PROCEEDINGS OF THE ACADEMY OF NATURAL SCIENCES OF PHILADELPHIA 154: 29-37. 11 FEBRUARY 2005 
Using checklists and collections data to investigate plant diversity: 
II. An analysis of five florulas from northeastern South America 
H. DAVID CLARKE 
Department of Biology, CPO #2440, University of North Carolina at Asheville, Asheville NC 28804, U.S.A.? 
dclarke@unca.edu 
V. A. FUNK 
US National Herbarium, Smithsonian Institution, MRC 166, P.O. Box 37012,  Washington D.C. 20013-7012,  U.S.A.? 
Funk.Vicki@NMNH.SI.EDU 
ABSTRACT?Five plant checklists from areas on and adjacent to the Guiana Shield were analyzed and used to test 
hypotheses of the salient properties of the flora of northeastern South America. Newly available checklists of Iwokrama, 
Mabura Hill, and Kaieteur Falls (all three in Guyana), Central French Guiana, and Reserva Ducke near Manaus, Brazil 
were compiled and their nomenclatural synonymies standardized. Data from checklists provide an attractive alternative 
to transect or plot data because they are based on rigorously determined plants of all habit types rather than the sterile 
vouchers of tree species often used in plot or transect studies. Descriptive data were compiled from the checklists regarding 
diversity, overlap, and endemism. Ranking of diversity at the family level was subjected to Kendall's coefficient of con- 
cordance of ranks test and Spearman rank correlation coefficients to evaluate similarities among the five sites. A UPGMA 
dendrogram was created from data for the presence or absence of species shared by two or more sites. The results indicate 
strong similarity among the three sites in Guyana and between Central French Guiana and Reserva Ducke, supporting 
a model of plant distributions determined by the presence or absence of sandstone or white sands rather than disjunct 
between the Roraima sandstone formation ("Guiana Highland") and other areas of the Guiana Shield. Relatively little 
overlap was found even between adjacent areas with ostensibly very similar abiotic environments, indicating that plant 
diversity will not necessarily be protected by conserving representative areas selected on the basis of general characteristics. 
INTRODUCTION 
How may the abundant data available from plant 
collections in herbaria be used to refine concepts of 
regional patterns of fioristic diversity in northern 
South America? This question has obvious impli- 
cations for biogeography in general and conserva- 
tion in particular. However, synthesis of data from 
plant collections has been hampered by the lack of 
comprehensive and uniform data. The paucity of 
information regarding the diversity and distribution 
of plant species in this region has frustrated attempts 
to make a historical and ecological synthesis that 
accounts for observed fioristic patterns. Concepts 
such as the Pleistocene refugia hypothesis (Haffer 
1969; Whitmore & Prance 1987) have been criti- 
cized because centers of plant diversity and ende- 
mism may, in fact, be artifacts of uneven collecting 
activity (Nelson et al. 1990). Therefore, any attempt 
to apply collections data to rigorous analyses of pat- 
terns of plant diversity must overcome limitations 
arising from the qualitative and incomplete nature 
of these data. Data taken from transects, for in- 
stance, are popular because transects may be sam- 
pled in locations selected to provide the most ap- 
plicable data, essentially all of the plant diversity 
along a transect may be sampled, and quantitative 
data may be collected such as basal area, relative 
density and dominance, and importance values (Bal- 
slev & Renner 1989; Balslev et al. 1987; Gentry 
1988a, b). Data from transects, however, have lim- 
itations because of the difficulty of determining the 
identity of the mostly sterile plants encountered on 
any given transect. Tuomisto (1998) attempted to 
overcome this limitation by sampling only pterido- 
phytes and Melastomataceae, which could be un- 
ambiguously and thoroughly sampled along tran- 
sects in the upper Amazon and used as an indicator 
of general fioristic patterns. This approach, however, 
although more rigorous and repeatable than those 
relying on determinations of sterile vouchers, is lim- 
ited by being a fragmentary view of only a very 
small subset of the total diversity in any given area. 
