacles, but a statement was included
to the effect that if there were any tentacles they
"were very likely to be overlooked." The dorsal fin
formula was given as 11 + 18, the anal as 18.
The distinctive life color in combination with
the notched dorsal fin and a dorsal spine count of
at least 11 leaves little doubt of the identification
of Tickell's figure with the species treated here as
E. bicolor. The only blenny that approximates the
appearance of E. bicolor is the nemophidinine
Meiacanthus atrodorsalis (Giinther), which does not
have a notched dorsal and has fewer than 11 dorsal
spines (Tickell's count is probably in error and
the reduced last?12th?dorsal spine was probably
missed). From my observations M. atrodorsalis is
more yellow than orange posteriorly. It would prob-
ably be well to designate a neotype for S. bicolor,
but as I have no material from the same geographic
area from which S. bicolor was described, it is not
possible.
Salarias furcatus was not compared with any other
blenny and the description and illustration leave
no doubt that it is a synonym of S. bicolor. I have
been unable to locate the holotype.
Salarias burmanicus was compared only with S.
anomalus (= S. pulcher). The illustration and de-
scription clearly indicate bicolor as the species.
W. F. Smith-Vaniz examined the holotype in the
Indian Museum in Calcutta. It bears the number
F 11872/1, type 429.
Salarias melanosoma was compared only with 5.
anomalus. I have examined the syntypic material
and find all specimens to be the same as S. bicolor.
Ecsenius hawaiiensis was compared with E. bi-
color, but it was thought that the pale bars on the
sides were distinctive. Wickler (1965A) has described
and illustrated the various color patterns exhibited
by E. bicolor, of which the pale barred form is but
one of several. He concluded that E. bicolor and
E. hawaiiensis were the same species. My examina-
tion of the type material of the latter indicated no
morphological differences between that material
and other specimens I assign to E. bicolor.
NUMBER 72
MATERIAL (localities abbreviated).?Christmas Is-
land, Indian Ocean: BMNH 1909.3.4.52-57 (5: 30.0-
48.8, syntypes of Salarias melanosoma), USNM
157373 (40.7, sytitype of Salarias melanosoma); Cey-
lon: USNM 204623 (43.3), NFIS 5256 (6: 35.4-59.0,
specimens reported by Wickler, 1965A, presumably
from Ceylon); Maldive Islands: NFIS 9578 (49.1);
Nicobar Islands: NFIS 9576 (41.4); Pulo Penju,
Indonesia: USNM 201864 (3: 23.4-52.1); Patong,
Phuket, Thailand: USNM 201755 (5: 25.0-45.0);
Hot du Sud, South China Sea: CAS GVF-2113 (9:
48.3-61.3); Ryukyus: BPBM 7467 (46.4); Guam:
BPBM 7851 (2: 26.0-35.1); Timor: ZMA 109.064
(36.9); Banda Sea: USNM 195718 (2: 36.8-42.0);
Palau Islands: CAS GVF-740 (5: 20.7-48.5), GVF-
1450 (59.5); Kapingamarangi: CAS GVF-424 (5:
22.0-46.9), GVF-452 (38: 18.5-56.7); Mortlock:
ZSZM 5152 (41.5); Marshall Islands: BPBM 5895
(20: 32.3-67.6), USNM 201472 (8: 16.1-56.6), 201473
(43.9), 201475 (23.4), 201476 (5: 38.0-59.3), 201477
(3: 26.1-48.3), UW 12008 (3: 34.0-0-54.0); Ponape
Island: CAS GVF-496 (20: 24.5-61.0), GVF-497
(50.7); New Britain: USNM 201813 (3; 47.7-49.8);
Neiafu, Tonga Islands: USNM 203334 (2: 39.6-
44.1); Fiji Islands: USNM 201827 (41.9); Espiritu
Santo, New Hebrides: USNM 144293 (2: 29.5-47.5),
144294 (2: 52.2-62.0), 144716 (7: 27.1-45.0), CAS
GVF-1826 (24.5); One Tree Island, Queensland,
Australia: USNM 201368 (74: 38.5-69.3, including
two cleared and stained); Endeavour Reef, Queens-
land, Australia: ANSP 109699 (2: 31.4-37.7); Oahu,
Hawaii: USNM 112293 (66.5, holotype of Ecsenius
hawaiiensis), 112294 (12: 48.0-77.0).
Ecsenius (Ecsenius) namiyei
(Jordan and Evermann)
FIGURE 22
Salarias namiyei Jordan and Evermann, 1902, p. 362 [Pesca-
dores Islands].
DESCRIPTION.?Dorsal spines 11-12; dorsal rays
18-20; segmented anal rays 20-22; pectoral rays 13
(one specimen each with 11 and 12, and two with
14, on one side only); segmented caudal rays 13-14
(usually 14); dorsal procurrent caudal rays 7-8;
ventral procurrent caudal rays 6-8; total caudal
elements 26-30 (usually 28-29); gill-rakers 12-17;
pseudobranchial filaments 6-8 (usually 7); lower
incisor teeth 35-45; lower jaw posterior canines
29
0-1 (usually 1); total lower jaw posterior canines
1-2 (usually 2); upper incisor teeth 129 (one count);
precaudal vertebrae 10-11; caudal vertebrae 25-27;
total vertebrae 36-37; epipleural ribs 12-14. Lateral
line with vertically paired pores for none to one-
half its length, usually some pairs present, extending
posteriorly to beneath level of 10th-13th dorsal fin
element (usually 11th?12th). Dorsal fin without
notch. Third (innermost) pelvic ray obvious. Two
cirri on each anterior nostril, one each arising from
anterior and posterior margins.
Color pattern: (Taiwan specimens) The body,
head, and dorsal and anal fins are dark black,
with the exception that in the caudal peduncular
region the melanophores are less densely distributed,
and that area is paler. The bodies of some specimens
exhibit three or four short, narrow, pale, vertical,
widely spaced marks on each side, similar to marks
that are found in some specimens of E. bicolor.
Most of the specimens exhibit a row of microscopic
pale spots along the midportion of the body in the
region where the lateral line might be expected to
occur. Still others have a few small oblong intensely
dark spots that underlie the dark surface pigment
on the sides. The spinous dorsal fin bears irregular
deeply pigmented lines below the dark surface
pigment. The anal fin bears an indistinct darker
stripe along its midlength. The caudal, pelvic, and
pectoral fins are dusky with a greater concentration
of pigment along the rays.
The life coloration of the female illustrated in
Figure 13 (preserved color pattern), which had been
in an aquarium for an indefinite period not exceed-
ing a few weeks, was as follows: head and body dark
brown; caudal peduncle grading into yellow-amber
and then orange on proximal portion of caudal fin.
Body with eight small, midlateral, blue-white spots
beginning in the pectoral fin axil and extending no
farther than the level of the last dorsal rays. Similar
spots on pectoral base and on dorsal body contour,
where they were less obvious than the midlateral
spots. Upper lip with blue-white bands separated
by dark interspaces. Pale stripe from behind eye
to lip. Some pale blue dashes on cheek. There is
no evidence of the blue-white markings on the
preserved specimen.
REMARKS.?Tomiyama (1955) has given a thor-
ough redescription of the holotype of E. namiyei.
On the north end of Taiwan I collected this
so
species from depths of about one to three meters
very close to shore.
The specimens, one each, from New Britain and
nearby Kerward Island, are very similar to those
from Taiwan, but the color of their caudal pedun-
cles is of about the same intensity as the rest of
the body. An anal ray count was possible for only
one of these specimens. The count was 20 and is
lower than for any of the Taiwan specimens. The
damaged specimen had a dorsal ray count of 18,
lower than for any Taiwan specimen. These facts
probably indicate racial variation.
MATERiAL.-Pescadores Islands: ZITU 5726 (49.5,
radiograph of holotype of Salarias namiyei); Taiwan
(north end): USNM 203125 (63.6, cleared and
stained), 203126 (2: 58.0-63.2), 203127 (5: 62.0-
80.4), 203128 (5: 55.4-81.8), 204478 (9: 59.0-76.3);
New Britain: USNM 201865 (47.7); Kerward Island:
USNM 201866 (49.0).
Ecsenius (Ecsenius) stigmatura Fowler
FIGURE 23
Ecsenius lineatus Klausewitz, 1962, p. 145 [Madewaru Island,
Fadiffulu Atoll, Maldive Islands].
DESCRIPTION.?Dorsal spines 12; dorsal rays 17-18;
segmented anal rays 19-20; pectoral rays 13 (one
specimen each with 12 and 14 on one side only);
segmented caudal rays 13; dorsal procurrent caudal
rays 5-8 (one specimen each with 5 and 8; all others
had 7); ventral procurrent caudal rays 6-8; total
caudal elements 25-28 (one had 25, none had 26);
gill-rakers 13-16 (one had 16, none had 15); pseudo-
branchial filaments 6-7 (one had 7); lower incisor
teeth 45-49; lower jaw posterior canines 1; total
lower jaw posterior canines 2; upper incisor teeth
125 (one count); precaudal vertebrae 10-11 (two
had 11); caudal vertebrae 24-26; total vertebrae
34-36 (usually 35); epipleural ribs 13-15. Lateral
line with no paired pores, extending posteriorly to
below 10th dorsal spine. Dorsal fin notched six-
ninths to seven-ninths length first dorsal ray. Third
(innermost) pelvic ray obvious. One cirrus on each
anterior nostril.
Color pattern: The commonest color pattern,
except as noted below, is that illustrated in Figure
23. The dark midlateral spots on the side of the
body are always nine in number (the anteriormost
spot is actually part of a continuous stripe extending
to the eye). In the holotype and one small specimen,
SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
20.5 mm SL, the spots are not evident, but instead
there is a single, broad, uninterrupted, dark mid-
lateral stripe on the side. In another specimen the
spots are connected and are distinguishable only
as slight constrictions along the length of the stripe.
Usually the area of the body below the stripe, or
row of midlateral spots, is abruptly and uniformly
pale, and there is no evidence of a thin pale stripe
below the row of dark spots as in Figure 23. The
thin pale stripe above the row of spots is also
frequently obscured. The presence of the tear-
shaped spot on the caudal peduncle with the tip
extending onto the central base of the caudal fin
is distinctive of this species.
There is some variation in the markings on the
head. The narrow pale stripes paralleling the dark
postorbital stripe are not always distinguishable.
The underside of the head is most noticeable for
a pale area covering the lower lip and the region
just behind the lip. The remainder of the underside
of the head is variably dusky, sometimes with
indistinct evidence of diffuse dark spots on both
sides. The upper lip may be uniformly or irregularly
dusky, sometimes with three bands anteriorly sep-
arated by narrower, paler interspaces.
In life the dark areas are various shades of brown
and black and the pale areas are faintly yellow.
A field assistant described one fresh-caught specimen
as having much bright yellow color, but fading
rapidly after preservation.
REMARKS.?E. lineatus co-occurs with E. namiyei
in northern Taiwan. It was collected at depths of
about 1 to 9 meters, the latter depth somewhat
deeper than that from which specimens of E.
namiyei were obtained.
MATERIAL (localities abbreviated).?Maldive Is-
lands: NFIS 5532 (65.9, holotype of Ecsenius
lineatus); north end of Taiwan: USNM 203129
(4: 42.1-48.2, including one cleared and stained),
203130 (2: 48.6-55.4), 203131 (54.9), 203132 (2:
44.9-49.5), 204477 (60.1); Pratas Reef, South China
Sea: CAS GVF-1749 (20.5); Vietnam: CAS GVF-
2116 (46.6).
