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

DOI: 10.13102/sociobiology.v68i3.5830Sociobiology 68(3): e5830 (September, 2021)

Introduction

Despite the importance of Apis bees, there has been 
a worldwide decline in the populations of these insects in 
recent years. Such decline is attributed to climatic factors, 
use of agrochemicals, diseases, parasites, and habitat and 
food (e.g. nectar and pollen) reduction, all of which directly 
impair the maintenance of colonies (Goulson et al., 2015; 
Wood et al., 2020).  

Among these factors, the use of agrochemicals in 
monocultures contributes to selecting pests that are resistant 
to the active ingredients used, culminating in the use of more 
and more toxic products, which are highly harmful to the 
environment and the pollinators (Johnson et al., 2010).

Abstract  
Inadequate quantity and quality of proteins in honey bee diet can cause 
weakening of their colonies and damage their resistance to agrochemical 
contamination, such as fipronil, which is highly toxic to bees. Thus, we tested the 
hypothesis if protein supplementation would improve longevity and locomotion 
of honeybees exposed to fipronil pesticide. Colonies of Apis mellifera Africanized 
were distributed into Control Group without protein supplementation and 
Supplemented Group with 25% crude protein provided as a paste form at 100 g 
per week. After four weeks, frames with sealed brood were removed and kept in 
an incubator until the emergence of worker bees, which were marked, returned 
to their hives and recaptured six days later to measure protein concentration in 
the hemolymph. The bee population development was measured by evaluating 
frames containing the queen’s oviposition from each colony. Also, nursing bees 
were recaptured exposed by contact to fipronil LD

50% 
(0.009 ± 0.003 μg/bee), 

and the longevity and motor activity were measured. The results showed that 
the bee swarms protein supplementation promoted a significant increase in the 
sealed brood area. However, it did not promote changes in the protein content 
of the hemolymph. Protein supplementation of bee swarms did not influence 
the survival of bees exposed to fipronil in the locomotion tests; however, fipronil 
was toxic to bees and promoted changes in the locomotion of bees.

Sociobiology
An international journal on social insects

Iloran RC Moreira, Daniel CB Barros, Juliana S Lunardi, Ricardo O Orsi

Article History

Edited by
Evandro N. Silva, UEFS, Brazil
Received                   01 September 2020
Initial acceptance    03 May 2021
Final acceptance      18 May 2021
Publication date       13 August 2021

Keywords 
Beekeeping, neurotoxicity, nutrition, 
protein, supplementation.

Corresponding author 
Ricardo de Oliveira Orsi
Faculdade de Medicina Veterinária  
e Zootecnia –  FMVZ
Campus Botucatu 
Distrito de Rubião Junior s/nº 
Caixa Postal 560, CEP 18618-97. 
Botucatu, São Paulo, Brasil.
E-Mail: ricardo.orsi@unesp.br

When bees collect resources (i.e., nectar and/or pollen) 
that contain high doses of agrochemicals, acute contamination 
of bees can occur, which causes their mortality over a short 
period. However, when applied in low doses, considered sublethal, 
it is often transported to the colony by the bees together with 
the collected resources, which may compromise the viability of 
breeding and the maintenance of colonies (Villa et al., 2000; Long 
& Krupke, 2016). The contamination of colonies by agrochemicals  
reduces the longevity (Colin et al., 2004; Pettis et al., 2004; 
Desneux et al., 2007) and affects the vitality of the colony (Belien 
et al., 2009), amongst other behavioral and physiological 
changes that impair its survival (Holdera et al., 2018).

One of the agrochemicals harmful to honeybees is 
fipronil, which belongs to the phenylpirazole group and targets 

Center of Education, Science and Technology in Rational Beekeeping (NECTAR), College of Veterinary Medicine and Animal Sciences, UNESP. 
Botucatu, São Paulo, Brazil

RESEARCH ARTICLE - BEES

Effect of Protein Supplementation in the Bee Apis mellifera L. Exposed to the Agrochemical Fipronil

ID

https://orcid.org/0000-0001-8099-8277


Iloran RC Moreira, Daniel CB Barros, Juliana S Lunardi, Ricardo O Orsi – Honeybee nutrition and fipronil2

the receptor of γ-aminobutyric acid as an antagonist. This 
agrochemical is used worldwide as a pesticide in agricultural 
and veterinary practices (Kairo et al., 2017). Commonly used 
on seeds, this systemic insecticide is absorbed by the growing 
plant and distributed through its tissues, including the flowers 
(Nauen & Jeschke, 2011). Thus, bees are exposed to residual 
levels of this insecticide when they collect nectar and pollen 
from the treated crops (Chauzat et al., 2011). Currently, 
neonicotinoids and fipronil represent one-third of the global 
insecticide market (Simon-Delso et al., 2015). In European 
countries such as Italy, Germany, and Slovenia, their use has 
caused a reduction of colonies of A.mellifera bees, leading the 
European community to ban these in 2013 (Eisenstein, 2015).