Terborgh & Andresen (1998) used data from 48 
one-hectare plots across Amazonia to study fioristic 
patterns; their study is limited because, like most 
others using plots or transects, only trees above a 
certain size class (? 10 cm dbh) were used. Further, 
their analyses were limited by being largely based on 
family-level determinations of individual trees in the 
plots. General plant collections made as part of flora 
and monographic projects have been underutilized 
29 
30 H. D. CLARKE AND V. A. FUNK 
Guyana 
French 
Guiana Atlantic 
Ocean 
Brazil 
jgo 500 KHorreters 
Fig. 1. Map of northeastern South America showing the location of the five florulas. 
in studies analyzing patterns of plant diversity. 
While the regional and continental floras and 
monographs that will be the full fruition of these 
projects may be decades away, sufficient progress has 
been made on a number of local florulas (a plant 
inventory of a limited geographic area) in north- 
eastern South America to allow for the development 
of hypotheses concerning fioristic gradients and 
their ecological and historical correlates. 
Thus, although a complete flora of the Guianas 
or Brazil cannot be expected in the near- or medi- 
um-term and the Flora Neotropica has an estimated 
completion time of 300 years (Mori 1992), five 
checklists of floras of restricted areas on and proxi- 
mate to the Guiana Shield have recently been made 
available. They may be used as proxies for regional 
floras to answer questions concerning the composi- 
tion and dynamics of the flora of a significant por- 
tion of the Guiana Shield in its ecological, geograph- 
ical, and historical context (Fig. 1). Three of these 
five areas are in Guyana: the Iwokrama International 
Centre for Rain Forest Conservation and Develop- 
ment (hereafter Iwokrama Forest; Clarke & Funk 
1998; Clarke et al. 2001), Mabura Hill (Ek & ter 
Steege 1997), and Kaieteur Falls National Park (Kel- 
loff & Funk 1998). A comprehensive checklist is 
also available for Central French Guiana (Mori et 
al. 1997, 2002) and a checklist has been produced 
for Reserva Ducke near Manaus, Brazil (Ribeiro & 
Hopkins 1999). A complete, synonymized checklist 
of all five areas is found in Clarke et al. (2001). 
Iwokrama Forest and Mabura Hill are characterized 
by low elevation (generally less than 100 meters 
above sea level (m asl), but Iwokrama has an isolated 
mountain range rising to 1000 m asl) and both 
sandstone- and granite-derived soils. Central French 
Guiana is very similar except that sandstone and 
white sands are absent. Reserva Ducke is also char- 
acterized by low elevation, but is in Amazonia prop- 
er and is not part of the Guiana Shield. Kaieteur 
Falls National Park is located at mid-elevation (500 
m asl) on the edge of the Pakaraima escarpment and 
is dominated by sand substrates associated with the 
Roraima sandstone formation. These areas and their 
associated checklists have features that make them 
appropriate for floristic comparisons on a regional 
scale: 1) the area of coverage of each flora is discrete, 
ranging from 10,000 to 360,000 hectares (ha); 2) 
they occupy positions and contain habitats that span 
significant geographic and ecological gradients of the 
FLORISTICS OF IWOKRAMA 31 
Guiana Shield and immediate environs; 3) the level 
of collecting intensity in each area is documented 
and can be compared with a view toward assessing 
the relative completeness of each of the checklists; 
4) the areas are relatively well characterized regard- 
ing environmental variables of precipitation, soils, 
climate, and topography (Kelloff & Funk 2004); 5) 
human disturbance in the areas is low or absent, 
allowing for inferences to be drawn from an essen- 
tially pristine flora; and 6) these five areas are fairly 
uniform regarding all but two of their environmen- 
tal parameters (soils and topography), allowing for 
the exclusion of differences in factors such as climate 
and precipitation as possible confounding factors 
when attempting to explain observed differences. 