Ecsenius (Ecsenius) stigmatura Fowler
FIGURES 24, 25
Ecsenius stigmatura Fowler in Chapman and Schultz, 1952,
p. 514 [Dammi Island, but see remarks section below].
DESCRipnoN.-Dorsal spines 12; dorsal rays 16-17;
segmented anal rays 18-19; pectoral rays 13-15 (13
NUMBER 72
on only one side of one of the four specimens);
segmented caudal rays 14; dorsal procurrent caudal
rays 7-8; ventral procurrent caudal rays 6-7; total
caudal elements 27-28; gill-rakers 15-17; pseudo-
branchial filaments 6; lower incisor teeth 37-40;
lower jaw posterior canines 1; total lower jaw poste-
rior canines 2; upper incisor teeth 107 (one count);
precaudal vertebrae 10; caudal vertebrae 23-24;
total vertebrae 33-34; epipleural ribs 12 (one count).
Lateral line with no paired pores, extending pos-
teriorly to beneath level of 9th dorsal spine. Dorsal
fin notched six-ninths to seven-ninths length of
first dorsal ray. Third (innermost) pelvic ray vary-
ing from obvious to not obvious. One cirrus on
each anterior nostril.
Color pattern: The ground color of the head and
body is evenly dusky brown. There is a narrow dark
stripe that begins at the posteroventral margin of
the eye and extends posteriorly across the opercle.
Below the opercular portion of the stripe is a
narrow pale stripe that is in line with a similar
area margining the upper fleshy pectoral base. A
large dark spot extends anteriorly from the anus.
Another large dark spot occurs on the middle of
the caudal peduncle and extends onto the bases
of the caudal rays. The stripe has a pale margin
anteriorly. The fins are variably dusky.
Three of the four specimens available are females.
One female is from Masbate, Philippine Islands,
and the others are from Tomahu Island in the
Moluccan Sea. The fourth specimen, a male from
Borneo, may not be the same species. The male
differs from the females in lacking the pale stripe
below the dark stripe on the head and in lacking
the large spot on the caudal peduncle. Whether
these differences are an indication of sexual di-
morphism, individual variation, or population dif-
ferences cannot be decided at present.
A color sketch of the holotype made during the
Albatross expeditions indicates that the specimen
was generally reddish brown in life. The dark streak
behind the eye was deep blue and the pale streak
below this was orange. The pupil was surrounded
by a narrow orange border and this surrounded by
a reddish-brown ring. The anal spot was black with
deep blue overtones. The caudal spot was black
with a pale lavender margin. The spinous dorsal
was reddish brown basally and orange-brown dis-
tally. The rayed dorsal and most of the caudal
were pale slate gray. There is a narrow orange-
brown stripe along the dorsal body contour extend-
ing from the anterior end of the dorsal to the
caudal base.
REMARKS.?In the original published description
accredited by Chapman and Schultz (1952) to
Fowler, the holotype and one paratype of E. stig-
matura are reported to have been taken at Dammi
Island, between Jolo and Tawi Tawi straits, at a
depth of 244 fathoms (ca. 443 meters) on 21 Sep-
tember 1909. In an unpublished manuscript kindly
lent me by J. E. Bohlke, however, Fowler stated that
he was unable to ascertain the type locality. How
the published locality was arrived at is not now
known. I became suspicious of the published lo-
cality because no salariinine blenniids are known
from depths nearly as great as 244 fathoms.
The original watercolor illustration upon which
the published illustration of E. stigmatura was based
is in the files of the Division of Fishes, National
Museum of Natural History. This illustration bears
a number, 2131, that corresponds with a number
written on a silk tag that was tied to the holotype.
Also written on the illustration was the following:
Tomahu Id, 12/11-09 see color notes. I have been
unable to locate the color notes or any other record
of the tag number 2131, but the locality and date
(interpreted as 11 December 1909) agree with the
published information (Anonymous, 1910, p. 92)
for a collection made by the steamer Albatross
(depth given as 2-15 feet) at Tomahu Island. A
handwritten ledger in the files of the Division of
Fishes, recorded during the Albatross collections,
indicates that blennies were collected at this station.
The published locality and date for the holotype
of E. stigmatura are also in agreement with a pub-
lished Albatross station (Anonymous, 1910, p. 82),
but the ledger does not record that any blennies
were collected at that station and they would not
be expected from such a depth (ca. 443 meters).
In view of the above information I prefer to
ascribe the Tomahu Island locality to the holotype
and one paratype of E. stigmatura. In addition, as
the second paratype, according to the locality rec-
ords, came from either beach seining or dynamiting
at a depth up to about 4.5 meters, and no salariinine
is known to have a very extensive depth range, it
seems much more probable that the species is re-
stricted to shallow depths.
MATERiAL.-Tomahu Island: USNM 99379 (45.9,
holotype of Ecsenius stigmatura), 111878 (36.6);
383-026 O - 70 - 3
32 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
Cataingan Bay, east of Masbate Island, Philippines:
USNM 122444 (36.5); Pulav Gaya, Darvel Bay,
Borneo: USNM 201815 (37.7).
Ecsenius (Ecsenius) lividinalis Chapman and
Schultz
FIGURE 26
Ecsenius lividinalis Chapman and Schultz, 1952, p. 517
[Munda, New Georgia, Solomon Islands].
DESCRIPTION.?Dorsal spines 12; dorsal rays 12-14
(one each with 12 and 14); segmented anal rays
13-14; pectoral rays 13-14 (one of 11 with 14 on
one side only); segmented caudal rays 13-15 (usu-
ally 14); dorsal procurrent caudal rays 5-6; ventral
procurrent caudal rays 4?6; total caudal elements
23-26; gill-rakers 12-14; pseudobranchial filaments
5-7 (usually 6); lower incisor teeth 30-37; lower jaw
posterior canines 1 (2 on one side in one specimen);
total lower jaw posterior canines 2-3 (3 in one
specimen); upper incisor teeth 98-111 (four counts);
precaudal vertebrae 10-11 (one of 10 with 11);
caudal vertebrae 19-20; total vertebrae 29 or 30;
epipleural ribs 11-13. Lateral line with no paired
pores, extending posteriorly to below level of 9th-
11th dorsal spine. Dorsal fin notched three-ninths
to five-ninths length of first dorsal ray. Third (inner-
most) pelvic ray obvious. One cirrus on each anterior
nostril.
Color pattern: The available specimens of E.
lividinalis are all old and to some degree faded.
They appear to have been uniformly dark when
fresh, with the fins perhaps paler than the body.
The most obvious mark is a dark spot that envelops
the anus and extends a short distance anterior from
the anus.
MATERIAL (localities abbreviated).?New Georgia:
USNM 144723 (33.0, holotype of Ecsenius lividi-
nalis), 144292 (6:22.1-26.8, including one cleared
and stained), 144291 (3:22.1-30.5); Philippine Is-
lands: ANSP 109211 (26.0).
Ecsenius (Ecsenius) yaeyamaensis (Aoyagi)
FIGURES 27-29
Salarias yaeyamaensis Aoyagi, 1954, p. 213 [in part, Iriomote
Island, Riukius].
DESCRIPTION.?Dorsal spines 12-13 (rarely 13); dor-
sal rays 13-15 (usually 15); segmented anal rays
15-17 (usually 16); pectoral rays 12-14 (rarely 12
or 14); segmented caudal rays 13 (14 in one of 120
specimens); dorsal procurrent caudal rays 6-9 (usu-
ally 7-8); ventral procurrent caudal rays 6-8 (usu-
ally 7); total caudal elements 25-30 (rarely 25 or 30);
gill-rakers 11-16 (rarely 11 or 16); pseudobranchial
filaments 5-8 (rarely 5 or 8); lower incisor teeth
43-56; lower jaw posterior canines 0-1 (usually 1);
total lower jaw posterior canines 0-2 (usually 2);
upper incisor teeth 97-127 (6 counts); precaudal
vertebrae 10; caudal vertebrae 21-23 (usually 22);
total vertebrae 31-33 (usually 32); epipleural ribs
11-14 (rarely 11); lateral line without paired pores,
extending posteriorly to beneath level of 10th-12th
dorsal spine (one specimen each, of 110, to 8th and
12th spine). Dorsal fin notched seven-ninths to
eight-ninths length first dorsal ray (usually eight-
ninths). Third (innermost) pelvic ray varying from
obvious to not obvious (usually not obvious). One
cirrus on each anterior nostril.
Color pattern: Aside from a complex and variable
color pattern, E. yaeyamaensis comprises several geo-
graphic populations that are distinguishable only
on color pattern. Although treated here as a sep-
arate species, E. nalolo may more properly be placed
with E. yaeyamaensis. In contrast with the color
pattern populations of E. yaeyamaensis, which are
generally of limited geographic occurrence, E. nalolo
occurs over most of the Indian Ocean and Red Sea
with little noticeable geographic variation in color
pattern.
The major feature of the color pattern that links
all the populations of E. yaeyamaensis is a dark,
forked stripe on the fleshy pectoral base. The arms
of the stripe extend onto the bases of the fin rays;
no other species of Ecsenius has such a mark. (E.
nalolo has a single, unforked, stripe on the fleshy
pectoral base.)
The commonest color pattern is best typified by
that illustrated in Figure 27. This color pattern is
found in specimens from the South China Sea,
Taiwan, the Ryukyus, Palaus and adjacent islands,
New Britain, and New Georgia. The illustrated
specimen has a fully developed pattern. Other
specimens from the localities just cited are quite
variable and are allied by lacking specific features
that are found in specimens from other localities.
Banda Sea: A single specimen is available (Figure
29), which has a pattern unlike that from any other
locality. The distinctive features are two long, nar-
row, dark stripes on the body below the anterior
NUMBER 72
dorsal rays, continuous as dark dashes and ulti-
mately as four dark spots on the caudal peduncle.
(A single, badly faded specimen of E. yaeyamaensis
was available from Flores. Only faint remnants of
the forked stripe on the pectoral base were visible.
In view of the color pattern exhibited by the
specimen from the Banda Sea, which is relatively
close to Flores, it would be important to know
what color pattern is exhibited by specimens of
E. yaeyamaensis from the various islands surround-
ing the Banda Sea.)
New Hebrides: Three specimens (none illus-
trated), with two aligned, lengthwise rows of short,
dark dashes on the body grading into spots below
the posterior dorsal rays. If the dashes were to
fuse anteriorly, they would form stripes as in the
preceding form. The fact that the Banda Sea and
the New Hebrides are quite distant from each other
and that almost midway between these two localities,
at New Britain and New Georgia, the common
color pattern occurs, leads me to conclude that the
populations are probably distinct.
Australia: All of a considerable number of speci-
mens (not all cited in the material list) from the
Capricorn group of islands at the southern end of
the Great Barrier Reef and Endeavour Reef, off
northern Queensland, exhibit numerous fine, dark
spots on the posterior half of the body (Figure 28).
These spots occur in at least two horizontally
aligned rows, but there is usually a sprinkling of
unaligned spots both above and between the rows.
All of the specimens are larger than those from
the New Hebrides and it may be that Australian
specimens of sizes equal to those from the New
Hebrides will be similar in color pattern.
REMARKS.?In Figure 2, a literature record for
E. yaeyamaensis is included, based on Aoyagi's (1954)
record from Iriomote Island, Ryukyus. For geo-
graphic variation see color pattern description
above.
NOMENCLATURE.?Aoyagi (1954) described Salar-
ias yaeyamaensis on the basis of three specimens:
two males, 49.4 and 46 mm total length from
Iriomote Island, and a female, 49 mm total length
from Ishigaki Island. Both Islands are in the
southern Ryukyus. Aoyagi wrote that the descrip-
tion was based on the 49.4 mm male, but he also
described the female. A male, presumably the 49.4
mm specimen, was illustrated as was also the female.