Depending on applied concentrations, fipronil may not 
cause the immediate mortality of bees. They can decrease the 
toxic effects of the pesticide through the action of enzymes 
such as glutathione-s-transferase, catalase, and cytochrome 
P450 (Johnson et al., 2012). In general, the detoxication system 
converts fat-soluble substances to insoluble substances in 
an aqueous environment (Berenbaum & Johnson, 2015). 
The quality and quantity of nutrients can modulate this 
system, making it extremely important for bees to maintain 
an adequate diet. Wahl and Ulm (1983) verified increased 
agrochemical resistance in young bees after receiving a pollen 
diet of adequate quality and quantity.

Thus, the supply of a protein diet to bee swarms in 
areas at risk of contamination by agrochemicals can increase 
the hemolymph protein levels in nursing bees and improve 
the resistance of bees exposed to the agricultural pesticide 
fipronil. We tested the hypothesis if  protein supplementation 
would help the honeybee’s longevity and locomotion exposed 
to fipronil pesticide 

Materials and Methods
Treatments

The experiment was undertaken at geographic 
coordinates 22°49′ S; 48°24′W, with a Cfa type climate 
(subtropical with summer of the higher temperatures) and an 
average altitude of 623 m. 

Six colonies Apis mellifera Africanized (Hymenoptera: 
Apidae) were used, housed in standard  Langstroth hives, and 
distributed randomly into groups, with three colonies  each: 
G1 – Control Group without protein supplementation and G2 
– Supplemented Group with 25% crude protein

For the formulation of the diet containing 25% crude 
protein, we used 47.6% of cornmeal, 47.0% of soybean 
meal, 5.0% of sugar, and 0.4% of oil, obtained from a single 
batch FMVZ Feed Factory, UNESP, Botucatu. The calculated 
nutritional levels were 4,035 kcal of crude energy and 25% of 
crude protein (Rostagno et al., 2011).

A bromatological analysis was performed to verify the 
calculated levels of the diet, which obtained values of 26.9% 
of crude protein and 3,846 of crude energy (lime/g). From the 

bee bread collected from the experimental colonies, 20% of 
crude protein and 4,050 crude energy (lime/g) were obtained.

The feed was provided in a paste form (a mixture of 
ingredients with a standardized amount of honey) and placed 
on the top bar of the central frame containing the bee swarms, 
at 100 g per week during December 2017. The leftovers from 
the rations were removed at the end of each week and weighed 
to measure consumption. All colonies had free access to 
nectar and pollen near the apiary.

Harvesting of bees for evaluation protein concentration in 
hemolymph, longevity, and locomotion of bees

Four weeks after the start of protein supplementation, 
two frames with sealed brood from the colonies (G1 and G2 
groups) were removed, marked, wrapped in tissue (to keep the 
bees newly emerged in the frame), and kept in an incubator 
at 32°C and relative humidity of 80% until the emergence 
of the worker bees (Roat et al., 2014). After the emergence, 
the newly emerged workers from each beehive were marked 
in the dorsal side of the thorax using a nontoxic pen (Posca 
Paint Pens, Mitsubishi Pencils, Japan) and returned to their 
respective hives. The marked bees were recaptured on their six-
day-old, and the concentration of proteins in their hemolymph 
was measured. So, the honeybees were exposed to fipronil at 
a concentration of 0.009 ± 0.003 μg/bee (LD50%) (Zaluski et 
al., 2015), and the longevity and motor activity measured in 
the laboratory.

Evaluation of the population development of A. mellifera

For the evaluation of population development (G1 and 
G2 groups), two frames containing the queen’s oviposition 
were located in the center of the nest. This nest had its brood 
area open and sealed. It was evaluated from the first day of 
the experiment, for four weeks, according to the methodology 
adapted from Al-Tikrity et al. (1971). 

Evaluation of the longevity of bees exposed to fipronil

On the seventh day, the nursing bees from colonies  (G1 
and G2 groups, totaling 30 bees/treatment) were recaptured, 
anesthetized in a freezer, and housed in a Petri dish (150 × 
20 mm) with perforated lids to ensure ventilation. The bees 
of G2 received 2µL of a solution containing LD50% of fipronil 
in the dorsal side region using a micropipette. The G1 group 
received 2µL of distilled water.