Comparisons made here among the five checklists 
have the goal of testing a number of salient and, in 
some cases, competing hypotheses that have been 
proposed for the flora of the Guiana Shield: 1) the 
Guiana Shield overall represents a center of ende- 
mism of the neotropical flora (Berry et al. 1995); 2) 
there exists a Guiana Lowland center of endemism 
that complements the better-known Guiana High- 
land center of endemism (Mori 1991); 3) that en- 
demic elements of the flora of the Guiana Shield 
should more properly be considered to be those as- 
sociated with sand and sandstone substrates ("psam- 
mophilous") rather than high elevation per se (Ku- 
bitzki 1989, 1990); 4) that certain plant families 
should be over-represented in each of the florula 
areas in comparison to the regional flora (Boggan et 
al. 1997) because of their emergent ecological prop- 
erties, e.g. Fabaceae in lowland forests and Bonne- 
tiaceae in the Guiana Highlands (Ek & ter Steege 
1997). 
Predictions based on these hypotheses for the data 
from the checklists include: 
If there is a Guiana Lowland floristic province, 
the three florulas on the Guiana Shield, but not 
those associated with the escarpment of the Roraima 
Formation (Mabura Hill, Iwokrama, and Central 
French Guiana) should share a greater number of 
species than, for example, Kaieteur, Mabura, and 
Iwokrama or Iwokrama, Mabura, and Reserva 
Ducke. As a corollary, the three Guyanan florulas 
(Iwokrama, Mabura, and Kaieteur), though in close 
geographic proximity, should not share a greater 
number of species than other sets of three florulas; 
-the existence of an endemic psammophilous flora 
would predict a high number of species shared 
among the three areas that have extensive white sand 
and sandstone habitats, viz., Kaieteur at mid-elevation 
and Mabura and Iwokrama at low elevation. The 
competing hypothesis of an endemic Guiana High- 
land flora, i.e., one centered on the upland tepui hab- 
itats of the Roraima sandstone formation, predicts 
that the flora of Kaieteur would share very little of 
its diversity with these two, or other, areas; 
-the existence of a flora that is endemic to the 
Guiana Shield overall predicts that the florula of Re- 
serva Ducke would share the least number of species 
with any other of the five florulas. 
MATERIALS AND METHODS 
Checklists of the floras were obtained for Kaieteur 
Falls National Park (Kelloff & Funk 1998), the 
Iwokrama Forest (Clarke & Funk 1998), Mabura 
Hill (Ek & ter Steege 1997), and Reserva Ducke 
(Ribeiro & Hopkins 1999). The checklist of the 
flora of Central French Guiana was taken from the 
website maintained by S. Mori (www.nybg.org/bsci/ 
french-guiana/Families.html). To make the data 
from these five checklists more comparable, only na- 
tive, vascular plants have been used in this analysis 
and only determined species were used in the com- 
bined checklist, i.e. varieties or subspecies were 
pooled into a combined record of the species. Spe- 
cies recognized as distinct but indeterminate (e.g. 
Pouteria sp. "A" or Licania sp. "1,2,3") were exclud- 
ed except where that record constituted the only 
record of that genus for a given site. In that case, 
the record was maintained as an undetermined, 
unique species of that genus. These checklists were 
reconciled with respect to their synonymies and au- 
thorities and compiled into a combined checklist 
covering all five flora areas. The combined checklist 
is presented as a separate publication (Clarke et al. 
2001). Data for the five flora areas was compiled to 
detail the physical characteristics and habitat diver- 
sity in each area; they are presented below for each 
area in succession. 
Iwokrama Forest 
Iwokrama Forest is located in central Guyana be- 
tween 04?-05?N and 58.5? and 59.5?W, occupying 
a total of 360,000 ha. The elevation ranges from 65 
to 1000 m asl, but is for the most part low with 
the exception of the isolated granitic massif of the 
Iwokrama Mountains (1000 m) and doleritic intru- 
sions in the Pakutau Hills and Turtle Mountain 
(400 and 300 m asl, respectively). Aside from these 
three upland areas, the topography is relatively flat 
although very limited local relief associated with in- 
cised streambeds may shift the balance between terra 
firme and seasonally or permanently flooded forest. 