No holotype was specifically designated. No indi-
cation of where the type material was deposited
was given, and I have been unable to locate Aoyagi's
specimens. The male, well illustrated, is clearly the
species that I treat here as E. yaeyamaensis. The
female, also well illustrated, is clearly the species
I describe below as Ecsenius oculus. (Aoyagi be-
lieved that color pattern differences between the
males and female were indicative of sexual di-
morphism.) In order to fix the name of Aoyagi's
species, I here designate the larger male, 49.9 mm
total length, as lectotype of Salarias yaeyamaensis
Aoyagi.
MATERIAL (localities abbreviated).?South end of
Taiwan: USNM 203133 (35.2), 203134 (2: 38.5-
39.0), 203135 (42.0), 203136 (2: 39.7-42.6), 203137
(10: 26.5-49.0), 203138 (4: 37.7-41.8); Vietnam:
CAS GVF-2072 (38.8); Flores: ZMA 109.100 (33.4);
Banda Sea: USNM 202477 (26.6); Yap: CAS GVF-
894 (11: 21.9-34.3), GVF-794 (9: 26.1-51.9), GVF-
1912 (4: 28.7-34.8), GVF-1913 (25.0), GVF-1915
(36.7), GVF-1924 (31.7), GVF-1946 (37.7), GVF-
1923 (2: 34.5-39.9); Palaus: CAS GVF-735 (46.4),
GVF-740 (11: 31.9-43.0), GVF-802 (2: 24.7-29.8),
GVF-807 (39.9), GVF-843 (4: 30.0-39.0), GVF-1450
(6: 31.6-43.6), GVF-1868 (46.2), GVF-1869 (41.5);
Western Caroline Islands, Sorol Atoll: CAS GVF-
993 (31.6); Bougainville: USNM 201824 (2: 30.4-
39.8); New Britain: USNM 200428 (3: 38.2-38.7,
including one cleared and stained), 201812 (32.3);
New Hebrides: USNM 195787 (3: 20.6-26.0); One
Tree Island, Great Barrier Reef: USNM 201818
(29: 32.1-46.8), 201822 (15: 34.1-45.4), 201836 (4:
32.0-36.0); Endeavour Reef, Great Barrier Reef:
ANSP 109691 (31: 20.0-46.6), 109690 (52: 13.5-
37.8).
Ecsenius (Ecsenius) nalolo Smith
FIGURE SO
Ecsenius nalolo Smith, 1959, p. 245 [Pinda, Mozambique].
Ecsenius minutus Klausewitz, 1963, p. 357 [Addu Atoll, Mal-
dive Islands].
DESCRIPTION.?Dorsal spines 11-13 (rarely 11 or
13); dorsal rays 12-15 (usually 13 or 14); segmented
anal rays 14-17 (rarely 14 or 17); pectoral rays 12-13
(rarely 12); segmented caudal rays 12-14 (rarely 12
or 14); dorsal procurrent caudal rays 6-9; ventral
procurrent caudal rays 5-9 (rarely 5 or 9); total
caudal elements 25-31; gill rakers 12-17 (rarely 12
34 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
or 17); pseudobranchial filaments 6-8; lower incisor
teeth 42-63; lower jaw posterior canines 0-1 (usu-
ally 1); total lower jaw posterior canines 0-2 (usu-
ally 2); upper incisor teeth 132 (one count); pre-
caudal vertebrae 10; caudal vertebrae 21-23; total
vertebrae 31-33; epipleural ribs 11-14 (usually 12-
13). Lateral line without paired pores, extending
posteriorly to below level of 8th-11th dorsal spine
(rarely 8th). Dorsal fin notched seven-ninths to
eight-ninths length of first dorsal ray. Third (inner-
most) pelvic ray varying from obvious to not
obvious. One cirrus on each anterior nostril.
Color pattern (see also description under Ecsenius
yaeyamaensis): Description of the color pattern of
E. nalolo is difficult because of individual variation
and the complexity of the pattern itself. The most
consistent feature is the presence of a dark stripe
on the fleshy pectoral base that extends onto the
fin rays. Occasionally there are dark spots above
and/or below the stripe on the fleshly base and,
frequently, on the bases of the rays. The stripe is
never forked as in E. yaeyamaensis.
The head typically bears a dark stripe, varying
in intensity along its length, and extending from
the midposterior margin of the orbit across the
top of the opercle to the posterior bony margin
of the opercle. Above this stripe is a parallel narrow
pale stripe, then a stripe paler than the first de-
scribed stripe, then a broad pale stripe and next a
thin, narrow, dusky stripe just lateral to the midline
of the top of the head. The last listed stripe may
intensify as a dark spot just anterior to the level
of the dorsal fin origin. Below the midorbital stripe
the cheek may be pale dusky or, in some non-Red
Sea males, peppered with tiny dark spots (Figure
30). The snout region is variably pale to dark dusky.
The underside of the head in males may be almost
black with a sharply defined, pale, triangular area,
apex directed posteriorly, just behind the lower lip.
In other males and females the underside of the
head is dusky with a similar pale triangular area
and a dorsally curving dark line on each side that
extends from behind the corner of the lower lip
up along the posterior margin of the opercle.
The dark stripes on the head may continue onto
the body anteriorly where they usually break up
into short, broad, dark dashes. Below these dashes
in the region above the venter, there are a variable
number of dark lines and splotches. The remainder
of the body is variably dusky with pale spots.
The pectoral fin and base were described above.
There is usually a dark or dusky spot in the pectoral
axil (also found in E. yaeyamaensis and to lesser
extent in E. oculus). The pelvics are pale to dark
dusky. The caudal is not noticeably marked, but
may be dusky basally. The dorsal fin is dusky
basally, mostly unmarked otherwise. The anal is
pale dusky in males, with the tips of the rays
noticeably paler in presumably mature males.
Females are paler overall than males and the
body of the female may be almost completely
unmarked.
GEOGRAPHIC VARIATION.?Mandibular tooth counts
(Table 17) of specimens from the northern Red
Sea (including the Gulf of Aqaba) are usually much
higher than those for specimens from the southern
Red Sea and Indian Ocean. (See also discussion of
this under E. oculus, geographic variation.)
REMARKS.?Specimens as small as 13.1 mm SL
were examined; they were not ophioblennius type
larvae, but were typical juveniles.
NOMENCLATURE.?Ecsenius minutus was not com-
pared with any other species of fish. I have examined
the holotype and find it to be a young specimen of
E. nalolo.
MATERIAL (localities abbreviated).?Gulf of
Aqaba: USNM 204571 (39: 13.1-46.4), 204568 (20:
15.3-38.4), 204569 (61: 16.1-42.5), HUI E-63/36 (3:
18.8-25.1), HUJ-F-3531 (25.1), HUJ-F-4376 (6:
14.5-32.0), HUJ-F-3542 (31.6), E-63/33 (2: 26.2-
28.2), HUJ-F-3553 (3: 22.0-33.8), HUJ-F-4384
(35.9), HUJ-F-3551 (3: 17.5-34.8). Red Sea: south-
ern tip of Sinai Peninsula, USNM 204570 (36: 21.8-
44.9); Egypt, NFIS 5119 (38.0), USNM 200602 (4:
30.3-45.0, including one cleared and stained),
201825 (28.1), 201754 (2: 32.3-43.1); Sudan, NFIS
(36.6); Zubair Island, HUI HUJ-F-4622 (25.2);
Ethiopia, USNM 204481 (9: 16.6-31.4). Aden:
USNM 203954 (16.8). Indian Ocean: Amirantes
Islands, USNM 201845 (7: 28.8-47.6), ANSP un-
cataloged (35.8); Farquhar Island, USNM 203955
(48.7); Aldabra Atoll, USNM 203072 (15: 29.9-
46.0), 203075 (11: 27.7-38.7), 201828 (6: 22.9-51.3);
Comoro Islands, USNM 201826 (2: 30.1-31.9),
201521 (31.4); Mozambique, RU BP2127C (39.2,
holotype of Ecsenius nalolo), BP2127B (34.3),
BP2127A (33.4), BP1924 (29.7), RU uncataloged
(5: 25.2-39.2, Pinda; 31.0, Ilha); Maldive Islands,
NFIS 6363 (20.0, holotype of Ecsenius minutus);
NUMBER 72
Chagos Archipelago, USNM 203071 (43.2), 203073
(2: 30.9-49.2).
Ecsenius (Ecsenius) oculus, new species
FIGURE 31
Salarias yaeyamaensis Aoyagi, 1954, p. 213 [in part, Ishigaki
Island].
DESCRipnoN.-Dorsal spines 12; dorsal rays 12-15
(usually 13-14); segmented anal rays 14-17 (usually
15-16); pectoral rays 13-14 (rarely 14); segmented
caudal rays 12-14 (rarely 12 or 14); dorsal procur-
rent caudal rays 7-10 (usually 8-9); ventral procur-
rent caudal rays 6-9 (usually 7-8); total caudal
elements 27-32 (usually 28-30); gill-rakers 12-18
(usually less than 16); pseudobranchial filaments
5-6; lower incisor teeth 47-64; lower jaw posterior
canines 0-1; total lower jaw posterior canines 1-2
(rarely 1); upper incisor teeth 138-148 (two counts);
precaudal vertebrae 10; caudal vertebrae 21-24
(usually 22-23); total vertebrae 31-34; (usually 32
or 33); epipleural ribs 11-14 (rarely 11). Lateral
line with no paired pores, extending to below level
of 10th spine to first dorsal ray (usually beyond 11th
spine). Dorsal fin notched nine-ninths length first
dorsal ray (one specimen of 46 had notch seven-
ninths). Third (innermost) pelvic ray obvious (not
obvious in one specimen only). One cirrus on each
anterior nostril, occasionally branched.
Color pattern: The color pattern of this species
is variable, but most specimens are characterized
by having at least three pairs of large, dark, pale
margined spots on each side of the body. The most
common pairs of spots are on or just above the
midline of the body. These spots frequently give
the appearance of sunglasses. Occasionally there
are similar pairs of smaller dark spots with pale
margins along the dorsal body contour in line
with the pairs lower on the sides; sometimes only
the dorsal pairs of spots are present. The general
body color is less dark than the spots and is punc-
tuated with pale areas of various sizes and shapes.
There is invariably a vertical pair of dark marks
(sometimes fusing, but always recognizable) on the
caudal peduncle, extending onto the caudal fin
and there decreasing in intensity. The dorsal spot
of the pair extends diagonally downward on the
caudal fin, tapering posteriorly, and the ventral
spot extends horizontally, also tapering posteriorly.
35
The extensions frequently meet posteriorly. These
two spots are characteristic of the species. The
caudal is otherwise clear or variably pale dusky.
The head pattern is variable, but frequently
there is a middorsal pale stripe extending from
just anterior to the dorsal fin to between the eyes.
There is a broader dusky stripe (sometimes repre-
sented posteriorly only, as a dark spot) on either
side of the median pale stripe, followed laterally by
another pale stripe, then a broader dusky stripe,
another narrower pale stripe, and then a broader
dark stripe. This last stripe begins at about the
posterior midorbital level and extends posteriorly
onto the body for a short distance. Sometimes there
is another thin, pale stripe ventral to this last dark
stripe. The cheeks are irregularly dusky with pale
marks. The corners of the upper lip may be darker
than the surrounding color. Occasionally the ventral
margin of the opercle is dark, and this darkness
extends as a stripe onto the lower surface of the
head, meeting a similar mark from the other side.
The underside of the head is otherwise dusky
except for a pale unmarked area around the lower
lip.
