CSIRO PUBLISHING 
www.publish.csiro.au/journals/ajz Australian Journal of Zoology, 2005, 53, 35?49 
Skinks currently assigned to Carlia aerata (Scincidae : Lygosominae) 
of north-eastern Queensland: a preliminary study of cryptic diversity 
and two new species 
Patrick J. Couper^'^, Jessica Worthington Wilmer^, Lewis Roberts^, Andrew P. Amey^ 
and George R. Zu^ 
"^Queensland Museum, PO Box 3300, South Bank, Brisbane, Qld 4101, Australia. 
'^Shipton's Flat, via PO Cooktown, Qld 4871, Australia. 
?^Smitlisonian Institute, PO Box 37012, Washington, DC 20013-7012, USA. 
^Corresponding author. Email: patrickc@qm.qld.gov.au 
Abstract. A preliminary investigation of genetic diversity in Carlia aerata, by sequencing the mitochondrial ND4 
gene, revealed the presence of two cryptic species, described herein. The sequence data was added to an existing 
phylogeny to discern molecular relationships. Interestingly, genetic affinities lie not with C. aerata, the species to 
which they key. Instead, one has affinities with C. tanneri, the other with C.foliorum. This casts doubt on the validity 
of morphological characters alone to infer relationships within this genus. Despite low levels of genetic divergence 
from sister taxa, the new species can be diagnosed from these by morphological characters that exhibit little or no 
intraspecific variation. The addition of these new species to the gene tree did not enhance resolution of the 
phylogenetic relationships at the deeper nodes of the Carlia tree. The discovery of these two new cryptic species 
provides further support for a previously suggested rapid mid-Miocene diversification of Carlia that may have 
resulted from the successful expansion of a rainforest-dwelling ancestor into the expanding woodlands associated 
with Miocene climate fluctuations. 
Introduction 
Australia's reptiles are a diverse group with more than 830 
described species; many others are recognised but still await 
description (Wilson and Swan 2003; Couper and Hoskin, 
unpublished data; Sadlier, personal communication). 
Molecular techniques provide a means of recognising faunal 
diversity that can remain undetected using traditional 
morphological criteria. Over the last decade, genetic evi- 
dence has become increasingly important in clarifying 
species boundaries and identifying cryptic elements in the 
fauna, which often represent highly divergent lineages 
(Mather 1990; Couper and Gregson 1994; James et al. 2001; 
Donnellan et al. 2002). The extent of cryptic speciation 
within Australian reptiles remains unknown, but given the 
small proportion of taxa examined (at least 24 of 141 genera 
have had at least one species group examined: S. Donnellan, 
personal communication) and the nimiber of cryptic species 
already detected (25 published and other studies identifying 
species complexes within existing taxa), it could be consid- 
erable. Indeed, Australian Cryptoblepharus, currently under 
review, are now known to consist of 23 species where only 
six were previously recognised (Horner 2003). Attempts to 
describe cryptic species identified by molecular data are 
often thwarted by a lack of diagnosable morphological char- 
acters (Moritz et al. 1993; Schneider et al. 1999). Hence 
faunal diversity is often recognised only in a phylogenetic 
context, without being placed in a taxonomic framework. 
Land-management authorities can therefore overlook these 
genetic lineages in a system where fauna-conservation 
priorities are linked to name-based lists. 
The genus Carlia (rainbow skinks) occurs widely in 
northern and eastern Australia (and also New Guinea), where 
it currently comprises 30 species and shows extreme 
morphological conservatism relative to many other con- 
generic lizard species (Storr 1974; Ingram and Covacevich 
1988, 1989; Couper 1993; Couper et al. 1994). Recent 
studies on Carlia members indicate that cryptic speciation 
may predominate in this genus (Schneider et al. 1999; 
Stuart-Fox et al. 2002). Highly divergent lineages have been 
shown to exist within C. rubrigularis (Schneider et al. 1999) 
and C amax, C gracilis, C. jarnoldae, C schmeltzii and 
C. vivax (Stuart-Fox et al. 2002). This study aims to further 
elucidate the extent of diversity within Carlia by investi- 
gating observed colour pattern differences in populations of 
C. aerata from north-eastern Queensland. This species 
occurs as two distinct colour forms: individuals are either 
dorsally dark brown with dark tails or medium brown with 
reddish hind limbs and tails. Examination of specimens in 
the Queensland Museum's herpetological collection showed 
that both occur sympatrically at four localities (Palmer River, 
Shipton's Flat, Isabella Falls and Laura). The most recent 
description of this small, litter-dwelling species was by 
) CSIRO 2005 10.1071/ZO04010    0004-959X/05/010035 
36 Australian Journal of Zoology P. J. Couper et al. 
Ingram and Covacevich (1988). These authors, recognising 
the existence of sexual dichromatism in Carlia species, 
regarded the red-tailed form as breeding males. We do not 
concur with this conclusion. The occurrence of red-tailed 
females and juveniles argues for a distinct species, not sexual 
dimorphism. Molecular data (mitochondrial protein coding 
ND4 gene) offered a means to test our hypothesis that the 
observed colour pattern differences in 'C aerata actually 
represent distinct species. 
Materials and Methods 
Genetics 
Samples, PCR and Sequencing 
Tissues were obtained from seven specimens initially identified as 
C. aerata collected at three different localities in Queensland (Table 1). 
This sample includes the two sympatric colour forms of 'C. aerata' 
recorded at Shipton's Flat (15?48 S, 145?16 E), via Cooktown. Tissues 
were available for analysis from another two Queensland Carlia 
species: C. seshrauna and C. tanneri. The latter species was also anal- 
ysed by Stuart-Fox et al. (2002), but was assigned to the wrong species 
in 'material examined' (see Results). Total genomic DNA was extracted 
from all tissues using a standard kit (DNeasy Tissue Kit, Qiagen). In 
order to discern the phylogenetic relationships of these new Carlia 
samples, we targeted the same region of the mitochondrial ND4 gene 
used by Stuart-Fox et al. (2002) to generate their recent molecular 
phylogeny of the Carlia group. Furthermore, we were able to access and 
download from GenBank all the other ND4 sequences generated by 
Stuart-Fox et al. (2002) for Carlia species (accession numbers 
AJ290504-53). While the same outgroup species used by Stuart-Fox 
et al. (2002) were unavailable, ND4 sequences were obtained from two 
other species also belonging to the Pseudemoia group of lygosomine 
skinks: Morethia butleri (accession number AY169647) and Eugon- 
gylus rufescens (accession number AY169642). 
Using the primer pairs listed in Stuart-Fox et al. (2002), the same 
726-bp region of the mitochondrial ND4 gene was amplified and 
sequenced. However, PCR conditions and amplification parameters 
varied from that paper. Each 25-nL reaction contained to a final concen- 
tration 1 X Taq polymerase buffer, 0.4 ^M each primer; 0.8 mM dNTPS, 
2.0 mM MgClj and 0.75 U of Taq polymerase. The use of the hot start 
polymerase AmpliTaq Gold (Applied Biosystems) required an initial 
denaturation at 95?C for 10 min before the commencement of the 
remaining cycle parameters; then followed 35 cycles of 95?C for 30 s, 
50?C for 45 s, 72?C for 45 s and a final extension 72?C for 5 min, 22?C 
for 30 s. 
PCR products were gel purified and sequencing reactions carried 
out according to standard ABI PRISM dye-deoxy terminator sequenc- 
ing protocols using Big Dye Terminator ver 1.1. Sequences from the 
new specimens have been deposited in GenBank nucleotide sequence 
database (accession numbers AY533654-62). 
Phylogenetic analysis 
Chromatographs were checked and all sequences were aligned 
using Se-Al v2.0al0 (Rambaut 1996). Maximum parsimony analyses, 
identical to those performed by Stuart-Fox et al. (2002) were conducted 
using PAUP* v4.bl0 (Swofford 2002). Trees were derived without 
bootstrapping using heuristic searches with tree bisection reconnection 
branch swapping and 1000 random stepwise sequence additions. A 
bootstrap tree was generated in the same manner using only 10 stepwise 
sequence additions with 1000 bootstrap pseudoreplications. 
Bayesian analyses were carried out using MrBayes v2.01 
(Huelsenbeck and Ronquist 2001) and posterior probabilities were 
calculated using a Marko chain, Monte Carlo sampling approach. These 
analyses used the TVM (transversion model) + T (gamma distribution 
of rates) and I (proportion of invariant sites) model of sequence evo- 
lution, as was suggested by Modelltest (Posada and Crandall, 1998). 
Starting trees were random and four simultaneous Markov chains were 
run for 1000000 generations with trees sampled every 100 generations. 
To generate the consensus tree, burnin values were set at 50000 gener- 
ations based on empirical values of stabilising likelihoods. 
Morphometrics 
All body measurements were taken using Mitutoyo electronic callipers. 
Supraciliaries, supralabials, infralabials and subdigital lamellae on the 
fourth toe were counted on the left side only. Both left and right counts 
are given for type specimens. The supraciliaries represent the scale row 
starting behind the prefrontal that has full contact with the supraoculars 
along its upper edge. Infralabials are the series fully contained between 
the mental and the posterior margin of the last supralabial. Subdigital 
lamellae were counted between the claw and the 3rd/4th toe junction. 