Levees associated with the three major rivers (Esse- 
quibo, Siparuni, and Burro Burro) are responsible 
for seasonally flooded forests occurring up to several 
kilometers from rivers. Although meteorological 
data are lacking, rainfall in Iwokrama Forest prob- 
ably averages between 2500 and 3000 mm per year 
32 H. D. CLARKE AND V. A. FUNK 
based on interpolation from surrounding areas. Soils 
are predominantly brown and white sands and lat- 
erite and are well-drained except in areas near 
streambeds or rivers and in a few limited areas where 
a clay hardpan occurs near the surface. 
Mabura Hill 
The checklist of the flora of Mabura Hill lists 
plants collected near the town of Mabura Hill in 
Central Guyana (5?13'N, 58?48'W) about 15 km 
N of a 900 ha ecological reserve maintained by the 
Tropenbos Foundation (Wageningen, The Nether- 
lands). Although Ek & ter Steege (1997) list the 
flora area as 10,000 ha, specimens were collected 
throughout the 220,000 ha Demerara Timbers Ltd. 
concession which is centered around the town of 
Mabura Hill. Mabura Hill is the only one of the 
five sites that has experienced human disturbance of 
any significant magnitude. This disturbance, result- 
ing from wide-scale, selective, commercial logging, 
certainly altered the flora quantitatively (for the 
most part after the plant collecting activities asso- 
ciated with producing the checklist took place) but, 
has had no qualitative effect on the flora since prob- 
ably neither extinction nor invasion of exotic species 
has occurred with increased frequency. Elevations in 
this area are uniformly low, ranging from 50?425 
m asl and rainfall is estimated at 2700 mm per year 
(Brouwer 1996). Soils are of white and brown sands 
with some laterite and are for the most part well- 
drained except in low areas or in association with 
the two major rivers, the Demerara and Essequibo 
(Kekem et al. 1996). 
Kaieteur National Park 
The Park is located at 5?10'N, 59?29'W in 
north-central Guyana where the Potato River de- 
scends from the escarpment of the Pakaraima 
Mountains to the lowlands, forming Kaieteur Falls 
which, at 226 m, is the highest sheer drop waterfall 
in the world. Kelloff & Funk (1998) state that his- 
torically the Park had an area of 58,000 ha. Al- 
though its size has recently been expanded, the cov- 
erage area of the flora does not extend beyond 
58,000 ha. Although elevations within the Park 
range from 150 m in the gorge below the falls to 
500 m around the falls, most collections were made 
above the falls because access to the gorge is diffi- 
cult. The topography is dominated by features of 
the Roraima sandstone formation, which is relatively 
fiat and forms numerous sandstone outcroppings. 
Soils, where they develop, are white sands and drain- 
age varies depending on slope and proximity of the 
relatively impervious sandstone layers. Annual pre- 
cipitation is approximately 3000 mm. 
Central French Guiana 
Coverage area of this flora is 140,000 ha bounded 
by  3?30'-3?45'N  and  53?00'-53?28'W in  the 
headwaters of the Mana, Approuague and Lawa/ 
Maroni Rivers and centered on the village of Saul. 
The topography of this area is varied, but mostly 
dominated by granite of the Guiana Shield, and el- 
evations are mostly low, about 200 m asl with a 
maximum of 760 m asl. Rainfall is approximately 
2500 mm per year. Soils in the area are brown sands 
and laterite; white sands are absent. 
Reserva Ducke 
The reserve is located on the outskirts of Manaus, 
Brazil at 2?53'S, 59?58'W and occupies 10,000 
hectares. The topography is relatively flat and the 
elevation is low (ca. 60 m). Sand terraces associated 
with the ancient Amazon riverbed provide limited 
local relief. Rainfall averages 2000 mm per year and 
soils are either white or brown sands and are for the 
most part well drained. 
