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

DOI: 10.13102/sociobiology.v63i1.854Sociobiology 63(1): 693-698 (March, 2016)

Morphological Differences between Reproductive and Non-reproductive Females in the 
Social Wasp Mischocyttarus consimilis Zikán (Hymenoptera: Vespidae)

Introduction

Insect societies are characterized by the division of 
labor between the reproductive and non-reproductive castes, 
which is essential for the success of their societies (Robinson, 
1992). In advanced eusocial species, castes are determined 
pre-imaginally and there is a clear physical divergence between 
queen and worker (Bourke, 1999). However, in less-advanced 
eusocial species, morphological divergences between females are 
less pronounced, and the factors affecting caste differentiation 
are not well known (Smith et al., 2011; Murakami et al., 2009; 
2013; Jandt et al., 2014; Montagna et al., 2015). Nevertheless, 
evidence suggests that the morphological attributes, such 
as body size and ovarian state, can play an important role 
in establishment of the reproductive division of  labor in 
independent-founding (IF) polistine wasps (Tibbetts & Dale, 
2004; Tibbetts, 2006; Cervo et al., 2008).

Abstract
Phenotypic divergence plays an important role in establishment of 
the reproductive division of labor among castes in eusocial insects; 
however, little is known about this subject in social wasps. We tested 
the hypothesis that alpha foundressesin colonial foundations of the 
independent-founding polistine wasp Mischocyttarus consimilis Zikán show 
greater body size and ovarian development than auxiliary and solitary 
foundresses. The hypothesis was also tested that females produced in 
the late post-emergence stage (gynes) are larger than those produced 
at the beginning (workers) of the colony cycle of this species. Our results 
showed that the body size of alpha foundresses was significantly greater 
than that of auxiliary foundresses, but did not differ from that of solitary 
foundresses. In addition, the alpha had greater ovarian development 
than the auxiliary and solitary. We also demonstrated that gynes were 
significantly larger than workers. These results therefore suggest that 
the phenotype of females emerging in colonies of M. consimilis can vary 
with the progress of the colony cycle, and that body size and ovarian 
state are closely linked to the function performed by the foundress.  

Sociobiology
An international journal on social insects

TS Montagna1, WF Antonialli-Junior1,2

Article History

Edited by
Kleber Del-Claro, UFU, Brazil
Received                           22 June 2015
Initial acceptance            28 January 2016
Final acceptance             16 March 2016
Publication date             29 April 2016

Keywords 
Caste determination, Division of labor, 
Dominance hierarchy, Neotropical wasp, 
Polistinae, Reproductive status.

Corresponding author
Thiago Santos Montagna 
Prog. de Pós-graduação em Entomologia 
e Conservação da Biodiversidade
Universidade Federal da Grande Dourados
CEP: 79804-970, Dourados-MS, Brazil
E-Mail: thiagomontag@yahoo.com.br

IF polistine wasps are an important model for study of the 
division of labor in less-advanced eusocial species. Colonies of IF 
polistine wasps can be initiated individually (haplometrosis), 
when a reproductive female unaccompanied by other females 
starts the colony; or by association (pleometrosis), when 
two or more reproductive females start the colony (West-
Eberhard, 1969; Reeve, 1991). In haplometrosis, the foundress 
performs all the intra- and extra-nidal tasks until the workers 
emerge (Jeanne, 1972; Gadagkar, 1991). In pleometrosis, 
the colony tasks are shared among the foundresses, although 
the reproductive function is performed by one female, who 
dominates the others (Röseler, 1991; Keeping, 1992; Prezoto 
et al., 2004). Hence, females with a greater capacity for 
dominance are more likely to perform the colony reproductive 
function (Cervo et al., 2008; Zanette & Field, 2009). Since 
physical attributes are linked to the capacity for dominance, 
it has been suggested that body size could influence the 

1 - Universidade Federal da Grande Dourados, Dourados-MS, Brazil
2 - Universidade Estadual de Mato Grosso do Sul, Dourados-MS, Brazil

RESEARCH ARTICLE - WASPS



T. S. Montagna; W. F. Antonialli-Junior – Morphological Caste in the Social Wasp Mischocyttarus consimilis694

reproductive strategies in pleometrotic foundations (Fukuda et 
al., 2003; Tannure-Nascimento et al., 2008). 