The total number of enlarged nuchals is given. Only original tails were 
included in the morphometric analysis (largely assessed by eye; 
X-rayed for C. malleolus, sp. nov). Abbreviations for body measure- 
ments are as follows: snout-vent length (SVL); forelimb (axilla to tip of 
longest digit, LI); hind limb (groin to tip of longest digit, L2); axilla to 
groin (AG); tail length (original tail, posterior margin of preanal scales 
to tip, TL); head length (tip of snout to mid-anterior edge of ear 
opening, HL); head width (level with posterior margin of parietal 
shields, HW). Configuration of the preocular/presubocular scales is 
discussed and illustrated in Appendix 1. Colour pattern descriptions 
include detail that is visible only with magnification. 
Table 1.    Species samples and localities for molecular analysis 
Museum registration codes are as follows: QMJ, Queensland Museum; USNM-Field Herp, Smithsonian Institution, National 
Museum of Natural History, USA 
Initial species identification    Locality Museum registration no. Final species identification'^ 
Carlia 
Carlia 
Carlia 
Carlia 
Carlia 
Carlia 
Carlia 
Carlia 
Carlia 
aerata 
aerata 
aerata 
cf. aerata 
aerata 
aerata 
aerata 
seshrauna 
tanneri 
Donkey Springs, Bulleringa NP, Qld 
Donkey Springs, Bulleringa NP, Qld 
Donkey Springs, Bulleringa NP, Qld 
Shipton's Flat, Cooktown, Qld 
Shipton's Flat, Cooktown, Qld 
Shipton's Flat, Cooktown, Qld 
Hann River, Cape York, Qld 
Klondyke, Cape York, Qld 
Mclvor River Crossing, Qld 
QMJ74495 Carlia abscondita 1 
QMJ74496 Carlia abscondita 2 
QMJ74498 Carlia abscondita 3 
QMJ78404 Carlia malleolus 
QMJ78405 Carlia aerata 1 
QMJ78378 Carlia aerata 2 
QMJ78381 Carlia aerata 3 
USNM-Field Herp 36306 Carlia seshrauna 2 
QMJ62424 Carlia tanneri 2 
?^Numbers refer to how the samples appear in the phylogeny (Fig. 1). 
Cryptic diversity within Carlia Australian Journal of Zoology        31 
In 'Comparison witli other species', the new taxa are separated from 
other Carlia species (and the koshlandae/sadlieri/timlowi subgroup of 
Menetia) by published descriptions (Ingram and Covacevich 1988, 
1989; Greer 1991; Couper 1993; Cogger 2000) and the examination of 
museum specimens (Appendix 2). 
Scale counts and measurements were compared between samples 
using ANOVAs and unpaired two-tailed f-tests. In most cases the results 
were uninformative, largely due to the small sizes of the Bulleringa and 
Mt Mulligan samples. 
Authorships for the new taxa do not follow that of the paper as a 
whole. 
Results 
Phylogeny o/Carlia 
The addition of the new species sequences failed to enhance 
the resolution of the phylogenetic relationships at deeper 
nodes of the Carlia tree. Our results are essentially the same 
as those reported by Stuart-Fox et al. (2002), with both 
maximum-parsimony trees (consensus and bootstrap) and 
the trees generated by Bayesian inference (consensus) 
showing litde support for any major resolution among 
lineages within Carlia (Fig. 1). The same sister-species 
groupings at shallower nodes of the tree reported in that 
study are in general also found here (Fig. 1). 
Two errors appear in the appendix of Stuart-Fox et al. 
(2002). These, however, do not affect their published phylo- 
geny. First, the registration number provided for the C. mac- 
farlani sample should be corrected to NTMR23034 (listed as 
NTMR20234). The number given belongs to a specimen of 
Litoria caerulea. Second, specimen QMJ62425, listed as 
C. zuma, is a topotypic specimen of C. tanneri, which groups 
with the new C tanneri sequence in our gene tree 
(QMJ62424; our specimen was collected at the same time and 
place as that used by Stuart-Fox et al. (2002). The C zuma 
tissues used in the study of Stuart-Fox etal. (2002) came from 
the material listed as C tanneri, SAMR32519. This speci- 
men, unavailable for examination, was collected at Mt Spec, 
Queenland. C. tanneri does not occur this far south, being 
narrowly restricted to riverine rainforests and monsoon 
forests in the Cooktown region (Ingram and Covacevich 
1988). C. zuma is morphologically similar to C tanneri: both 
species have moveable lower eyelids, seven supralabials, 27 or 
fewer midbody scale rows and flat ear lobules (Ingram and 
Covacevich 1988; Couper 1993). C. zuma-like specimens are 
known to occur at Mt Spec and are represented in the 
Queensland Museum's herpetological holdings. We note that 
the affinities of this population remain uncertain. C. zuma was 
described fi"om specimens collected from the Mackay district. 
Between Mackay (Central Mackay Coast Zoogeographie 
Region) and Mt Spec (Wet Tropics Zoogeographie Region) 
lies an expanse of dry woodland known as the 'Burdekin 
Gap', which has separated the faunas of these regions for an 
'evolutionarily long period' (Joseph et al. 1993). 
Despite the lack of resolution at the deeper nodes of the 
Carlia   tree,   both   maximum  parsimony   and   Bayesian 
analyses identified three distinct and strongly supported 
clades among the 'Carlia aerata' samples, providing support 
for the recognition of two new Carlia species (Fig. 1). 
C aerata sensu stricto (see Systematics of Carlia aerata 
below) forms a monophyletic clade that comprises only three 
of the seven 'aerata' individuals in the phylogeny (two from 
Shipton's Flat, 15?48 S, 145? 16 E, and one from Hann River, 
15?1121 S, 143?52 25 E). The red-tailed 'aerata' from 
Shipton's Flat is the sister species of Carlia tanneri (100% 
bootstrap support) and is here described as Carlia malleolus, 
sp. nov. The three specimens from Bulleringa National Park 
(17?35 12 S, 143?48 46 E) also form a distinct group whose 
phylogenetic affinities lie with neither C aerata nor 
C. malleolus, sp. nov, but rather with Cfoliorum (bootstrap 
value 100). 
The placement of the Bulleringa specimens results in the 
Cfoliorum branch of the phylogeny becoming paraphyletic. 
The Queensland C foliorum specimen (Mt Aberdeen) is 
more closely allied to the Bulleringa specimens (4.36% 
average sequence divergence, 68% bootstrap support) than it 
is to its New South Wales coimterpart (Denman Tip, 6.47%i 
sequence divergence). Reanalysis of the morphology of the 
Bulleringa specimens and their comparison with 50 C. folio- 
rum specimens, including north Queensland individuals 
(n = 26, Appendix 2), found that they could be reliably sepa- 
rated from Cfoliorum in all instances. It is therefore unlikely 
that the Bulleringa population merely represents a range 
extension of C. foliorum. The diagnostic character, a move- 
able lower eyelid (versus preablepharine condition), is taxo- 
nomically significant. There is no known intraspecific 
variation in this character in any scincid lizard (A. Greer, per- 
sonal communication). This, coupled with their apparent 
geographic isolation, was pivotal to our decision to describe 
the Bulleringa specimens as C abscondita, sp. nov. Despite 
some authors' confusion in distinguishing between a move- 
able lower eyelid and a preablepharine condition (Ingram 
and Covacevich 1988), we could find no ambiguity in this 
character. All Cfoliorum specimens, including those used in 
the genetic analysis, were found to possess the preable- 
pharine state and a free interparietal, characters that separate 
C. foliorum from all other Carlia species. 
Sequence-divergence estimates between C. malleolus, sp. 
nov, and C abscondita, sp. nov, with C. aerata differ by an 
average \A.A1% and 13.87%i respectively. In contrast, 
C. malleolus, sp. nov, differs from its sister taxon, 
C. tanneri, by only an average of 6.68% and C abscondita, 
sp. nov, from its sister taxon, Cfoliorum, by an average of 
5.05%. 
Systematics o/Carlia aerata 
Lygosoma aeratum Garman, 1901 was described from a 
single specimen collected from 'Cooktown'. In the same 
paper, Garman recognised a second species, Ablepharus 
heteropus,  from   'the  Great Barrier Reef.   Subsequent 
38 Australian Journal of Zoology 
88 
99 
71 
94 
100 
100 
99 
100 65 
97 
100 
62 
99 
100 100 
89 
100 
100 
100 
97 99 
100 
99 
80 
99 
100 
100 
97 
100 
100 
99 1 
100 
65 
100 
100 
100 
100 
99 
99 
100 
100 
100 
99 
100 
100 
61 
99 
100 
100 
100 
?? 100 
81 
99 
52 
100 
100 
100 
100 
78 
100 
100 
100 
98 
99 
P. J. Couper et al. 
C. amax1 
C. amax2 
C. bicarinata 
C. coensis 
C. mundivensis 
C. dogarel 
C. dogare2 
C. fusca 
C. longipesi 
C. longipes2 
C. gracilisi 
C. gracilis2 
C.jamoldael 
C. jamoldae2 
C. jarnoldaeS 
C. johnstoneil 
C. johnstonei2 
C. triacanthal 
C. triacantha2 
C. mundal 
C. munda2 
C. novaeguineae 
C. macfarlanil 
C. parrhasiusi 
C. parrhasius2 
C. pectoralis 
C. rhomboidalisi 
C. rhomboidalis2 
C. rubrigularisi 
C. rostralisi 
C. rostralis2 
C. rubrigularis2 
C. rubrigularis3 
C. rufilatusi 
C. rufilatus2 
C. schmeltziH 
C. schmeltzH2 
C. storril 
C. stom2 
C. tetradactylal 
C. tetradactyla2 
C. vivaxi 
C. vivax2 
C. vivax3 
C. abscondital 
C. abscondita2 
C. absconditaS 
C. foliorumi 
C. foliorum2 
C. tannerU 
C. tanneri2 
C. malleolus 
C. sesbraunal 
C. timlowi 
C. zuma 
C. sesbrauna2 
C. aeratal 
C. aerata2 
C. aerataS 
E. rufescens 
M. butleri 
Fig. 1.    Strict consensus tree. Numbers above branches represent bootstrap values obtained from maximum parsimony analysis (1000 replicates), 
numbers below branches represent frequency of observed bipartitions from MrBayes consensus tree (1000000 generations). 
