DOI: 10.13102/sociobiology.v65i4.3451Sociobiology 65(4): 780-783 (October, 2018) Special Issue

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

The Life Histories of the "Uruçu Amarela" Males (Melipona flavolineata, Apidae, Meliponini)

Over the last 50 years, the life histories of male 
stingless bees (Apidae: Meliponini) have been documented 
in great detail (Nogueira-Neto, 1954; Kerr et al., 1962; Van 
Veen et al., 1997; Koffler et al., 2016; Schorkopf, 2016), 
showing that male behaviors and reproductive strategies are 
diverse and very different of Apini (Engels & Imperatriz-
Fonseca, 1990; Paxton, 2005). Males leave the nests after they 
reach sexual maturity (Van Veen et al., 1997), before forming 
reproductive aggregations in specific sites (Paxton, 2005). 
During the copula, the male attaches his genital capsule inside 
the female, resulting in a sterile individual (Kerr et al., 1962; 
Engels & Imperatriz-Fonseca, 1990).

This short note combines several field observations and 
experiments that, together, help to understand the life histories 
of Melipona flavolineata Friese males. All observations took 
place at Embrapa Amazônia Oriental, Belém, Pará State, 
Brazil, between 2014 and 2017.

Abstract 
Here we describe the life histories of adult males of the the Amazonian 
stingless bee Melipona flavolineata Friese, commonly known as “uruçu 
amarela”. Males reach sexual maturity inside nests, presenting seminal 
vesicles full of sperm cells and becoming able to fly at a mean age of 10 
and 15 days, respectively. They aggregate twice in their lives, once before 
leaving the nest, and another at external congregation sites, by using their 
capacity to reach congregation sites dependent on morphological attributes, 
such as large eyes and elongated thorax. Furthermore, we describe three 
atypical phenomena for Meliponini males: M. flavolineata males have 
dimorphic color pattern; they lose their genital capsules, even when they 
fail to copulate; and penisless (sterile) males can stay alive for up to two 
days. The life history strategies of Meliponini males have only just started 
to be told and provide many interesting questions for future studies.

Sociobiology
An international journal on social insects

JC Veiga1, KL Leão1, BWT Coelho2, ACM de Queiroz3, C Menezes3, FAL Contrera1

Article History

Edited by
Denise Alves, ESALQ-USP, Brazil
Received        10 May 2018
Initial acceptance       20 June 2018
Final acceptance       16 August 2018
Publication date            11 October 2018

Keywords 
Congregation sites, stingless bees, sterile 
males, dimorphism. 

Corresponding author
Jamille Costa Veiga
Laboratório de Biologia de Abelhas 
Instituto de Ciências Biológicas
Universidade Federal do Pará
Rua Augusto Corrêa nº 01
Campus Básico Guamá 
CEP 66075-110, Belém, Pará, Brasil.
E-Mail: jal.cveiga@gmail.com

Inside the nests: intranidal behaviors, sexual maturity and 
the point of no return

To study sexual maturation in M. flavolineata males, 
we used the total number of sperm cells in seminal vesicles as 
a proxy of a male’s sexual maturity, and evaluated its variation 
as a function of age (time since eclosure). Males were held 
in minicolonies under laboratory conditions and sampled at 
different ages – from 0 to 25 days after emergence (ESM1, 
Table 1). We also tested the flight ability of each male through 
light stimulus (details in ESM1). The sperm migration from 
the testicles to the seminal vesicles started between zero 
and five days, when we could observe a greater number of 
sperm bundles in the seminal vesicles, and a few free sperm 
cells. From 10 days, we could not find the bundles anymore, 
observing only the presence of individual sperm cells until 
25 days (Fig 1a). We found that males reach sexual maturity 

1 - Laboratório de Biologia e Ecologia de Abelhas, Universidade Federal do Pará, Belém, Pará, Brazil
2 - Coleção Institucional do Museu Paraense Emílio Goeldi, Belém, Pará, Brazil
3 - Laboratório de Botânica - Embrapa Amazônia Oriental, Belém, Pará, Brazil

ShORT NOTE



Sociobiology 65(4): 780-783 (October, 2018) Special Issue 781

between 10 and 15 days after emergence, following which, 
total sperm cells was similar to subsequent age categories 
(KW-H (5;55) = 36.425; p < 0.001), and the increment in this 
number was followed by simultaneous improvement in flight 
ability (Fig 1a). 