The fleshy pectoral base is dusky with indications
of one, rarely two, darker dusky stripes, the more
dorsal of which may be bordered by pale areas.
The pectoral fin is mostly unmarked except for a
dusky area basally on the rays. The pelvic fins are
pale to dark dusky. The dorsal may bear a basal
or subbasal dusky stripe with the color mostly
restricted to the membrane or to the fin elements.
The anal fin is mostly uniformly dusky, paling at
the distal tips of the rays.
There are some striking variations from the
commonest type color pattern described above. It is
probable that some of these represent population
differences as they are in some degree paralleled
by meristic and tooth count differences (Table 18).
Three specimens (USNM 195716) collected by
Longley and presumably from the Banda Sea area
(see appendix) are somewhat faded, but the two
spots at the caudal peduncle extending onto the
caudal fin are still apparent, as are pairs of large
dark spots on the dorsal half of the body. These
specimens differ in having four dark spots in a
longitudinal series posteriorly on the ventral half
of the body. These spots are of about equal size
and intensity as those of the upper half of the body.
36
Four specimens from the New Hebrides (AMS
1-6521-24) are similar to those from the Banda Sea,
but exhibit about 6 to 8 dark spots on the ventral
half of the body. The dark spots on the dorsal half
of the body are not segregated as pairs but appear
as a somewhat irregularly linear series.
The single specimen available from the Palau
Islands (CAS GVF-880) differs from all others of
the species in having three large, dark, saddle-like
spots with pale ventral margins posteriorly on the
dorsal body contour. Each spot is separated from
the next by a slightly paler dark spot, which is
darker than the ground color of the body. The two
spots at the caudal base are relatively larger than
those for any other specimen.
A specimen from Hot du Sud, South China Sea
(CAS GVF-2113), is unique in having only a single
dark spot on the body, on the dorsal body contour
at the end of the dorsal fin. The body color is
generally dark, but paler than the spot, and is
punctuated with rows of pale, round or oblong
spots. The spots at the caudal base are normal.
The fleshy pectoral base bears a dark bar with a
shallow fork at its posterior end. The anterior end
grades into the dusky color of the pectoral base.
Above and below the bar are pale spots. The color
pattern is, in general, somewhat intermediate be-
tween that of typical E. oculus and E. yaeyamaensis.
Other specimens from the South China Sea are more
normal.
GEOGRAPHIC VARIATION.?In addition to color pat-
tern variation (see above), there is some evidence
that populations from various localities differ in
meristics and tooth numbers (Table 18). Until more
specimens from more localities are available, it is
not possible to say definitely what the cause of this
variation is. There is a tendency for the meristic
characters to gradually decrease in numbers toward
the south to the equator and then to increase south
of the equator. Tooth numbers seem to exhibit a
sharp break near the northern end of the range of
the species.
A possible explanation for the observed meristic
variation may be the fact that water temperatures
tend to increase in a north-south direction to the
equator and decrease southward from the equator.
It has been demonstrated often in fishes that meris-
tics decrease in numbers with increase in water
temperatures, but tooth numbers have not been
examined for such a correlation. In this respect
SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
the tooth numbers of Ecsenius nalolo specimens
from the northern Red Sea including the Gulf of
Aqaba) are higher than those of the southern Red
Sea and Indian Ocean specimens (Table 12). Gulf
of Aqaba water temperatures average lower than
those of the southern Red Sea (and Indian Ocean1)
during every month (Oren, 1962).
REMARKS.-Aoyagi (1954) illustrated a female E.
oculus from the Ryukyus that he identified as E.
yaeyamaensis, and Kamohara (1954) illustrated a
male, from Takarajima, northern Ryukyus. Kamo-
hara's record is included on Figure 3 although the
specimen was not seen.
RELATIONSHIPS.?Ecsenius oculus is most closely
related to E. opsifrontalis, from which it is dis-
tinguished in usually having more dorsal and anal
rays (Table 1), usually shorter third and last dorsal
spines (Tables 5 and 7), and in overall color pattern
(compare Figures 31 and 32).
ETYMOLOGY.?The specific name oculus is Latin
for eye, and refers to the eyelike spots on the body
of the species.
HOLOTYPE.-USNM 203140, male, 53.8 mm SL,
immediately south of cut between large outstanding
rock and Ch'uan-fan-shih, south end of Taiwan.
Collector V. G. Springer, et al., 24 April 1968. Depth
approximately 6 meters. Original field number VGS
68-3.
PARATYPES.-USNM 203923 (7: 38.0-52.4), col-
lected with the holotype. USNM 203142 (4: 43.9-
50.5,) just north of type locality. USNM 203141
(45.5), northwest of swimming beach of Sha Toa,
south end of Taiwan. USNM 203139 (3: 40.8-42.7),
just south of Chin-chiao-wan, south end of Taiwan.
BPBM 7464 (19.5), Taketoni Island, Ishigaki, Ryu-
kyus. BPBM 7468 (13: 19.7-47.6), Ishigaki City
Harbor, Ishigaki, Ryukyus. CAS GVF-2113 (41.3),
west shore Hot du Sud, South China Sea. USNM
201811 (4: 26.2-32.5), Goh Huyong, Similand Island,
Thailand. USNM 201560 (2: 30.4), Pulo Jara, Strait
of Malacca, Indonesia. USNM 201522 (3: 31.8-
39.9), Pulo Mega, Mentawei Islands, Indonesia.
CAS GVF-880 (40.7), vicinity of Garudowaishi
Point, Nardueis Island, Palau Islands. USNM
195716 (3: 31.0-37.8), Banda Sea. AMS 1.6521-24
(4: 34.7-41.8), New Hebrides.
Much additional field data is available for the
specimens listed above from Taiwan and those
bearing California Academy of Sciences numbers.
The data are on my field data sheets for the year
NUMBER 72 37
1968 (in the files of the Division of Fishes, National
Museum of Natural History) and the George Van-
derbilt Foundation register sheets at the California
Academy of Sciences.
Ecsenius (Ecsenius) opsifrontalis Chapman
and Schultz
FIGURE 32
Ecsenius opsifrontalis Chapman and Schultz, 1952, p. 521
[Rongelap Island, Marshall Islands].
DESCRIPTION.?Dorsal spines 12; dorsal rays 13-14
(usually 13); segmented anal rays 14-16 (usually 15);
pectoral rays 12-13 (rarely 12); segmented caudal
rays 13; dorsal procurrent caudal rays 8-9; ventral
procurrent caudal rays 7-8; total caudal elements
28-30; gill rakers 12-15; pseudobranchial filaments
5-6; lower incisor teeth 43-50; lower jaw posterior
canines 0-1; total lower jaw posterior canines 1-2;
upper incisor teeth 127 (one count); precaudal
vertebrae 9-10 (rarely 9); caudal vertebrae 21-22
(usually 22); total vertebrae 31-32 (usually 32);
epipleural ribs 12 (one count). Lateral line with
no paired pores, extending to below level of 11th-
12th dorsal spine (usually 12th). Dorsal fin notched
eight-ninths to nine-ninths length of first dorsal
ray. Third (innermost) pelvic ray not obvious. One
cirrus on each anterior nostril.
Color pattern: This is usually a faintly marked
species. The most noticeable and consistent marking
is a narrow stripe extending posteriorly from the
orbit across the top of the opercle and, broadening
and becoming fainter, along the upper portion of
the body, sometimes onto the bases of the caudal
rays. The body portion of the stripe is frequently
absent in part or completely. The second most
frequent and obvious marking is a dark edging of
the anterior margin of the lower lip. The head is
otherwise variably dusky, sometimes with one or
two dusky stripes connecting the orbits across the
anterior interorbital region. A second longitudinal
stripe occasionally occurs along the ventral half of
the body, extending onto the bases of the caudal
rays. Characteristic of many specimens are up to
10 faint to dark dusky, narrow, vertical stripes on
the upper two thirds of the body. Except for the
anal fin, which is dusky, and the body stripes
extending onto the base of the caudal, the fins are
essentially unmarked. In some specimens the black
lining of the intestine everts at the anus and gives
the appearance of a black ring in this region.
MATERiAL.-Guam: USNM 203742 (25.5); Kapin-
gamarangi: CAS GVF-440 (23: 15.6-32.4), GVF-468
(5: 17.8-33.8), GVF-446 (3: 18.6-28.7), GVF-452 (6:
21.9-35.8); Marshall Islands: USNM 142065 (29.7,
holotype of Ecsenius opsifrontalis), 142066 (26.1),
152978 (34.8), 202548 (32.3).
Ecsenius (Ecsenius) prooculis Chapman and
Schultz
FIGURE 33
Ecsenius prooculis Chapman and Schultz, 1952, p. 519
[Munda Lagoon near Sassavelle, New Gorgia, Solomon
Islands].
DESCRIPTION.?Dorsal spines 12; dorsal rays 14;
segmented anal rays 15-16; pectoral rays 13; seg-
mented caudal rays 13; dorsal procurrent caudal
rays 7; ventral procurrent caudal rays 6-8; total
caudal elements 26-28; gill-rakers 11-13; pseudo-
branchial filaments 6; lower incisor teeth 41-49;
lower jaw posterior canines 1; total lower jaw pos-
terior canines 2; precaudal vertebrae 10; caudal
vertebrae 21-22; total vertebrae 31-32; epipleural
ribs 12 (one count). Lateral line with no paired
pores, extending posteriorly to below level of 8th-
9th dorsal spine. Dorsal fin notched eight-ninths
length of first dorsal ray. Third (innermost) pelvic
ray obvious. One cirrus on each anterior nostril.
Color pattern: This species is characterized by a
pattern of three dark stripes, separated by pale
dusky interspaces, extending the length of the body.
The dorsalmost stripe extends along the dorsal
body contour. The second and darkest stripe ex-
tends along the midlength of the body, and the
ventralmost, and least dark of the three, extends
along the ventral body contour. The dorsalmost
stripe gradually diminishes in intensity anteriorly
and fades into the head. The middle stripe extends
anteriorly onto the head (entering just below the
dorsal level of the opercle) as a narrow dark line
that reaches the posterior margin on the eye. The
ventralmost stripe broadens anteriorly and may
spread over much of the venter. All three stripes
extend onto the bases of the caudal rays where
the stripes fuse and form a crescentic dusky area.
Just above the head portion of the middle stripe
there may be an indication of a dark spot, which
SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
in one specimen is faintly continuous with a spot
on the dorsal margin of the opercle. The under
surface of the head is generally paler than the sides
of the head and there is faint indication in all
specimens of a dusky stripe extending a short dis-
tance posteriorly from the anteriormost mandibular
sensory pore on each side. The stripe on each side
shows indications of two concentrations of pigment,
which make the stripe appear as two diffusely
connected spots.
The holotype exhibits some dark spots on the
head not found in the other specimens. There is
a spot behind each anterior nostril and five spots
in the interorbital region: two anteriorly, two pos-
teriorly, and one in the midline slightly closer to
the anterior pair.
The rayed portion of the dorsal fin bears a diffuse
dusky stripe in its lower third. Otherwise the fin
bears only some melanophores basally. The anal
fin is uniformly dusky, except for the tips of the
rays, which are pale. The pelvics are pale dusky and
the pectorals are clear except that the rays are
faintly overlain with melanophores.
REMARKS.?see under Ecsenius bandanus.
MATERiAL.-New Georgia: USNM 144722 (39.5,
holotype of Ecsenius prooculis); New Britain:
USNM 201819 (4:28.2-34.0).
