
Hindawi Publishing Corporation
Psyche
Volume 2012, Article ID 928371, 7 pages
doi:10.1155/2012/928371

Research Article

Comparison of the Ant Assemblages in Three
Phytophysionomies: Rocky Field, Secondary Forest, and
Riparian Forest—A Case Study in the State Park of
Ibitipoca, Brazil

Juliane Floriano Santos Lopes,1 Noelle Martins dos Reis Hallack,1

Tatiane Archanjo de Sales,2 Mariana Silva Brugger,3 Laila Fieto Ribeiro,1

Isabel Neto Hastenreiter,2 and Roberto da Silva Camargo1

1 Pós-Graduação em Comportamento e Biologia Animal, Instituto de Ciências Biológicas, Universidade Federal de Juiz de Fora,
Campus Universitário de Martelos, 36.036-330 Juiz de Fora, MG, Brazil

2 Pós-Graduação em Ecologia, Instituto de Ciências Biológicas, Universidade Federal de Juiz de Fora,
Campus Universitário de Martelos, 36.036-330 Juiz de Fora, MG, Brazil

3 Departamento de Produção Vegetal, UNESP, Faculdade de Ciências Agronômicas, Caixa Postal 237, 18.603-979 Botucatu, SP, Brazil

Correspondence should be addressed to Juliane Floriano Santos Lopes, julianeflopes@yahoo.com.br

Received 13 September 2012; Revised 23 October 2012; Accepted 25 October 2012

Academic Editor: Kleber Del-Claro

Copyright © 2012 Juliane Floriano Santos Lopes et al. This is an open access article distributed under the Creative Commons
Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is
properly cited.

Ant assemblages are almost all related with the vegetation composition and so can provide us important information for
conservation strategies, which are especially relevant to an environmentally protected area. We sampled the ant fauna in three
different phytophysionomies in order to verify if the composition of ant species is different among the areas, especially because
one of the areas is a Rocky Field and there is little information about the ant fauna in this habitat. A total of 8730 individuals
were registered and an NMDS analysis showed that the ant assemblies are different at the three phytophysionomies (Rocky
Field, Riparian Forest, and Secondary Forest). This study shows that the species that compose the ant assemblies in different
phytophysionomies are a reflex of the environment, supporting the hypothesis that the vegetational composition results in different
compositions in the ant assembly. Vegetal composition is determinant in the formation of the litter and consequently in the
occurrence of ant species that depend on this layer of organic matter for nesting and foraging.

1. Introduction

Ants exert important effects in most ecosystems due to their
abundance, population stability, and foraging activity [1, 2].
Some of their main activities are the nutrient cycling and
control of other invertebrate populations [3]. They also
participate actively in the composition of vegetation through
seeds dissipation [4, 5], which gives them great importance
in recovering degraded areas [6].

Besides their ecological importance, the Neotropical ants
fauna are still little studied, especially if we consider the
region of “Mata Atlântica” (Atlantic Forest) which occupies

only 7% of its original area, according to the Ministry of
Environment data [7]. Studies made in this biome indicate a
high diversity of endemic species, which may comprise 50%
of total species and 95% in certain groups [8, 9].

Actually in recent years, myrmecologists attention has
been concerned essentially with ant communities, ant-
plant relations, mutualisms, biomonitoring, biogeography,
morphology and anatomy, genetics and cytogenetics, and
taxonomy [10]. Ant species inventories made in Brazil are
used to evaluate the conservation state of the environments,
especially in fragmented areas, as the Atlantic Forest [11].
Also, according to Delabie et al. [10] perusal of recent papers


2 Psyche

indicates there are still new ant species to be described in
Neotropical.

Inserted in the Atlantic Forest Biome, the State Park of
Ibitipoca (PEIb) is classified in the category of “Extreme Bio-
logical Importance” because of endemism of some species,
the relevance, the speleological singularity, and the diversity
of habitats [12]. This park occupies an isolated hilly area
from other areas of Rocky Field, presenting a distinctive
flora of “Cadeia do Espinhaço” itself, being considered a
disjunction concerning this Range [13].

PEIb presents significant diversity not only of vegetation,
but also of fauna, landforms, soils, and microclimates [14]
and covers two areas of regional vegetation, originally
composed by semideciduous seasonal forests and “cerra-
dos” [15]. It may be distinguished by five basic types
of phytophysiognomies—altitude “cerrado”, Rocky Fields,
Riparian Forest, capon of forest, and an area of dense
ombrophilous secondary forest.

