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

DOI: 10.13102/sociobiology.v64i4.1936Sociobiology 64(4): 477-483 (December, 2017)

Polistes canadensis (Linnaeus, 1758) (Vespidae: Polistinae) in the Western Amazon: a 
Potential Biological Control Agent

Introduction

Wasps are Hymenoptera that present different 
behaviour, ranging from solitary species to social groups 
with female caste variations (Prezoto et al., 2007). The wasps 
reveal an opportunistic characteristic: they return to places 
with a great supply of resources or food, in search of the 
optimization of the foraging and reduction of the search effort 
(Raveret-Richter, 2000). In general, wasps perform several 
ecological functions; a relevant point among these ecological 
functions is their role as natural enemies, since predatory 
wasps contribute to the regulation of insect populations 
and consequently to the reduction of insecticide use, with 
natural biological control being a significant contribution in 

Abstract
Wasps of the genus Polistes (Vespidae: Polistinae) are eusocial, considered 
valuable biological control agents. The objective of this work was to determine 
the resources collected by Polistes canadensis wasps, evaluate their performance 
and importance as a natural enemy and possible agent of biological control in the 
Brazilian Amazon. Between  October 8th and November 20th, 2014, 20 evaluations 
were performed, totalizing 101 hours of observations of the foraging activity of 
an aggregation out in stage of development post-emergence with approximately 
50 adult individuals distributed in 15 colonies. Additionally, observations of the 
predatory activity of Polistes canadensis on Plutella xylostella on a small organic 
plantation of kale (Brassica oleracea L. var. acephala DC), were also made. During 
the evaluations 1742 returns were recorded, 11.72% of them with prey, 3.10% 
with plant fiber, 16.76% with nectar, 45.17% with water and 23.25% without any 
visible load. All the preys identified were classified as Lepidoptera, belonging 
to ten morphospecies. Only one morphospecies was identified as Spodoptera 
frugiperda, which was the most commonly resource used by the wasps in 37 % in 
immature feeding. Only returns with nectar had statistically significant difference 
between the evaluated schedules.  Polistes canadensis wasps did not prey Plutella 
xylostella caterpillars. The wasp aggregation studied was able to prey an average 
of 10.2 caterpillars per day, which demonstrates the potential of this species for 
the biological control of pests in the Amazon region.

Sociobiology
An international journal on social insects

M Montefusco1, FB Gomes2, A Somavilla1, C Krug2

Article History

Edited by
Gilberto M. M. Santos, UEFS, Brazil
Received       10 August 2017
Initial acceptance      03 October 2017
Final acceptance      13 October 2017
Publication date           27 December 2017

Keywords 
Foraging activity, resources, caterpillars, 
agricultural pests. 

Corresponding author
Matheus Montefusco 
Instituto Nacional de Pesquisas da 
Amazônia (INPA), Programa de Pós-
Graduação em Entomologia
Av. André Araújo  nº 2936, Aleixo 
CEP 69080-971 Caixa-Postal 2223
Manaus-AM, Brasil. 
E-Mail: matheus.montefusco10@gmail.com 

this process (Gallo et al., 2002). They use a large source of 
resources present in the environment: water (used to cool the 
colony); plant fibers (construction and maintenance of the 
colony); nectar and pollen (a rich source of energy) and prey 
(used to feed the immature).

Polistes (Vespidae: Polistinae) is one of the most 
common genus among social wasps (Carpenter, 1996). It 
is a cosmopolitan genus, with 222 valid species distributed 
in all biogeographical zones, except in Antarctica, most of 
which occur in the tropics (Carpenter, 1996; Pickett et al., 
2006). Some authors pointed out the importance of Polistes 
in the regulation of insect-plague populations of crops of 
economic importance and for the facility of manipulation and 
translocation of their colonies to artificial shelters (Figueiredo 

1 - Instituto Nacional de Pesquisas da Amazônia (INPA), Manaus-AM, Brazil  
2 - Empresa Brasileira de Pesquisa Agropecuária (EMBRAPA), Manaus-AM, Brazil

RESEARCH ARTICLE - WASPS

mailto:matheus.montefusco10@gmail.com


M Montefusco et al. – Polistes canadensis: a potential biological control agent478

et al., 2006; Elisei et al., 2010; Prezoto, 1999; Prezoto et al., 
1994; Giannotti et al., 1995; Prezoto & Machado, 1999a, 
1999b; Andrade & Prezoto, 2001). 