Ecsenius (Ecsenius) bimaculatus, new species
FIGURE 34
DESCRIPTION (data for holotype followed in paren-
theses by data for largest and smallest paratypes, if
different).?Dorsal spines 12; dorsal rays 14; seg-
mented anal rays 16 (16, 15); pectoral rays 13 (13,
12?but 13 on opposite side); segmented caudal rays
13; dorsal procurrent caudal rays 7 (7, -); ventral
procurrent rays 6 (6, -); total caudal elements 26
(26, -); gill-rakers 12 (14, 14); pseudobranchial fila-
ments 6; lower incisor teeth 42 (42, 41); lower jaw
posterior canines 1; total lower jaw posterior canines
2; precaudal vertebrae 10; caudal vertebrae 22;
total vertebrae 32; epipleural ribs - (-, 12). Lateral
line with no paired pores, extending to below level
of 10th dorsal spine (9th, 10th). Dorsal fin notched
eight-ninths length of first dorsal ray. Third (inner-
most) pelvic ray obvious. One cirrus on each anterior
nostril.
Color pattern: The head is dusky above the level
of the upper third of the eye. Immediately below
this dusky area is a dark stripe that encompasses
the two circumorbital pores at the midposterior
orbital margin. This stripe extends posteriorly
across the head along the dorsal opercular margin
and enters the body, where it narrows and becomes
diffuse, ending below the third or fourth dorsal
spine. The head is less dark below the stripe than
above. One specimen exhibited a dark spot on
either side of the head at the dorsoposterior margin
of the eye just above the dark stripe. There are two
dusky spots on each side of the ventral surface of
the head. The anterior spot of each pair is just
behind the anteriormost pore of the mandibular
series, and the posterior is a little medial to the
fifth pore of this series.
The body is generally dusky, slightly darker
anteriorly above the level where the head stripe
enters the body. Just below the body portion of
the stripe, the body pales abruptly or gradually.
There are two distinct, dark, oblong spots on each
side just below the midlevel of the body under
the third or fourth through ninth dorsal spines.
There is a narrow dark line at the dorsal body
contour that continues on the base of the spinous
dorsal only. The rayed portion of the dorsal is
clear basally and has a diffuse stripe extending
along its length just above the clear area. The anal
fin is evenly dusky except for a paling at the distal
ends of the rays. The caudal is faintly sprinkled
with melanophores except for a faint crescentric
concentration of melanophores at its base. The
pectorals are marked similarly to the caudal; the
pelvics are unmarked.
RELATIONSHIPS.?See under Ecsenius bandanus.
MATERiAL.-Holotype, USNM 201817, male, 31.0
mm SL, Pulav Bohidulong, Darvel Bay, east end
of Borneo. Fringing coral reef on eastern (outer)
side of island; depth ca. 1.5-3.6 meters; 2 February
1965, Te Vega Cruise 6, station 216.
PARATYPES.-USNM 203922, two males, 31.7 and
30.6 mm SL collected with the holotype.
ETYMOLOGY.?The name bimaculatus refers to the
characteristic two dark spots on the side of the body.
Ecsenius (Ecsenius) bandanus, new species
FIGURE 35
DESCRIPTION (holotype and only known sped-
NUMBER 72 39
men).?Dorsal spines 12; dorsal rays 14; segmented
anal rays 16; pectoral rays 13; segmented caudal
rays 13; dorsal procurrent caudal rays 8; ventral
procurrent caudal rays 7; total caudal elements 28;
gill-rakers 13; pseudobranchial filaments 6; lower
incisor teeth 43; lower jaw posterior canines 1;
total lower jaw posterior canines 2; precaudal verte-
brae 10; caudal vertebrae 21; total vertebrae 31.
Lateral line with no paired pores, extending pos-
teriorly to below level of 9th dorsal spine. Dorsal
fin notched eight-ninths length of first dorsal ray.
Third (innermost) pelvic ray obvious. One cirrus
on each anterior nostril.
Color pattern: Distinctive markings appear only
on the head of this species, which has as its most
noticeable marking a broad stripe extending pos-
teriorly from just behind the eye across the top of
the opercle. On the right side of the specimen there
is faint indication of a continuation of this stripe
on the body to just beyond the level of the pectoral
base. There is also faint evidence anteriorly that
the stripe continues dorsally following the margin
of the eye and meeting in the interorbital region
the stripe from the other side. There is a faint,
narrow band in the anterior interorbital region
connecting the two orbits, and a dark sprinkling
of melanophores around the anterior nostrils. On
each side of the undersurface of the head there is
a dusky spot encompassing the anteriormost two
pores of the mandibular series and a similar spot
just medial to the fifth pore of this series. The
rayed portion of the dorsal fin has a faintly dusky
stripe extending the length of the fin on its basal
half. The anal is dusky except for the unmarked
basal half. The specimen is otherwise evenly dusky.
RELATIONSHIPS AND REMARKS.?Ecsenius bandanus
is most and very closely related to E. bimaculatus
and E. prooculis: the prooculis species subgroup of
the yaeyamaensis species group. The species of this
subgroup differ from one another only in matters
of color pattern, and in this they are strikingly
different from one another (Figures 33-35). The
species are rare in collections and all known speci-
mens are males. The species occupy different geo-
graphic areas (Figure 4).
Divergence of the species probably occurred as a
result of isolation in the different island groups,
either by differentiation of an ancestral founding
species that invaded new island areas, or after the
breaking up of the geographic range of a widespread
ancestral species. The distribution of the three
species correlates somewhat with biogeographic
areas recognized for terrestrial organisms. Thorne
(1963) prepared a biogeographical analysis of the
islands of the Pacific based on terrestrial organisms.
The tropical portion of the Pacific was called the
Oriental Region, which was divided into five sub-
regions. Each subregion was divided into provinces
and some provinces were divided into districts. E.
bimaculatus occupies the Bornean District of the
Malayan Province of the Indo-Malayan Subregion.
E. bandanus occupies the Moluccan Province of the
Papuan Subregion, and E. prooculis occupies the
Bismarckian and Solomonian Districts of the Bis-
marckian Province of the Papuan Subregion. If
these distributions are indicative of distributional
patterns generally, then additional species in the
prooculis subgroup can be expected to occur in
other provinces and subregions.
HOLOTYPE.-USNM 195717, male, 31.4 mm SL,
Banda Sea, Indonesia (see discussion of Banda Sea
locality in Appendix).
ETYMOLOGY.?Named for the area from where the
holotype is believed to have come.
Ecsenius (Ecsenius) mandibularis McCulloch
FIGURE 36
Ecsenius mandibularis McCulloch, 1923, p. 122 [Masthead
Island, Australia].
DESCRIPTION.?Dorsal spines 12 (rarely 11 or 13);
dorsal rays 14-16 (usually 15); segmented anal rays
16-18 (rarely 18); pectoral rays 13 (rarely 12); seg-
mented caudal rays 13; dorsal procurrent caudal
rays 6-7 (one of 53 with 8); ventral procurrent
caudal rays 5-7; total caudal elements 24-27; gill-
rakers 12-16 (usually 14); pseudobranchial filaments
6 (rarely 7); lower incisor teeth 45-53; lower jaw
posterior canines 2-8 (usually 5-7); total lower jaw
posterior canines 7-15; upper incisor teeth 120-121
(two counts); precaudal vertebrae 10 (one of 91
specimens with 11); caudal vertebrae 22-23 (rarely
21 or 24); total vertebrae 31-34 (usually 32-33);
epipleural ribs 12 or 13 (rarely 11 or 14). Lateral
line with no paired pores, extending posteriorly to
below 10th-11th dorsal spine. Dorsal fin notched
seven-ninths to eight-ninths length of first dorsal
ray (usually eight-ninths). Third (innermost) pelvic
ray obvious to not obvious (45 of 51 specimens with
40
ray obvious). One cirrus, rarely forked, on each
anterior nostril.
Color pattern: Specimens may range from almost
uniformly pale, with no distinct marks, to quite
dark anteriorly, grading into moderately dusky pos-
teriorly with two longitudinal rows of dark spots
on the body. When the spots are present the upper
row usually begins between the dorsal fin origin
and the lateral line and terminates at some point
below the dorsal fin rays. The ventral row of spots
begins at about the midlateral line of the body no
farther anteriorly than the level of the anus and
extends to the caudal base. The upper row of spots
may be obscured by the dark color of the body.
I have seen collections from One Tree Island taken
within a week of each other in which almost all
the specimens in one collection exhibited spotting
and almost none of the specimens in the other
exhibited spotting. While not so restricted, the
spotting seems to be found predominantly in males.
In many specimens there is a narrow, dark stripe
extending from the posterior margin of the orbit
across the top of the opercle. There may also be a
narrow, dark stripe on each side of the underside
of the head, beginning somewhat behind the tip
of the lower jaw and extending to the margin of
the branchiostegal membrane, thence continuous
along the ventral margin of the fleshy pectoral base.
The anterior margin of the lower jaw may be dark
in pale as well as dark specimens. Some nonspotted
specimens exhibit adumbrations of several vertical
dusky bars on the upper half of the body.
The fins are not distinctively marked, usually
having an overall dusky appearance. Melanophores
usually concentrate along the fin elements. The
caudal is darker along its midlength; the tips of
the anal rays may be pale, especially in mature
males; there may be a dark crescentic area at the
base of the pectoral rays.
REMARKS.?At One Tree Island E. mandibularis
was collected with E. yaeyamaensis (also rarely with
E. bicolor). Superficially the two species are very
similar and difficult to tell apart in the field. They
can be separated readily, however, by the fact that
E. yaeyamaensis always has a dark forked stripe on
the fleshy pectoral base. This mark is not present
in E. mandibularis.
MATERIAL.?Australia, Queensland: Endeavour
Reef, ANSP 109694 (2:28.1-35.2), 109692 (30.3),
109696 (14:21.4-37.2), 109698 (20.6); Little Hope
SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
Island, ANSP 109693 (4:27.3-37.1), 109695 (18.6);
Big Hope Island, ANSP 109697 (29.8); Gillett Cay,
Swains Reef, AMS IB-6222 (4:28.5-35.7), IB-6237
(2:15.6-17.9); Masthead Island, Capricorn Group,
AMS 1-7112 (48.4, holotype of Ecsenius mandibu-
laris, 1-7114-6 (6: 33.6-50.6); One Tree Island,
Capricorn Group, USNM 201367 (2 of 56: 31.5-
44.3, cleared and stained), 201821 (57:29.7-49.1);
Hoskyn Island, Bunker Group, AMS IA-3585 (35.0).
In addition, several series of specimens at USNM
from One Tree Island were cursorily examined in
preparing the color pattern description, and one
specimen from USNM 201820, also One Tree Island,
was used for preparation of figure 36).
ACKNOWLEDGMENTS.?For loans of specimens and
other favors aiding in the completion of this study
I wish to thank: F. H. Talbot and J. R. Paxton,
AMS; J. E. Bohlke and J. C. Tyler, ANSP; P. H.
Greenwood, A. C. Wheeler, N. B. Marshall, and
G. Palmer, BMNH; J. E. Randall, BPBM; W. N.
Eschmeyer and P. Sonoda, CAS; S. Rajagopalan
and R. S. Lai Mohan, FMRI; H. Steinitz, HUI;
K. Deckert and C. Karrer, ISZZ; E. Tortonese,
MCSN; M. L. Bauchot, MNHN: W. Klausewitz,
NFIS: M. Smith, RU; H. Nijssen, ZMA; I. Tomi-
yama, Amakusa Marine Biological Laboratory,
Japan; L. Fishelson, UTAI; W. Freihofer, Stanford
University.