The Petri dishes were kept in a dark incubator at 32 ± 1°C 
and relative humidity of 70 ± 10%. The bees received syrup 
and 50% sugar and water ad libitum during all trials. These 
experiments were performed in triplicate. The number of dead 
bees was recorded daily, and the dead bees were removed 
from the plates. The experiment was conducted until all the 
bees had died.



Sociobiology 68(3): e5830 (September, 2021) 3

Evaluation of the motor activity of bees exposed to fipronil

The evaluation of the motor activity of bees was 
performed according to the methodology described by 
Zaluski et al. (2015). Motricity was included in the study 
to evaluate the possible effects on the motor activity of bees 
after supplementation with a 25% crude protein diet and 
contamination with agrochemicals. A total of 10 nursing 
bees were collected from each experimental colony (G1 
and G2 groups) and exposed by contact to LD50% of the 
agrochemical fipronil.

We used a wooden box in the form of a drawer to 
perform the locomotion tests, with dimensions of 60 cm long, 
40 cm wide, and 4 cm high. The box was capped with a glass 
plate to observe the bees. A fluorescent lamp was placed at the 
top of the box to attract the insects via positive phototaxis. The 
tests were performed in a dark room with the box tilted at 45°. 
The box presented five lanes with 50 cm for bee observations 
during the locomotion test. The bees were separated into two 
groups. One was subject to contact with fipronil at the LD50%, 
and the other not. Bees belonging to the experimental groups 
were placed at the box and released simultaneously. The time 
spent by bees to travel a 50 cm distance was recorded at two 
different periods: the first was 1h after contamination, and the 
second was 4h after contamination.

Protein quantification in the hemolymph of bees

A total of 10 nursing bees were recaptured from the 
colonies (T1 and T2 groups; totaling 30 bees/treatment) and 
anesthetized on ice for 10 min. Hemolymph was collected 
using a micropipette through an incision made at the base of the 
bee’s wing (Cremonez et al., 1998). The protein concentration 
from the hemolymph sample obtained from each hive was 
measured using the Bradford (1976) method with a Quick 
Start™ Bradford Protein Assay (Cat. Nº. #5000201; BioRad).

The readings were performed on a spectrophotometer 
(Spectrophotometer Evolution 60 Thermo Fisher Scientific, 
USA) at a wavelength of 595 nm. Bovine serum albumin was 
used to prepare the standard curve (Cremonez et al., 1998). 
The reading of each sample was made in triplicate.

Statistical analysis

The protein concentration in the hemolymph, motor 
activity, population development, and bee longevity were 
evaluated using a Student’s t-test. In all tests, the results were 
considered statistically different when P<0.05.  

Results

During the experimental period, the average consumption 
of 17.6 ± 13.1% of the crude protein ration provided to the 
bee swarms was measured. Supplementation with 25% crude 
protein significantly influenced the offspring in the sealed 
brood area compared to the control; however, it did not 
significantly affect the open brood area (Table 1). Protein 
supplementation did not affect bee survival compared to 
the control. However, bees of the control group and those 
supplemented with 25% crude protein and contaminated with 
fipronil showed 100% mortality 24 h after exposure (Fig 1).

Population development

Brood area open Brood area sealed 

G1 174.4 ± 85.8a 1548.0 ± 531.3a

G2 191.2 ± 67.7a 2335.0 ± 892.0b

Lowercase letters in the column represent a significant difference between 
the means (P<0.05).
G1: without proteic supplementation; G2: supplemented with 25% crude protein.

Table 1. Open and sealed brood area (cm2) of honeybees Apis mellifera 
Africanized supplemented or not with 25% of crude protein.

Fig 1. Survival Curve of Apis mellifera Africanized supplemented (G2) or not (G1) with 25% of 
crude protein and challenged or not with LD 50% of fipronil.



Iloran RC Moreira, Daniel CB Barros, Juliana S Lunardi, Ricardo O Orsi – Honeybee nutrition and fipronil4

In the control group, which did not receive crude 
protein supplementation, the contamination of bees with LD50% 
fipronil affected their locomotion compared to those not 
contaminated with fipronil for 1 and 4 h. However, there was 
no difference in locomotion between the bees that received 
protein supplementation and were contaminated with fipronil 
compared to bees not supplemented and challenged with 
LD50% fipronil for 1 and 4 h (Table 2).

2016), and protein supplementation showed a positive effect in 
the sealed breeding area of the swarms compared to the control, 
suggesting an improvement in the nutrition of bees because the 
balanced diet could help in the development and reproduction 
of these insects (Behmer, 2009; Lihoreau et al., 2015).