Cryptic diversity within Carlia Australian Journal of Zoology        39 
authors (Cogger et al. 1983; Ingram and Covacevich 1988) 
have regarded these taxa as conspecific and Ingram and 
Covacevich (1988) chose aerata as the available name, on 
the basis of page priority. These authors assigned aerata to 
the genus Lygisaurus, which they resurrected from 
synonymy with Carlia. Recent molecular studies (Stuart-Fox 
et al. 2002) have assessed the phylogenetic relationships of 
Carlia and Lygisaurus by examining 29 species (23 Carlia, 
6 Lygisaurus). The resulting phylogeny showed that most 
Lygisaurus form a single clade nested within Carlia. The 
clade also includes Carliaparrhasius, which possesses char- 
acters that assign it to Carlia sensu stricto (number of 
supradigital scales on 4th toe, size and scale carinations: see 
Couper et al. in press). Stuart-Fox et al. (2002) resyn- 
onymised Lygisaurus with Carlia on the strength of this evi- 
dence, coupled with the paucity of external morphological 
characters separating the two genera (Ingram and 
Covacevich 1988, 1989; Couper et al. in press). The nomen- 
clature in this paper follows Stuart-Fox et al. (2002) in treat- 
ing Lygisaurus de Vis, 1884 and Carlia Gray, 1845 as 
congeneric. 
Herein, we describe the two new species, redescribe 
C. aerata and highlight a morphologically distinct popu- 
lation from Mt Mulligan (16?52 S, 144?52 E), which we 
tentatively refer to C. abscondita, sp. nov. The types of 
Lygosoma aeratum Garman, 1901 and Ablepharus heteropus 
Garman, 1901 were examined and enhanced descriptions are 
provided. 
The new species are assigned to Carlia (as defined by 
Stuart-Fox et al. 2002) by the following external character 
states (polarity follows Greer 1979, and outgroup compari- 
son follows Hutchinson et al. 1990): fore limbs tetradactyl, 
hind limbs pentadactyl (digital formula 4/5, derived); 
supraocular scales transversely oriented (primitive); ear 
opening surrounded by sharp lobules (derived); prefrontal 
scales present (primitive); frontoparietals fused to form a 
single shield (derived) and lower eyelid moveable, with 
transparent disc (primitive) (Ingram and Covacevich 1988, 
1989; Greer 1991; Cogger 2000; Couper et al. in press). The 
only other Australian scincid genera containing species with 
a 4/5 digital formula are: Eroticoscincus, Menetia (as 
defined by Greer 1991) and Saproscincus. Eroticoscincus 
lacks prefrontal scales (present in Carlia). Six species of 
Menetia (M. alanae, M. amaura, M. concinna, M. greyii, 
M. maini and M. surda) have obliquely oriented supra- 
oculars. The remaining three species (M timlowi, 
M. koshlandae and M. sadlieri) have transversely oriented 
supraoculars like Carlia but lack lobules on the margins of 
the ear. Saproscincus has paired frontoparietal shields. Our 
genetic analysis clearly places timlowi as a member of the 
Carlia group. The relationship of timlowi to koshlandae and 
sadlieri, and the generic placement of these species is yet to 
be assessed using molecular techniques. 
Carlia malleolus Roberts, Couper, Worthington Wilmer, 
Amey & Zug, sp. nov. 
(Figs 2, 3) 
Lygisaurus aeratus (in part) Ingram & Covacevich, 1988: 341. 
Material examined 
Holotype. QMJ42740, Shipton's Flat, via Cooktown (15?48 S, 
145?16E). 
Paratypes. QMJ17818, Isabella Falls, 32 km NW Cooktown 
(15?17S, 145?02E), 4.X.1969; QMJ74221-22, Coal Seam Ck, S of 
Laura (15?37 S, 144?29 E), 28.X.2000; QMJ78379, QMJ78404, 
Shipton's Flat, via Cooktown (15?48 S, 145?14 E), 15.X.2002; 
QMJ40975-76, Shipton's Flat, via Cooktown (15?48 S, 145?16E), 
July-September 1982; QMJ42738-39, QMJ42741^2, Shipton's Flat, 
via Cooktown (15?48 S, 145?16 E), July 1984; QMJ62404, Palmer R. 
(16?09S, 144?08E), 10.vii.l996; QMJ38755, Mt Windsor Tableland 
(16?19 S, 145?01 E), 20-21.xii.1980; QMJ45571-73, Granite Gorge, 
via Mareeba (17?01 S, 145?21 E), 14.ivl985; QMJ26691, Atherton 
Tableland, Walkamin (17?08 S, 145?26 E), 5.X.1974. 
Diagnosis 
Carlia malleolus, sp. nov, is distinguished from all other 
Australian Carlia species by the following characters com- 
bined: small size (maximum SVL 32.2 mm); mediimi brown 
body; hind limbs and tail reddish orange; venter impatterned, 
body scales smooth, lower eyelid moveable (containing large 
palpebral disc), six supraciliaries, seven supralabials; ear 
round (horizontal axis sometimes slightly longer) with sharp 
lobules on margins. 
Description 
SVL (mm) 19.1-32.2. Proportions as %SVL: TL 152-172 
(160 ? 6 (mean ? s.d.), n = 3); AG 46.1-56.1 (51.2 ? 2.4, 
n = 17); LI 24.2-32.6 (28.5 ? 2.2, n = 18); L2 34.6^2.9 
(38.6 ?2.5, n = 18); HL 18.6-23.2 (21.1 ? 1.0, n = 18). Body 
robust. Head barely distinct from neck. HW 63.8-76.3% HL 
(70.3 ? 3.4, n = 18). Limbs moderate. LI 66.3-83.3% L2 
(73.8 ?3.8, ? = 18). 
Scalation. Rostral in broad contact with frontonasal. 
Prefrontals large, narrowly to widely separated. 
Supraoculars 4, 1 and 2 in contact with frontal, 2, 3 and 4 in 
contact with frontoparietal. Frontoparietals fused, forming a 
single shield. Interparietal distinct. Enlarged nuchal scales 
2-3 (mode = 2, 78%i, ? = 18). Snout rounded in profile. 
Loreals 2. Preoculars 2. Presubocular single (see 
Appendix 1). Supraciliaries 5-7 (mode = 6, 89%i, ? = 18). 
Lower eyelid moveable with clear window; palpebral disc 
large, occupying more than half of lower eyelid. Ear aperture 
much smaller than palpebral disc; round, or with slightly 
longer horizontal axis, with sharp lobules on margins. 
Supralabials 7 (? = 18), with the fifth below the eye. 
Infralabials 5-6 (mode = 6, 83%, ? = 18). Midbody scale 
rows 22-26 (mode = 24, 50%i, ? = 18). Paravertebral scale 
rows 41-48 (mode = 43, 33%, ? = 15). Lamellae beneath 4th 
toe 18-23 (mode = 21, 43%, n = 14). 
40        Australian Journal of Zoology P. J. Couper et al. 
Fig. 2.    Carita malleolus, paratype QMJ40976, head in lateral (a) and 
dorsal (h) views. 
Skeletal.    Presacral vertebrae 26-27 (mode = 27, 89%, 
? = 18); caudal vertebrae 37^1 (mode = 41, 66%, n = 3). 
Colour pattern in preservative (alcohol) 
Mediimi brown above. Dorsal and lateral scales finely 
marked with 2-3 dark longitudinal streaks. White to cream 
below. Head shields stippled with black (not visible to naked 
eye). A dark streak in front of eye, encompassing a portion of 
the prefrontal, first and second supraciliaries, loreals, pre- 
oculars and presubocular; continuing as a fine line along 
Fig. 3.    Carlia malleolus in life, paratype QMJ78404 from Shipton's 
Flat, via Cooktown (photograph by G. Cranitch). 
dorsal edge of fifth supralabial. Labials heavily barred. 
Several dark, broken lines running from angle of mouth to 
forelimb. Upper surfaces of tail and hind limbs with greatly 
reduced ground colour; reddish orange (in all size classes 
examined, irrespective of season). Forelimbs also orange, but 
heavily speckled with brown. Belly immaculate, but some- 
times with dark edging to outer scales. Faint speckling (not 
visible to naked eye) beneath tail and hind limbs. 
Measurements and scale counts for the holotype 
SVL 29.3 mm, T regrown, AG 14.3 mm, LI 8.36 mm, L2 
10.9 mm, HL 6.2 mm, HW 4.3 mm, midbody scale rows 24, 
paravertebral scale rows 44, supraciliaries 6/6, supralabials 
7/7, infralabials 6/6, scales between nasal and presubocular 
3/3, subdigital lamellae beneath 4th toe 20/21, nuchals 2. 
