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

DOI: 10.13102/sociobiology.v64i3.1647Sociobiology 64(3): 347-351 (September, 2017)

Description of the Intramandibular Gland II in Polybia emaciata Lucas, 1879 (Hymenoptera: 
Vespidae)

Introduction

Exocrine glands have a major role in insect social 
life, because these glands regulate communication, social 
structuring, and nest construction of colonies, among other 
behaviors (Billen & Morgan, 1998). The characterization of 
exocrine glands has been an important research area dated 
back to the 17th century (Heselhaus, 1922; Billen & Wilson, 
2008). However, the discovery of new glands is ongoing with 
new reports published on a regular basis, particularly for 
social wasps for which studies are less frequent (Samacá et 
al., 2013; da Silva et al., 2015; Penagos-Arévalo et al., 2015).

Polybia emaciata Lucas, 1879 is a medium-sized 
wasp (head width 2.18 mm, wing length 10 mm), with a 
color pattern that is primarily dark yellow with black or 
brown markings on several parts of the body. The wasp is a 

Abstract 
The intramandibular gland II in Polybia emaciata Lucas is 
described. This species is among the few that uses mud for 
nest construction, and their nests persist for a long time 
following abandonment. The intramandibular gland II has been 
found in single representatives of the genera Mischocyttarus, 
Apoica and Leipomeles, and this record is the second for the 
genus Polybia. Despite expectations derived from the nest 
characteristics of the species, gland dimensions such as cell 
diameter were well within the range observed for other 
species, with the cell number even comparatively small. 
Gland function remains to be investigated.

Sociobiology
An international journal on social insects

C Cely1, AP Arévalo2, J Billen3, CE Sarmiento2

Article History

Edited by
Marcel G. Hermes, UFLA, Brazil
Received                        06 April 2017
Initial acceptance      25 July 2017
Final acceptance      26 July 2017
Publication date          17 October 2017

Keywords 
Exocrine glands, Polistinae, mandibles.

Corresponding author
Carlos E. Sarmiento
Laboratorio de Sistemática y Biología 
Comparada de Insectos
Instituto de Ciencias Naturales
Universidad Nacional de Colombia
A. A. 7495 - Bogotá, Colombia. 
E-Mail: cesarmientom@unal.edu.co

swarm-founding species found extensively from Mexico to 
Brazil, from sea level up to 1500 m.a.s.l., and is very common 
in farmlands. The colonies range from 100 to 500 individuals 
and include several queens (Richards, 1978; Strassman et al., 
1992). A notorious characteristic of this species, shared only 
with four other congeneric species of the Polistinae, is the use 
of mud for the nest; these nests persist for a long time even 
after being abandoned (Rau, 1933; Skutch, 1971; O´Donnell & 
Jeanne, 2007). This persistence may be attributed to the mud-
saliva mixture used in nest construction (Schremmer, 1984). 
Given the results of Schremmer (1984) on nest composition and 
characteristics, which require extensive chewing and processing 
behaviors from the wasps, we agreed with the proposed role of 
the head glands in determining the characteristics of the nest 
materials for this species. In addition to the salivary glands, 
palpal and mandibular glands also occur and may have a function 

1 - Department of Ecology and Evolutionary Biology, University of Michigan, Ann Arbor, USA
2 - Instituto de Ciencias Naturales, Universidad Nacional de Colombia, Bogotá, Colombia
3 - Zoological Institute, Katholieke Universiteit Leuven, Leuven, Belgium

RESEARCH ARTICLE - WASPS

mailto:cesarmientom@unal.edu.co


C Cely, AP Arévalo, J Billen, CE Sarmiento – Intramandibular Gland II in Polybia emaciata348

associated with nest construction material characteristics; 
however, these structures have not been investigated. 