Figures 12, 17, 20, 25, 28, and 29 were drawn by
Sharon L. Chambers; Figures 13, 18, 24, 26, 27, 32,
33, 35, and 36 were drawn by Martha H. Lester;
Figures 22 and 23 were drawn by Michelle R. Davis;
Figure 21 was drawn by Sandra Collum; Figure 31
was drawn by Ann Schreitz; Figure 30 was drawn
by Barbara Holden; Figures 14, 15, 18, 19, and 34
were drawn by Jack R. Schroeder. The graphs were
prepared by Richard Goodyear.
J. A. Peters, National Museum of Natural History,
was extremely helpful in advising me on computer
use and programing. W. F. Smith-Vaniz, University
of Miami Rosenstiel School of Marine and Atmos-
pheric Sciences, and B. B. Collette, United States
Fish and Wildlife Service, called important refer-
ences to my attention. E. A. Lachner, R. H. Gibbs,
Jr., S. H. Weitzman, and R. Goodyear, Division of
Fishes, National Museum of Natural History, of-
fered critical comment on portions of the manu-
script and useful advice during discussions of some
of the problems raised during my study.
NUMBER 72 41
Considerable financial and field support was pro-
vided by the staffs of the Department of Zoology
and Marine Laboratory of Hebrew University, under
a foreign currency grant, SFC-7-0062 (2), Drs. W.
Aron and H. Steinitz, principal investigators. Much
field support was provided by the staffs of the
United States Navy Medical Research Unit Number
2, Captain R. H. Watten, commanding, and the
Imperial Ethiopian Navy, H. I. H. Commodore
Alexander Desta, commanding.
This study was aided by a grant to me from the
Smithsonian Research Foundation (SG0661084).
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Appendix
NOTE ON BANDA SEA LOCALITIES.?After W. H.
Longley's death in 1937, the Carnegie Institution
of Washington presented his fish collections to the
Smithsonian Institution. The only localities asso-
ciated with Longley's specimens were general ones
accompanying the containers holding his fishes
(Schultz, 1966, p. 194). In general, these localities
seem applicable, but it is known that some mixing
of specimens from different localities did occur.
During his lifetime Longley collected marine
fishes from only two general areas: Dry Tortugas,
Florida, and the western tropical Pacific Ocean.
Many of Longley's unlabeled specimens were ob-
viously tropical western Atlantic species and a
number of these were saved and cataloged into the
collections of the Division of Fishes, National Mu-
seum of Natural History, as having come from
Tortugas. Some of this group of specimens, how-
ever, were discarded when they were found mixed
with obviously Pacific Ocean species.
The remainder of Longley's collections were
obviously tropical western Pacific in origin, and
all but a small lot were accorded the same general
locality by L. P. Schultz, formerly curator, Division
of Fishes, when they were entered into the collec-
tions: Dutch East Indies. The small lot (catalog
numbers 160665-160717) was catalogued with the
locality datum only of Hawaii. At least one species
in this lot, Enchelyurus brunneolus (Jenkins), is a
Hawaiian endemic
Prior to 1926, Longley (1918, 1920) made one or
two trips to the tropical western Pacific where he
spent time observing fishes at Pukoo, Molokai,
Hawaiian Islands, and Pago Pago, Samoa. There
is no information that he did any collecting on these
NUMBER 72 43
trips. During 1926-27 Longley (1927) made another
trip to the tropical western Pacific. On this trip he
spent two weeks at Pukoo, nine weeks at Pago Pago,
one week at Amboina, and eight weeks at Banda
Island (the last two localities are in the Banda Sea
and are about 250 km apart) collecting and making
field observations on the habits of fishes. He also
stopped in Sydney, but mentioned nothing about
his work there.
I have been unable to locate any of Longley's
specimens that bear Samoan locality data, although
on the basis of his handwritten field notes in the
files of the Division of Fishes, National Museum
of Natural History, he definitely made collections
of fishes in Samoa. Because some of the containers
holding Longley's fishes did have specimens from
obviously mixed localities, one cannot exclude the
possibility that the Dutch East Indies locality may
be erroneous for any particular specimen.
Longley appears to have made field notes on
almost every specimen he collected during his
1926-27 trip. On the basis of his color pattern
description of a blenny from Banda Island, I feel
fairly confident that the specimen I list in the
material of E. yaeyamaensis as having come from
the Banda Sea in fact came from Banda Island..
With regard to the specimens of E. bicolor, E.
oculus, and E. bandanus that I list as having come
from the Banda Sea, I am less certain, but I
believe that none of these came from the Hawaiian
Islands or Samoa.
Ecsenius bicolor has been reported from the
Hawaiian Islands only under unusual circumstances
(see remarks under E. bicolor species account) and
has never been found in Hawaii subsequent to the
original report despite considerable collecting in
that area in recent years. Samoa has been fairly
well collected since Longley was there and no
specimens of Ecsenius have been taken there.
Ecsenius generally does not occur much farther west
than 170? east longitude, and Samoa is located at
approximately 170? west longitude. It is possible
that the wide-ranging E. bicolor may turn up in
Samoa as it is the only species that comes close to
that island group. The Banda Sea, however, is well
within the range of E. bicolor, and E. oculus and
E. bandanus are most typical of species that seem
to be limited to west of 160? west longitude.
As Longley collected only at Amboina and Banda
in the Dutch East Indies, his Ecsenius specimens
from this area could have come from either island.
The two islands are close together and I have
elected to use the locality "Banda Sea" for his
Ecsenius specimens.
It is probable that proof of a Banda Sea (Amboina
or Banda) locality for Longley's Ecsenius specimens
will never be possible. Strong evidence favoring the
Banda Sea would be the re-collection of the species
described herein as Ecsenius bandanus, and also
the re-collection of the peculiar color pattern forms
of E. oculus and E. yaeyamaensis reported here as
occurring in the Banda Sea. Longley's specimens are
much too valuable to discard because of the locality
data problem. Aside from their intrinsic value as
specimens, I wish to use the present circumstances
as a test of the predictive value of systematic work.

TABLE I.?Frequency distributions for certain meristic characters in species of Ecsenius
Species Dorsal spines
10 11
1 10
2
2
1
2
12
261
3
4
2
251
23
13
4
11
208
127
48
41
5
3
1
on
13
11
5
58
77
45
4
4
14
1
5
6
1
Dorsal rays
12 13 14 15 16 17 18 19 20 21
Anal rays
13 14 15 16 17 18 19 20 21 22 23
midas
frontalis....
pulcher
grdvieri. . ..
aroni
bicolor
namiyei. . . .
lineatus . . . .
stigmatura. .
lividinalis...
yaeyamaensis
nalolo
oculus
opsifrontalis.
prooculis
bimaculatus.
bandanus. . .
mandibularis
10
11
1 26
2 12
36
1
186
103
31
6
5
3
1
21
2
24
1
3
65
4
54
2
3
3
45
22
164
10
2
108
11
38
26
32
1
3
6
96
38
1
9
5
59
16
15
1
3
n
8
3
1
1
17
30
12
37
1
1
182
93
32
4
4
2
1
1
1
12
2
3
9
3
33
2
97
1
44
11
163
4
2
1
118
3
36
36
59
1
8
5
45
21
3
2
12
4
1
37
11
35 56
(For sexual dimorphism and geographic variation see individual species accounts and section on sexual dimorphism.)
TABLE 2.?Frequency distributions for number of vertebrae in species of Ecsenius
Species Precaudal vertebrae
9 10 11 12
Caudal vertebrae
19 20 21 22 23 24 25 26 27 28 29
Total vertebrae
29 30 31 32 33 34 35 36 37 38 39 40
midas
frontalis... .
pulcfur
gravieri. . ..
aroni
bicolor
namiyei
lineatus.
stigmatura. .
lividinalis
yaeyamaensis.
nalolo
oculus
opsifrontalis..
prooculus
bimaculatus. .
bandanus . . . .
mandibularis.
12
1 282
44
2 83
1 47
237
21
11
4
8
202
124
37
34
5
3
1
90
10
17
4
3
2
1
1
179
94
23
33
3
3
34
2
1
9
2
15
10
19
49
80
5
9
145
3
2
1
6
158
49
34
82
4
9
34
4
31
4
13
1
30 8
10
17
4
4
2
179
94
23
32
3
3
9
2
15
10
19
1
1
145
1
2
1
94
6
9
82
1
11
169
49
35
15
1
32
4
29
3
9
30 8
33 50
(For sexual dimorphitm and geographic variation see individual species accounts and section on sexual dimorphism.)
TABLE $.?Frequency distributions for certain characters in species of Ecsenius
Species
midas
Jrontalis
pulcher
gravieri
oront
bicolor
namiyei
lineatus
stigmatura
lividinalis
yaeyamaensis
nalolo
oculus
opsifrontalis
prooculis
bimaculatus
bandanas
mandibularis
Pectoral rays
12 13 14 15 16
1 11
15 236 27
60 4
1 62 6
1 39 3
4 231 4
1 23 1
11 1
1 2 1
10 1
4 119 3
2 67
44 1
2 39
5
1 2
1
2 65
Segmented caudal rays in
specimens over 26 mm SL
12 13 14 15
1 7 4
190 6
31 2
51
29
2 268
3 22
12
4
2 5 1
113 1 1
1 84 1
1 40 4
25
5
3
1
87
Total caudal rays
23 24 25 26 27 28 29 30 31 32 33 34
1 1 7 3
7 21 116 37 26 2
2 7 9 7
5 13 47 5 4
1 5 12 13 10 3
2 21 29 100 13 4
1 4 8 9 2
1 - 9 2
1 2
2 - 5 2
2 8 36 18 13 1
4 4 9 9 24 5 1
2 12 8 11 2 1
3 4 3
1 2 1
2
1
6 23 26 11
TABLE 4.?Frequency distributions for number of dentary incisor teeth (including anterior canines) in species of Ecsenius
Species Number of teeth
13 14 15 16 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64
midas
frontalis
(see also table 12)
pulcher
gravieri
aroni
bicolor
male
female
namiyei
lineatus
stigmatura
lividinalis
yaeyamaensis
male
female
nalolo
(see also table 17)
oculus
(see also table 18)
opsifrontalis
prooculis
bimaculatus
bandanas
mandibularis
2 - 2 8
1 1 1 4 9 22 40 39 51 28 32 9 12 3
2 3 7 9 10 3 8 11 2 1
2 - 3 8 10 11 14 13 3 4 1
1 - - 1 1 2 8 9 8 4 4 1
1 -
1 2 4 13 53 32 26 3 3 1
1 _ _ _ _ _ _ 2 13 22 36 15 14 1 1
1 1 1 1 2 3 5 4 3 3 1
4 1 2 5 1
1 2 - 1
1 1 4 3 - 1
1 2 13 10 12 18 12 2 3 1
1 - - 2 - - 6 6 14 8 1 1 6 4 2 1
1 1 2 4 4 9 15 6 8 10 11 14 16 16 12 13 12 11 7 5 3 2
1 1 1 3 - 2 3 4 3 3 3 5 4 4 2 3 1 1
1 2
1 3 6 3 15 9 - 3
2 - - 1 - - 1
4 4 7 17 18 10 6 2 1
G1
TABLE 5.?Frequency distributions for depth of dorsal fin notch (to nearest ninth of length of first dorsal ray) and length of last dorsal
spine as percent standard length in species of Ecsenius
Species
Notch depth
0 1 2 3 4 5 6 7 8 9
Last dorsal spine length (lower class limits)
0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0 8.0 9.0 10.0 11.0 12.0 13.0 14.0 15.0 16.0 17.0 18.0 19.0 20.0
midas
frontalis...
pulcker... .
gravieri. . .
aroni
bicolor. . . .
namiyei. . .