In tropical regions, colonies of  IF polistine wasps are 
started at any time of the year, so different colonial stages can 
occur in the same population in the same period. This nesting cycle 
pattern is termed asynchronous (Poltronieri & Rodrigues, 1976; 
O’Donnell & Joyce, 2001; Giannotti, 1998; Torres et al., 2011). 
The workers are produced at the beginning of the post-emergence 
stage, and they are mainly dedicated to defending the colony and 
foraging for food and nest material (Jeanne, 1972; Torres et al., 
2011). In contrast, gynes are produced in the late post-emergence 
stage and generally invest in their own reproduction, contributing 
little to the maternal colony (Jeanne, 1972; Torres et al., 2011). 
It is therefore possible that the conditions for the development 
of immature vary with the progress of the colony cycle, due 
to fluctuations in the work force, which may be reflected in 
differences in the body size of emerging females (O’Donnell, 
1998; Schmidt et al., 2012).

Mischocyttarus consimilis Zikán is an IF polistine 
wasp belonging to the subgenus Phi, one of the largest 
groups in the tribe Mischocyttarini, with the most extensive 
geographic distribution. In M. consimilis, the caste system 
is based on the division of tasks between the reproductive 
and non-reproductive females, in which the behaviors of 
oviposition, physical dominance, and nest presence characterize 
the reproductive caste, while behaviors such as alarm and 
resource foraging characterize the non-reproductive caste 
(Torres et al., 2012). In order to investigate morphological 
differences among castes in M. consimilis, we measured 
the body size and ovarian development of foundresses from 
haplometrosis and pleometrosis foundations, as well as the 
body size of females emerging in different phases of the colony 
cycle. 

Materials and Methods

Field procedures and data collection

Colonies of M. consimilis were collected from the eaves 
of vacant houses situated in rural areas in the municipality of 
Dourados (22º13’ S, 54º48’ W) in Mato Grosso do Sul, from 
March 2011 through February 2012. To prevent the loss of 
individuals, colonies were collected in the early evening when 
foraging activity had ceased. All the individuals collected were 
killed by freezing (-20°C), prior to any manipulation procedure. 

A total of 59 foundresses from 29 foundations were evaluated 
for body size and ovarian development. The foundresses were 
classified as: alpha (female performing the reproductive function 
in a pleometrotic foundation); auxiliary (each female subordinate 
to the alpha); and solitary (female of a haplometrotic foundation). 
Alpha foundresses were identified by direct observation of the 
oviposition behavior. We encouraged oviposition by the alpha by 
removing a larva with the aid of tweezers, leaving an empty cell in 
the comb. Our study did not require an ethics statement; however, 
we endeavored to minimize the stress caused by manipulation.

Additionally, we evaluated the body sizes of a total of 
90 newly-emerged females (<24 h old), from 47 colonies. The 
newly-emerged females were classified as: worker (female 
created only by the foundresses); intermediate (female created 
by foundresses and workers); and gyne (female emerging in 
the colony reproductive phase). The reproductive phase in 
colonies of M. consimilis occurs in the final post-emergence, 
when males appear among the offspring (Torres et al., 2011).

Measurements of body size and ovarian development

The measurements of body size, obtained according to 
Gunnels (2007), were: head height; maximum distance between 
the inner margins of the eyes; minimum distance between the 
inner margins of the eyes; mesonotum length; mesonotum 
width; thorax length; mesopleura height; tibia length; and 
forewing length. For analysis of ovarian development, the 
gasters were fixed by immersion in Dietrich’s solution, stored 
in 70% ethanol, and dissected in a petri dish containing 
physiological saline solution. The ovarian development index 
was obtained for each female, based on the mean length of the 
six largest oocytes (Sledge et al., 2004). All measurements of 
body size and ovarian development were obtained with the aid 
of a Stemi 2000C stereomicroscope (Carl Zeiss Microscopy, 
Oberkochen, Germany) fitted with a micrometer eyepiece.

Statistical analyses

All statistical analyses were carried out using R Statistical 
Environment software (R Development Core Team, 2013), with 
significance level of 0.05. Morphometric data were subjected 
to principal component analysis (PCA), and the first PCA 
component was used as the body size index (Gunnels, 2007). 
In all cases, the data for body size were normally distributed 
(Shapiro-Wilk test, P>0.05) and showed homogeneity of 
variance (Bartlett’s test, P>0.05), so the differences among 
the categories of females were evaluated by parametric 
tests, including analysis of variance (one-way ANOVA) and 
Tukey’s test (HSD) for multiple comparisons. The ovarian 
development data were not normally distributed (Shapiro-
Wilk test, P<0.05), so differences among groups were assessed 
by nonparametric tests, including the Kruskal-Wallis and 
Steel-Dwass test for multiple comparisons. 