The species Polistes canadensis (Linnaeus, 1758), is a 
social wasp found in the New World, with a wide distribution, 
occurring from the southern United States to southern Brazil 
and Argentina (Carpenter, 1996). The nests are established 
by independent foundation, where only one or a few queens 
begin to construct the nest, oviposit and feed the immature 
forms (Wenzel, 1998). They are able to obtain resources at 650 
meters from the colony, but with radius of action of 125 meters, 
foraging in an area of approximately 49,000 m² (Santos et al., 
1994). This species is relatively non-aggressive, which allows 
translocate their nests easily (Marques et al., 1992; Marques, 
1996). The pattern of foundations and dropouts of colonies of 
P. canadensis canadensis occurring all year round, presents 
an asynchronous pattern between nesting and environmental 
variables (Masques et al., 1992; Torres et al., 2009b).

The social wasp P. canadensis presents several 
characteristics which qualifies it as important natural enemies 
of pest insects. Studying aspects related to their foraging 
activity and the resources collected by them, may contribute to 
ecological and agricultural benefits. Therefore, the objective 
with this work was to determine the resources collected by P. 
canadensis and to evaluate their performance and importance 
as a natural enemy and possible agent of biological control.

Material and methods

The experiment was carried out at the experimental field 
of Embrapa Western Amazon called Caldeirão (Fig 1), located 

at coordinates 03º 14’22 “and 03º15’47” south latitude and at 
60º 13’02 “and 60º 13’50” west longitude, in the municipality 
of Iranduba, Amazonas, during the period from October 8 
to November 20, 2014. Were evaluated an aggregation of P. 
canadensis colonies with approximately 50 adult individuals 
distributed in 15 colonies (Fig 2 A). Besides, observations on 
an organic small plantation of kale (Brassica oleracea L. var. 
acephala DC), were also realized. 

Resources collected by Polistes canadensis

In total, 101 hours of observations of foraging activity 
of the aggregation were carried out in stage of development 
the colony post-emergence (Jeanne, 1972). The method used 
in the evaluations was adapted from Prezoto et al. (1994), 
where the identification of the material collected by the wasps 
was carried out by observing the behaviour presented by them 
when they returned to the nest: nectar collection, when there 
were trophallaxis, adult-adult or adult-larvae (Fig 2B); water 
collection (Fig 2C), when the liquid was deposited directly on the 
cell walls; the returns with wood pulp used in cells construction 
(Fig 2D) and returns with prey used in feeding of the immatures 
(Fig 2E, F and G) were identified by the observation of the 
resources in the mouthparts besides the slow flight. 

The evaluation of foraging activities occurred in 16 
non-consecutive days. On each day, the foraging activity was 
observed and registered every 30 minutes, with intervals of 
the same time, during the hours of highest foraging activity 
of the colonies, between 10 am and 15:30 pm. The wasps 
that returned to the colony with some material between 
the jaws were intercepted with the use of entomological 

Fig 1. Location of the Experimental Field of Caldeirão of EMBRAPA Western Amazon, Iranduba, Amazonas, Brazil.



Sociobiology 64(4): 477-483 (December, 2017) 479

net and the material that they carried was collected. The 
preys carried by the wasps were collected and fixed in 70% 
alcohol, inside microtubes. In the Entomology Laboratory of 
Embrapa Western Amazonia the samples were screened using 
a stereomicroscope equipped with a camera and categorized 
in morphospecies, based on corporeal structures such as 
cephalic capsule, pseudopodia and seta, according to Elisei 
et al. (2010). Some data on atmosphere conditions such as 
mean temperature, relative air humidity, precipitation and 
wind speed were obtained at the weather station of the same 
experimental field.