Protein supplementation of bee swarms did not interfere 
with the protein content of the hemolymph of the bees, 
although a direct relationship between these two parameters 
may occur (De Jong et al., 2009). Nicodemo et al. (2018) 
verified an increase in hemolymph protein content in bees at 
seven days of age who had received protein supplementation 
under laboratory conditions. In the present experiment with 
protein, supplementation was conducted in field conditions, 
whith bees performing their normal foraging activities and 
using the protein provided to balance their needs, which did not 
promote an increase in the protein content of the hemolymph.

The tests performed under laboratory conditions to 
evaluate the toxicity of fipronil showed significant mortality 
of bees with or without supplementation with the protein diet, 
showing the high toxicity of this agrochemical (Zaluski et 
al., 2015). Diet supplementation with 25% crude protein did 
not influence the survival of bees. One way that bees protect 
themselves from the toxic effects of compounds released in 
nature is via their detoxification system, which is composed 
of enzymes such as P450 monooxygenase, glutathione 
transferase, and carboxylesterase (Li et al., 2007; Rand et al., 
2015). Wahl and Ulm (1983) found that young bees showed 
high resistance after exposure to agrochemicals when they 
received a protein diet in adequate quality and quantity, 
suggesting an improvement in the bee detoxification system. 
However, in the present study, there was no effect of protein 
supplementation, probably because there was no increase in 
protein content in the hemolymph of the bee swarms. Thus, 
the detoxification system was not influenced.

Fipronil significantly affected the locomotor activity 
of bees, with or without supplementation with 25% crude 
protein. This result suggests the action of the neurotransmitter 
gamma-aminobutyric acid (GABA), which is responsible for 
the reestablishment of the resting state of the central nervous 
system and muscles of insects (Dowson, 1977; Aajoud et 
al., 2003; Narahashi et al. 2010). Fipronil may have acted 
on GABA receptors, promoting neurological and muscular 
alterations, evidenced in the present study by the locomotor 
alterations of bees exposed to it. The result of the locomotion 
test is important because the normal motor activity of bees is 
essential for their foraging activities, and it was shown that 
fipronil directly affected this activity, which may compromise 
the swarm as a whole and promote behavioral, biochemical, 
and neurological alterations (Sanchez-Bayo & Goka, 2014).

Conclusion

The present study showed that protein supplementation 
promoted improvement in the development of bee swarms 

Locomotion test

1 hour 4 hour

G1 control 7.0 ± 3.1a 7.22 ± 2.5a

G1 control + LD50% 14.31 ± 7.6b 18.37 ± 6.9b

G2 + LD50% 13.13 ± 3.2b 21.13 ± 9.3b

Lowercase letters in the column represent a significant difference between 
the means (P<0.05).
G1: without proteic supplementation; G2: supplemented with 25% crude protein.

Table 2.  Locomotion (seconds) of honeybees Apis mellifera 
Africanized supplemented or not with 25% of crude protein and 
challenged or not with LD 50% of fipronil.

Supplementation did not influence the protein content 
of the hemolymph of bees compared to the control (Table 3).

Discussion

In the present study, an average intake of 17.6% of 
the protein diet supplied to the bee swarms was found, 
corresponding to a 5% intake of the supplied protein. Therefore, 
the bees supplemented with the protein feed in the field 
consumed what they needed for their protein needs, which 
was approximately 25% crude protein (Manning, 2016) because 
the protein content found in the bee bread harvested from the 
experimental swarms was 20%.

Although bees can receive their protein needs by foraging 
floral resources, such as pollen, the protein concentration 
varies depending on the region and plant variability near the 
apiary (Forcone et al., 2011). Thus, protein supplementation 
is important in beekeeping, especially during the off-season 
period, to help the swarms balance their nutritional needs. Bees 
can balance their diets to meet their needs (Hendriksma & Shafir, 

Hemolymph

G1 G2

18.20 ± 0.36a 18.52 ± 0,60a

Lowercase letters in the column represent a significant difference between 
the means (P<0.05).
G1: without proteic supplementation; G2: supplemented with 25% crude protein.

Table 3. Protein content in hemolymph of nursing honeybees Apis 
mellifera Africanized supplemented or not with 25% of crude protein.



Sociobiology 68(3): e5830 (September, 2021) 5

and is a management practice that beekeepers should adopt, 
especially during the off-season period when the natural 
bee forage is reduced. However, this supplementation did 
not influence the survival of bees when exposed to the 
agrochemical fipronil, which proved to be toxic for honey 
bees and promoted changes in their locomotion.

Acknowledgment

This work was funded by the Research Support 
Foundation of the State of São Paulo – FAPESP (Process 
2017/05695-8).

Authors’ Contributions

IRCM: conceptualization, methodology and formal analysis, 
writing and editing
ROO: conceptualization, methodology and formal analysis, 
writing and editing
DCBB: writing and editing
JSL: writing and editing

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