The Rocky Fields are distinguished mainly by the grass-
land vegetation consisting of grass, herbs, and shrubs on
outcrops of quartzitic rocks associated to shallow soils and
high solar incidence [16]. The PEIb floristic studies indicate
predominance of “candeia” specimens (Vanillosmopsis ery-
thropappa).

The Semideciduous Secondary Forest covers an area
of 90 hectares at the south of the PEIb and it is totally
surrounded by woodlands, being named “Mata Grande.”
Due to the presence of anticlinal crests, this environment
is greatly influenced by clouds, winds, and lightning [17].
There is marked abundance of epiphytic plants and lichens,
with predominance of high trees (up to 25 m) [18].

The Riparian Forest in its extension mostly consists of
shrubs patches that accompany the distribution of thicker
soils, in slope conditions or concave lands. This subtype
of vegetation is humid, with reduced wind action and
remarkable presence of bromeliads and mosses and, in the
edges or less shaded areas, many kinds of lichens [19].

Considering that the vegetation is a good predictor of the
structure of community of ants [20–23], one could suppose
that in different phytophysionomies the composition of ant
species is equally distinct. In this context, a comparison
of ant assemblies in three distinct phytophysionomies was
accomplished—Rocky Field, Semideciduous Secondary For-
est, and Riparian Forest—in the PEIb. The knowledge of
how the ant species composition varies according to different
characteristics of habitat provides important information for
conservation strategies, which are especially relevant to an
environmentally protected area.

2. Material and Methods

2.1. Area of Study. This study was conducted in the State
Park of Ibitipoca—PEIb (21◦40′44′′ S and 43◦52′55′′ W) in
the city of Lima Duarte, Minas Gerais, Brazil (Figure 1). The
PEIb has approximately 1.488 ha with a mesothermic humid
climate (Köppen classification), with dry winters, pleasant
summers, and average annual temperature around 18.9◦C.
The influence of the relief over the climate is very important,

Figure 1: Parque Estadual do Ibitipoca (PEIb) in Minas Gerais
State, Brazil. Red pins: Rocky Fields (RKF); Green pins: Riparian
Forest (RPF); Yellow pins: Semidecidous Secondary Forest (SSF).
Font: Google Earth, 2010.

because the altitude and topography are differentiated and
the anticlinal crests in the PEIb stand out locally concerning
the neighboring areas, leading to a differentiated climate in
the area [17]. In the PEIb three phytophysionomies were
sampled: Rocky Fields (RKF), Semideciduous Secondary
Forest (SSF), and Riparian Forest (RPF).

2.2. Ants Sampling. In each of the three phytophysionomies,
three quadrants of 800 m2 each were established. The
minimum distance between the quadrants within the same
phytophysionomy was 50 m. The sampling of ants was
accomplished monthly between July and December 2008.

In each quadrant three parallel transects were established,
spaced from each other by 10 m. Along each transect the
sampling points were determined apart from each other
also by 10 m, in a total of 15 samples/quadrant. In each
transect a different method was employed, as follows: honey
and sardine attractive baits, pit-fall traps, and extraction in
Berlese funnel of litter samples.

The baits contained 5 g of a mixed paste of honey and
sardine (1 : 1 vol), distributed over paper tissues. The baits
remained in the field for 60 min [24], after been collected for
screening. Pitfall traps consisted of 500 mL plastic cups filled
with 200 mL of water and liquid neutral detergent (10%).
Pitfall traps remained in field for 24 h. Litter samples were
standardized with a plastic grid of 0.25 m2 on soil. The litter
was put in Berlese funnel for 48 h for screening material.

In the quadrants of Rocky Fields, the pitfall traps and the
litter samples were replaced by the attractive bait, considering
the impossibility of using these methods, because litter is
absent in the Rocky Fields and the installation of pitfalls
under the rock is infeasible.

Collected ants were sorted, counted, and stored in
alcohol 90%, recording phytophysionomy, method, and date
of collect. After, a taxonomic identification was made under
stereoscopic microscope (Leica), from dichotomous keys


Psyche 3

0

5

10

15

20

25

Sp
ec

ie
s

1 11 21 31 41

Samples

Rocky Field
Riparian Forest
Secondary Forest

Figure 2: Sample-based rarefaction curves for the ant species at
three phytophysionomies at Parque Estadual do Ibitipoca—Brazil.
July–December, 2008.

[25, 26]. Ants were coded at genera level and separated
in morph-species. Dr. Rodrigo Feitosa from the Museum
of Zoology of São Paulo confirmed the species identifica-
tion. The specimens were mounted and deposited in the
thematic collection of MirmecoLab, ICB-UFJF (Campus
Universitário, Cidade Universitária-s/n, Juiz de Fora-MG,
CEP: 36036900).