Results 

The PCA with the morphometric data for the foundresses 
recovered most of the variation among the groups, with the first 
principal component explaining 82.9% of the total variation 
and being positively associated with all the measured 
variables. The second principal component explained an 
additional 6.7% of the variation. Considering the first principal 
component as the explanatory variable in the analysis of 
variance, it was demonstrated that the foundresses differed 
in body size (one-way ANOVA, F2.56=9.26, P<0.001, Fig 1). 



Sociobiology 63(1): 693-698 (March, 2016) 695

Fig 1. Variation in body size index (mean ± SD) for foundresses 
of Mischocyttarus consimilis. Different letters indicate statistical 
significance (P<0.05).

The analysis comparing the groups demonstrated that alpha 
foundresses were significantly larger than auxiliary (Tukey’s 
HSD, P<0.01, Fig 1), but did not differ from solitary (P=0.78, 
Fig 1). In addition, solitary foundresses were significantly larger 
than auxiliary (P<0.01, Fig 1).

 The three categories of foundresses also differed 
significantly in the degree of ovarian development (Kruskal-
Wallis, H=38.20, df=2, P<0.001, Fig 2). Comparison of 

Fig 2. Variation in ovarian development index for foundresses of 
Mischocyttarus consimilis. Box-plot represents the median, 25% - 
75% percentiles and minimum/maximum range. Different letters 
indicate statistical significance (P<0.05).

Fig 3. Correlation analyses between the body size index and ovarian 
development index for foundresses of Mischocyttarus consimilis 
(r=0.41; P<0.01).

Fig 4. Variation in body size index (mean ± SD) for newly-emerged 
females in colonies of Mischocyttarus consimilis. Different letters 
indicate statistical significance (P<0.05).

the groups showed that alpha foundresses had greater ovarian 
development than auxiliary (Stell-Dwass, P<0.001, Fig 2) and 
solitary (P=0.01, Fig 2), while solitary foundresses had greater 
ovarian development than auxiliary (P<0.001, Fig 2). There 
was a significant positive correlation between body size and 
ovarian development when the foundresses were evaluated together 
(Pearson correlation coefficient; r=0.41, P<0.01, n=59, Fig 3).

The PCA performed with the morphometric data for 
the newly-emerged females recovered most of the variation 
among the groups. The first principal component was positively 
associated with all the variables and explained 75.8% of the 
total data variation. The second principal component explained 
an additional 5.6% of the variation. Considering the first 
principal component as the explanatory variable in the analysis 
of variance, significant differences in body size were found 
among the categories of newly-emerged females (one-way 



T. S. Montagna; W. F. Antonialli-Junior – Morphological Caste in the Social Wasp Mischocyttarus consimilis696

ANOVA, F2.87=6.86, P<0.01, Fig 4). Comparison of the groups 
showed that the gynes were significantly larger than the workers 
(Tukey’s HSD, P<0.01, Fig 4) and the intermediates (P=0.02, 
Fig 4). However, the body size of the workers did not differ 
significantly from that of the intermediates (P=0.79, Fig 4). 

Discussion

The results showed that foundresses of M. consimilis 
performing the reproductive function in pleometrotic foundations 
were significantly larger than their auxiliary. Several studies 
have shown that in pleometrotic foundations of IF polistine 
wasps, the colony reproductive function is aggressively disputed 
among potential females, and larger females have increased 
chances of subduing smaller competitors (Cant & Field, 2001; 
Tannure-Nascimento et al., 2008). Under these conditions, the 
reproductive organization is highly dependent on a dominance 
hierarchy, with larger females occupying higher positions in this 
hierarchy (Turillazzi & Pardi, 1977; Cervo et al., 2008). Larger 
females are therefore more likely to assume colony reproductive 
functions, suggesting that attributes established during immature 
development are relevant for the adult behavioral phenotype 
(Zanette & Field, 2009). Recent studies have shown that pre-
imaginal caste determination can occur in IF polistine wasps, 
and that subtle morphological differences can be decisive in 
establishing the reproductive division of labor among foundresses 
(Fukuda et al., 2003; Judd et al., 2015; Montagna et al., 2015). These 
results provide evidence that body size affects the reproductive 
organization in pleometrotic foundations of M. consimilis. 

It was also shown that the solitary foundresses were 
similar in size to the alpha. In a study with M. consimilis, Torres 
et al. (2011) demonstrated that haplometrotic foundation is the 
most common strategy adopted by the foundress. Our results 
suggest that large females with high reproductive potential invest 
in direct reproduction using the strategies of either fighting for 
the alpha position in pleometrotic foundations, or founding 
colonies individually. In addition, individual foundation could 
be an alternative strategy for large females who refrainfrom 
disputing the reproductive function in pleometrotic foundations. 
Nevertheless, these hypotheses need to be evaluated, considering 
the origins of the females that found colonies alone.

