Open access journal: http://periodicos.uefs.br/ojs/index.php/sociobiology
ISSN: 0361-6525

DOI: 10.13102/sociobiology.v63i3.1014Sociobiology 63(3): 881-888 (September, 2016)

Mandibles of Leaf-Cutting Ants: Morphology Related to Food Preference

Introduction

The mandibular morphology reflects the species’ 
adaptations to particular foraging habits and social life 
(Gronenberg et al., 1997). Leaf-cutting ants (Atta and 
Acromyrmex), in particular, use different parts of plants for 
cultivation of their symbiotic fungus, with some species 
preferring dicotyledons and others grasses (monocotyledons) 
(Fernandez et al., 2015). Grass-cutting ants tend to have more 
massive and shorter mandibles, while the mandibles of leaf-
cutting ants are longer and less massive (Fowler et al., 1986). 
Actually, comparing Atta species with these different plant 
preferences has demonstrated they had similar mandible 
morphology, primarily differing in distal tooth length, while 
Acromyrmex exhibited a higher variation in the mandible 
format as a whole (Camargo et al., 2015).

In general, the leaf blade of grasses contains abundant 
cells with lignified walls (Scheffer-Basso et al., 2002; Pelegrine 

Abstract 
Feeding adaptation is crucial for the ecological success of animals, which 
explore specific or varied resources according to the suitability of the selected 
morphological feature. We hypothesized that the mandibles of leaf-cutting 
ants exhibit a specialization because of the specific food preference of some 
species. The objective of this study was to highlight possible morphological 
differences between the mandibles of leaf-cutting ant species of the genus 
Atta related to food preference, i.e., to investigate the morphofunctionality. 
A detailed description of the mandibles of workers of the grass-cutting ant 
Atta bisphaerica and of the leaf-cutting ant Atta sexdens rubropilosa was 
provided. For morphometric analysis, 50 individuals of four size classes were 
dissected for removal of the right mandible and one sample of each caste was 
processed for scanning electron microscopy. It was observed differences between 
species and among castes, demonstrating the clear specialization of workers. 
Although the results of mandibular morphometry accept the hypothesis of 
morphofunctionality, further investigation is needed taking into consideration 
the body size of foragers, robustness and factors that confer greater resistance 
to the mandibles such as zinc content, the force employed during cutting, and 
mandibular biomechanics.

Sociobiology
An international journal on social insects

LC Silva1, RS Camargo1, JFS Lopes2, LCForti1

Article History

Edited by
Evandro Nascimento Silva, UEFS, Brazil
Received                    02 March 2016
Initial acceptance     19 June 2016
Final acceptance       11 September 2016
Publication date        25 October 2016

Keywords 
Hymenoptera, Atta, Social insects, Leaf-
cutting ants. 

Corresponding author
Roberto da Silva Camargo
Laboratório de Insetos Sociais-Praga 
Departamento de Produção Vegetal 
Faculdade de Ciências Agronômicas/UNESP 
Rua Dr. José Barbosa de Barros, 1780 
CEP: 18610-307 - Botucatu-SP, Brasil
E-Mail: camargobotucatu@yahoo.com.br

et al., 2009), which renders them more resistant to cutting, as 
well as solid particles of hydrated silica (SiO2nH2O) found in 
the epidermal cells (Motomura et al., 2002). The accumulation 
of silicon has been associated with a variety of functions, 
including protection against fungal attacks, resistance to water 
loss, stimulation of photosynthesis, and structural support (Lux et 
al., 2003; Müller, 2003; Hattori et al., 2005). Moreover, silica 
plays an important role in the interaction between herbivores 
and plants. Massey et al. (2006a, 2006b, 2007, 2008, 2009) 
showed that silica accumulation in grasses increases leaf 
abrasiveness, causing the wear and deterioration of mandibles 
and impairing insect feeding.