Descriptive data were extracted from the com- 
bined checklist regarding the species diversity of in- 
dividual sites, overall diversity, and overlap of this 
diversity between sites. Further, the five sites and the 
Guianas overall (Boggan et al. 1997) were compared 
with regard to the rank of the twenty most diverse 
families at the species level and the percentage of 
the total flora of each site contained in the twenty 
most diverse families from the regional checklist. 
Data from the regional checklist (Boggan et al. 
1997) were included to show deviation in floristic 
composition at the family level for the five sites from 
the more comprehensive, regional flora. 
A Kendall's coefficient of concordance of ranks 
test (Sokal & Rohlf 1995) was performed on the 
rank of species diversity for the five sites plus the 
Guianas overall to test agreement among the six 
rankings of family diversity. Spearman rank corre- 
lation coefficient tests (Sokal & Rohlf 1995) were 
performed between all fifteen combinations of the 
five sites as well as the Guianas overall to test for 
significance of correlations in rankings between the 
sites. Clustering by the unweighted pairgroup meth- 
od, arithmetic average (UPGMA; Rohlf 1994) was 
used to create a phenogram indicating the relative 
similarities of the florulas. To correct for biases in- 
troduced by disparities in the sizes of the florulas, 
only the 1691 species present at two or more of the 
five sites were input into a matrix listing each of 
these species as present (1) or absent (0) at each site. 
These binary data were then used to create a simi- 
larity matrix with simple matching coefficients 
which was subsequently used to create the dendro- 
gram. 
FLORISTICS OF IWOKRAMA 33 
Table 1. Species diversity of the five florulas. Diagonal: Number of unique species/total number of species. 
Above diagonal: Number of uniquely shared species/number of shared species. 
Total = 4659 
Central French 
Iwokrama Mabura Kaieteur Guiana Ducke 
312/1251 116/545 71/383 135/589 40/370 
255/1240 63/405 132/627 51/422 
438/1134 73/416 
835/2069 
41/275 
227/658 
1047/1922 
Iwokrama 
Mabura 
Kaieteur 
Central French Guiana 
Ducke 
RESULTS 
The combined checklist contains 4790 species: 
1175 at Iwokrama, 1245 at Mabura Hill, 1060 at 
Kaieteur, 2073 in Central French Guiana, and 2085 
in Reserva Ducke. These totals along with figures of 
endemism and overlap of the species are presented 
in Table 1. 
The twenty most diverse families from Boggan et 
al. (1997) account for approximately 75% of the 
total species diversity in the combined checklist, so 
conclusions drawn from data from these families 
may be expected to reflect properties of the entire 
flora. The Kendall's coefficient of concordance of 
ranks test was highly significant (%^ = 82.6801, p 
< 0.001) indicating strong disagreement among the 
rank order of the twenty most diverse families across 
the five sites and the Guianas. Table 2 shows these 
twenty most diverse families with the total number 
and rank order of number of species in each of these 
families. Spearman rank correlation coefficients for 
all pairwise comparisons of rankings of the twenty 
most diverse families at the five sites and the Guian- 
as overall are listed in Table 3. Lower, non-signifi- 
cant correlation coefficients were found in compar- 
isons of Kaieteur with Mabura Hill (0.3093), Re- 
serva Ducke (0.0685), and Central French Guiana 
(0.2425) as well as the Guianas overall with Mabura 
Hill (0.2794), Central French Guiana (0.2889), and 
Reserva Ducke (0.1918). 
The UPGMA dendrogram (Fig. 2) shows that, in 
relative terms, Central French Guiana and Reserva 
Ducke are most similar floristically, Iwokrama and 
Mabura Hill next most similar, that the flora of Kai- 
eteur Falls is related to those of Mabura Hill and 
Iwokrama, and that these three florulas are more 
Table 2. Kendall's coefficient of concordance of ranks test of the 20 most diverse families from Boggan et 
al. (1997) for the five florulas and the Guianas. 