2.3. Data Analysis. To evaluate the sampling effort, we
constructed a rarefaction curve [27], using the program Esti-
mateS [28]. Sample-based rarefaction curves indicate that
sampling effort was significant for three phytophysionomies
(Figure 2).

The content of five samples per method of collect was
grouped to obtain a single sample for each transect in
each quadrant. To compare the ant species composition
from different phytophysionomies, we used multivariate
analysis with the program PAST [29]. Data were organized
in a binary matrix, considering the taxonomic level of
genera (presence and absence) and submitted to nonmetric
multidimensional ordination (NMDS). The dissimilarity
between the phytophysiognomies was calculated through the
Bray-Curtis index, which is less affected by the occurrence of
rare species in the samples [30]. The stress index calculated
by NMDS is a measure of goodness-of-fit [31].

Also a one-way analysis of similarity was applied (one-
way ANOSIM), with 10 thousand permutations. This anal-
ysis compares the differences between the averages of the
ranked similarities among the samples within and between
the phytophysiognomies, verifying if there are significant
differences in the composition of genera. ANOSIM generates
a statistic R, which is a measure of dissimilarity between
the areas. R values near zero indicate high similarity while
R values near 1 indicate low similarity [32]. To calculate

ANOSIM, the Bray-Curtis index was also used and each R
value has its corresponding probability.

A similarity percentage test (SIMPER) was applied,
which permits to determine which genera more contributed
to discriminate among assemblies. SIMPER analysis provides
a percentage of dissimilarity among the phytophysiog-
nomies, presenting a percentage of contribution of each
genera for such dissimilarity [31].

3. Results

A total of 8.730 individuals were collected, belonging to
46 species, 20 genera, and eight subfamilies: Ecitoninae,
Ectatomminae, Heteroponerinae, Ponerinae, Formicinae,
Dolichoderinae, Pseudomyrmecinae, and Myrmicinae, pro-
viding a list of ant species that occur in the PEIb (Table 1).

The greatest number of species was recorded for Riparian
Forest, followed by Rocky Field and Secondary Forest,
listing as exclusive species of Riparian Forest: Pheidole sp6,
Strumigenys louisianae, Brachymyrmex sp2, Paratrechina sp1,
and Labidus sp1. As unique species of Rocky Field are listed
up: Cephalotes pusillus, Brachymyrmex sp3, Camponotus
genatus, Myrmelachista sp2, Myrmelachista sp3, and Pseu-
domyrmex sp1; and in the Secondary Forest: Brachymyrmex
sp1, Myrmelachista sp1, and Hypoponera foreli (Table 1).

Among the 19 ant species shared within the three
studied areas, the most representative genera were Pheidole
(7 species), Camponotus (4 species), and Hypoponera (3
species). We highlight the Camponotus absence in the
Secondary Forest and the exclusive occurrence of each one
of the three Brachymyrmex species in each phytophysionomy
(Table 1).

Ant species composition in the three phytophysionomies
differed significantly. (ANOSIM, R = 0.48, P = 0.0001),
being more similar to the samples belonging to the same
phytophysionomies (Figure 3, Table 2). The ordination
NMDS indicates a stress value of 0.16, with the coordinates 1
and 2 explaining 48% and 26% of data variation, respectively.
Actually, the greatest values of dissimilarity were verified
between the Secondary Forest and the Rocky Fields (Table 3),
being their samples, respectively, separated by coordinate
1.

According to the SIMPER test, the genera that most con-
tributed for the dissimilarity among the phytophysionomies
were Crematogaster and Myrmelachista which are responsible
for 66.58% of the variation of species composition among the
phytophysionomies (Table 4).

4. Discussion

The phytophysionomies showed differences in the com-
position of ant species, especially between SSF and RKF
(Figure 3), evidencing the relationship between the vegeta-
tion and the ant fauna.

The SSF presents larger diversity of vegetal species, with
genera of the families Rubiaceae, Lauraceae, Myrtaceae,
Euphorbiaceae, Nyctaginaceae, Melastomataceae, Annon-
aceae, Palmae, Apocynaceae, and Monimiaceae [19]. This


4 Psyche

Table 1: Relative frequency of occurrence of ant species in the three phytophysionomies in the Parque Estadual do Ibitipoca, Brazil. July–
December, 2008.