In view of this previous knowledge, we hypothesized 
that the mandibular morphology of workers differs according 
to the plants preferentially cut by them. Therefore, this study 
compared the morphology of worker mandibles between 
castes (soldier, forager, generalist and gardener according 
to Wilson, 1980). It is expected that the mandible of grass-

1 - Faculdade de Ciências Agronômicas/UNESP, Botucatu-SP, Brazil
2 - Universidade Federal de Juiz de Fora, Juiz de Fora-MG, Brazil

RESEARCH ARTICLE - ANTS



LC Silva et al. – Mandibles of leaf-cutting ants882

cutting ants is more massive and shorter, while the mandible 
of leaf-cutting ants would be longer and less massive.

Material and methods

Two leaf-cutting ant species, A. s. rubropilosa and 
A. bisphaerica, were used in this study. Field and laboratory 
colonies were used. For the collection of  A. bisphaerica workers, 
a single fungus chamber of an adult nest was excavated on the 
Santana farm located near the Lageado Experimental Farm of 
UNESP, Botucatu, São Paulo, Brazil (geographic coordinates: 
22o 50’ 46” S and 48o26’2” W). In this farm, the pasture  was 
predominantly covered with Paspalum sp. with some patches 
of Brachiaria here and there. A. s. rubropilosa workers were 
obtained from an adult laboratory colony (10 years old, 50 liters 
of fungus garden). For morphometric analysis, 50 individuals 
of each caste were dissected for removal of the right mandible 
under a stereoscope: gardener (head width 0.8-1.2 mm; n=50), 
generalist worker (head width 1.3-1.6 mm; n=50), forager 
(head width 1.7-2.2 mm; n=50), and soldier (head width ≥ 3.3 
mm; n=50). This caste determination was proposed by Wilson 
(1980, 1983). The observations were made on the ventral side 
of right mandibles.

The following measurements were made using a 
micrometer eyepiece coupled to a stereomicroscope: 1) length 
of the mandible; 2) width of the mandible; 3) length of the 
first tooth; 4) length of the second tooth; 5) number of teeth 
and 6) head width (mm).

To detect morphological differences between mandibles of 
the different ant species, samples of the right mandible of workers 
of all size classes were fixed in 2.5% glutaraldehyde in 0.1 M 
phosphate buffer, pH 7.3, critical point dried, sputtered with gold 
(Robards, 1978), and examined by scanning electron microscopy 
(SEM) (FEI Quanta™ 200) at the Center of Electron Microscopy, 
Institute of Biosciences (Centro de Microscopia Eletrônica do 
Instituto de Biociências – CME-IBB), UNESP, Botucatu, SP. For 
determination of the occurrence of wear, the mandible of an A. 
s. rubropilosa forager was collected 1 day after emergence and 
submitted to the same procedures for SEM analysis.

We analyzed the data and verified that all variables 
weren’t normally distributed (Shapiro-Wilk normality test), 
being thus log-transformed. Principal Component Analysis 
(PCA) was used to examine variation in the morphometric data 
among species using the free software PC-ORD 5.15 (McCune 
& Mefford, 2011), with exception of the number of teeth. 
The number of principal components (PCs) was determined 
considering eigenvalues higher than those generated by the 
Brokenstick method. The morphometric measurements that 
most contributed to the axes, were selected by Pearson (r > 
0.7). After that, we performed an ANOVA comparing the 
PCA scores with Tukey HSD post-test (α=0.05), to point out 
the differences among the variables.

Results

We found differences between species and among 
castes (ANOVA, F 7;391=455.2, P <0.001). All castes differed 
among them, except between soldiers from A. s. rubropilosa 
and A. bisphaerica (P=0.31) and A. bisphaerica generalist 
workers with A. s. rubropilosa foragers (P=0.11) (Table 2).