Inside the mandibles of Neotropical social wasps, 
three glands have been identified, the intramandibular gland 
I, the intramandibular gland II, and the ectal mandibular gland 
(Penagos-Arévalo et al., 2015). The intramandibular gland I is 
a class 1 gland, whereas the other two are class 3 glands. Class 
1 glands are a lining of epithelial cells on the internal surface of 
the body wall, and class 3 glands are bicellular units consisting 
of a large secretory cell and a duct cell (Noirot & Quennedey, 
1974). Previous authors have identified the intramandibular 
gland II in other hymenopterans (Nedel, 1960; Costa Leonardo, 
1978; Schoeters & Billen 1994). Cely-Ortiz observed this 
gland in Polybia emaciata in his unpublished undergraduate 
work (2011). However, in vespids, Penagos-Arévalo et al., 
(2015) provide the formal record of this gland. These authors 
recorded the gland in four of 33 species studied, and although 
P. emaciata was included in their extensive study, they did not 
report the intramandibular gland II in this species. Here, we 
describe the intramandibular gland II for Polybia emaciata.

Materials and Methods

For our results to be more comparable with previous 
publications (Penagos-Arévalo et al., 2015) and because 
foragers are the caste involved in nest construction, foragers of 
Polybia emaciata were net-collected from Silvania, a farmland 
municipality in Cundinamarca, Colombia (4°24´19.7”N, 74° 
22´30.9”W, 1475 m.a.s.l.). Wasps were delicately handled 
with soft forceps. Head section preparation followed standard 
protocols as described by Billen (1998), Samacá et al. (2013) 
and Penagos-Arévalo et al. (2015). Forager heads were 
sectioned after the posterior part of the vertex was removed 
and were immediately submerged in 2% glutaraldehyde in 
Na-cacodylate buffer for approximately 12 h at 4°C. The 
heads were then transferred to fresh buffer. Tissues were 
then dehydrated in a graded acetone series and embedded in 
Araldite. Serial sections of 2 µm in thickness were obtained 
with a Leica EM-UC6 ultramicrotome (Leica microsystems, 
Vienna, Austria), followed by staining with methylene blue 
and thionin. A Zeiss Jenaval optical microscope (Carl Zeiss, 
Jena, Germany) was used for morphological analysis and a 
Canon D90 digital camera for photography (Canon, Japan). 

We described cell shape, cell distribution, and duct 
presence of the gland cells following Herzner et al. (2007) and 
Samacá et al. (2013). Gland description included the following: 
location, cell type according to the classification provided by 
Noirot and Quennedey (1974), maximum dorsoventral or 
anteroposterior extension, and cell diameter (Britto et al., 
2004; Billen, 2009; Penagos-Arévalo et al., 2015).

Results 

As described by Penagos-Arévalo et al. (2015) for other 
species, the intramandibular gland II is a class 3 exocrine organ 

located inside the mandibles at the mesal and ectal sides close 
to the denticles. In P. emaciata, secretory cell clusters were 
formed by approximately 28 round-shaped well-defined cells, 
with an average diameter of 22.3 µm. The nuclear membrane 
was not clearly defined but between 4 and 5 nucleoli were 
observed per cell. Ducts with an internal diameter of 0.5μm 
directed to the mesal part of the mandible exoskeleton were 
observed, although we did not find skeletal pores (Fig 1). 

Discussion

Contrary to our expectations, given the nature of 
the material used for nest construction and the potential 
role of head glands in processing this material, the gland 
characteristics observed in P. emaciata fit well within those 
observed for the other four species in which the gland has 
been observed: Mischocyttarus angulatus Richards, 1978; 
Apoica gelida Van der Vecht, 1973; Leipomeles spilogastra 
(Cameron, 1912); and Polybia liliacea (Fabricius, 1804).