Iwokrama Mabu 
Central 
French 
Guiana Kaieteur Ducke Guianas 
Fabaceae 103 (1) 114(1) 136 (2) 66 (3.5) 192 (1) 742 (1) 
Rubiaceae 81 (2) 60(3) 127 (3) 72 (2) 85 (5) 506(3) 
Orchidaceae 51 0) 110 (2) 150 (1) 111 (1) 92 (3) 701 (2) 
Cyperaceae 42(4) 22 (15) 27 (19) 43 (6) 22(17) 303 (6) 
Myrtaceae 36 0) 35 (5.5) 76 (4) 66 (3.5) 80(6) 324 (5) 
Poaceae 34(7) 20 (17) 38 (12) 52 (5) 21 (18) 374 (4) 
Araceae 32 (8.5) 23 (13.5) 57 (5) 18 (12) 50 (10.5) 139 (10) 
Lauraceae 32 (8.5) 28 (9.5) 51 (7) 8 (17) 96 (2) 129 (16) 
Annonaceae 30(10) 30 (7) 29 (17) 7 (18) 62 (7) 126 (17) 
Chrysobalanaceae 29 (11) 35 (5.5) 35 (13.5) 20 (10.5) 50 (10.5) 134 (13) 
Euphorbiaceae 25(12) 25 (11) 46 (8.5) 15 (14) 46 (12) 191 (7) 
Sapindaceae 23(13) 24 (12) 42 (11) 6 (19.5) 40 (15) 122 (18) 
Apocynaceae 20(14) 29(8) 35 (13) 23 (9) 41 (14) 134 (13) 
Piperaceae 18 (15.5) 17 (19.5) 46 (8.5) 9 (16) 34(16) 108 (20) 
Bignoniaceae 18 (15.5) 37 % 43 (10) 17 (13) 45(13) 132 (15) 
Asteraceae 16 (17.5) 17 (19.5) 26 (20) 20 (10.5) 11(20) 159 (9) 
Sapotaceae 16 (17.5) 28 (9.5) 55 (6) 6 (19.5) 87 % 115 (19) 
Clusiaceae 15 (19) 23 (13.5) 28 (18) 25 (8) 530) 138 (11) 
Bromeliaceae 7(41) 20 (17) 33 (15) 33 (7) 17 (19) 134 (13) 
34 H. D. CLARKE AND V. A. FUNK 
Table 3. Spearman rank correlation coefficients test of the rank of the twenty most diverse families in the 
five fiorulas and the Guianas overall. H0: ps = 0; H^ ps ^ 0, rs indicated for each comparison. Non- 
significant rs values underlined. 
Mabura Kaieteur 
Central French 
Guiana Ducke 
Iwokrama 
Mabura 
Kaieteur 
Central French Guiana 
Ducke 
0.4531 0.4772 
03093 
0.4644 
0.6081 
0.2425 
0.5004 
0.7171 
0.0685 
0.6417 
0.7054 
0.2794 
0.8371 
0.2889 
0.1918 
similar to each other than they are to the floras of 
Central French Guiana and Reserva Ducke. 
DISCUSSION 
Sources of Error 
Bias may have been introduced in this study at 
any of three points: 1) selection of sites for com- 
parison, 2) during plant collecting at each site, and 
3) in the identification of plant specimens. There- 
fore, conclusions drawn from this study rest on the 
following assumptions: 1) that the five fiorulas are 
equally well sampled and that collecting methods at 
each site were equally successful in sampling plant 
diversity, 2) that all of the fiorulas are equivalent in 
size, 3) that differences in the sizes of coverage areas 
of the fiorulas do not result in significant differences 
in the sizes of the fiorulas, and 4) that determina- 
tions and synonymies have equal accuracy and pre- 
cision for all five fiorulas. 