Uneatus. . .
stigmatura.
lividinalis.
12
277
24
- 1
14 18 5 1
2 2 17 33 7
1 24 1
2 1 9 42 45 13
6 26
2 17 9
6 15 20
1
1 1
9 4 1
18 25 21 9 15 10
2 15 37 12 2
2 1 9 8
4 3 1
yaeyamaensxs. ?
nalolo
oculus
opsifrontalis
prooculis
bimaculatus
bandanus....
mandibularis. . ..
3 10
1 3
7 101
3 14 40 19
1 - 45
4 18
5
1 2
1
7 55
7
2
2 27 64
1 26 42
21 13 -
4 16 3
1 3 1
3
1
34 22
1 - 1 - 1
50 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
TABLE 6.?Frequency distributions for certain characters in species of Ecsenius
Species
Lateral line extends posteriorly to below
level of dorsal Jin element
7 8 9 10 11 12 13
Pseudobranchial filaments
5 6 7 9 10 11 12
midas
frontalis... .
pulcher
gravieri. . ..
aroni
bicolor
namiyei. . ..
liruatus. . . .
stigmatura. .
lividinalis...
yaeyamaensis
nalolo
oculus
opsifrontalis.
prooculis....
bimaculatus.
bandanas. . .
mandibularis
8
3
4
3
7
1
1
1
2
2
36
15
41
13
3
3
-
9
3
1
161
35
30
25
51
1
13
5
74
66
2
3
25
4
64
5
2
34
27
3
3
1
1
46
16
1
1
37
24
1
1
5
1 28 12
5
4
1
2
11
5
1
81
28
10
7
163
3
10
4
7
77
21
17
16
5
3
1
45
-
3
8
4
3
26
18
1
1
38
24
1
2
1
1
2
3
1
3
NUMBER 72 51
TABLE 1?Frequency distributions of third dorsal spine length as percent standard length in species of
Ecsenius
Species
Percent SL (lower class limits)
7.0 8.0 9.0 10.0 11.0 12.0 13.0 14.0 15.0 16.0 17.0 18.0 19.0 20.0 21.0 22.0
midas
Males...
Females.
frontalis
Males...
Females.
pulcher
Males...
Females.
gratneri
Males...
Females.
aroni
Males...
Females.
bicolor
Males...
Females.
namiyei
Males...
Females.
lineatus
Males...
Females.
stigmatura
Females.
lividinalis
Males...
Females.
yaeyamaensts
Males...
Females.
nalolo
Males...
Females.
ocutus
Males...
Females.
opsifrontalis
Males...
Females.
prooculis
Males...
bimaculatus
Males...
bandanas
Males...
mandibularis
Males...
Females.
2
1
1
2
1
-
1
2
2
1
1
1
1
1
-
-
1
3
1
1
1
14
8
4
-
1
4
2
_
3
-
1
13
10
7
6
5
8
2
23
8
3
3
_
3
17
10
2
1
3
3
1
9
9
3
2
12
7
5
5
16
in
5
2
5
2
25
22
5
4
7
5
2
13
7
-
11
3
7
8
1
1
1
1
1
11
5
10
16
6
2
5
1
3
6
9
-
4
2
1
1
2
1
2
13
3
2
2
4
3
1
4
5
3
1
_
1
2
3
1
2
1
6
3
3
_
2
2
2
1
1
1
1
2
1
52 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
TABLE 8.?Frequency distributions of fifth dorsal ray length as percent standard length in species of Ecsenius
Species
Percent SL (lower class limits)
10.0 11.0 12.0 13.0 14.0 15.0 16.0 17.0 18.0 19.0 20.0 21.0 22.0
midas
Males
Females
frontalis
Males
Females
pulcher
Males
Females
gravteri
Males
Females
aroni
Males
Females
bicolor non-Australian
Males
Females
bicolor Australian
Males
Females
namiyei
Males
Females
stigmatura
Males
Females
lividinalis
Males
Females
yaeyamaensis
Males
Females
nalolo
Males
Females
oculus
Males
Females
opsifrontalis
Males
Females
prooculis
Males
bimaculatus
Males
bandanas
Males
mandibularis
Males
Females
10
4
9
19
13
6
1
3
5
2
26
14
1
10
4
1
1
3
17
14
1
13
8
10
7
2
2 1
5 5
2 1
NUMBER 72 53
TABLE 9.?Frequency distributions of length of longest caudal ray as percent standard length in species of
Ecsenius
Species
midas
Males
Females
frontalis
Males
Females
ptdcher
Males
Females
gravieri
Males . . .
Females
aroni
M a l e s . . . .
Females
bicolor
Males
Females
namiyei
Males
Females
lineatus
Males
Females..
stigmatura
Males
Females..
lividinalis
Males
Females..
yaeyamaensis
Males
Females
nalolo
Males
Females
oculus
Males
Females
opsifrontalis
Males
Females
prooculis
Males
bimaculatus
Males
bandanas
Males
mandibularis
Males
Females
18.0 20.0
4
10
1
1 4
1
1
4
3
2 3
2
1
1
22.0
13
49
2
3
2
4
2
2
17
2
2
1
8
29
2
11
?,
12
1
5
8
24.0
1
26
32
2
1
9
8
5
11
4
3
1
1
26
11
14
n
s
3
?5
1
1
6
26.0
2
2
13
5
1
4
1
2
6
1
4
1
2
4
4
6
7
2
1
2
1
28.0
2
12
2
2
4
2
1
7
-\
1
1
3
2
2
1
4
Percent SL (lower class limits)
30.0 32.0 34.0 36.0 38.0 40.0
11
1
2
?
1
4
?
?
1
4
7.
1
3
3
1
7
4
3
7
3
3
3
1
1
6
1
5
4
2
6
1
1
1
1
3
1
3
3
10
_
2
1
2
2
4
4
?.
6
1
1
1
6
3
-
8
2
42.0
4
3
1
2
2
44.0 46.0 48.0 50.0 52.0
4 - 1
2
1
2 1 3 3 3
54 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
TABLE 10.-Frequency distributions of nasal cirrus length as percent standard length in species of Ecsenius
Species
midas
Males
F e m a l e s . . .
frontalis
Males
FrmaVs,, ,
(ndcktr
Males
Females
gravtert
Males
Females
ofont
Males
F e m a l e s . . . .
bicolor non-Australian
Males
Females
bicolor Australian
Males
Females
namiyei
Males
Females.. .
lineatus
Males
Females
sttgmatura
Males
F e m a l e s . . . .
lividinalis
Males
Females.
yaeyamaensis
Males
Females
nalolo
Males
Females
oculus
Males
Females...
opsifrontalis
Males
Females.
prooculis
Males
bimaculatus
Males
bandanus
Males
mandibularis
Males...
Females
0.0
1
1
1
3
1.0
1
1
1
2
1
27
29
2
5
5
2
3
13
2.0
1
6
7
9
10
1
2
1
32
17
17
24
4
8
2
1
1
16
1
3.0
1
2
1
1
1
3
7
7
4
3
2
9
4
1
to
 
to
17
2
4
6
1
6
6
1
4.0
1
1
7
2
4
3
14
7
7
5
1
6
3
1
2
4
8
1
4
3
Percent SL {lower class limits)
5.0 6.0 7.0 8.0 9.0 10.0 11.0 12.0 13.0
3
1
15
17
4
3
3
20
9
to
 
to
3
4
1
2
2
1
1
1
15
29
1
2
9
5
9
2
1
1
2
1
21
14
1
3
1
5
5
10 3 6 2 2 1
11 6 6 5 1
1
1
1
4 1
(In E. fttcofor and E. namiyei, which have two cirri on each nostril, the posterior cirrus was measured.)
TABLE 11.?Frequency distributions for certain characters of the three color pattern forms of Ecsenius frontalis
Locality and form
Dorsal spines
11 12 13
Dorsal rays
17 18 19 20 21
Anal rays
18 19 20 21 22
Precaudal vertebrae
10 11 12
Caudal vertebrae
23 24 25 26
Pectoral rays
14 15 16
Israel
frontalis form
males
females
albicaudatus form
males
females
Sudan
frontalis form
males
females... .
Ethiopia
frontalis form
males
females
albicaudatus form
males
females
nigrovittatus form
males
females
Gulf of Aden
frontalis form
males
females....
4 36
1 28
2 26
2 25
40
1 45
2
4
25
1 24
4 18 17 2
15 14
11 16
3 15 11 1
1
1 1
2
1
22
36
1
4
18
19
16
10
1
6
8
1 1
1
3 21 14
18 10
14 10
1 19 10
2
3
1
1
2
22
32
1
3
18
17
16
11
1
5
7
1 37
29
27
31
40
1 45
2
4
25
26
4 24 10
23 6
21
1 23
2 30
2 24
21
26
1
1
16
30
3
12
14
24
16
2
1
12
10 2
3
1
1
2
4
35
45
1
3
22
23
2
1
Dau from Egyptian and Gulf of Suez localities are combined with dau from Israel; dau from all southern Red Sea localities are combined with dau from
Ethiopia.
TABLE
Locality and form
Israel
frontalis form
males
females
albicaudatus form
males
females
Sudan
frontalis form
males .
females . . . .
Ethiopia
frontalis form
males
females
albicaudatus form
males
females
nigrovittatus form
males
females
Gulf of Aden
frontalis form
males
females
12.?Frequency distributions for
25
1
1
1
1
1
1
1
Total caudal fin rays
(procurrent and principal)
26 27 28 29
4
1
1
3
6
2
1
10
10
7
10
1
25
23
1
1
12
13
1
1
1
3
2
1
7
9
1
8
3
2
2
2
3
3
6
1
1
3
3
30
1
1
certain characters o F the threecolor pattern forms
Dentary incisor teeth (including anterior canines)
40 41 42 43 44 45 46 47 48 49 50 51 52
1
1 - 1 1 3
1 4
1 - 1 1
1
2
1
1
6 12
8 12
1
3 5
4 5
1 1
?
5
1
6
4
7
7
S
1
4
3
4
8
1
7
10
1
1
9
ft
7
1
?
?
s
9 3 5
6 4 3
8
7 2 4
1
1
of Ecsenius frontalu
53
1
2
Lateral line terminates
below level of dorsal spine
8 9 10 11 12
2 6
7
3
6
1
2
1 1
1
7
2
77
18
7
17.
1
27
34
1
4
17
15
2
1
1
1
2
1
6
8
1 1
5
Data from Egyptian and Gulf of Suez localities are combined with data from Israel; data from all southern Red Sea localities are combined with data from
Ethiopia.
TABLE 13.?Frequency distributions for measurements of certain fin elements of the three color pattern forms of Ecsenius frontalis
(see also figure 6)
?z
cI
Locality and form
Third dorsal spine length as percent SL
Lower class limits
10.0 11.0 12.0 13.0 14.0 15.0 16.0 17.0
Last dorsal spine length as percent SL
Lower class limits
10.0 11.0 12.0 13.0 14.0 15.0 16.0 17.0 18.0 19.0 20.0 12.0 13.0 14.0
Fifth dorsal ray length as percent SL
Lower class limits
\.O 15.0 16.0 17.0 18.0 19.0 20.0 21.0 22.0
Israel
frontalis form
males
females
albicaudatus form
males
females
4 1
2 -
2 1
1 4 1
1
2
_
5
3
1
5
5
5
4
1
3
1
-
1
1
1
1
1
1
1
2
1
2
1
3
3
1
6
5
3
1
3
-
1
6
1
1
_
_
1
_
_
2
Sudan
frontalis form
males
f e m a l e s . . . .