To investigate males’ intranidal behaviors and the age 
that males would leave the nests we marked 160 individuals 
with numbered and colored tags (40 worker bees from four 
different colonies). We observed three main activities performed 
by males inside the nests: walking-standing, self-grooming 
and nectar dehydration, as previously observed in other 
Melipona species (Van Veen et al., 1997). We also observed 
males forming groups of at least three individuals with a 
mean age of 14 days. Groups were observed near inner nest 
entrances, with a persistence of no longer than 48 h. After this, 
these individuals were never observed again inside the nests. 
Outside of nests, we identified eight marked males gathering 
in aggregations, with a mean age of 20.5 days (± 1.41 S.D.). 

Outside the nests: reaching the congregation sites

Melipona flavolineata reproductive aggregations can be 
formed at the entrance of conspecific nests, and sometimes are 
composed of hundreds of males (about 150 to 300 individuals; 
Fig 2a-b). Although male aggregations are only temporary, we 
observed that these aggregations remain present for several 
days or weeks between the months of July and December over 
three consecutive years (2013, 2014 and 2015). M. flavolineata 
seems to differ from other species of Melipona, whose males 
are known to aggregate distant from nests and in some cases 

in groups of few individuals (Sommeijer & de Bruijn, 1995; 
Santos et al., 2014), but whether such pattern sustains out of a 
meliponary context, it still need to be confirmed. 

Aggregations are known to be a source of pre-
copulatory selection in eusocial bees, selecting more 
competitive males in Apis mellifera L. and Scaptotrigona 
depillis (Moure) (Jaffé et al., 2010; Koffler et al., 2016). 
Based on this, we compared the body size of M. flavolineata 
males before and after the formation of congregation sites 
(corresponding to pre- and post-selection scenarios), as follows: 
(i) we first sampled males emerging as adults inside different 
nests (brood combs: pre-selection group; n = 90 obtained from 
ten nests); and (ii) after about 20 days of this first step, males 
were sampled from congregation sites (congregation: post-
selection group; n = 90 collected at random in five different 
congregation sites); finally (iii) all bees were measured 
in order to compare head and thorax attributes (details in 
ESM1). We highlight that male origin was not controlled for 
the congregation group, which may have affected our results. 
However, we believe our sampling effort represented the 
variation in population once we obtained males from different 
congregation sites.

We found differences in body size among males 
sampled before and after congregation formations: males 
sampled from brood combs showed higher median values 
and variation   of interocular distance and intertegular distance, 
and lower median values of thorax length in relation to 
males sampled from congregation sites (Fig 1b-e), despite not 
differing in other body size attributes such as head width, 
head length and tibia length (ESM1, Table 2). Our results 

Fig 1. Development of sexual maturity of the "Uruçu Amarela" males, Melipona flavolineata. Here we show the phases of males’ life history 
and the variation of estimated number of total sperm cells in seminal vesicles as a function of males’ age in days; rank comparisons are 
indicated with letters (a); we also show the comparison of four body size attributes of Melipona flavolineata males sampled from brood combs 
(n = 90) and congregation sites (n = 90), showing similarities in head width (b), and differences in interocular distance (c), thorax length (d) 
and intertegular distance (e).



JC Veiga, KL Leão, BWT Coelho, ACM de Queiroz, C Menezes, FAL Contrera – The Life of "Uruçu Amarela" Males782

show that although all males had similar head sizes, the 
males sampled from congregation sites had shorter interocular 
distances, meaning they have larger eyes; they also had shorter 
intertegular distances and more elongate thoraxes than males 
sampled from brood combs, suggesting their body shape 
may be more aerodynamic. We also suggest that extremes 
were negatively selected as variation in body size was much 
lower in congregations. Even though the brood comb males 
were not compared to males from the same colonies that 
successfully reached an aggregation, which would be ideal, 
our results corroborate with previous findings that Meliponini 
males undergo pre-copulatory selection (Koffler et al., 2016).