The number of plant collections providing the 
basis for the fiorulas vary from 3,887 collections of 
1,075 species from Iwokrama to 12,847 collections 
of 2,073 species from Central French Guiana. That 
Central French Guiana, at 140,000 hectares, is less 
than half the size of Iwokrama's 360,000 hectares 
leads us to believe that plant collecting at Iwokrama 
has been insufficient to thoroughly sample the flora. 
In the absence of more objective criteria, this con- 
clusion must be drawn on the assumption that alpha 
diversity does not vary greatly between the two sites. 
Oliveira and Mori (1999) and Oliveira & Daly 
(1999) however, indicate a mechanism by which Re- 
serva Ducke and the Manaus area may have en- 
riched alpha diversity resulting from being in the 
contact zone among putative Tertiary and Quater- 
nary refugia, the Guiana Shield among them. Thus, 
the high diversity of Reserva Ducke in proportion 
to its size (2,085 species in 10,000 hectares) com- 
pared with the other four sites, in addition to being 
an artifact of greater collecting intensity, may also 
Iwokrama 
Mabura 
Kaieteur 
Ducke 
Central 
French Guiana 
1 1 r 1 1 1 1 1 1 T 1 1 1 1 r 1 1 1 1 1 1 
041 0.44 0.48 0J2 Oj) 
coefficient 
Fig. 2. UPGMA dendrogram showing relative similarity of the five fiorulas. 
FLORISTICS OF IWOKRAMA 35 
be an indication of higher actual diversity per unit 
area. 
Endemism and Overlap of the Florulas 
The results of this study indicate remarkably little 
overlap of the combined flora of the five areas. Be- 
tween 25 percent (at Mabura Hill) and 59 percent 
(at Reserva Ducke) of the species are found at only 
a single site in the combined checklist. Further, even 
Iwokrama and Mabura Hill, which share a common 
boundary, share only 513 species or less than half 
of each of their plant diversities. This may be a con- 
servative estimate of the proportion of the flora 
shared by the two sites, given that the two areas are 
undersampled and that widespread and common 
taxa have almost certainly been oversampled com- 
pared with the uncommon, endemic, or patchily 
distributed species that, when sampled, would de- 
crease our estimate of the percentage of the flora 
shared by Iwokrama and Mabura Hill. This strong 
indication of floristic heterogeneity occurs in the vir- 
tual absence of environmental gradients (soils, to- 
pography, temperature, precipitation, elevation). It 
has important implications for conservation efforts 
in the region, because we cannot assume that con- 
servation efforts in Iwokrama, which is protected at 
present, also preserves the plant diversity of even 
very similar adjacent areas such as Mabura Hill, 
which is now very seriously threatened by widescale 
logging. Additional collecting and soils and habitat 
mapping are needed in both Mabura and Iwokrama 
to obtain a more refined understanding of species 
overlap. 
Models of Elevational and Edaphic Endemism 
The inclusion of Kaieteur Falls, which is a classic 
example of the escarpment forming the border of 
the Roraima sandstone formation, with the other 
largely low elevation areas from the Guiana Shield 
(Iwokrama, Mabura Hill, and Central French Gui- 
ana) in this study allows for testing of competing 
hypotheses of elevational or landform ("Guiana 
Highland," Maguire 1979) and edaphic ("psam- 
mophilous," Kubitzki 1989 and 1990) models of 
endemism for the Guiana Shield. Our study indi- 
cates that Kaieteur Falls shares approximately one 
third of its flora with the two nearby low elevation 
areas in Guyana, Iwokrama and Mabura Hill (318 
and 349, respectively, of its 1065 species). Further, 
the UPGMA dendrogram indicates a similarity co- 
efficient greater than 0.5 among these three areas 
and a high similarity in the composition of their 
floras. Also, the Central French Guiana and Reserva 
Ducke florulas were not found to be very similar to 
that of Kaieteur. That these two areas lack sandstone 
substrates but have elevations similar to Iwokrama 
and Mabura Hill indicates that the endemic flora of 
the Guiana Highland should more properly be con- 
sidered as an endemic flora of white sand and sand- 
stone substrates rather than one determined by el- 
evation or landform per se. It is important to note 
that elevations in the Guiana Highland, particularly 
in Guyana, are often relatively low (500 m asl, for 
instance, in the example of Kaieteur) and that low- 
land areas in the Guiana Shield are frequently punc- 
tuated by massifs of moderate elevation (1000 m asl 
in the case of the Iwokrama mountains). It is there- 
fore not surprising that elevation turns out to be a 
confounding factor in explaining the distribution 
and endemism of the flora in this region. 