Based in an empirical knowledge that P. canadensis 
could be a regulated agent of Plutella xylostella (Linnaeus, 
1758), during the intervals between evaluations of foraging 
activity (every 30 minutes), some observations of this expected 
predatory activity were performed. Two small kale plantation 
measuring 6m long and 1m wide were observed, each 
plantation had 20 plants in 2.8 liter pots, spaced 50 x 50cm, 
distant approximately 12m from the wasps colonies evaluated. 
The plantations were covered with voile cloth to ensure the 
fixation and spread of P. xylostella insects that were later 
released. The observations were made very close to the plants 
allowing the record of the predatory action of the wasps and 
their foraging behaviour.

Data analysis

Variance analysis (ANOVA) and a Tukey’s post-
test (5% significance) were done in order to compare the 
data collected by the wasps in every 30 minutes per hour 
observed. The analyses were performed with R Core team 
software (2017).

Results and discussion 

Polistes canadensis foraging wasps presented 
homogenously return activity with resources practically at all 
times evaluated, with no peaks of returns (Table 1). In total, 
1742 returns of foraging wasps to the colonies were recorded 
during this study. Of these returns, 45.17 % were returns with 
water, 11.72 % with prey, 3.10 % with vegetal fiber, 16.76 % 
with nectar and 23.25 %, returns were considered frustrated 
based on behavior during the arrival at the colony. Following, 
these returns will be better evaluated individually.

Resources collected by Polistes canadensis

Water: Most of the recorded returns during the 
evaluations were identified as water 45.17 % (N = 787).  

Assessments Water Prey Fiber Nectar Frustaded

10:00-10:30 h 7.37±5.61 A 1.62±1.58 A 0.5±0.83 A 3.81±2.26 A 3.93±2.95 A

11:00-11:30 h 7.06±4.40 A 2.25±1.61 A 0.37±0.5 A 2.62±1.96 A 4.12±2.44 A

12:00-12:30 h 8.12±6.11 A 1.75±1.73 A 0.62±0.80 A 3.12±1.66 AB 3.62±2.5 A

13:00-13:30 h 5.87±5.09 A 1.81±1.47 A 0.25±0.44 A 1.81±2.00 AC 3.18±3.35 A

14:00-14:30 h 7.5±6.11 A 1.68±1.13 A 0.37±0.61 A 2.25±1.65 A 4.31±2.62 A

15:00-15:30 h 6.43±5.98 A 2.18±1.60 A 0.5±0.81 A 1.18±1.37 CD 2.93±2.37 A

Table 1.  Average and standard error of returns with water, prey, plant fiber, nectar and frustrated returns of the foragers of Polistes canadensis. 
Values followed by the same letter in the column do not differ from each other, by the Tukey test at 5% significance.

This resource was provided to the immature or divided 
between the wasps and placed inside the cells, mainly with 
immature ones, being also deposited in the back part of the 
colonies. The water is used to cool the colony and is collected 
by the foragers in large quantity, mainly in hours with higher 
temperature (Akre, 1982; Greene, 1991). The effort employed 
by P. canadensis in the collection was higher than compared to 
other species of Polistes: P. simillimus, P. versicolor, P. lanio, 
in studies conducted on days with temperature between 22 
and 35°C (eg: Prezoto & Machado 1999a; Prezoto et al., 1994; 
Elisei et al., 2010; Giannotti et al., 1995). The large amount 
of water collected shows that the availability of this resource 
nearby the colonies is fundamental for the maintenance of the 
nest microclimate and colony equilibrium.

Preys: 11.72 % (N = 204) of worker wasps returns were 
recorded as returns with preys. The behavior presented by the 
wasps as soon as they arrived at the colony was to remain still 
while chewing the prey. After a few moments, the macerate 

was divided with other wasps, which later fed the larvae. This 
same behavior was recorded and described by Torres et al. 
(2009a) for this same species of wasp. An average of 10.2 
returns with prey per day was recorded, a similar value to this 
one was found by Prezoto et al. (2006) for P. versicolor and 
Prezoto et al. (1994) for P. simillimus, with averages of 11 
and 16.9 returns with preys per day. These results demonstrate 
the potential of P. canadensis as a biological control agent, 
when compared to the previously mentioned species, as a 
controlling agent of herbivores of agricultural importance 
(Elisei et al., 2010; Prezoto & Machado, 1999b). 