Atypical phenomena: color dimorphism and penisless males

Males of M. flavolineata exhibit dimorphic color-
patterning, including both light and dark morphs (Fig 2). 
Light morphs can be diagnosed by their yellow metasoma, 
yellow-ferruginous legs with blackish marks, and vertex and 
mesosoma with corn yellow setae. The decumbent setae on third 
to fifth metasomal tergum are bright yellow. All these patterns 
being similar to those of worker bees. The dark morph differs 
from light morphs in having black legs and metasoma, vertex 
and mesosoma with brownish-yellow setae. The decumbent 
setae on third to fifth metasomal tergum are brownish-yellow. 
We observed that the two morphs can emerge in the same 
colony. From a sample of twenty-one brood combs with pre-
emergent pupae from twelve colonies, we observed of the 
1,364 males emerging as adults, 78.15% were light morph 
and 21.85% were dark morph. The proportion of light and 
dark phenotypes produced in each brood comb varied and did 
not follow a pattern (ESM1, Table 3). According to Pereboom 
and Biesmeijer (2003) abdominal coloration in stingless bees 
might be involved in the regulation of body temperature in 
extreme thermal conditions. This suggests that, it is possible 

Fig 2. Melipona flavolineata reproductive aggregation placed 
at a congregation site near conspecific nests (a). Detail of the 
aggregation showing males with different body color-patterns (b). 
Melipona flavolineata dimorphic males, the light morph (left) and 
the dark morph (right).

that variation in color-patterns of males of M. flavolineata has 
also a role in thermoregulation.To our knowledge, this is the 
first report of color dimorphism in male stingless bees. 

Another atypical behavior was observed when we used 
males’ mating attempts as a proxy of sexual attractiveness of 
virgin queens in M. flavolineata under laboratory conditions 
(Veiga et al., 2017). We observed two interesting behaviors: 
(i) M. flavolineata males permanently lose their genital capsules 

Fig 3. Atypical phenomena observed in Melipona flavolineata males: (a) loss of male genital capsule without a successful copulation, (b) 
male genital capsules lost after mating failures, (c) male with complete reproductive apparatus, including the genital capsule (white arrow) 
and genital sterna (black arrows), and (d) a penisless male found at congregation sites, presenting only genital sterna (black arrows) and with 
absent genital capsule.



Sociobiology 65(4): 780-783 (October, 2018) Special Issue 783

when they copulate, also when they fail to do so (here failing 
in copulation means that males which attempted to copulate 
everted their genital capsule outside female’s body); and 
(ii) these penisless (sterile) males can stay alive, reengage 
in congregation sites and behave similarly to virgin males. 
When males failed in copulation, they simply everted their 
genital capsules, losing it in the air (Fig 3a-b). We repeatedly 
observed such behavior under laboratory conditions, where 
13.23% of 650 (in the first experiment), and 7.83% of 600 (in 
the second experiment) males permanently lost their genital 
capsules without a successful copulation. Additionally, when 
we sampled reproductive aggregations, we found males lacking 
genital capsules (10% in the first congregation site, from a 
total of 50 sampled individuals; 5% in the second, from 60 
samples, and 7.7% in the third, from 90 samples). Penisless 
males stay alive on average for a further 2.62 days (±1.41 
s.d.) and can be easily identified by the absence of the genital 
capsule (Fig 3c-d).

The life history of males of stingless bees has just 
started to be told. The main message is that their life histories 
are much more diverse than previously thought, and many 
aspects are yet to be described and understood.

Acknowledgements

We would like to thank Denyse Cardoso da Silva and 
Rodriga de Andrade e Silva for their support in field work. 
We also thank Dr. Alistair Campbell for language review, and 
the anonymous referees for insightful suggestions. We thank 
CAPES/EMBRAPA (15/2014) for providing grants to JCV 
and KLL. This research was funded by CNPq (400435/2014-
4) through the PVE 2014 Project. We dedicate this work to the 
memory of Prof. Warwick E. Kerr (1922 - 2018), a pioneer on 
studies of stingless bees.

Supplementary Material

DOI: 10.13102/sociobiology.v65i4.3451.s2226
Link: http://periodicos.uefs.br/index.php/sociobiology/rt/supp 
Files/3451/0

Authors’ Contributions

JC Veiga, FAL Contrera conceived the sampling designs; 
JC Veiga, KL Leão, BWT Coelho collected and analyzed data; 
JC Veiga, FAL Contrera wrote initial draft of the manuscript 
and all authors contributed to subsequent revisions and gave 
final approval for publication.

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