Species Rocky Field Riparian Forest Secondary Forest

Myrmicinae

Acromyrmex aspersus F. Smith, 1858 0.00 92.29 7.71

Acromyrmex hispidus Santschi, 1925 20.08 78.74 1.18

Apterostigma (gr. pilosum) sp1 Mayr 20.00 40.00 40.00

Apterostigma sp2 Mayr 94.12 0.00 5.88

Cephalotes pavonii Latreille, 1809 93.52 6.48 0.00

Cephalotes pusillus Klung, 1824 100.00 0.00 0.00

Crematogaster sericea Forel, 1912 98.46 1.50 0.05

Octostruma balzani Emery, 1894 0.00 37.50 62.50

Octostruma rugifera Mayr, 1887 0.00 50.00 50.00

Pheidole obscurithorax Forel, 1985 77.78 15.56 6.67

Pheidole radoskowskii Mayr, 1884 44.32 5.68 50.00

Pheidole sp1 Westwood 21.90 59.65 18.45

Pheidole sp2 Westwood 39.20 14.20 46.60

Pheidole sp3 Westwood 48.88 26.85 24.27

Pheidole sp4 Westwood 33.33 18.52 48.15

Pheidole sp5 Westwood 60.14 17.39 22.46

Pheidole sp6 Westwood 0.00 100.00 0.00

Solenopsis sp1 Westwood 1.03 97.94 1.03

Solenopsis sp2 Westwood 38.96 57.14 3.90

Strumigenys louisianae Roger, 1863 0.00 100.00 0.00

Wasmannia affinis Santschi, 1929 27.78 50.00 22.22

Wasmannia auropunctata Roger, 1863 19.28 57.83 22.89

Formicinae

Brachymyrmex sp1 Mayr 0.00 0.00 100.00

Brachymyrmex sp2 Mayr 0.00 100.00 0.00

Brachymyrmex sp3 Mayr 100.00 0.00 0.00

Camponotus crassus Mayr, 1862 92.14 7.86 0.00

Camponotus genatus Santschi, 1922 100.00 0.00 0.00

Camponotus melanoticus Emery, 1894 59.46 40.54 0.00

Camponotus pr bonariensis Mayr, 1868 60.00 40.00 0.00

Camponotus renggeri Emery, 1894 78.02 21.98 0.00

Myrmelachista sp1 Roger 0.00 0.00 100.00

Myrmelachista sp2 Roger 100.00 0.00 0.00

Myrmelachista sp3 Roger 100.00 0.00 0.00

Paratrechina sp1 Motschoulsky 0.00 100.00 0.00

Ectatominae

Ectatomma edentatum Roger, 1863 58.23 40.51 1.27

Heteroponerinae

Heteroponera dentinodis Mayr, 1887 0.00 18.75 81.25

Heteroponera inemis Emery, 1894 0.00 5.56 94.44

Ponerinae

Hypoponera foreli Mayr, 1887 0.00 0.00 100.00

Hypoponera sp1 Santschi 1.75 8.77 89.47

Hypoponera sp2 Santschi 25.00 25.00 50.00

Hypoponera sp3 Santschi 0.00 7.32 92.68

Pachycondyla striata Smith, 1858 22.22 50.00 27.78

Ecitoninae

Labidus sp1 Jurine 0.00 100.00 0.00


Psyche 5

Table 1: Continued.

Species Rocky Field Riparian Forest Secondary Forest
Dolichoderinae

Linepithema cerradense Wild, 2007 89.61 7.79 2.60
Linepithema pulex Wild, 2007 9.35 90.65 0.00

Pseudomyrmicinae
Pseudomyrmex sp1 Lund 100.00 0.00 0.00

Table 2: Comparisons ANOSIM paired of the composition of ant
species in the three phytophysiognomies sampled in the Parque
Estadual do Ibitipoca, Brazil. July–December, 2008.

Riparian
Forest

Secondary
Forest

Rocky
Field

Riparian
Forest

— 0.257 (P = 0.0003) 0.435 (P = 0.0003)

Secondary
Forest

— 0.747 (P = 0.0003)

Rocky Field —

Table 3: Dissimilarity values (SIMPER) between the three phyto-
physiognomies sampled in the Parque Estadual do Ibitipoca, Brazil.
July–December, 2008.

Riparian Forest Secondary Forest Rocky Field

Riparian Forest — 83.45 86.31

Secondary Forest — 88.61

Rocky Field —

vegetation composition promotes the litter formation and,
consequently the occurrence of cryptic ant species that
depend on this layer to their nesting and foraging [33].

Actually we sampled seven and six cryptic ant species at
SSF and RPF, respectively, while there are just four cryptic ant
species at RKF. We pointed out that among these four cryptic
species at RKF, two of them are arboricolous (Myrmelachista)
[34], so they are not litter-dependent for nesting or foraging.