Comparison with other species 
Within Carlia, C malleolus can only be confused with the 
species formerly assigned to Lygisaurus (i.e. small size, 
coupled with striate body scales: Ingram and Covacevich 
1988) or Menetia (timlowi, sadlieri and koshlandae: Greer, 
1991). Morphologically, it is most like C aerata, to which it 
would key in Cogger (2000) and Ingram and Covacevich 
(1988), from which it is readily distinguished by body colour 
pattern (hind limbs and tail reddish orange v. brown) and 
ventral colouration (tail, hind limbs and groin not patterned 
or very faintly speckled v. strongly speckled). It is further 
distinguished from this species by the nimiber of supralabial 
scales (7 v. 6, rarely 7) and the shape of its ear aperture 
(round to slightly horizontally elongate v. horizontally elon- 
gate, upper and lower edges often in close proximity). Its 
genetic affinities clearly lie with C tanneri, which is identi- 
fied as its sister taxon with 100% bootstrap support. 
C malleolus is readily separated from C. tanneri by the size 
of its palpebral disc (large v. small) and the shape of its ear 
lobules (sharp v. low and flat). It is also separated from 
C laevis, C. macfarlani, and C. sesbrauna by the size of the 
palpebral disc (large v. small) and from C. rococo by the 
shape of its ear lobules (sharp v. low and flat). C. malleolus 
differs fi"om C.foliorum and the fimlowi group' by the state 
of its lower eyelid (moveable v. fused). 
Distribution 
Coastal and subcoastal areas of north-eastern Queensland 
(Fig. 4) from slightly north of Cooktown (Isabella Falls, 
15?17S, 145?16E) to just south of Cairns (Walkamin, 
17?08S, 145?26E). All known localities lie east of 
144?00 E. In addition to localities for which voucher speci- 
mens exist (see material examined), C. malleolus has also 
been recorded at the following localities (field examinations 
by LR, voucher specimens not taken): Mclvor River 
(15?07 S, 145?00 E), BaldHills (15?18 S, 145?02 E), Mount 
Rose (15?23S, 145?02E), Hazelmere Station (15?23 S, 
145?03 E), Crocodile Station (15?43 S, 144?40 E), Lakeland 
Cryptic diversity within Carlia Australian Journal of Zoology        41 
Downs (15?53S, 144?47 E), Fairlight Station (15?47 S, 
144?03E), West Normanby River (15?53 S, 144?57 E), 
Bonnyglen Station (15?57 S, 144?47 E), Palmerville 
(16?00 S, 144? 04' E), Mt Mulgrave, 5 km E, (16?23 S, 
144E?01E), Cyclone Creek (16?23 S, 144?35 E) and 
Campbell Creek (16?28 S, 144?58 E). 
Habits and habitat 
Carlia malleolus occurs in sparsely grassed open eucalypt 
woodlands on poor soils. It is foimd in leaf-litter, particularly 
around rocky outcrops, logs and grass tussocks. The domi- 
nant trees in these communities are Melaleuca viridiflora, 
Erythrophleum chlorostachys (Cooktown Ironwood) and 
eucalypt species, including Corymbia clarksoniana, 
C. nesophila, C. tessellaris, Eucalyptus chlorophylla, 
E. crebra, E. cullenii, E. leptophleba, E. persistens and 
E. platyphylla. 
Etymology 
Latin, fire-dart (Handford and Herberg 1966). 'The term 
malleolus denoted a hammer, the transverse head of which 
? C. a?jsconc???a 
T C 5?r^?^ 
? 0. msliGOiuS 
0 C m&lieolos (sight records) 
? C. ssrsia ? C mstieolus 
A Mt Mulligan 
^1  Cooktown 
o 
*tr 
Fig. 4.    Distribution o? Carlia ahscondita, C. aerata and C. malleolus. 
was formed for holding pitch and tow; which, having been 
set on fire, was projected slowly, so that it might not be extin- 
guished during its flight, upon houses and other buildings in 
order to set them on fire; and which was therefore commonly 
used in sieges together with torches and falaricae (Liv. 
xxxviii.6; Non. Marcellus, p556, ed. Lips.; Festus, s.v.; Cic. 
pro Mil. 24; Veget. de Re Mil. iv.l8; Vitruv. x.16.9 ed. 
Schneider).' We propose the name in reference to this Roman 
usage for a fire-dart and in our context for a fast-moving, 
small, red-tailed skink. 
Carlia ahscondita Worthington Wilmer, Couper, Amey, 
Zug & Roberts, sp. nov. 
(Figs 5, 6) 
Material examined 
Holotype. QMJ74496, Donkey Springs (near), Bulleringa NP 
(17?35 12 S, 143?48 46 E). 
Paratypes. QMJ74495, Donkey Springs (near), Bulleringa NP 
(17?35 12 S, 143?48 46E); QMJ74498, Donkey Springs, N, 
Bulleringa NP (17?36 14 S, 143?48 38 E); QMJ74234-35, Bulleringa 
NP via Mt Surprise (17?39 S, 143?44 E); QMJ80043, Donkey Spring 
Gorge, Bulleringa NP (17?35 12 S, 143?48 51 E). 
Diagnosis 
Carlia abscondita is distinguished fi"om all other Australian 
Carlia species by the following characters combined: small 
size (maximum SVL 30.0 mm); dark olive brown body; hind 
limbs and tail lighter than body, but retaining dark pigment; 
faint dark speckles visible on underside of tail and limbs; 
body scales smooth; lower eyelid moveable (containing large 
palpebral disc) with a clearly defined row of upper ciliaries; 
six supraciliaries; seven supralabials; ear round with sharp 
lobules on margins. 
Description 
SVL (mm) 26.4-30.0. Proportions as %SVL: TL 
121.8-154.2 (138.7 ? 14.4 (mean ? s.d.), n = 4); AG 
49.2-54.0 (51.6 ? 2.2, n = 5); LI 23.2-31.6 (28.7 ? 3.4, 
? = 5); L2 32.1-43.6 (40.2 ? 4.6, n = 5); HL lO^-llA 
(21.2 ? 0. 77, n = 5). Body robust. Head barely distinct from 
neck. HW 63.8-69.3% HL (65.8 ? 2.1, n = 5). Limbs mod- 
erate. LI 64.9-74.1% L2 (71.4 ? 3.68, n = 5). 
Scalation. Rostral in broad contact with frontonasal. 
Prefrontals large, moderately separated. Supraoculars 4, 
1 and 2 in contact with frontal, 2, 3 and 4 in contact with 
frontoparietal. Frontoparietals ?ised, forming a single shield. 
Interparietal distinct. Enlarged nuchal scales 2. Snout 
rounded in profile. Loreals 2. Preoculars 2. Presubocular 
single (see Appendix 1). Supraciliaries 6. Lower eyelid 
movable with clear window; palpebral disc large, occupying 
more than half of lower eyelid; upper ciliaries present. Ear 
aperture much smaller than palpebral disc; round, or with 
slightly longer horizontal axis, with sharp lobules on margins. 
42        Australian Journal of Zoology P. J. Couper et al. 
Fig. 5. Carlia ahscondita, paratype QMJ74234, head in lateral (a) and 
dorsal (?) views. 
Supralabials 7, with the fifth below the eye. Infralabials 6. 
Midbody scale rows 24-26 (mode = 24, 80%, n = 5). 
Paravertebral scale rows 42^4 (mode = 43, 40%, n = 5). 
Lamellae beneath 4th toe 21-25 (mode = 25, 50%, n = 4). 
Colour pattern in preservative (alcohol) 
Dark olive brown above. Dorsal and lateral scales finely 
marked with 2-3 dark, longitudinal streaks. White to silvery 
Fig. 6. Carlia ahscondita in life, QMJ80043, Donkey Spring Gorge, 
Bulleringa NP, 17?35 12 S, 143?50 35 E (photograph by Colin 
DoUery, QEPA). 
grey below. Head shields stippled with black (not visible to 
naked eye). A dark streak in front of eye, encompassing a 
portion of the prefrontal, first and second supraciliaries, 
loreals, preoculars and presubocular; continuing as a fine 
line along dorsal edge of fifth supralabial. Labials heavily 
barred with black. Several dark, broken lines running from 
angle of mouth to forelimb. Upper surfaces of tail and hind 
limbs paler than body though still heavily etched with darker 
pigment. Belly immaculate, sometimes with dark edging to 
outer scales. Faint speckling beneath the tail and hind limbs 
(visible to naked eye). 
Measurements and scale counts for the holotype 
SVL 27.4 mm, TL 42.3, AG 14.8 mm, LI 8.7 mm, L2 
12.0 mm, HL 6.1 mm, HW 3.9 mm, midbody scale rows 24, 
paravertebral scale rows 42, supraciliaries 6/6, supralabials 
7/7, infralabials 6/6, scales between nasal and presubocular 
3/3, subdigital lamellae beneath 4th toe 25/25, nuchals 2. 
Comparison with other species 
The diagnosis will separate C. ahscondita from all other 
Australian Carlia species. However, difficulty may arise in 
morphologically distinguishing it from C. malleolus, to 
which it is similar in all aspects of scalation. These species 
do, however, exhibit subtle differences in colour pattern. 
While both species are medium-dark brown above, 
C malleolus has a greater degree of pigment loss from the 
tail and hind limbs, which are reddish orange in all size 
classes, irrespective of season. This species also shows some 
loss of pigment in the forelimbs. In C. ahscondita, the tail 
and hind limbs are generally paler than the dorsal ground 
colour, but remain heavily etched with darker pigment. There 
is no loss of pigment from the forelimbs of this species. 
