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

DOI: 10.13102/sociobiology.v61i4.517-522Sociobiology 61(4): 517-522 (December, 2014)

Assessing Sperm Quality in Stingless Bees (Hymenoptera: Apidae)

Introduction 

In order to exploit the great potential of stingless 
bees as commercial pollinators, it is of great importance to 
improve management and optimize practices to produce 
colonies on a large scale. Therefore, it is essential to develop 
accurate diagnostic tools that enable a better understanding of 
the reproductive biology of stingless bees. 

Semen quality is known to determine male reproductive 
success across taxa (Simmons, 2001). In turn, semen quality 
can be affected by factors such as the number, morphology 
and viability of sperm (Garófalo, 1980; Simmons, 2001; 
den Boer et al., 2009). Few studies have looked at sperm 
characteristics of bees in general, and even less in stingless 
bees. Cortopassi-Laurino (1979) counted the number of sperm 
in males of Plebeia droryana (Friese) and found 313,000 
± 102,050 sperm per male. Garófalo (1980) evaluated the 
amount of semen produced by the males and stored in the 
female’s spermathecae in different species of bees, including 
eight stingless bees, and found that there is no relationship 
between social levels and the amount of sperm found in 

Abstract
Although stingless bees have a great potential as commercial pollinators, their 
exploitation depends on the successful reproduction of colonies on a large scale. 
To do so, it is essential to develop accurate diagnostic tools that enable a better 
understanding of the reproductive biology of stingless bees. Sperm counts, sperm 
morphology and sperm viability (the relative proportion of live to dead sperm), are 
key parameters assessing semen quality and potential fertilization success. Here 
we present standardized protocols to assess these three parameters. We used 
Scaptotrigona aff. depilis (Moure) as a study model. Semen extractions from the 
seminal vesicles were found to yield better results when performed in mature rather 
than in younger males. For morphology and viability analyses, the best semen dilution 
on Hayes solution was adding 120 µl to the contents of the two seminal vesicles. For 
sperm counts, however, we recommend a higher dilution (1,000 µl). Sperm viability 
values   were higher when Hayes solution was adjusted to pH 8.7, and when samples 
were analyzed before 24 hours from collection. Based on these results we present 
standard protocols, hoping they will be useful to future researchers assessing sperm 
quality in other stingless bee species. 

Sociobiology
An international journal on social insects

HM Meneses1, S Koffler2, BM Freitas1, VL Imperatriz-Fonseca2, R Jaffé2

Article History

Edited by
Denise Araujo Alves, ESALQ-USP, Brazil
Received                  14 November 2014
Initial acceptance   01 December 2014
Final acceptance    01 December 2014

Keywords
sperm viability, sperm morphology, 
sperm counts, semen, Meliponini.

Corresponding author
Hiara Marques Meneses
Av. Mister Hull 2977, Campus do Picí, 
Bloco 808, 60021-970, Fortaleza-CE, Brazil
E-Mail: hiarameneses@gmail.com

females and produced by males. Conte et al. (2005) found 
that the small spermatids are lost during the early stages of 
spermiogenesis of Melipona quadrifasciata anthidioides Lepeletier. 
Also addressing the spermatogenesis process, Lino-Neto et al. (2008) 
found that half of the spermatids formed during the spermatogenesis 
are not transformed into viable sperm cells in Scaptotrigona 
xanthotricha Moure. Pech-May et al. (2012) found a strong positive 
relationship between the size of male and semen production in 
Melipona beecheii Bennett. Camillo (1971) noted an increase of 2.35 
times in the number of sperm of giant Friesella schrottkyi (Friese) 
males (produced occasionally when an unfertilized egg is raised on 
a royal cell) compared to what is found in common males. Table 1 
summarizes previous contributions to the study of stingless bee sperm. 

The viability of spermatozoa, or relative proportion of 
live to dead sperm, is an important parameter to appreciate 
reproductive success of males (Simmons, 2005), and it is used to 
analyze semen quality in honeybees (Collins & Donoghue, 1999; 
Collins, 2004; den Boer et al., 2009; Gençer et al., 2014). It 
is also commonly used in other organisms to study various 
aspects of their reproductive biology (Garner et al., 1994; Ball 
et al., 2001; Paulenz et al., 2002). 