Ethiopia
frontalis form
males
females
albicaudatus form
males
females
nigrovittatus form
males
females
3 3 4
3 2 2
1 1
1
3 5
7 7
6
3 8 1
3 1 2
1
- 1
5 4
3
1 - 1
1 3
2 2 4 6
6 4 1
1 - - 1
2 3 3 4
3 - 3 1
Data from Egyptian and Gulf of Suez localities are combined with data from Israel; data from all southern Red Sea localities are combined with data from
Ethiopia.
TABLE 14.?Frequency distributions for measurements of nasal cirrus and longest caudal ray of the three color pattern forms of Ecsenius
frontalis (see also figures 7-10)
Locality and form
Nasal cirrus length as percent SL
Lower class limits
1 . 0 2 . 0 3 . 0 4 . 0 5 . 0 6 . 0 7 . 0 8 . 0 9 . 0 1 0 . 0 1 1 . 0 1 2 . 0 1 3 . 0
Longest caudal ray length as percent SL
Lower class limits
20.0 22.0 24.0 26.0 28.0 30.0 32.0 34.0 36.0
Israel
frontalis form
males
females
albicaudatus form
males
females
Sudan
frontalis form
males
females....
Ethiopia
frontalis form
males
females
albicaudatus form
males
females
nigrovittatus form
males
females
1
5
_
6
5
1
1
3
2
1
1
3
3
1
6
-
2
1
3
3
1
3
4
2
1
_
4
1
1
1
1 1
2
10
1
9
1 1
4
2
2
7
5
7
7
7
14
2
1
7
10
6
1
7
4
4
1
1
1
1
1
1
1
3
5
1
1
8
15
3
2
11
13
17
1
3
2
6
2
_
1
_
Data from Egyptian and Gulf of Suez localities are combined with data from Israel; data from all southern Red Sea localities are combined with data from
Ethiopia.
NUMBER 72 59
TABLE 15.?Sexual dimorphism and geographic variation in frequencies of some meristic characters as indi-
cated by specimens of Ecsenius bicolor from selected localities
Locality
Australia
Males
Females . . . .
New Hebrides
Males
Females. . . . . .
Kapingamarangi
Males
Females
Ponape
Males
Females
Marshall Islands
Males
Females
South China Sea
Males
Females.
Malacca Straits
Males
Females
Christmas Island (Indian
Ocean)
Females
15
1
1
1
1
16
2
1
4
4
9
0
?
9
1
?
Dorsal rays
17 18
21
31
4
1
21
8
8
4
24
2
1
2
5
20
2
1
1
5
1
Av.
17.5
17.0
17.0
16 2
16.9
16.5
17.0
16.3
16.8
16.1
17.8
17.3
15.5
15.7
17.0
17 18
1
4
11
1 1
6
1
Anal rays
19 20 21
12
28
4
5
23
13
6
2
7?
6
7
7.
7
4
28 1
6
2
3
2
2
5
3
1
Av.
19.7
19.1
19.3
19.0
19.1
18.8
19.2
18.2
19.0
18.5
19.7
20.0
19.0
18.7
19.2
Caudal vertebrae
23 24 25 Av.
7
20
2
1 4
16
16
7
6 7
15
10
2
1
2
3
3
28
13
4
8
1
10
1
4
2
1
24.8
24.4
24.7
23 8
24.3
24.0
24.1
23.5
24.4
24.1
24.7
24.7
24.0
24.0
24.2
60 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
TABLE 16.?Sexual dimorphism in frequencies of some meristic characters as indicated by specimens of
Ecsenius namiyei from Taiwan and Escenius pulcher
Species
namiyei
M a l e s . . .
pulcher
Males
Females
18
3
7
Dorsal rays
19 20
1
7
17
17
13
1
14
2
Av.
19.9
19.1
19.3
18 S
19
1
20
1
Anal
21
4
8
11
9
rays
22
10
?1
14
23
1
Av.
21.7
21.0
21.6
21.5
25
1
1
Caudal vertebrae
26 27 28
5
7
1
3
8
21
9
S
3
Av.
26.5
25.9
27.1
27.0
TABLE 17.?Frequency distributions for numbers of dentary incisor teeth (including anterior canines) in
Ecsenius nalolo
Locality
Northern Red Sea and
Gulf of Aqaba
Males
Females
Middle Red Sea
Females
Southern Red Sea
Males
Females
Indian Ocean
Males
Females
Number of teeth
42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63
6 8 14 15 13 4 2 2
3 1 1 4 9 7 9 7 5 3 2
1 - 2 2 1 - 2
1 1
1 1 2 2 3 6 7 3 4 3 1
1 1 1 4 1 4 4 4 3 1
TABLE 18.?Variation in meristic characters and number of dentary incisor teeth (including anterior canines) in populations oi Ecsenius
oculus
Locality
R y u k y u s
T a i w a n
H o t d u S u d . .
T h a i l a n d . . . .
P a l a u
M e n t a w e i I s l a n d . . . .
Strai t o f M a l a c c a . . . .
B a n d a S e a . .
N e w H e b r i d e s . . . .
12
1
1
Dorsal rays
13 14
3
3
1
3
1
1
12
12
1
1
1
4
15
2
1
Anal rays
14 15 16 17
3
3
1
3
1 1
1
11 3
13
1
1
2
4
Caudal vertebrae
21 22 23 24
1
1
1
1
4
11
3
1
2
1
1
9 1
3
1
2
4
47 48 49 50 51
1 - 1 -
1 -
1 - 1
1 -
52
1
1
-
53
-
1
2
Dentary incisor teeth
54 55 56 57
1
1
1
1
1 3 3
2
58
CO
 
C
M
59
CM
 
C
M
 
<
-
60
1
3
61
1
1
62 63 64
2 1 1
1
Localities arranged from north to south. Dashed line separates localities north of equator from those south of equator.

FIGURES 12-36
383-026 O - 70 - 5

NUMBER 72 65
FIGURE 12.?Ecsenius midas, ANSP 111148, holotype, male, 74.4 mm SL,
D'Arros Island, Amirante Islands, Seychelles. Insert presents ventral
aspect of region around anus.
FIGURE 13.?Ecsenius frontalis, USNM 200613, male, 58.6 mm SL,
frontalis color pattern form, Strait of Jubal, Egypt, Red Sea.
FIGURE H.-Ecsenius frontalis, USNM 204650. female. 37.3 mm SL, albicaudatus
color pattern form, El Himeira, Sinai Peninsula, Gulf of Aqaba.
66 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
10
FIGURE 15.?Ecsenius frontalis, USNM 204490, male, 38.7 mm SL,
nigrovittatus color pattern form. Sheikh el Abu, Ethiopia, Red Sea.
l cm FIGURE 16.?Ecsenius pulcher, USNM 201571, male, 32.9 mm SL,banded form, Tarut Bay, Ras Tanura, Persian Gulf.
cm FIGURE 17.?Ecsenius gravieri, HUI HUJ-F-4382, male, 38.6 mm SL,
pale form, Dahab, Sinai Peninsula, Gulf of Aqaba.
NUMBER 72 67
10
FIGURE 18.?Ecsenius gravieri, USNM 204480, female, 40.1 mm SL,
dark form, Sheikh el Abu, Ethiopia, Red Sea.
FIGURE 19.?Ecsenius aroni, USNM 204468, male. 36.8 mm SL, El Himeira,
Sinai Peninsula, Gulf of Aqaba.
FIGURE 20? Ecsenius bicolor, USNM 201368, male, 66.3 mm SL,
One Tree Island, Queensland, Australia.
68 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
l c m FIGURE 21.?Ecsenius bicolor, NFIS 9578, female, 49.1 mm SL,
Madewaru Island, Fadiffulu Atoll, Maldives.
icm , FIGURE 22.?Ecsenius namiyei, USNM 203125, female,63.6 mm SL, north end of Taiwan.
icm FIGURE 23.?Ecsenius lineatus, USNM 203129, male, 48.2 mm SL,just SW of Yeh-Liu, north end of Taiwan.
NUMBER 72 69
1 cm i i
5 mm
FIGURE 24.?Ecsemus stigmatura, USNM 111878, female, 36.6 mm SL, Tomahu Island, Indonesia.
Insert presents ventral aspect of region about anus.
i cm T
FIGURE 2S.-Ecsenius stigmatura, USNM 201815, male, 37.7 mm SL, Pulav Gaya, Darvel Bay,
Borneo. Insert presents ventral aspect of region about anus.
SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
FIGURE 26.?Ecsenius lividinalis, USNM 144292, male, 25.8 mm SL, Munda Lagoon, New Georgia,
Solomon Islands. Insert presents ventral aspect of region about anus.
l cm
FIGURE 27.?Ecsenius yaeyamaensis, USNM 203136, female, 42.6 mm SL,
typical color form Ch'uan-fan-shih, south end of Taiwan.
FIGURE 28.?Ecsenius yaeyamaensis, USNM 201818, male, 38.1 mm
SL, spotted form, One Tree Island, Queensland, Australia.
NUMBER 72 71
cm
FIGURE 29.?Ecsenius yaeyamaensis, USNM 202477, male, 26.6 mm SL,
striped form, Banda Sea, Indonesia.
FIGURE SO.?Ecsenius nalolo, USNM 203072, male 43.3 mm SL, Aldabra Atoll, Indian Ocean
(penultimate dorsal spine abnormally reduced). Insert presents ventral aspect of head.
-
72 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
i cm
FIGURE 31.?Ecsenius oculus, USNM 201522, male, 39.9 mm SL, Pulo Mega, Mentawei Islands,
Indonesia (forked nasal cirrus is atypical).
5 mm
FIGURE 32.?Ecsenius opsifrontalis, CAS GVF-468, male, 325 mm SL, Kapingamarangi Atoll.
Insert presents anterior view of head.
NUMBER 72 73
l cm
FIGURE S3.?Ecsenius prooculis, USNM 201819, male, 305 mm SL, Simpson Harbour, Rabaul, New
Britain. Insert presents enlarged view of two of the anal rays exhibiting fleshy envelopment of
the ray tips, a common characteristic of presumably mature males of most species of Ecsenius.
\0
FIGURE 34.?Ecsenius bimaculatus, USNM 203922, male, 31.7 mm
SL, Pulav Bohidulong, Darvel Bay, Borneo. Insert presents region
of body hidden by pectoral fin.
74 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY
/ /
cm
FIGURE 35.?Ecsenius bandanus, USNM 195717, holotype, male, 31.4 mm SL,
Banda Sea, Indonesia.
L_^^_J
FIGURE 36.?Ecsenius mandibularis, USNM 201820, male, 51.1 mm SL, One Tree Island,
Queensland, Australia.
U.S. GOVERNMENT PRINTING OFFICE : 1970 O - 383-026
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full pages on a different stock of paper, they will be termed Plates, and individual components
should be lettered (Plate 9b) but may be numbered (Plate 9: figure 2). Never combine the
numbering system of text illustrations with that of plate illustrations. Submit all legends on pages
separate from the text and not attached to the artwork.
In the bibliography (usually called "Literature Cited"), spell out book, journal, and article
titles, using initial caps with all words except minor terms such as "and, of, the." (For capitaliza-
tion of titles in foreign languages, follow the national practice of each language.) Underscore
(for italics) book and journal titles. Use the colon-parentheses system for volume, number, and
page citations: "10(2) :5-9." Spell out such words as "figures" and "plates" (or "pages" when
used alone).
For free copies of his own paper, a Smithsonian author should indicate his requirements on
"Form 36" (submitted to the Press with the manuscript). A non-Smithsonian author will receive
50 free copies; order forms for quantities above this amount with instructions for payment will be
supplied when page proof is forwarded.