C malleolus and C. ahscondita also differ in the intensity of 
spotting on the underside of the tail and hind limbs. In the 
former, these markings are so diffuse that they are not visible 
to the naked eye. In the latter, these markings can be seen 
without magnification. The genetic affinities of C. ahscon- 
dita clearly lie with C. foliorum, which is identified as its 
sister taxon with 100%i bootsttap support. The two species 
are readily distinguished. C ahscondita has a moveable 
lower eyelid with a clearly defined series of upper ciliaries (v. 
eyelid immoveable, upper ciliaries absent). Further, 
C. ahscondita always has a presubocular scale (v. rarely 
present in C. foliorum, only one of 26 specimens examined 
from north Queensland). The configuration of the pre- 
ocular/presubocular scales in C. foliorum is variable and is 
discussed further in Appendix 1. 
Distrihution 
Carlia ahscondita is currently known from a single popu- 
lation in Bulleringa NP (17?39 S, 143?44 E), via Mt 
Surprise, north-eastern Queensland (Fig. 4). 
Cryptic diversity within Carlia Australian Journal of Zoology 43 
Habits and habitat 
Carlia abscondita inhabits open woodlands dominated by 
Eucalyptus and Corymbia species witli a sparse to 
medium/dense grass cover. Tlie Donkey Springs specimens 
were found in leaf-litter among exfoliated sandstone slabs. 
The type locality is a narrow creek line, fed by a perennial 
spring. This dissects an area of sand sheets and cuts deeply 
into the underlying sandstone, forming a small gorge system. 
The foot slopes and creek bed contain sandy patches as well 
as silt and coUuvium deposits. There are also areas of 
exposed rock with larger boulders present above the creek 
line. 
Notes 
In our assessment of C. abscondita we examined a series of 
specimens from the Mt Mulligan area (16?52 S, 144?52 E, 
see Appendix 2). These specimens are, in most respects, 
morphometrically indistinguishable from this species. 
However, the Mt Mulligan specimens have a statistically 
higher paravertebral count than C. abscondita (46-48 v. 
42^4; unpaired two-tailed ?-test t = 7.60777, d.f = 10, P < 
0.0001). In the absence of biochemical data to support these 
differences between specimens of C. abscondita from 
Bulleringa NP and those from Mt Mulligan, 130 km to the 
north-east, we are reluctant to comment further on the status 
of this population. 
Etymology 
Latin, concealed, hidden (Handford and Herberg 1966). The 
name alludes to the species' close similarity to C. malleolus 
and its initial detection using molecular techniques. 
Redescription of Carlia aerata 
Carlia aerata (Garman) 
(Figs 7, 8) 
Lygosoma   aeratum   Garman,   1901:   7.   Holotype   MCZ?Al?, 
Cooktown, Queensland. 
Ablepharus heteropus Garman, 1901: 9. Holotype MCZ6484, Great 
Barrier Reef, Queensland. 
Material examined 
QMJ80023, Mungan-Kaanju NP; QMJ58224, QMJ58231, Rokeby 
NP; QMJ23442, Rokeby Hsd, QMJ37489, Peach Ck, 12 km NE Mt 
Groll; QMJ37527, Coen Airport, 23 km NNW Coen; QMJ77438, Coen, 
20 km N, QMJ26272 Coen, 3 km N; QMJ26263-65, Coen, 2 km up 
Lankelly Ck; QMJ20517, Melville Ra.; QMJ64614-15, 
QMJ64617-18, Cape Melville NP; QMJ78393-95, Musgrave-Coen 
Rd; QMJ20485, Cape Melville, Wakooka Outstation; QMJ63493, 
Altanmoui Range, Cape Melville NP; QMJ57984, Meton Yard, 
Strathgordon Holding; QMJ38029-30, Glen Garland Stn, 24 kmN, via 
Musgrave; QMJ78383-86, Windmill Ck, Artemis Stn; QMJ78381-82, 
QMJ78396, Hann River Crossing; QMJ42770, Isabella Falls, 32 km 
NW Cooktown; QMJ27089, Mclvor Rd, 20.8 km W Cooktown; 
QMJ78397, Laura; QMJ74218, Peninsula Developmental Road, ~8 km 
S Laura; QMJ57781, Pinnacles Dam; QMJ78378, QMJ78405 
QMJ40977-82, Shipton's Flat, via Cooktown (15?48 S, 145?16E) 
QMJ57785, Sandy Ck, Maytown; QMJ62400, Palmer R. 
QMJ26611-13, QMJ26615-17, Ingham, 19.9 km S, on Bruce Hwy: 
QMJ70114, Rattlesnake I., 20 km NE of Townsville; QMJ65224, 
Clemant SF, 5 km SE RoUingstone; QMJ67487, Clemant SF, 40 km N 
Townsville. 
Description 
SVL (mm) 15.0-30.1. Proportions as %SVL: TL 
129.8-153.9 (140.0 ? 7.7 (mean ? s.d.), ? = 13); AG 
45.4-55.9 (51.8 ? 2.5, n = 49); LI 24.5-31.7 (27.7 ? 1.8, 
n = 49); L2 30.6-41.0 (36.5 ? 2.3, ? = 49); HL 19.1-24.3 
(21.7 ? 1.1, ? = 50). Body robust. Head barely distinct from 
neck. HW 53.1-75.8% HL (69.9 ? 4.0, n = 50). Limbs mod- 
erate. LI 69.2-97.0% L2 (75.9 ? 5.5, n = 49). 
Scalation. Rostral in broad contact with frontonasal. 
Prefrontals large, narrowly to widely separated. 
Supraoculars 4, 1 and 2 in contact with frontal, 2, 3 and 4 in 
contact with frontoparietal (? = 54) or 3 with 1 in contact 
with frontal, 1,2 and 3 in contact with frontoparietal (? = 2). 
Frontoparietals fused, forming a single shield. Interparietal 
distinct. Enlarged nuchal scales 2-4 (mode = 3,41%, n = 54). 
Snout rounded in profile. Loreals 2. Preoculars 2. 
Presubocular single (see Appendix 1). Supraciliaries 5-6 
(mode = 6, 96%, n = 55). Lower eyelid movable with clear 
window; palpebral disc large, occupying more than half of 
lower eyelid. Ear aperture much smaller than palpebral disc; 
horizontally elongate, with sharp lobules on margins. 
Supralabials 6-7 (mode = 6, 87%, n = 55, rarely 5 as in one 
(a) 
(6) 
Fig. 7. 
views. 
Carlia aerata, QMJ78378, head in lateral (a) and dorsal (b) 
44 Australian Journal of Zoology P. J. Couper et al. 
side of holotype MCZR6476), usually 4th below eye. 
Infralabials 5-6 (mode = 6, 95%, n = 55). Midbody scale 
rows 22-25 (mode = 22, 51%, n = 47). Paravertebral scale 
rows 42-48 (mode = 44,43%, n = 49). Lamellae beneath 4th 
toe 16-23 (mode = 21, 35%, ? = 44). 
Colour pattern in preservative (alcohol) 
Mediimi-dark olive brown above. Flanks with or without 
white speckling. A broad, dark vertebral streak, encompass- 
ing both paravertebral scale rows is evident in many speci- 
mens. Dorsal and lateral scales finely marked with 2-3 dark, 
longitudinal streaks. White to silvery grey below. Head 
shields stippled with black (not visible to naked eye). A dark 
streak in front of eye, encompassing a portion of the pre- 
frontal, 1st and 2nd supraciliaries, loreals, preoculars and 
presubocular; continuing as a fine line along dorsal edge of 
5th supralabial (not always obvious in darker specimens). 
Labials heavily barred with black. Several dark, broken lines 
running from angle of mouth to forelimb. Upper surfaces of 
tail sometimes paler than body but lacking reddish orange 
flush; sometimes marked with small white specks. Belly 
usually immaculate but sometimes boldly spotted; darker 
edging often present on outer scales. Speckling beneath the 
tail and hind limbs generally bold. 
Comparison with other species 
Carlia aerata is separated from all other Carita species 
formerly assigned to Lygisaurus by the following suite of 
characters: 6 supralabial scales; lower eyelid moveable, with 
large palpebral disc; ear aperture horizontally elongate, sur- 
rounded by sharp lobules. On rare occasions where C. aerata 
has 7 supralabial scales, it superficially resembles C. folio- 
rum, C malleolus and C abscondita. It is readily distin- 
guished from C. foliorum by the state of its lower eyelid 
(moveable v. fused above forming a fixed spectacle over the 
eye). It is separated from both C malleolus and C. abscon- 
dita by the shape of the ear aperture (horizontally elongate v. 
Fig. 8.    Carlia aerata in life, QMJ78405, Sliipton's Flat, via Cooktown 
(photograph by G. Cranitch). 
round to slightly elongate) and the intensity of the speckling 
beneath the tail and hind limbs (bold v. diffuse). 
Distribution 
Coastal and subcoastal areas of north-eastern Queensland 
(Fig. 4) from the Rokeby Station area (Mungan-Kaanju NP, 
13?36 40 S, 142?47 24 E) to just north of Townsville 
(Clemant SF, 19?08 11 S, 146?27 42 E). All known local- 
ities lie east of 142?00 E. 
Habits and habitat 
Commonly found in sympatry with C. malleolus (see 
account of C malleolus). 