RESEARCH ARTICLE - BEES

1 - Universidade Federal de Ceará,UFC, Fortaleza, CE, Brazil
2 - Universidade de São Paulo, USP, São Paulo, SP, Brazil



HM Meneses, S Koffler, BM Freitas, VL Imperatriz-Fonseca, R Jaffé - Assessing Sperm Quality in Stingless Bees518

Recent advances in the use of flow cytometry to 
assess sperm traits in social insects allowed significant 
improvements, decreasing processing times and increasing 
accuracy (Cornault & Aron, 2008; Paynter et al., 2014). 
However, flow cytometry equipment is not common across 
the tropics (where stingless bees occur), and the costs involved 
in their use and maintenance are substantially higher than 
those involving fluorescence-based methods. We thus provide 
standard protocols for fluorescence-based methods, which 
are cheap and ready available across the tropics, aiming at 
facilitating further research on stingless bees. Although less 
accurate than flow cytometry methods, fluorescence-based 
methods have been widely used and they are well accepted 
as standard methods (Thomas & Simmons., 2007; den Boer 
et al., 2008, 2010; Cobey et al., 2013). Moreover, sperm 
viability obtained with fluorescence microscopy and flow 
cytometry has been found indistinguishable in some cases 
(Paynter et al., 2014).

To date, no standard protocol is available to assess 
sperm quality in stingless bees. Here we fill this gap by 
presenting appropriate protocols for assessing sperm counts, 
sperm morphology and sperm viability in stingless bees.

Table 1. Works addressing sperm biology in stingless bees.

Materials for details). Males were collected from male 
aggregation and from the interior of colonies. Those found in 
aggregations (Fig 1) were considered mature and originated 
from different colonies (Paxton et al., 2000). Males collected 
inside the colonies were only distinguished as freshly emerged 
males (usually of a lighter color) or adult (darker) males. 
However, during dissections, we found marked differences 
between males in testis size and migration of sperm to the 
seminal vesicles. We thus used this information as a proxy 
for male age, where males with bigger testis and incomplete 
semen migration were characterized as immature males.

Fig 1. Aggregation of Scaptotrigona aff. depilis males.

Different semen dilutions were tested (40, 100 and 
200 µl) to facilitate the counting of sperm cells (5 males per 
treatment). As pH was found to have a profound effect on 
sperm viability during our initial trials, we experimentally 
manipulated pH to identify the pH yielding maximal sperm 
viability (pH tested was 8.4, 8.7 and 9.0, with 3 males per 
treatment). Likewise, because sperm cells start to die once the 
ejaculate has been collected, we also tested the effect of time 
on sperm viability (fresh, 1, 3, 5 and 24 hours after dissection, 
with 5 males per treatment). 

For the sperm counts and sperm morphology analyses 
we stained sperm using DAPI (Fig 2, see Supplementary 
Material for details). In order to assess the morphology of 
sperm cells, black and white images of the DAPI-stained cells 
were taken (20x magnification). Images were analyzed with the 
software Image J, adjusting brightness and contrast for better 
visualization. For the measurement of the sperm head area, 
each image was adjusted by changing the threshold parameter, 
which enhances binary contrast. This modification was done 
until all head area was selected, excluding the sperm tail and 
background. After this procedure, head area was selected 
with the automatic selection tool (wand) and measured. 
Because threshold adjustments may be subjective, training 
and standardizing the procedure is suggested before the real 
measurements are taken. Illustrative results are presented for 

Species Topic Reference

Friesella schrottkyi (Friese) Giant males Camilo et al. (1971)

Plebeia droryana (Friese) Sperm number Cortopassi-Laurino 
(1979)

Friesella schrottkyi (Friese)
Lestrimelitta limao (Smith)
Melipona marginata Lepeletier
M. quadrifasciata Lepeletier
M. rufiventris Lepeletier
Scaptotrigona postica (Latreille)
Tetragonisca angustula (Latreille)
Trigona hyalinata (Lepeletier)

Sperm produced 
by males and 
stored in queen’s 
spermathecae

Garófalo (1980)

Melipona quadrifasciata Lepeletier Spermatogenesis Conte et al. (2005)

Scaptotrigona xanthotricha Moure Spermatogenesis Lino-Neto et al. (2008)

Melipona beecheii Bennett Sperm number Pech-May et al. (2012)

Material and Methods

We used established protocols for sperm counts and 
sperm viability in honeybees (Apis mellifera Linnaeus) 
(Collins & Donoghue, 1999; Cobey et al., 2013), as a 
guideline to develop protocols to analyze stingless bee sperm. 
All tests were conducted in the Bee Laboratory, Department 
of Ecology, University of São Paulo. Our study model was 
Scaptotrigona aff. depilis (Moure), a common stingless 
bee of Southeastern Brazil. Specimens of each colony were 
collected and identified with the aid of a specialist (Dr. Silvia 
R. M. Pedro). Voucher specimens can be found in the Coleção 
Entomológica Paulo Nogueira-Neto (CEPANN), located in 
the University of São Paulo, São Paulo, Brazil.

