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

DOI: 10.13102/sociobiology.v65i4.2878Sociobiology 65(4): 777-779 (October, 2018) Special Issue

Biological Data of Stingless Bees with Potential Application in Pesticide Risk Assessments

Brazil has the greatest global richness of stingless 
bees (Michener, 2013) and is also the world’s largest 
consumer of pesticides (MAPA, 2017). Therefore, it is 
essential that ecotoxicological information on native fauna 
be made available to agencies responsible for environmental 
assessments of pesticides, represented in the case of Brazil 
by the Instituto Brasileiro do Meio Ambiente e dos Recursos 
Naturais Renováveis (IBAMA). According to IBAMA 
(2017), among the main limitations for pesticide risk 
assessments for native bees is the lack of basic data on the 
biology of these bees, such as food consumption at different 
life stages and the mass of the individuals. In addition, the 
safety of the current use of the exotic species Apis mellifera 
L. as a substitute for the other native species of Brazil in 
these assessments is questioned.

Abstract 
Due to the current practice of intensive pesticide use in Brazil on crops 
with flowers that are attractive to bees, biological information about 
Brazilian native bees is required in order for public authorities that are 
responsible for environmental safety to use them for calculations of risk 
assessments. Thus, the present study aimed to obtain biological data 
on stingless bees: Melipona scutellaris Latreille, Scaptotrigona postica 
Latreille and Tetragonisca angustula Latreille. The food consumed by 
larvae and by adults and the mass of forager workers were obtained. 
The results provide essential inputs for the risk assessment of stingless 
bee exposure to pesticides, which combined with information about 
the concentrations of these substances in crops with flowers that are 
attractive to bees, may be used in risk calculations. 

Sociobiology
An international journal on social insects

AS Dorigo1, AS Rosa-Fontana1, IF Camargo2, RCF Nocelli2, O Malaspina1

Article History

Edited by
Cândida Aguiar, UEFS, Brazil
Received                         04 February 2018
Initial acceptance         02 May 2018
Final acceptance           14 August 2018
Publication date           11 October 2018

Keywords 
Model organism, pesticides, pollinators, 
risk assessment, sensitivity to pesticides, 
stingless bees’ larval food.

Corresponding author
Annelise Rosa-Fontana
Universidade Estadual Paulista Júlio de 
Mesquita Filho - UNESP
Centro de Estudos de Insetos Sociais 
Av. 24-A, 1515 - Bela Vista 
Código postal 199 - CEP: 13506900   
Rio Claro-SP, Brasil. 
E-Mail: annesouzar@gmail.com

Melipona scutellaris Latreille, Scaptotrigona postica 
Latreille and Tetragonisca angustula Latreille are interesting 
species to be used as model organisms for risk assessment. 
The first two are considered as priorities for pesticide 
risk assessments, according to the recent list of species 
selection, which consider several criteria such as geographic 
distribution, association with crops, and importance as 
pollinators, among others (Pires & Torezani, 2018). A 
species of the Scaptotrigona genus (S. postica) was chosen 
by both its broad distribution in Brazil and its intermediate 
size among the other species. In addition to composing the 
native Brazilian fauna, there is a need for biological data on 
stingless bee species, which may be useful for carrying out 
risk assessments for native species (IBAMA, 2017). Based on 
the data gaps mentioned, the present study aimed to provide 

1 - Universidade Estadual Paulista Júlio de Mesquita Filho (UNESP), Rio Claro, São Paulo, Brazil
2 - Universidade Federal de São Carlos (UFSCar), Araras, São Paulo, Brazil

ShORT  NOTE



AS Dorigo, AS Rosa-Fontana, IF Camargo, RCF Nocelli, O Malaspina – Stingless Bees and Pesticide Risk Assessments778

data to fill the gaps in knowledge about aspects related to 
nutrition and body mass of stingless bees. These results will 
provide essential inputs for the risk assessments of exposure 
of stingless bees to pesticides.

To quantify the larval food consumed by brood cell, as 
well as the daily syrup consumption and the individual mass 
of worker foragers, three non-parental colonies of each species, 
maintained at Universidade Estadual Paulista, Rio Claro, 
Brazil, were used. To measure the amount of larval food 
consumed per brood cell, the food of 20 newly oviposited 
cells per colony was collected by random selection. Before 
food collection, the eggs were removed from cells. With 
an automatic micropipette, the food from each colony was 
homogenized in Eppendorf microtubes with volumetric 
graduation. They were weighed in an analytical balance 
before and after the food collection. The total volume and 
mass were divided by the number of brood cells to estimate 
the amount of individual food per cell.

To estimate the food consumption and individual 
mass of worker foragers, individuals from the three species 
(total number/species = 30 for each test) were collected at 
the entrances of the nests when they left to forage. The mass 
of the individuals was verified using an analytical balance. 
To check the food consumption, 10 individuals from the 
same colony were placed on plastic perforated pots for air 
circulation. Eppendorf microtubes syrup feeders (sugar and 
water 1:1,v:v), simulating nectar, were placed on the pots, 
and the bees fed ad libitum. For 4 days, every 24 hours, the 
feeders were weighed using an analytical balance in order to 
verify daily consumption.