PCA analysis found that the first principal component 
explains 91.5% of the variation. Also it is strongly correlated 
with the four morphometric variables. The first principal 
component increases with decreasing length mandible (r= 
-0.96), width mandible (r= -0.96), length of the first teeth (r= 
-0.98) and length of the second teeth (r=-0.93). This suggests 
that these four morphometric measures vary together. If 
one decreases, then the remaining also decreases. It would 
follow that species and castes would tend to be grouped due 
to their mandible features, in terms of the morphometric 
measurements (Figure 1).

Differences were also detected within the different 
castes of each species. Soldiers of the two species had larger 
and more robust mandibles compared to the other castes. 
Mandibular morphology of foragers although similar to that 
of soldiers, were smaller mandibles and with teeth more worn  
(Figure 6-7). The mean number of teeth was 7 or 8 for A. 
bisphaerica and 7 to 9 for A. s. rubropilosa (Table 1). Tooth 

Fig 1. Principal components analysis of mandible morphometric data of Atta sexdensrubropilosa and Atta bisphaerica 
in each worker caste for the variables width mandible (WM), Length mandible (LM) Length of the fisrt tooth (LFT) 
and length of the second tooth (LST) First two principal components (PCs) are plotted with the proportion of variance 
explained by each component printed next to the axes labels.



Sociobiology 63(3): 881-888 (September, 2016) 883

Ant species Caste Head width
Mandibular 
length

Mandibular 
width

Length of 1st 
tooth

Length of 2nd 
tooth

Number of 
teeth

Atta bisphaerica

Gardener 0.76±0.20 0.40±0.10 0.25±0.09 0.08±0.06 0.04±0.02 10.14±2.12

Generalist 1.29±0.10 0.67±0.06 0.46±0.04 0.20±0.04 0.09±0.03 7.92±0.73

Forager 2.13±0.19 0.99±0.08 0.70±0.06 0.26±0.05 0.13±0.04 7.78±0.79

Soldier 4.79±0.43 1.58±0.08 1.11±0.07 0.49±0.07 0.14±0.03 7.78±0.68

Gardener 0.89±0.13 0.51±0.10 0.30±0.06 0.10±0.03 0.05±0.02 9.46±1.15
Atta sexdens Generalist 1.32±0.08 0.65±0.06 0.40±0.05 0.13±0.03 0.07±0.02 8.84±1.08
Rubropilosa Forager 2.02±0.18 0.88±0.11 0.52±0.07 0.17±0.05 0.09±0.03 8.36±1.05

Soldier 3.79±0.23 1.54±0.07 0.94±0.05 0.41±0.04 0.17±0.03 8.64±0.80

Table 1. Morphometric measures (mean and standard deviation) (mm) of the mandibles and teeth of Atta bisphaerica and Atta sexdens 
rubropilosa.

wear was observed when adult foragers of undetermined 
age (Figure 10) were compared with an adult on day 1 after 
hatching (Figure 11). As can be clearly seen in Figure 10, 
the teeth of probably older foragers were slightly rounder, 
probably due to wear out, when compared to the naive forager 
worker (1-day old) (Figure 11), in which a larger number of 
teeth and more pointed teeth can be seen.

Generalist workers of A. bisphaerica had more elongated 
mandibles when compared to A. s. rubropilosa (Figure 4-5) and 
presented no tooth wear. However, Figure 4 shows wear out 
of the mandible of generalists A. bisphaerica workers.

The elongated mandibles of A. bisphaerica were also 
observed in gardeners of this species (Figure 2-3). No tooth 
wear was observed in this caste of the both species. Gardeners 
had a larger number of teeth and more pointed teeth than the 
other castes analyzed (Table 1).

In all castes of the two species the teeth had a serrated 
appearance characterized by a progressive reduction in their 
size. The main difference between species was the larger size 
of the distal tooth in Atta bisphaerica.

These results demonstrate that the mandible morphology 
is different between species and within castes. However, 
a difference within castes seems to be found at the same 
features in both species.