Adjustments were implemented to improve the collection 
of semen from the seminal vesicles (see Supplementary 



Sociobiology 61(4): 517-522 (December, 2014) 519

10 sperm cells from one male (mean ± SE). Sperm counts were 
estimated by diluting the total amount of sperm of each male 
10,000 times and counting cells in three samples of 1 µl (air 
dried in microscope slides). The samples were also DAPI-
stained. Counting began at the right edge of each sample, 
and continued until de left side of the sample was reached. The 
mean value obtained from the three samples was multiplied by 
10,000, to estimate the total number of sperm per male. Results 
for sperm counts are presented for six males (mean ± SE). 

Statistical analyses consisted in binomial generalized 
linear models, as they are the standard method to analyze 
proportion data (Crawley, 2013), such as sperm viability 
(dead/alive). Similar analyses are often implemented in 
studies of sperm viability (den Boer et al., 2009; Stürup et al., 
2011). All statistical analyses were implemented in R. 

Results 

Semen was more easily collected from the seminal vesicles 
of mature males (Fig 5) rather than younger ones (Fig 6), as semen 
had already migrated from the testicles to the seminal vesicles 
in mature males only. 

Sperm counts in S. aff. depilis resulted in an average 
(± SE) of 1,487,778 ± 36,044 sperm cells per male. When 
assessing sperm morphology, we found a mean total length 
of 85.58 ± 1.06 µm, a mean head length of 9.50 ± 0.24 µm, 
a mean tail length 76.08 ± 0.98 µm and a mean head area of 
23.42 ± 0.58 µm2. Finally, sperm viability ranged from 52 to 
87% (Figs 7 and 8). 

We found that the best semen dilution for sperm 
morphology and viability assays was 100 µl Hayes solution 
to the contents of the two seminal vesicles, in addition to the 
initial 20 µl Hayes for emptying the vesicles. This was due 
to the greater ease during the identification and counting of 
sperm cells. For sperm counts, however, we recommend a 
higher dilution (10,000 x) in order to identify single isolated 
sperm cells. 

Sperm viability was significantly affected by pH, 
being highest when Hayes solution was adjusted to a pH of 
8.7 (Fig 6; Table 2). We also found a significant effect of 
incubation time (Table 3). No difference was found in sperm 
viability for the initial time intervals tested (fresh, 1, 3 and 5 
hours after collection), but a marked decrease in viability was 
found after 24 hours (Fig 7). 

Fig 2. Honeybee (Apis mellifera) sperm cell marked with DAPI.

Fig 3. Live (green) and dead (red) honeybee (Apis mellifera) sperm.

Fig 4 A. Diagram summarizing the workflow of the semen extrac-
tion protocol; B. Diagram summarizing the workflow of the sperm 
count and morphology protocol; C. Diagram summarizing the 
workflow of the sperm viability protocol.

We used the LIVE / DEAD ® Invitrogen Sperm 
Viability Kit to assess sperm viability. Employing a 
fluorescence microscope and a cell counter, we proceeded to 
count the first 400 cells found from the center of the cover 
slip. Sperm cells were classified as green (live), red (dead) 
and green / red (dying) (Fig 3). The workflow protocols are 
summarized in Figs 4 A, B, and C.



HM Meneses, S Koffler, BM Freitas, VL Imperatriz-Fonseca, R Jaffé - Assessing Sperm Quality in Stingless Bees520

Fig 7. Sperm viability of sperm from Scaptotrigona aff. depilis 
diluted in Hayes solution with different pH values.

Fig 8. Sperm viability of sperm from Scaptotrigona aff. depilis 
assessed on fresh semen, 1, 5 and 24 hours after collection.

Table 2. Summary statistics for the effect of pH on sperm viability.

Table 3. Summary statistics for the generalized linear mixed effect 
model for sperm viability in different intervals between semen 
collection and viability analysis.

Discussion

Semen extraction in stingless bees is different 
than in honeybees. First, stingless bees lack the enormous 
mucus glands found in honeybees, so the dissection of the 
reproductive tract is more delicate. Second, the manual 
collection of the ejaculate from the end phallus is not possible, 
because the manual eversion of the endophallus fails to 
stimulate ejaculation. Finally, dissection is more difficult in 
smaller species, requiring the use of specialized equipment.