In addition to the establishment of the data for the 
stingless bee species, the same data for honey bees were taken 
from literature, in order to compare them.

The mean values of the larval food consumed by brood 
cell, the daily syrup consumption by forager workers, the 
individual mass of the bees and the data taken from literature 
are shown in the Table 1.

The data on the amount of food consumed by larvae 
and syrup by forager workers, combined with information on 
the concentrations of these substances in agricultural crops 
with flowers that are attractive to bees, may be used for risk 

assessments. Understanding this relationship is extremely 
relevant since Brazil currently bases its protocols on standards 
of the OECD (Organisation for Economic Co-operation and 
Development), which uses A. mellifera as a model organism. 
These protocols were adopted by the United States EPA 
(Environmental Protection Agency) for the schematization of 
risk assessment, which was used as a reference for the current 
Brazilian risk assessment scheme. Nevertheless, among the 
main uncertainties noted by IBAMA (2017), the use of A. 
mellifera stands out, since stingless bees are part of the native 
pollinator fauna. One way to remedy this issue would be to 
carry out a comparison of A. mellifera with native species 
regarding the toxicity of and exposure to pesticides, and our 
work provides important information that contributes to this 
evaluation. The differences between the groups are evident in 
biological parameters, such as their larval feeding systems. 
While A. mellifera nurse workers progressively deposit the 
food to the brood, in stingless bees, they do it all at once, 
depositing all the food that will be consumed (Velthuis, 1998). 
In addition, the volume of food consumed by the brood also 
differs between groups: in A. mellifera, each larva consumes 
a total of 160 µl (Aupinel, 2005), and in the stingless bee 
species, M. scutellaris, S. postica and T. angustula, each 
larva ingests 130.58, 25 and 5.6 µl, respectively. The nectar 
consumption by the forager workers and the individual mass 
of the bees also give rise to the uncertainty about using A. 
mellifera as a study model in Brazil. According to Cresswell 
et al. (2012), one forager worker of A. mellifera consumes a 
daily average of 50 mg of nectar and weighs on average of 
79.1 mg, showing greater food consumption and body mass 
comparing to stingless bees (Table 1).

In addition to that, the mass of individuals presented 
herein may be a relevant factor in the sensitivity of the 
different species to a particular type of pesticide, for 
example. Comparing the sensitivity of bee species to 
exposure to pesticides, a meta-analysis study conducted 
by Arena and Sgolastra (2014) indicated the sensitivity of 
stingless bees was in general higher than bumblebees. In 
addition, Devillers et al. (2003) suggested the sensitivity of 
different bee species is generally inversely proportional to 
their mean body mass.

Volume of larval food 
by brood cell (µL)

Mass of larval food 
by brood cell (mg)

Daily syrup consump-
tion by worker (mg)

Individual mass of 
forager worker (mg)

Melipona  scutellaris 130.58 ± 0.52 158.04 ± 5.18 35.06 ± 9.15 76.65 ± 2.9

Scaptotrigona postica 25 ± 1.14 32.5 ± 0.8 9.45 ± 2.41 17.02 ± 0.35

Tetragonisca angustula 5.6 ± 0.77 7.96 ± 1.03 7.23 ± 1.74 4.1 ± 0.37

Apis mellifera 160† - 50† 79.1±4.9†

†The data of volume of larval food by brood cell, daily syrup consumption by worker and individual mass of forager worker were obtained, respectively, from 
Aupinel (2005), Cresswell et al. (2012) and Blatt and Roces (2001).

Table 1. Amount of larval food consumption by cell, daily syrup consumption and individual weight of forager workers.± indicates standard 
deviations values. “–” indicates absence of data.



Sociobiology 65(4): 777-779 (October, 2018) Special Issue 779

Nevertheless, it is interesting to observe that, in the 
workers of the species of smaller body size of this study, 
T. angustula, the amount of food consumed corresponds 
to twice the body mass, compared to the other species of 
stingless bees and also to A. mellifera. This is an interesting 
point to be considered for future investigations regarding 
species-sensitivity.

In this work, some information required for the 
characterization of pesticide exposure risks to stingless 
bees was presented. Although there is a high richness of 
stingless bee species in Brazil, little is known about their 
basic biological data (IBAMA, 2017). For the inclusion of 
native species in risk assessments of pesticides in Brazil, it is 
necessary that this approach continues in future studies.  

Acknowledgements

We thank CAPES and Fundação de Amparo à Pesquisa 
do Estado de São Paulo (FAPESP process Nº 2016/00328-4) 
for financial support. 

Authors’ Contribution

All of the authors conceived research. Authors 1, 2 and 
3 conducted experiments. Authors 1 and 2 analysed data and 
conducted statistical analyses. All of the authors wrote, read 
and approved the manuscript.

References

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MAPA. (2017). Agrotóxicos. Ministério da Agricultura, 
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