Discussion

Leaf-cutting ants in general (Atta and Acromyrmex) use 
different parts of plants for cultivation of the symbiotic fungus. 
Some species prefer dicotyledons, while others prefer grasses 
(monocotyledons) (Fernandez et al., 2015), a fact raising the 
hypothesis of a greater degree of specialization in view of the 
specific food preferences of these species. The results of the 
present study accept the hypothesis of morphofunctionality 
of leaf-cutting ant (A. s. rubropilosa) and grass-cutting ant 
mandibles (A. bisphaerica) is related to food preference. This 
hypothesis was raised by Fowler et al. (1986) based on the 
morphological differences observed in these groups. In this 
respect, in species that preferentially cut grasses the foragers 
tend to have shorter mandibles compared to foragers of leaves 

Comparisons
Mean 

difference

Confidence Intervals
P- value 
adjustedLower 

Bound
Upper 
Bound

FS-JS 0.606 0.491 0.720 < 0.0001
FS-SB -0.756 -0.870 -0.641 < 0.0001
FS-SS -0.670 -0.785 -0.555 < 0.0001
GS-GB 0.173 0.058 0.288 0.0001
JB-GB 0.742 0.627 0.857 < 0.0001
JS-GB 0.502 0.386 0.617 < 0.0001
SB-GB -0.860 -0.975 -0.745 < 0.0001
SS-GB -0.774 -0.889 -0.659 < 0.0001
JB-GS 0.569 0.454 0.684 < 0.0001
JS-GS 0.328 0.214 0.443 < 0.0001
SB-GS -1.033 -1.148 -0.918 < 0.0001
SS-GS -0.947 -1.062 -0.833 < 0.0001
JS-JB -0.240 -0.355 -0.125 < 0.0001
SB-JB -1.603 -1.717 -1.488 < 0.0001
SS-JB -1.517 -1.632 -1.402 < 0.0001
SB-JS -1.362 -1.477 -1.247 < 0.0001
SS-JS -1.276 -1.391 -1.162 < 0.0001
SS-SB 0.085 -0.029 0.200 0.3097
FS-FB 0.253 0.139 0.368 < 0.0001
GB-FB 0.357 0.242 0.473 < 0.0001
GS-FB 0.531 0.416 0.645 < 0.0001
JB-FB 1.100 0.985 1.215 < 0.0001
JS-FB 0.859 0.745 0.974 < 0.0001
SB-FB -0.502 -0.617 -0.387 < 0.0001
SS-FB -0.416 -0.531 -0.302 < 0.0001
GB-FS 0.104 -0.011 0.219 0.1096
GS-FS 0.277 0.162 0.392 < 0.0001
JB-FS 0.846 0.732 0.961 < 0.0001

 
*Significant difference at 95% family-wise confidence level by Tukey HSD test.

Table 2. Statistical summary of multiple comparison by Tukey HSD 
(α=0.05). SS: A. s. rubropilosa soldiers; FS: A. s. rubropilosa foragers; 
GS: A. s. rubropilosa generalist workers; GS: A. s. rubropilosa 
gardeners; SB: A. bisphaerica soldiers; FB: A. bisphaerica foragers; 
GB: Atta bisphaerica generalist workers; GB: A. bisphaerica gardeners.



LC Silva et al. – Mandibles of leaf-cutting ants884

which tend to have less massive mandibles. As a consequence, 
these foragers cut plants differently. For example, during 
foraging Atta capiguara assumes a downward position while 
cutting the leaf blade of grasses, performing the cut and 
immediately returning to the nest. In contrast, in leaf-cutting 
ants the metathoracic legs serve as a pivot during cutting 
and their mandibles slide across the leaf blade. Behavioral 
differences between grass-cutting and leaf-cutting ants are 
also observed during cultivation of the symbiotic fungus 
(Lopes, 2004). Leaf-cutting ants exhibit a higher degree of 
processing of the foraged material that resembles grinding 
before incorporation of the symbiotic fungus. In contrast, in the 
case of grass-cutting ants the degree of processing is lower, i.e., 

the leaf blades are just arranged on the fungus garden and the 
symbiotic fungus is subsequently incorporated (Lopes, 2004). 
This behavior is probably related to the greater difficulty in 
processing the material due to the higher proportion of lignified 
tissues in grass leaves (Lopes, 2004).