Different protocols are available for counting sperm 
cells. Counting cells using a hemocytometer was described 
for A. mellifera sperm (Cobey et al., 2013; Human et al., 
2013), in which a known volume containing unstained cells 
is analyzed. A drawback of this method is that the counting 
procedure must be done immediately after dissection. In our 
protocol, microscope slides are prepared with samples of 
sperm in a known dilution, and only three samples are counted 
to estimate the total number of sperm cells. Since samples are 
dried, the slides can be stored for later analyses, which is an 
advantage when a high number of males need to be analyzed. 
Other studies implemented similar techniques successfully 
(Baer et al., 2006; Stürup et al., 2011).

Our results show that sperm counts, sperm 
morphology and sperm viability can be effectively assessed 

Fig 6. Reproductive system of immature male of Scaptotrigona 
aff. depilis.

Fig 5. Reproductive system of mature male of Scaptotrigona 
aff. depilis. 

Response Predictor Estimate SE P-value 

Sperm viability Fresh semen 0.15 0.18 0.41 

 
1h after collection 0.08 0.26 0.76 

 
5h after collection 0.12 0.26 0.64 

 
24h after collection -0.76 0.26 0.003 

 



Sociobiology 61(4): 517-522 (December, 2014) 521

in a stingless bee. For sperm morphology and viability, the 
best semen dilution was found to be 120 µl Hayes solution 
to the total semen content of a male. For sperm counts, the 
best dilution factor was 10,000 x. While the pH yielding the 
highest sperm viability was at 8.7, we found that the best time 
to assess viability was before 24 h of semen collection. Given 
the high susceptibility of sperm to manipulation, desiccation, 
pH and temperature extremes, we recommend that great care 
must be taken to ensure sperm are analyzed shortly after 
collection and under the best possible conditions. Based on 
these results we present standard protocols, hoping they will 
be useful to future researchers assessing sperm quality in other 
stingless bee species. Such studies could contribute advance 
basic knowledge on the reproductive biology of stingless 
bees, and facilitate their commercial use.

Acknowledgments 

We thank Paulo Cesar Fernandes for technical 
assistance in the lab, Prof. Dr. Ana Castrucci for kindly 
providing access to her fluorescence microscope and FAPESP 
for funding (RJ, Process 2012/13200-5).

References

Baer, B., Armitage, S.A.O. & Boomsma. J.J. (2006). Sperm 
storage induces an immunity cost in ants. Nature 441: 872-875.

Ball, B.A., Medina, V., Gravance, C.G. & Baumber, J. (2001). 
Effect of antioxidants on preservation of motility, viability 
and acrosomal integrity of equine spermatozoa during storage 
at 5ºC. Theriogenology 56: 577-589.

Camillo, C. (1971). Estudos adicionais sobre os zangões de Trigona 
(Friesella) schrottkyi (Hym. Apidae). Ciênc. Cult. 29: 279.

Cobey, S.W., Tarpy, D.R. & Woyke, J. (2013). Standard 
methods for instrumental insemination of Apis mellifera 
queens. In V. Dietemann, J.D. Ellis, P. Neumann (Eds.) The 
COLOSS BEEBOOK, Volume I: standard methods for Apis 
mellifera research. J. Apicul. Res. 52(4): 1-18.

Collins, A.M. & Donoghue, A.M. (1999). Viability assessment 
of honey bee, Apis mellifera sperm using dual fluorescent 
staing. Theriogenology 51: 1513-1523.

Collins, A.M. (2004). Sources of variation in the viability of 
honey bee, Apis mellifera L., semen collected for artificial 
insemination. Invertebr. Reprod. Dev. 45: 231-237.

Conte, M., Lino-Neto, J. & Dolder, H. (2005). Spermatogenesis 
of Melipona quadrifasciata anthidioides (Hymenoptera: 
Apidae): Fate of the Atypical spermatids. Caryologia 58: 183-
188. doi: 10.1080/00087114.2005.10589449.

Cortopassi-Laurino, M. (1979). Observações sobre atividade 
de machos de Plebeia droryana Friese (Apidae, Meliponinae). 
Rev. Bras. Entomol. 23: 177-191.

Cournault, L. & Aron, S. (2008). Rapid determination of sperm 
number in ant queens by flow cytometry. Insect. Soc. 55: 283-287.