Preys captured by P. canadensis: was possible to 
characterize 49 % (N = 100) of the prey captured by the size, 
color and body structures, for 51 % (N = 104) of the preys 
specimens, the identification was not possible due to the high 
level of maceration of the samples. All samples with possible 
identification were classified as immature of Lepidoptera order, 
being categorized as belonging to 10 different morphospecies 



M Montefusco et al. – Polistes canadensis: a potential biological control agent480

Fig 2. A – Evaluated colonies of Polistes canadensis.; B- Nectar collection, when there were trophallaxis adult-
larvae.; C- Water collection.; D- Gathering of vegetable fiber in the vicinity of the colonies.; E and F returns with 
prey used in feeding of the immatures.; G- Prey being shared.



Sociobiology 64(4): 477-483 (December, 2017) 481

(Fig 3). Only one morphospecies was identified, as Spodoptera 
frugiperda (Smith, 1797) (morphospecies 1), which was the most 
commonly resource used by the wasps in 37 % in immature 
feeding. Caterpillars (Lepidoptera) are the major food source 
to the immature of P. canadensis and other species of this 
genus (Prezoto et al., 1994; Giannotti et al., 1995; Andrade & 
Prezoto, 2001; Torres et al., 2009a). In other studies showing  
the efficiency of Polistes spp. As a predator, wasps were also 
related to the predation of large caterpillars, such as S. frugiperda 
predated by P. simillimus (Prezoto & Machado, 1999a) and 
Chlosyne lacinia saundersii  Doubleday & Hewitson, 1849 
predated by P. versicolor (Prezoto et al., 2006). Considering 
the agricultural importance of the fall armyworm S. frugiperda 
and the resistance presented by the insect to both insecticides 
(Omoto & Diez-Rodriguez, 2001) and transgenic crops (Farias 
et al., 2014), a biological control agent stands out as a great 
option in the management this pest. From the results obtained 
with this study, it can be estimated that an aggregation of a 
colony containing 50 individuals is able to prey on an average 
of 10.2 caterpillars per day, which demonstrates the potential 
of P. canadensis as a biological control agent, including the 
possibility of agent control of  the armyworm S. frugiperda. 

Plant fiber: 3.10 % (N = 54) of the foraging wasps 
returns were characterized as returns with fibers of vegetal 
material. Approximately 60 % (N = 34) of the foragers 
returning to the colony with fibers, divided this resource with 
other wasps, which later deposited it in the cells, mainly with 
immature ones. The objective of this activity and behavior 
is probably due to the need to increase the height of the 
cells, as a function of immature development, as proposed 
for this species by Torres et al. (2009a) and for other species 
of the genus, such as P. lanio (Giannotti et al., 1995) and P. 
versicolor (Zara & Balestieri, 2000).

Trophallaxis: 16.76 % (N = 292) of the returns were 
considered as returns with nectar to the colony followed by 
trophallaxis. The foraging wasps performed the behavior 
considered as trophallaxis when they returned to the colony, 
apparently with no visible recourse between mouthparts, but 
always followed, soon after, by trophallaxis with the immature 
or with the adult present at the colony. Elisei et al. (2010) 
quantified this behavior associated with the nectar collection 
for P. versicolor in 51.6 % (934) and Andrade & Prezoto 
(2001) in 54.2 % for P. ferreri in the post-emergence period. 
Yet Prezoto et al. (1994) quantified a lower percentage to P. 
simillimus (28.5 %). And Torres et al. (2009a), studying the 
division of labor of 15 colonies of P. canadensis under natural 
conditions in Mundo Novo, Mato Grosso do Sul, showed that 
35% of returns of wasps were with nectar. The percentage 
of returns with nectar followed by trophallaxis in this study 
was lower than the others mentioned previously, however, 
the differences of species, biome and experimental conditions 
prevent further generalizations or conclusions in this respect.