In the present study, mandible morphometry was useful 
to discriminate between species and castes (Figure 1). These 
results are possibly related to the recent evolutionary history 
of the two species. The genus Atta is monophyletic (Bacci 
et al., 2009), with relatively recent adaptive radiation about 
8 to 13 million years ago (Brady et al., 2006). However, the 
identification of adaptive radiation is based on the phylogenetic 
relationships of species and not on the dating of known fossils 

Figs 2-3. ventral side of right mandibles of Atta bisphaerica (2) and Atta sexdens rubropilosa (3) gardeners.

Figs 4-5. Ventral side of right mandibles of Atta bisphaerica (4) and Atta sexdens rubropilosa (5) generalist workers.



Sociobiology 63(3): 881-888 (September, 2016) 885

of Atta, which are scarce for the genus. There is only one trace 
fossil of an Atta nest from the Miocene located in Patagonia, 
Argentina (Laza, 1982).

This intimate phylogenetic relationship between the 
species studied (A. s. rubropilosa and A. bisphaerica) and 
their recent evolutionary history explain the morphological 
differences of the mandibles, at least in terms of the features 
evaluated (Table 1). These species are widely distributed in the 
Neotropical region and differ in nesting site, food preference 
and behavior. The grass-cutting ant A. bisphaerica is only 
found in Brazil (Wilson, 1986), particularly in the states of 
São Paulo, Minas Gerais, Rio de Janeiro and Mato Grosso do 
Sul (Forti & Boaretto, 1997). In contrast, Atta sexdens and its 
subspecies are distributed from Costa Rica to Argentina and 
Paraguay (Wilson, 1986), with A. s. rubropilosa occurring in 
the midwestern and southeastern regions of Brazil (Forti & 
Boaretto, 1997). The nesting site is a result of the biome. In 
this respect, A. bisphaerica nests are shallow and are generally 
found in open areas such as pastures characterized by a high 
incidence of insolation, while A. s. rubropilosa nests are 
relatively deep and are only found in shadow areas, such as 
native and eucalyptus forests (Forti et al., 2011).

Morphological differentiation between castes was observed 
in both species studied (Figures 2-3, 4-5, 6-7, 8-9, and 10-11) 
and was supported by the separation of species and grouping 
of the same castes by PCA analysis, using the mandible 
morphometric data. Gardeners are the smallest workers which 
are always found inside the nest and in larger quantities. The 
typical tasks attributed to this set of workers occur exclusively 
inside the nest, including brood care, final treatment of the 
substrate and hyphal inoculation into the fragments incorporated 
into the fungus garden (Wilson, 1983). Their mandibles are 
small in A. bisphaerica they are more elongated compared 

to the other castes since the tasks of gardeners are the most 
laborious and precise, with their teeth showing no wear 
(Figure 2-3). Generalist workers perform a relatively larger 
number of tasks that range from the elimination of residues 
from the colony and caring for the brood and queen to tasks 
related to cultivation of the symbiotic fungus (Wilson, 1983). 
The mandibles of A. bisphaerica generalists are visibly more 
elongated than those of A. s. rubropilosa, probably to facilitate 
the grass blades manipulation (Figure 4-5). Gardeners and 
generalists are the predominant size classes in the population 
of a leaf-cutting ant colony and are responsible for a large 
number of tasks related to preparation of the plant material 
during the process of incorporation (Peregrine & Cherrett, 
1974, 1976; Littledyke & Cherrett, 1976). The elongated 
mandibular morphology observed only in A. bisphaerica 
gardeners and generalists might be related to the way grasses 
are processed. The leaf blades of grasses are not chopped or 
processed before incorporation as observed for dicotyledon 
leaf fragments which have a pulp-like appearance after 
processing by workers. According to Lopes et al. (2004), the 
latter processing facilitates the implantation of hyphal tufts.