Alpha foundresses had a significantly greater degree of 
ovarian development, compared to the auxiliary. Furthermore, 
a significant positive correlation was found between body 
size and ovarian development, when the foundresses were 
evaluated together. These data suggest that the degree of 
ovarian development is closely relatedto both body size and 
the function performed by the foundress. Other studies have 
shown that foundresses performing reproductive functions (i.e., 
alpha and solitary), must invest more in ovarian development 
(Turillazzi & Pardi, 1977; Dropkin & Gamboa, 1981; Fukuda 
et al., 2003; Tannure-Nascimento et al., 2008). Moreover, 
auxiliary foundresses performing activities with high energy 
costs, such as foraging for resources, are likely to undergo 

ovarian regression (Keeping, 2000; Cervo et al., 2008).
It was also found that gynes were significantly larger than 

workers and intermediates, in agreement with other studies that 
evaluated differences in the body size of offspring females in 
IF polistine wasps (West-Eberhard, 1969; Haggard & Gamboa, 
1980; Miyano, 1983). For example, females of Polistes fuscatus 
(Fabricius) produced in the late post-emergence stage, which 
were possibly gynes, were larger than workers produced at the 
beginning of this stage (West-Eberhard, 1969). Since the adult 
body size in holometabolous insects is fixed before emergence, 
it is possible that in IF polistine wasps it could be influenced 
by pre-imaginal trophic factors (Miyano, 1998; Karsai & Hunt, 
2002). Differential feeding is known to be the main factors 
influencing caste determination in the honey bee, Apis mellifera, 
where larvae fed a highly nutritious diet (based on royal jelly) 
develop into queens (Winston, 1987). The effect of differential 
feeding in caste determination has also been demonstrated 
in the bumblebee, Bombus terrestris, where larvae that have 
access to greater amounts of food emerge as queens (Cnaani et 
al., 2002). In the case of IF polistine wasps, Judd et al. (2010) 
showed that the development of larvae of Polistes metricus 
into either workers or gynes was significantly influenced by 
the levels of nutrients in the hemolymph, including lipids, 
carbohydrates, and proteins, and that the differences were 
associated with possible variations in nutritional quality. In 
studies of the same species, Judd et al. (2015) showed that an 
increase in the quality of larval nutrition led to the development 
of larger females. In M. consimilis, workers and gynes emerge 
in different phases of the colony cycle, so the conditions for 
development of the immature are different (Torres et al., 2011). 
These findings suggest a link between body size and colonial 
stage, which needs to be further investigated.

However, in IF polistine wasps, other factors are 
associated with the caste ontogeny, which vary as the colony 
grows. For example, larvae of P. fuscatus developing in 
the pre-emergence stage are subjected to higher levels of 
vibration, compared to larvae that develop in the later post-
emergence stage (Suryanarayananet al., 2011). The vibration 
is produced by adults using their antennas to touch the walls 
of cells occupied by larvae. Adult females subjected to high 
levels of vibration in the larval stage show a worker-like 
phenotype, while those subjected to low levels of vibration 
show a gyne-like phenotype (Suryanarayanan & Jeanne, 2008; 
Suryanarayanan et al., 2011). This form of manipulation of 
the caste ontogeny is essential for the success of the colony, 
because it allows adults to control the caste production 
throughout the colony cycle. 

The results presented in this study suggest that individual 
attributes such as body size and ovarian development are linked 
to the function performed by the foundresses in M. consimilis. 
In addition, it is clear that gynes are larger than workers, 
suggesting that factors associated with the pre-imaginal caste 
determination vary with the development of the colony. 
Knowledge of the caste ontogeny in IF polistine wasps 



Sociobiology 63(1): 693-698 (March, 2016) 697

sheds light on individual attributes that increase the chances 
for direct reproduction, in the context of disputes, and also 
helps to understand the conditions under which the castes are 
produced in less-advanced eusocial wasps.

Acknowledgements

The authors acknowledge the Coordenação de 
Aperfeiçoamento de Pessoal de Nível Superior (CAPES) for 
a scholarship granted to the first author. The Fundação de 
Apoio ao Desenvolvimento do Ensino, Ciência e Tecnologia 
do Estado de Mato Grosso do Sul (FUNDECT) provided 
financial support (Proc. No. 23/200.767/2012). WFAJ thanks 
the Conselho Nacional de Desenvolvimento Científico e 
Tecnológico (CNPq) for research productivity scholarship.

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