Frustrated returns: Practically ¼ of the returns (23.25 
%, N = 405) were considered frustrated, in other words, without 

any behavior or apparent material or prey at the return, 
performing an efficient foraging index of 76.75 %. Similar 
value was found by Prezoto et al. (1994) and Elisei et al. 
(2010) for P. simillimus and P. versicolor, with 72.93 % and 
80.13 % returns with resources.

Foraging activity 

The average of returns with prey at the different times 
did not present significant differences (Table 1). Foraging 
wasps collected prey at all times evaluated. Despite the post-
emergence development stage of the 15 colonies assessed, 

Fig 3. Caterpillar morphospecies collected through flight interception of  
P. canadensis returning to the colony: A- Spodoptera frugiperda (N = 
37) (Morphospecies 1); B- Morphospicies 2 (N = 7); C- Morphospecies 
3 (N = 3); D- Morphospecies 4 (N = 6); E- Morphospecies 5 (N 
= 3); F- Morphospecies 6 (N = 15); G- Morphospecies 7 (N = 2); 
H- Morphospecies 8 (N = 18); I- Morphospecies 9 (N = 4); J- 
Morphospecies 10 (N = 5).



M Montefusco et al. – Polistes canadensis: a potential biological control agent482

plant fiber was the least used resource, approximately 3.1 %, 
with no difference between the 30-minute evaluations (Table 
1). Return with nectar was the only resource with statistically 
significant difference between the evaluated schedules (p = 
0.001). Although there was a tendency to decrease the amount 
of nectar returns, a significant difference was observed only 
in the half hour evaluations performed from 12:00 to 12:30, 
13:00 to 13:30 and 15:00 to 15:30 (Table 1). The production 
and availability of floral resources, such as nectar, may be 
directly related to the number of floral visitors/pollinators 
visited during the day (Waddington, 1983). Therefore, the 
decrease in the amount of nectar returns may be related to the 
availability of this resource in the environment. Water was 
the most used resource, also with no significant difference. 
According to Torres et al. (2009a), P. canadensis collects more 
water at temperatures above 22°C. During our evaluations of 
the foraging activity, the temperature was higher than that, 
ranging from 23.85 to 35.29ºC, with an average of 26.59ºC 
and a standard deviation of 2.90ºC, therefore, requiring a large 
amount of water returns to maintain the thermal comfort of the 
colonies. There was also no significant difference in frustrated 
returns, showing that the resources used by P. canadensis are 
available throughout all the period studied. 

Predatory activity of P. canadensis on P. xylostella 

During the evaluations of the foraging activity of P. 
canadensis in the small plantation of kale, the predation of 
P. xylostella caterpillar wasn’t observed. However, other social 
wasps of the genus Polybia, which were collected and identified 
as P. bistriata, P. rejecta and P. sericea, preyed P. xylostella in 
small amounts. P. canadensis wasps were frequently observed 
above the kale plants seeking drops of water and predating 
another larger caterpillar species identified as Pieridae family, 
which used kale as host. Most of the P. canadensis wasps 
observed in kale presented the behavior of removing the 
cephalic capsule from the caterpillar. In addition, cephalic 
capsules of caterpillars were also found on kale leaves, 
possibly predated by this species or other social wasps.

Conclusion 

In several regions of the Amazon, the advance 
of agriculture is undeniable and crescent, thought this 
activity presents great gaps in the knowledge of sustainable 
agricultural practices adapted to the local reality, especially 
in the phytosanitary area. For this reason, the biological 
control with predatory wasps is an excellent strategy for the 
Amazon, in order to regulated the pest insect population, 
reducing the use of insecticides and consequently reducing 
the environmental impacts.

The species P. canadensis is widely distributed in the 
new world, showed intense foraging activity and generalist 
habit of predation for the selection of caterpillars in the Amazon 

region studied, predating caterpillars of several species and 
preferring larger caterpillars. Due to the high index of captured 
prey and the intense foraging activity, this species should be 
considered as a potential species for the biological control of 
agricultural pests in crops in the Amazon region.

Acknowledgements

To FAPEAM and EMBRAPA (03.13.00.012.00.00) 
for the financing of the Project and to Marinice Cardoso for 
leading the bigger project. CNPq (150029/2017-9) for the 
posdoctoral scholarship (PDJ) to AS.

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