Notes 
Ingram and Covacevich (1988) comment on the difficulty in 
distinguishing C aerata from C. foliorum in preservative 
because it is not always easy to determine whether the eyelid 
is fused above. Such confusion occurs when the lower eyelid 
begins to separate along the suture on its upper edge. Any 
attempt to examine this condition closely usually results in 
tearing and makes interpretation of this character more diffi- 
cult. Interpreting the state of the lower eyelid in these 
species, however, is relatively straightforward. In C. aerata, 
a series of upper ciliaries indicates the moveable eyelid con- 
dition (these lie immediately below the supraoculars). 
C foliorum has no upper ciliaries. 
Re-examination of Garman types 
Lygosoma aeratum Garman 
Lygosoma aeratum Garman, 1901: 7. 
Material examined 
Holotype.    MCZR6476, Cooktown, Queensland. 
Description 
SVL (mm) 27.8. Proportions as %SVL: TL broken; AG 49.6; 
LI 25.2; L2 38.5; HL 21.1. Body robust. Head barely distinct 
from neck. HW 62.7% HL. Limbs moderate. LI 65.4% L2. 
Scalation. Rostral in broad contact with frontonasal. 
Prefrontals large, moderately separated. Supraoculars 4, 
1 and 2 in contact with frontal. Frontoparietals fused, 
forming a single shield. Interparietal distinct. Enlarged 
nuchal scales 2. Snout rounded in profile. Loreals 2. 
Preoculars 2. Presubocular single. Supraciliaries 6. Lower 
eyelid moveable with clear window; palpebral disc large, 
occupying more than half of lower eyelid. Ear aperture 
smaller than palpebral disc; horizontally elongate, with sharp 
lobules on margins. Supralabials 6/5, with 3rd or 4th beneath 
eye. Infralabials 6. Two scales between nasal and presub- 
ocular scale. Midbody scale rows 24. Paravertebral scale 
rows 46. Lamellae beneath 4th toe 16-17. 
Cryptic diversity within Carlia Australian Journal of Zoology 45 
Colour pattern in preservative (alcohol) 
Not informative because of age and original manner of 
preservation. Medium to dark brown dorsally and laterally; 
light brown to tan ventrally. 
Measurements and scale counts for the holotype 
SVL 27.8 mm, T broken, AG 13.8 nmi, LI 7.0 nmi, L2 
10.7 mm, HL 5.9 mm, HW 3.7 mm. 
Ablepharus heteropus Garman 
Ablepharus heteropus Garman, 1901: 9. 
Material examined 
Holotype.    MCZR6484   (mature   female),   Great  Barrier  Reef, 
Queensland. 
Description 
SVL (mm) 25.3. Proportions as %SVL: TL 94.8; AG 51.4; 
LI 24.9; L2 30.0; HL 19.0. Body robust. Head barely distinct 
from neck. HW 79.2% HL. Limbs moderate. LI 82.9% L2. 
Scalation. Rostral in broad contact with frontonasal. 
Prefrontals large, moderately separated. Supraoculars 4, 
1 and 2 in contact with frontal. Frontoparietals fused, 
forming a single shield. Interparietal distinct. Enlarged 
nuchal scales 2. Snout rounded in profile. Loreals 2. 
Preoculars 2. Presubocular single. Supraciliaries 6. Lower 
eyelid moveable with clear window; palpebral disc large, 
occupying more than half of lower eyelid. Ear aperture much 
smaller than palpebral disc; nearly circular, largely hidden by 
sharp lobules around margin. Supralabials 6, with fourth 
beneath eye. Infralabials 6. Three scales between nasal and 
presubocular scale. Midbody scale rows 24. Paravertebral 
scale rows 45. Lamellae beneath 4th toe 17-19. 
Colour pattern in preservative (alcohol) 
Not informative because of age and original manner of 
preservation. Medium to dark brown dorsally and laterally; 
light brown to tan ventrally. 
Measurements and scale counts for the holotype 
SVL 25.3 mm, T 24 mm, AG 13.0 mm, LI 6.3 mm, L2 
7.6 mm, HL 4.8 mm, HW 3.8 mm. 
Notes 
Our examination of the Garman types (GZ) concurs with the 
findings of Ingram and Covacevich (1988); both taxa are 
clearly conspecific. They also exhibit characters that show 
they are not referrable to C. malleolus or C. abscondita, both 
of which have seven supralabials (v. 6/5 MCZR6476 and 6/6 
MCZR6484). The subdigital lamellae coimts for these speci- 
mens (MCZR6484 17-19, MCZR6476 16-17) are more 
consistent with the lower end of the range for C. aerata 
(16-23) than for C. malleolus (18-23) or C. abscondita 
(21-25). Unfortunately, the condition of the Garman types 
did not allow colour pattern comparisons with the new taxa. 
Discussion 
Carlia abscondita and C. malleolus are truly cryptic species, 
both keying to C. aerata and separated from one another by 
subtle pattern differences. This, while problematic for field 
identification, in no way diminishes their validity as species. 
Skinks can be highly visually oriented and subtle pattern dif- 
ferences can play important roles in mate recognition. The 
significance of ultraviolet reflectance in males of the con- 
generic C. pectoralis has been demonstrated (Blomberg etal. 
2001). 
Both C abscondita and C. malleolus represent discrete 
lineages in the phylogeny of Carlia (Fig. 1). In considering 
the appropriate criteria for species recognition in 
Batrachoseps (slender salamanders), Jockusch et al. (2001) 
justified their recognition of B. minor from its close con- 
geners B. incognitus and B. luciae because of its isolation 
from both, and it was regarded as being 'on its own imique 
evolutionary trajectory'. We believe the same to be true of 
C. abscondita. This species falls apart from its morpho- 
logically closest congeners, C. malleolus and C. aerata, on 
the phylogenetic tree, its genetic affinities clearly lying with 
C. foliorum. There is no doubt that C. abscondita and 
Cfoliorum are distinct, their separation supported by a char- 
acter state that exhibits no intraspecific variation. Further, on 
the basis of existing collections, C. abscondita is geographi- 
cally isolated from C. malleolus, C. aerata and C foliorum. 
Carlia shows remarkable morphological conservatism for 
such an ecologically diverse assemblage (Storr 1974; 
Stuart-Fox et al. 2002). Character states used to diagnose 
species include differences in palpebral disc size, ear and ear 
lobule shape, scale shape and degree of keeling. Some 
species are so close morphologically that they have been 
diagnosed from what are presumed to be their closest rela- 
tives by colour pattern differences alone (for example, 
C rhomboidalis from C rubrigularis, and C rostralis from 
C. longipes). Hence, the presence of new taxa, particularly 
within the smaller, less conspicuous forms, is not surprising. 
The placement of the new taxa within our phylogeny of 
Carlia is of particular interest. Both C. malleolus and 
C. abscondita are morphologically consistent with the diag- 
nosis of C. aerata (as Lygisaurus aeratus) provided by 
Ingram and Covacevich (1988). All three taxa are small (max 
SVL <33 mm) with smooth body scales, have a moveable 
lower eyelid containing a large palpebral disc and an ear 
aperture surrounded by sharp lobules. These combined char- 
acters separate them from all other Carlia species. That 
C. malleolus and C. abscondita form strongly supported 
sister-species groupings with C. tanneri (a species with a 
small palpebral disc and flat ear lobules) and C. foliorum 
(fused lower eyelid) respectively, suggests that the morpho- 
logical characters used to delineate species boundaries do 
46 Australian Journal of Zoology P. J. Couper et al. 
not necessarily point to close phylogenetic relationships. The 
placement of C. longipes and C. rostralis in the molecular 
phytogeny (Stuart-Fox et al. 2002, present study) further 
illustrates this point. These species, separated from one 
another on colour pattern differences, were both assigned to 
the 'C. fusca complex (Ingram and Covacevich 1989). The 
consensus tree clearly shows that C. rostralis has molecular 
affinities with C. dogare and C. vivax while C. longipes is 
placed with C. fusca (from New Guinea: Zug 2004). A 
similar disparity between molecular and morphological 
'relatedness' is seen in the scincid genera Cryptoblepharus, 
Ctenotus (both morphologically conservative) and Egernia. 
Australian Cryptoblepharus show a disparity between 
morphological and genetic data: 'In some cases genotypes 
were divergent but phenotypes indistinguishable or, con- 
versely, phenotypes divergent but genotypes were shared' 
(Horner 2003). Within Ctenotus, colour pattern is often 
paramoimt in species delineation and Storr (1981) created 
species groups, largely pattern based, as an aid to identifi- 
cation. These groups were later expanded by Wilson and 
Knowles (1988). A preliminary molecular study shows that 
the validity of these species-groups as monophyletic assem- 
blages is questionable (Pianka, personal commimication 
1996, http://utexas.edu/~varanus/ctenotus.html). The place- 
ment of any Ctenotus species within the existing scheme 
remains largely subjective (Couper et al. 2002). A recent 
study on Egernia showed that '... species groups appear to 
be paraphyletic and the morphological characters on which 
they are based may represent instances of convergence to a 
particular environment ...' (Chappie 2003). The validity of 
morphological criteria alone for defining species is ques- 
tioned by Donnellan et al. (1993). These authors show that 
this approach is often inadequate and give case studies: 
Mixophyes (Mahony et al, unpublished data), Sphenodon 
(Daugherty et al. 1990), Pseudemoia (Donnellan and 
Hutchinson 1990; Hutchinson and Donnellan 1992) and 
Thamnophis (Lawson and Dessauer 1979), in which 
morphologically defined species have later, under genetic 
scrutiny, been shown to contain several taxa. 