Geographic Endemism, Centripetal and 
Centrifugal Models of Dispersal of Plants of the 
Guiana Shield 
Mori (1991) argues for the existence of an en- 
demic Guiana Lowland flora to complement that of 
the Guiana Highland. The basis of the argument is 
abundant evidence for the existence of a rainforest 
refugium across the entire Guiana Shield rather than 
just in the Guiana Highland throughout the Tertiary 
and Quaternary. This refugium would have resisted 
both marine and savanna incursions resulting from 
global climatic fluctuations. This hypothesis predicts 
strong similarities among the floras of the three low 
elevation areas of the Guiana Shield, (Iwokrama, 
Mabura, and Central French Guiana), and strong 
dissimilarities between both Reserva Ducke and Kai- 
eteur on the one hand and any of the other florulas 
on the other. That the UPGMA dendrogram of our 
study indicates a strong similarity between the floras 
of Central French Guiana and Reserva Ducke and 
relatively little similarity between those of Reserva 
Ducke and the other two low elevation Guiana 
Shield areas, Iwokrama and Mabura Hill, is an in- 
dication that Central French Guiana has been rela- 
tively porous to centripetal migration of floristic el- 
ements from Amazonia proper onto the Guiana 
Shield. That the floras of Iwokrama and Mabura 
Hill, though geographically closer to Reserva Ducke 
than Central French Guiana, have resisted this cen- 
tripetal dispersal may possibly be attributed to the 
existence of white sand soils in these areas and the 
importance of competitive exclusion by those taxa 
adapted to sterile substrates of invading species with 
more general edaphic and nutrient requirements. 
Further testing of these ideas will be accomplished 
by integrating data from other collections into the 
existing data set. In particular, the 8000 collections 
made by the senior author in southern Guyana 
south of Iwokrama and Mabura Hill, an area that, 
like Central French Guiana, lacks white sand soils, 
36 H. D. CLARKE AND V. A. FUNK 
may help to document the transition between areas 
with a fundamentally Hylaean or Amazonian flora, 
such as Reserva Ducke, to that of a genuinely 
Guianan flora, such as Iwokrama, Mabura, and Kai- 
eteur. 
ACKNOWLEDGMENTS 
We wish to thank the Macushi, Wapisiana, and 
Arawak Amerindians of the communities surround- 
ing Iwokrama, particularly Romeo Williams, Clau- 
dius Perry, Milner Captain, Daniel Allicock, and 
Rodrigues Antone, without whose help the field 
portion of this work would not have been possible. 
Staff and faculty of the University of Guyana and 
the Centre for the Study of Biological Diversity on 
the campus of the University of Guyana, particularly 
Marlene Cox, Indarjit Ramdass, John Caesar, Phillip 
da Silva, and Dyantie Naraine, provided assistance 
with permits. Special thanks are due to the curators 
and staff of numerous herbaria for the determina- 
tion of specimens; without their many years of ac- 
cumulated effort in working with the Guyana flora 
this work would not have been possible. Particular 
gratitude is extended to Carol Kelloff for many in- 
tercessions on behalf of both authors. Two anony- 
mous reviewers contributed helpful comments to 
the manuscript. Funding was provided by the Unit- 
ed Nations Development Programme through the 
Iwokrama International Centre for Rainforest Con- 
servation and Development and by the Biological 
Diversity of the Guiana Shield Program of the 
Smithsonian Institution. This is publication number 
88 in the Smithsonian's Biological Diversity of the 
Guiana Shield Program publication series. 
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