The Rocky Field presents characteristics completely
different from the other areas. With a rocky soil, this
open environment has a predominance of small trees with
extra floral nectaries, especially of the genera Vanillosmopsis
(“candeia”). Also the lack of nearby water bodies makes this
phytophysionomy a hostile environment. According to Cam-
pos [16], rocky and sand exposed at the top of these fields are
among the most extreme combinations of an environment.
Mountainous areas, on which are found the rocky fields, are
comparable to islands separated by very different ecological
conditions [35]. The occurrence of arboreal ant species that
present association with plants (Crematogaster, Cephalotes,
Pheidole, Camponotus, Myrmelachista, Linepithema, and
Pseudomyrmex) is a reflex of Rocky Field characteristics.

We emphasize the high frequency of Camponotus in the
Rocky Field in contrast to its absence in the Secondary
Forest. Camponotus is cited as the most frequent in open
habitats such as sandbanks [36], “cerrado” [37–39], and
“caatinga” [40]. This study includes Rocky Field as a habitat
that allows to its occurrence. The absence of Camponotus in

−0.3 −0.24−0.18−0.12−0.06 0.06 0.12 0.18 0.24

Coordinate 1

C
oo

rd
in

at
e 

2

−0.25

−0.2

−0.15

−0.1

−0.05

0.05

0.1

0.15

Figure 3: Nonmetric multidimensional ordination (NMDS) of
ant species composition in three phytophysionomies sampled in
the Parque Estadual do Ibitipoca, Brazil. July–December, 2008.
Secondary Forest (triangles), Riparian Forest (squares), and Rocky
Field (circles). Stress value = 0.16.

the Secondary Forest could be related to the achievement of
collects exclusively in soil, combined with the high scale of
the vegetation in this area.

Besides Camponotus, Brachymyrmex is also noteworthy,
given the observed spatial segregation in which each of the
three species was exclusively sampled in one of the areas.
This spatial segregation can be explained given the high level
of aggression recorded for the genera, even in intraspecific
interactions [41].

For Riparian Forests the values of dissimilarity are near
50% and can be considered as a transition range between
the two other phytophysiognomies, agreeing with the spatial
location of this habitat in the PEIb (Figure 1) and with the
presence of specialist (e.g., Acromyrmex, Labidus), invasive
(e.g., Solenopsis, Paratrechina), and cryptic ant species (Stru-
migenys).

This study shows that the species that compose the ant
assemblies in different phytophysiognomies are a reflex of the
environment, especially of the plant species, supporting the
hypothesis that differences in the vegetational composition
result in different compositions in the ant assembly.

Also the vegetational composition is determinant in the
formation of the litter and consequently in the occurrence
of ant species that depend on this layer of organic matter for


6 Psyche

Table 4: Cumulative contribution of ant genera for the dissimilarities among the phytophysionomies (SIMPER) sampled at Parque Estadual
do Ibitipoca, Brazil. July–December, 2008.

Genus Cumulative contribution %
Average abundance

Rocky Field Riparian Forest Secondary Forest

Crematogaster 42.64 1.78 0.05 0

Myrmelachista 66.58 0 1.78 0.05

Pheidole 80.35 0.05 0.27 2.78

Acromyrmex 93.13 3.83 0.33 0.11

Camponotus 96.92 0 0.22 2.83

Linepithema 98.83 0.22 0.5 0.27

Solenopsis 99.41 0.88 0 0.05

Wasmannia 99.68 0.11 0.11 0.27

Heteroponera 99.85 0 0.05 0

Strumigenys 100 0.11 0 0

nesting and foraging as the cryptic ant species [42]. Obtained
data suggest that determination of ant fauna in the Secondary
Forest and Riparian Forest is dependent of the conditions
and resources provided by these phytophysiognomies, for
instance, the presence of litter, shaded areas, and high trees.
Unlike, in the Rocky Field, it is expected that the competition
is the most important factor in determining the species that
compose the assembly, considering the absence of litter, high
insolation, and scarcity of resources.

Acknowledgments

The authors thank the Instituto Estadual de Florestas
(IEF) from Minas Gerais State and the Parque Estadual
do Ibitipoca Administration for allowing the research and
for facilities in the Park, especially to João Carlos Lima
de Oliveira and Clarice Nascimento Lantelme Silva. The
IBAMA for permission to collect the ants, R. Feitosa for
identifying the ants at the taxonomic level of species,
FAPEMIG (Fundação de Amparo a Pesquisa do Estado de
Minas Gerais) (Proc. APQ 00411-08) for funding and CNPq
for the Grant to the first author (Proc. 307335/2009-7). The
authors declare that they have no conflict of interests.

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