A further assessment of C aerata, with genetic sampling 
across the species' range is likely to reveal additional new 
taxa. Our examination of C. aerata also revealed colour 
pattern differences between adult-sized individuals. These 
differences were considered to be sexual differences initially, 
with darker specimens having spotted sides being adult 
males in breeding condition. Less ornate specimens were 
believed to be adult females. Examination of gonads showed 
that this was not the case. The dark, spotted specimens were 
of both sexes (QMJ78738, J78382, J78384 ?; J78393, 
J78396 6, the latter in peak reproductive condition), as were 
the paler, inornate specimens (QMJ37527 ? gravid; 
J58224 S). Without genetic sampling to assess divergence, 
the taxonomic significance of these characters remains 
problematic. 
The intraspecific genetic distances between populations 
of some Carlia species (C. amax 21%; C. vivax 20%; 
C rubrigularis 22%): Stuart-Fox et al. 2002; C. sesbrauna 
11%: this study) are in the order of 2^ times those separat- 
ing C malleolus and C. abscondita from their sister taxa, 
C. tanneri (6.68%i) and C.foliorum (5.05%i). Such large dis- 
tances, combined with paraphyletic relationships among 
individuals of at least two other species (C. rubrigularis and 
C sesbrauna), suggest that these 'units' may represent more 
than just divergent populations of a single species. 
Recognition and description of cryptic species is funda- 
mental to conserving biodiversity (Donnellan et al. 1993), 
and available data clearly point to Carlia as a group warrant- 
ing further investigation. 
Most of Australia's Carlia species inhabit open forests 
and woodland communities. Indeed, only six of the 30 
described species could be termed rainforest dwellers, and 
even these thrive in edge habitats. North-eastern Queensland 
is especially rich in Carlia species and could be termed a 
diversity hotspot for the genus (19 species occur in this 
region and 15 of these are largely restricted to latitudes north 
of20?S). 
An overall lack of phylogenetic resolution among Carlia 
species led Stuart-Fox et al. (2002) to propose a scenario for 
a relatively rapid speciation within this group. However, they 
did not attempt to speculate on the imderlying forces that 
may have driven this process. Their molecular divergence 
estimates loosely date this diversification as occurring some- 
time in the Miocene. This is consistent with other phylo- 
geographic studies of rainforest vertebrates in this region, 
which have indicated that most recognised species are of 
Miocene or Pliocene age (Joseph and Moritz 1993; Moritz 
et al. 1997; Schneider et al. 1998). However, we acknowl- 
edge the weaknesses of biogeographical discussions in the 
absence of strong supporting evidence (Greer 1989). Yet, 
assimiing that the timing of Stuart-Fox et al. (2002) is 
correct, we suggest that the rapid-speciation scenario is con- 
gruent with current theories on Miocene climate and habitat 
changes (mid-Miocene onwards). It is widely accepted that a 
drop in temperature combined with an expansion of the 
Antarctic ice sheet led to increasing aridity over the 
Australian continent with a reduction of widespread rain- 
forests in favour of xerophytic woodlands (Galloway and 
Kemp 1981). Such environmental shifts may have provided 
new opportunities for ancestral Carlia, allowing them to 
diversify in the expanding open woodland habitats. If ances- 
tral Carlia had the same edge-dwelling propensities as 
modern rainforest forms, this may have conferred advan- 
tages for the colonisation of drier woodland habitats. The 
recognition (in this study) of two new taxa, coupled with 
molecular evidence suggesting considerable cryptic specia- 
tion, indicates that this radiation event may be more dramatic 
than previously thought. 
Cryptic diversity within Carlia Australian Journal of Zoology 47 
Acknowledgments 
We thank the Queensland Museum and Smithsonian 
Institution for providing funds to support this study; Jeanette 
Covacevich and Pat Zug for assistance in the field; Jeanette 
Covacevich, Conrad Hoskin and Ross Sadlier for their com- 
ments on the manuscript; Allen Greer and Glenn Shea for 
advice on the significance of character states; Colin DoUery 
(Queensland Parks and Wildlife Service) for providing a 
specimen and photographs and habitat data; Nigel Weston 
(James Cook University), Joe Sambono (JCU) and Alastair 
Freeman (QPWS) for additional habitat details; Dr James 
Hanken and Jos? Rosado (Museum of Comparative Zoology, 
Harvard) for providing digital images of the head scalation 
of MCZR6476; Dr Devi Stuart-Fox for ongoing discussions 
and Ms Lauren D. Keim for her assistance in the laboratory. 
References 
Blomberg,  S. P.,  Owens, I.  P. F., and  Stuart-Fox, D.  M.  (2001). 
Ultraviolet   reflectance   in  the   small   skink   Carlia pectoralis. 
Herpetological Review 32, 16?17. 
Chappie, D. G. (2003). Ecology, life-history, and behaviour in the 
Australian scincid genus Egernia with comments on the evolution 
of complex sociality in lizards. Herpetological Monograph  17, 
145-180. 
Cogger, H. G. (2000). 'Reptiles and Amphibians of Australia.' 6th edn. 
(Reed New Holland: Sydney.) 
Cogger, H. G., Cameron, E. E., and Cogger, H. M. (1983). 'Amphibia 
and Reptilia. Zoological Catalogue of Australia, Vol. 1.' (Australian 
Government Publishing Service: Canberra.) 
Couper, P. J. (1993). A new species o? Lygisaurus de Vis (Reptilia: 
Scincidae)    from    mideastern    Queensland.    Memoirs    of   the 
Queensland Museum a, 163?166. 
Couper,  P.  X,  and  Gregson,  R. A.  M.  (1994).  Redescription  of 
Nephrurus asper G?nther, and description o?N. amyae sp. nov. and 
N. sheai sp. nov. Memoirs of the Queensland Museum 37, 53?67. 
Couper, P. X, Covacevich, X A., and Lethbridge, P. X (1994). Carlia 
parrhasius, a new Queensland skink. Memoirs of the Queensland 
Museum 35, 31?33. 
Couper, P. X, Amey, A. P., and Kutt, A. S. (2002). A new species of 
Ctenotus (Scincidae) from central Queensland. Memoirs of the 
Queensland Museum 48, 85?91. 
Couper, P. X, Covacevich, X A., Amey, A. P., and Baker, A. M. (in press). 
The genera of skinks (family Scincidae) of Australia and its island 
territories: diversity, distribution and identification. In 'Evolution 
and Biogeography of Australasian Vertebrates'. (Eds X R. Merrick, 
M. Archer, G. M. Hickey and M. S. Y. Lee.) (Auscipub: Sydney.) 
Daugherty, C. H., Cree, A., Hay, X M., and Thompson, M. (1990). 
Neglected   taxonomy   and   continuing   extinctions   of   tuatara 
(Sphenodon). Nature 347, 177-179. doi:10.1038/347177A0 
Donnellan, S. C, and Hutchinson, M. N. (1990). Biochemical and 
morphological variation in the geographically widespread lizard 
Leiolopisma entrecasteauxii (Lacertilia: Scincidae). Herpetologica 
46, 149-159. 
Donnellan, S. C, Adams, M., Hutchinson, M. N., and Baverstock, P. R. 
(1993). The identification of cryptic species in the Australian 
herpetofauna:   a   high   research   priority.   In   'Herpetology   in 
Australia'. (Eds D. Lunney and D. Ayers.) pp. 121-126. (Surrey 
Beatty: Sydney.) 
Donnellan, S. C, Hutchinson, M. N., Dempsey, P., and Osborne, W. S. 
(2002). Systematics of the Egernia whitii species group (Lacertilia: 
Scincidae) in south-eastern Australia. Australian Journal of Zoology 
50, 439^59. doi:10.1071/ZO01065 
Galloway, R. W., and Kemp, E. M. (1981). Late Cainozoic environ- 
ments in Australia. In 'Ecological Biogeography of Australia. 
Monographie Biologicae. Vol. 1'. (Ed. A. Keast.) pp. 51-80. 
(Dr W.Xunk: The Hague.) 
Garman, S. (1901). Some reptiles and batrachians from Australasia. 
Bulletin of the Museum of Comparative Zoology 39, 1?14. 
Greer, A. E. (1979). A phylogenetic subdivision of Australian skinks. 
Records of the Australian Museum 32, 339?371. 
Greer, A. E. (1989). 'The Biology and Evolution of Australian Lizards.' 
(Surrey Beatty: Sydney.) 
Greer, A. E. (1991). Two new species of Menetia from northeastern 
Queensland with comments on the generic diagnoses o? Lygisaurus 
and Menetia. Journal of Herpetology 25, 268?272. 
Handford, S. A., and Herberg, M. (1966). 'Langenscheidt's Shorter 
Latin Dictionary' (Hodder and Stoughton: London.) 
Horner, P. (2003). 'Cryptic Cryptos' - A taxonomic revision of 
Australian Cryptoblepharus (Scincidae). In 'Australian Society of 
Herpetologists, Inc. Conference 2003'. Mary River Park, via 
Darwin, NT. 
Huelsenbeck, X P, and Ronquist, F (2001). MRBAYES: Bayesian 
inference on phylogenetic trees. Bioinformatics (Oxford, England) 
17, 754-755. 
Hutchinson, M. N., and Donnellan, S. C. (1992). Taxonomy and genetic 
variation in the Australian lizards of the genus Pseudemoia 
(Scincidae: Lygosominae). Journal of Natural History 26,215-264. 