The gland cell diameter of P. emaciata, 22.3 µm, was 
within the range of 10-70 µm for the other four species, as 
described by Penagos-Arévalo et al. (2015). The diameter 
was most similar to that observed for the distant species 
Mischocyttarus angulatus (25 µm) and most different from 
that of the more closely related species Polybia liliacea (70 
µm). The number of glandular cells was much lower than the 
range of 50-150 cells observed in the other species, including 
in the congeneric P. liliacea (60) (Penagos-Arévalo et al., 
2015). We did not observe any pattern for the number of 
cells and the species Mischocyttarus angulatus and Apoica 
gelida, show the extreme variations in cell number (50 and 
150 cells, respectively). The low number of cells might be a 
consequence of the age stage at which wasps were captured. 
Task partitioning is well known in vespids (Jeanne, 1991), 
and several studies demonstrate a relationship between gland 
size and task frequency (Downing, 1991; García & Noll, 
2013); however, studies have also debated this correlation 
(Britto et al., 2004). We collected foragers of P. emaciata, 
and therefore, the gland was possibly not active in individuals 
at this stage. A planned sampling strategy is required to 
determine the relation in P. emaciata. 

The hypopharyngeal and clypeal glands of P. emaciata 
are not particularly different in gland cell diameter and cell 
number from other polistines of similar size or from congeneric 
species (Penagos-Arévalo et al., 2015). For example, the 
cell number for the hypopharyngeal gland of P. emaciata 
is within the range observed in other species of similar 
head-widths, such as Brachygastra augusti (de Saussure, 
1854), Angiopolybia pallens (Lepeletier, 1836) and Polybia 
occidentalis (Olivier, 1791). For this gland in P. emaciata, the 
number of cells was also within the range of the number for 
seven other Polybia species.

The taxonomic distribution of this gland is somewhat 
challenging, because the gland has been found in only four 
phylogenetically dispersed genera, including Mischocyttarus, 



Sociobiology 64(3): 347-351 (September, 2017) 349

Fig 1 A-B. Intramandibular gland II in forager of Polybia emaciata Lucas. A. General cross-sectional view of the mandibles; the inset 
indicates the location of gland cells at the base of the mandible. B. Close-up view of framed part in A, showing gland cells (g) and ducts (d). 
Scale bars: A=50 µm, B=20 µm. 



C Cely, AP Arévalo, J Billen, CE Sarmiento – Intramandibular Gland II in Polybia emaciata350

Apoica, Leipomeles and Polybia itself; additionally, congeneric 
species of Mischocyttarus and Apoica that have been carefully 
studied previously do not present this organ (Penagos-Arévalo 
et al., 2015). Within the genus Polybia, we observe a similar 
situation, because the gland was reported for Polybia liliacea 
(F. 1804) by Penagos-Arévalo et al. (2015), but not for six 
other species studied.

In all species of Neotropical Polistinae studied, glands 
are found such as the hypopharyngeal gland, the periocular 
gland, and the intramandibular gland I (Penagos-Arévalo et 
al., 2015); however, either a reversal of a gland or a scattered 
occurrence in the Polistinae has been previously reported. For 
example, following a more precise definition of Richards´ 
gland, this gland apparently evolved in the Epiponini but 
two reversals occurred (Samacá et al., 2013). In the study by 
Penagos-Arévalo et al. (2015) conducted with 33 species of 
Neotropical Polistinae, the periocular gland, the posterobasal 
gland, the ocellar gland I, the ocellar gland II, and the 
subantennal gland were reported in only a few taxa or absent 
in some species. Clarifying the factors responsible for this 
lability in gland occurrence should be an interesting area of 
research that requires detailed information. 

Schremmer (1984) conducted an interesting study on 
the nests of P. emaciata, and the results strongly indicate that 
organic compounds provided by the workers are the agents 
responsible for the physical characteristics of the structure. 
He hypothesized that the salivary glands could provide these 
molecules. Although we did not directly study the salivary 
gland, our results and the comparative data provided by 
Penagos-Arévalo et al. (2015) for all the other head glands 
provide indirect support to that hypothesis, because none of 
the morphometric characteristics observed in these organs are 
significantly different from other species. A specific study on 
this organ will help to confirm this hypothesis.

Acknowledgements

We are grateful to An Vandoren, K.U. Leuven, for her 
help in section preparation. We thank the referees for their 
helpful comments. 

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