On the other hand, the function of foragers is to 
explore, to excavate, to recruit other ants, and mainly to 
cut new plant material at field (Wilson, 1983), i.e., in both 
species studied these workers are not involved in the more 
laborious activities of plant processing, but rather in the 
exploration and cutting of plant material. As a consequence, 
the mandibles of these workers exhibited more marked tooth 
wear (Figure 6-7) reflecting the repetitive cutting effort. This 
assumption is mandibles of different age workers (Figure 
10-11). Finally, the task attributed to soldiers is the defense 
of the nest (Wilson, 1983), an activity that requires larger 
and more robust mandibles (Figure 8-9) and is not related 

Figs 6-7. ventral side of right mandiblesof Atta bisphaerica (6) and Atta sexdensrubropilosa (7) foragers.



LC Silva et al. – Mandibles of leaf-cutting ants886

Figs 10-11. ventral side of right mandibles of Atta sexdens rubropilosa foragers at different ages, showing natural wear due to 
foraging activity. Adult of undetermined age (10) and adult one day after hatching (11). 

with plant manipulation, explaining why soldier mandibles 
were not different between species. Like foragers, this group 
is not involved in the processing of plant material and no 
morphological differentiation between species is therefore 
observed. Also, A. bisphaerica generalist mandibles did not 
differ from  A. s. rubropilosa forager mandibles suggesting 
that task allocation between species must be different. 
Actually, task allocation is different between species in 
function of which abilities the task require.

The mandibles of ants have many functions, such as 
catching prey, fight, cutting leaves, brood care, and commu-

nication (Paul, 2001). Although an important tool for many 
tasks (Hölldobler & Wilson, 1990), there is little information 
on the morphology of ant mandibles and no quantitative 
data regarding mandibular differences are available. The 
specialization of mandibles does not only depend on their 
morphology, but is also related to the velocity of movement 
and the force generated by them. For example, catching 
prey obviously requires movement characteristics that differ 
from those necessary for cracking seeds (Paul, 2001). Thus, 
the veins patterns of grasses and dicotyledons and the greater 
abundance of lignified cells in grasses should also influence the 

Figs 8-9. ventral side of right mandibles of Atta bisphaerica (8) and Atta sexdens rubropilosa (9) soldiers.



Sociobiology 63(3): 881-888 (September, 2016) 887

specialization of mandibles. Although the results of mandibular 
morphometry accept the hypothesis of morphofunctionality, 
further investigation is needed taking into consideration the 
body size of foragers, robustness and factors that confer 
greater resistance to the mandibles such as zinc content, the 
force employed during cutting, and mandibular biomechanics. 

Acknowledgements

We are grateful to Fundação de Amparo à Pesquisa 
do Estado de São Paulo (FAPESP) for the financial support 
and stipends to the authors [grant numbers 2007/04010-0 
and 2007/07091-0]. R.S. Camargo thanks Coordenação de 
Aperfeiçoamento de Pessoal de Nível Superior (CAPES) 
for the Postdoctoral fellowship. L.C. Forti thanks Conselho 
Nacional de Desenvolvimento Cientifico e Tecnológico for the 
research assistance (301917/2009-4). The authors are indebted 
to Dr. Rafael Barbieri for help with statistical analyses and 
helpful comments.

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http://dx.doi.org/10.1007/s00442-007-0703-5
http://dx.doi.org/10.1017/S0007485300047842
http://dx.doi.org/10.1017/S0007485300047842
http://dx.doi.org/10.1016/S1095-6433(01)00458-5
http://dx.doi.org/10.1016/S1095-6433(01)00458-5

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