Hutchinson, M. N., Donnellan, S. C, Baverstock, P. R., Krieg, M., 
Simms, S., and Burgin, S. (1990). Immunological relationships and 
generic revision of the Australian lizards assigned to the genus 
Leiolopisma (Scincidae: Lygosominae). Australian Journal of 
Zoology 38, 535-554. 
Ingram, G. X, and Covacevich, X A. (1988). Revision of the genus 
Lygisaurus de Vis (Scincidae: Reptilia) in Australia. Memoirs of the 
Queensland Museum 25, 335?354. 
Ingram, G. X, and Covacevich, X A. (1989). Revision of the genus 
Carlia (Reptilia, Scincidae) in Australia with comments on Carlia 
bicarinata of New Guinea. Memoirs of the Queensland Museum 27, 
443-490. 
Xames, B. H., Donnellan, S. C, and Hutchinson, M. N. (2001). 
Taxonomic revision of the Australian lizard Pygopus nigriceps 
(Squamata: Gekkonoidea). Records of the South Australian Museum 
34, 37-52. 
Xockusch, E. L., Yanev, K. P, and Wake, D. B. (2001). Molecular phylo- 
genetic analysis of slender salamanders, genus Batrachoseps 
(Amphibia: Plethodontidae), from central coastal California with 
descriptions of four new species. Herpetological Monograph 15, 
54-99. 
Xoseph, L., and Moritz, C. (1993). Phylogeny and historical ecology of 
eastern Australian scrubwrens Sericornis spp.: evidence from mito- 
chondrial DNA. Molecular Ecology 2, 161-170. 
Xoseph, L., Moritz, C, and Hugall, A. (1993). A mitochondrial DNA 
perspective on the historical biogeography of mideastern 
Queensland rainforest birds. Memoirs of the Queensland Museum 
34,201-214. 
Lawson, R., and Dessauer, H. C. (1979). Biochemical genetics and sys- 
tematics of garter snakes of the Thamnophis elegans?couchii?ordi- 
noides complex. Occasional Papers of the Museum of Zoology, 
Louisiana State University 56, 1?24. 
Mather, P. B. (1990). Electrophoretic and morphological comparisons 
of Lampropholis delicata (Lacertilia: Scincidae) populations from 
eastern Australia, and a resolution of the taxonomic status of this 
species. Australian Journal of Zoology 37, 561?574. 
48 Australian Journal of Zoology P. J. Couper et al. 
Moritz, C, Joseph, L., and Adams, M. (1993). Cryptic diversity in an 
endemic rainforest skink (Gnypetoscincus queens landiae). 
Biodiversity and Conservation 2, 412^25. 
Moritz, C, Josepti, L., Cunningham, M., and Schneider, C. J. (1997). 
Molecular perspectives on historical fragmentation of Australian 
tropical and subtropical rainforest: implications for conservation. In 
'Tropical Rainforest Remnants: Ecology, Management and 
Conservation of Fragmented Communities'. (Eds W. R Laurence 
and R. O. Bierregard.) pp. 442-454. (Chicago University Press: 
Chicago.) 
Posada, D., and Crandall, K. A. (1998). Modeltest: testing the model of 
DNA substitution. Bioinformatics (Oxford, England) 14, 817-818. 
Rambaut, A. (1996). 'Se-A: Sequence Alignment Editor' Version 
2.0al 1. Available at http://evolve.zoo.ox.ac.uk [Verified 3 February 
2005]. 
Schneider, C. X, Cunningham, M., and Moritz, C. (1998). Comparative 
phylogeography and the history of endemic vertebrates in the Wet 
Tropics rainforests of Australia. Molecular Ecology 7, 487-498. 
doi:10.1046/J.1365-294X.1998.00334.X 
Schneider, C. X, Smith, T. B., Larison, B., and Moritz, C. (1999). A test 
of alternative models of diversification in tropical rainforests: eco- 
logical gradients versus rainforest refugia. Proceedings of the 
National Academy of Sciences of the United States of America 96, 
13 869-13 873. 
Storr, G. M. (1974). The genus Carlia (Lacertilia, Scincidae) in Western 
Australia and the Northern Territory. Records  of the  Western 
Australian Museum 3, 151?165. 
Storr, G. M. (1981). Ten new Ctenotus (Lacertilia: Scincidae) from 
Australia. Records of the Western Australian Museum 9, 125?146. 
Stuart-Fox, D. M., Hugall, A. F, and Moritz, C. (2002). A molecular 
phylogeny of rainbow skinks (Scincidae: Carlia): taxonomic and 
biogeographic  implications. Australian Journal of Zoology 50, 
39-51. doi:10.1071/ZO01051 
Swofford,   D.   L.   (2002).   'PAUP*   Phylogenetic   Analysis   Using 
Parsimony (* and other methods).' 4th edn. (Sinauer Associates: 
Sunderland, MA.) 
Wilson,  S. K., and Knowles, D. G.  (1988).  'Australia's Reptiles. 
A Photographic Reference to the Terrestrial Reptiles of Australia.' 
(Collins Publishers Australia: Sydney.) 
Wilson, S. K., and Swan, G. (2003). 'A Complete Guide to Reptiles of 
Australia.' (Reed New Holland: Sydney.) 
Zug, G. R. (2004). Systematics of the Carlia 'fusca' lizards (Squamata: 
Scincidae) of New Guinea and nearby islands. Bishop Museum 
Bulletin in Zoology 5, 1?82. 
Manuscript received 4 February 2004, accepted 18 October 2004 
Cryptic diversity within Carlia Australian Journal of Zoology 49 
Appendix 1.    Configuration of preocular/presubocular scales 
The character, 'number of scales between the second presubocular and 
the nasal scale', has been used to diagnose Lygisaurus species and 
remains a significant character in separating C aerata and C. foliorum 
(Ingram and Covacevich 1988): the former species usually has three 
scales, while the latter usually has two. This character, however, can be 
confusing. Some C. foliorum specimens (3 of 26 examined) exhibit a 
downward rotation of the upper preocular scale, so that it contacts an 
upper labial along its anterior margin. When this occurs, the scale count 
between the second presubocular and the nasal increases from two to 
three, without any change in the number of scales present. The normal 
configuration is illustrated in Fig. 9a. Fig 9h illustrates the reconfigured 
state. It is less confusing to consider the scales by name (i.e. preocular 
and presubocular) and then score presence or absence. In C. foliorum, 
the normal condition is two preoculars, no presuboculars, with only 8% 
of the sample possessing a presubocular scale. A presubocular is always 
present in C. abscondita but the preoculars are often fused. We define 
preoculars as the scales that are situated immediately anterior to the 
orbit. These are upper and lower (but may be fused) and are in broad 
medial contact. The presubocular contacts the posteroventral margin of 
the lower preocular. Our lower preocular and presubocular scales were 
regarded as two presuboculars by Ingram and Covacevich (1988). 
Appendix 2.    Additional material examined 
All material is from Queensland unless otherwise stated. 
Carlia cf. aerata (Mount Mulligan population) 
QMJ45385-87, QMJ45404-07, QMJ64429, Mount Mulligan; 
QMJ45359, Mt Mulligan summit, 2.5 km SW Mt MuUigan township. 
Carlia foliorum 
QMJ11891, Tinaroo Dam, 8 km N; QMJ75430-31, Kennedy Hwy, 
W Ravenshoe; QMJ59749, 40 Mile Scrub NP; QMJ31054, 40 Mile 
Scrub; QMJ74275, Princess Hills NP; QMJ42461-63, Peak Ra; 
QMJ70401-02, Conjuboy Holdings; QMJ57284, Eight Mile Ck; 
QMJ26614, Ingham, 19.9 km S; QMJ58072, QMJ58134, QMJ58136, 
Hidden Valley, 22 km W Paluma; QMJ58690, Forty Mile Scrub NP; 
QMJ26625, MoongobuUa, 1 km W; QMJ27691-92, QMJ32567-8, 
Hencamp Ck., 5 km N; QMJ26338, Magnetic I.; QMJ76644-45, 
Arcadia, Magnetic I.; QMJ77454, Blackbraes NP; QMJ62701, 
Mt Aberdeen. South Australian Museum R33733, Denham Tip, NSW. 
Carlia macfarlani 
Northern Territory Museum R23021, R23031, R23034, Maxwell Ck., 
Melville I., NT; QMJ78355, Coen; QMJ78392, Coen, 2 km S. 
Carlia sesbrauna 
QMJ78356, QMJ78387-91, USNM Field Herp 036306-7 Klondyke 
Mine, Station Ck, Mcllwraith Ra. 
Carlia tanneri 
Holotype.    QMJ32352, Morgan R Crossing. 
Paratypes. QMJ32358-59, Hopevale Mission, 33 km N; 
QMJ20609-11, QMJ32362-64, Mclvor R Crossing; QMJ22380, 
Tanner Farm; QMJ42771-2, Endeavour R.; QMJ27093-96, Cooktown, 
13 km W; QMJ24117-18, Endeavour R., 15 km W Cooktown; 
QMJ22789, Cedar Scrub, via Cooktown. 
Fig.   9.    Configuration   of preocular   scales   in   Carlia foliorum. 
(a) Normal configuration - upper preocular not contacting supralabials. 
(b) Rotation of upper preocular, excluding lower preocular from second 
loreal. N = nasal, L1-L2 = 1st and 2nd loreal, UP = upper preocular, 
LP = lower preocular, S1-S5 = supralabials lst-5th supralabial. 
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