Crawley, M.J. (2013). The R book. John Wiley & Sons.

den Boer, S.P.A, Boomsma, J.J. & Baer, B. (2008). Seminal 
fluid enhances sperm viability in the leafcutter ant Atta 
colombica. Behav. Ecol. Sociobiol. 62: 1843-1849. doi: 
10.1007/s00265-008-0613-5. 

den Boer, S.P.A., Boomsma, J.J. & Baer, B. (2009). Honey bee 
males and queens use glandular secretions to enhance sperm 
viability before and after storage. J. Insect. Physiol. 55: 538-543.

den Boer, S.P.A., Baer, B. & Boomsma, J.J. (2010). Seminal 
fluid mediates ejaculate competition in social insects. Science 
327: 1506. doi: 10.1126/science.1184709.

Garner, D.L., Johnson, L.A., Yue, S.T., Roth, B.L. & 
Haugland, R.P. (1994). Dual DNA staining assessment of 
bovine sperm viability using SYBR-14 and propidium iodide. 
J. Androl. 15: 620-629.

Garófalo, C.A. (1980). Reproductive aspect and evolution 
of social behavior in bees (Hymenoptera, Apoidea). Braz. J. 
Genet. 3:139-152.

Gençer, H.V., Kahya, Y. & Woyke J. (2014). Why the viability 
of spermatozoa diminishes in the honeybee (Apis mellifera) 
within short time during natural mating and preparation 
for instrumental insemination. Apidologie 45: 757-770. 
doi:10.1007/s13592-014-0295-0.

Human, H., Brodschneider, R., Dietemann, V., Dively, G., 
Ellis, J., Forsgren, E., Fries, I., Hatjina, F. Hu, F., Jaffé, R., 
Jensen, A.B., Köhler, A., Magyar, J.P., Özkýrým, A., Pirk, 
C.W.W., Rose, R., Strauss, U., Tanner, G., Tarpy, D.R., van 
der Steen, J.J.M., Vaudo, A., Vejsnæs, F., Wilde, J., Williams, 
G.R. &  Zheng, H.Q. (2013). Miscellaneous standard methods 
for Apis mellifera research. J. Apicult. Res. 52.

Lino-Neto, J., Araújo, V.A. & Dolder, H. (2008). Inviability 
of the spermatids with little cytoplasm in bees (Hymenoptera; 
Apidae). Sociobiology 51: 163-172.

Paulenz, H., Soderquist, L., Pérez-Pé, R. & Berg, K.A. (2002). 
Effect of different extenders and storage temperatures on sperm 
viability of liquid ram semen. Theriognology 57: 823-836.

Paynter, E., Baer-Imhoof, B., Linden, M., Lee-Pullen,T., 
Heel, K., Rigby, P. & Baer, B. (2014). Flow cytometry  as a 
rapid and reliable method to quantify sperm viability in the 
honeybee Apis mellifera. Cytometry Part A 85: 463-472.

Paxton, R.J. (2000). Genetic structure of colonies and a male 
aggregation in the stingless bee Scaptotrigona postica, as 
revealed by microsatellite analysis. Insect. Soc. 47: 63-69

Pech-May, F.G., Medina-Medina, L., May-Itzá, W.J., Paxton, R.J. 
& Quezada-Euán, J.J.G. (2012). Colony pollen reserves affect 
body size, sperm production and sexual development in males of 
the stingless bee Melipona beecheii. Insect. Soc. 59: 417-424.



HM Meneses, S Koffler, BM Freitas, VL Imperatriz-Fonseca, R Jaffé - Assessing Sperm Quality in Stingless Bees522

Simmons, L.W. (2001). Sperm competition and its evolutionary 
consequences in the insects. Priceton: Princeton Univ. Press.

Simmons L.W. (2005) Sperm viability matters in insect 
sperm competition. Curr. Biol. 15: 271-275. doi: 10.1016/j.
cub.2005.01.032

Stürup, M., den Boer, S., Nash, D., Boomsma, J. & Baer, B. 
(2011). Variation in male body size and reproductive allocation 

in the leafcutter ant Atta colombica: estimating variance 
components and possible trade-offs. Insectes Soc. 58: 47-55.

Thomas, M.L. & Simmons, L.W. (2007). Male crickets adjust 
the viability of their sperm in response to female mating 
status. Am. Nat. 170: 190-195. DOI:10.1086/519404

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DOI: 10.13102/sociobiology.v61i4..s760