DOI: 10.13102/sociobiology.v65i2.2670Sociobiology 65(2): 312-319 (June, 2018) 

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

Niche overlap and daily activity pattern of social wasps (Vespidae: Polistinae) in kale crops

Introduction

Insects from the Vespidae family, order Hymenoptera, 
popularly known by wasps, include species with solitary or 
eusocial habits. Social wasps comprise three subfamilies 
(Stenogastrinae, Polistinae and Vespinae) (Carpenter & Marques, 
2001). Wasps from the subfamily Polistinae are the only social 
species that occur in Brazil and belong to three tribes, Polistini, 
Mischocyttarini and Epiponini, representing 21 genera and 343 
species (Hermes et al., 2017).

Social wasps forage to find water for nests and cooling, 
for plant fibers for nest materials, and for carbohydrates, such 
as pollen and nectar, for adult and larval nutrition (Raveret-
Richter, 2000; Lima & Prezoto, 2003; Clemente et al., 2017). 
In addition, they forage for animal protein, especially insects 

Abstract 
Kale (Brassica oleraceae var. acephala) is of great importance in human nutrition 
and local agricultural economies, but its growth is impaired by the attack of several 
insect pests. Social wasps prey on these pests, but few studies report the importance 
of this predation or the potential use of wasps as biological control for agricultural 
pests. This study aimed to survey the species of social wasps that forage in kale 
(B. oleraceae var. acephala), recording the influence of temperature and time of 
day on the foraging behavior of these wasps. The research was conducted at the 
Federal Institute of Education, Science and Technology of Minas Gerais - Bambuí 
Campus, from July to December 2015, when twelve collections of social wasps that 
foraged on a common area of kale cultivation were made, noting the temperature 
and time of collection for each wasp. Polybia ignobilis, Protonectarina sylveirae and 
Protopolybia sedula were the most common wasp species foraging in fields of kale. 
Interspecific interactions between wasp species did not affect their coexistence 
within kale fields, with peak foraging occurring between 1000 and 1100 hours. 
Social wasps are important predators of herbivorous insects in the agricultural 
environment and the coexistence of a great diversity of these predators can 
help control pest insects that occur in the crop. Moreover, knowing factors that 
influence foraging behaviors of common wasp species that occur in this crop is 
important for effective use of these insects in the biological control of pests.

Sociobiology
An international journal on social insects

GC Jacques¹,², TG Pikart³, VS Santos³, LO Vicente², LCP Silveira¹

Article History

Edited by
Gilberto M. M. Santos, UEFS, Brazil
Received                      23 November 2017
Initial acceptance       19 December 2017
Final acceptance         07 February 2018
Publication date         09 July 2018

Keywords 
Biological control, foraging, Polistinae.

Corresponding author
Gabriel de Castro Jacques
Departamento de Entomologia - 
Universidade Federal de Lavras 
Av. Doutor Sylvio Menicucci, 1001, Kennedy
CEP 37200-000, Lavras-MG, Brasil. 
E-Mail: gabriel.jacques@ifmg.edu.br

from the orders Diptera, Hemiptera, Hymenoptera, and 
Lepidoptera, which comprise about 90-95% of captured prey 
(Prezoto et al., 2005; Bichara-Filho et al., 2009). These prey 
are torn, macerated and fed to larvae, being the main source of 
protein for social wasps in their early stages of development 
(Rabb & Lawson, 1957; Jeanne et al., 1995; Gomes et al., 2007). 
Nutrients, carbohydrates and proteins, can be stored inside the 
cells for later consumption, constituting a reserve for unfavorable 
periods (Barbosa et al., 2017; Michelutti et al., 2017).

Foraging activity is one of the most important and 
complex behaviors exhibited by social wasps (Lima & Prezoto, 
2003) and it depends on the insects’ ability to interact with the 
environment, as well as the availability of essential resources 
to support the colony (Gomes et al., 2007). These wasps, like 
other generalists, forage predominantly on the most abundant 

1 - Universidade Federal de Lavas, Minas Gerais, Brazil 
2 - Instituto Federal de Educação, Ciência e Tecnologia de Minas Gerais, Campus Bambuí-MG, Brazil
3 - Universidade Federal do Acre, Rio Branco-AC, Brazil

RESEARCH ARTICLE - WASPS



Sociobiology 65(2): 312-319 (June, 2018) 313

resource, without preference or selective behavior (Raveret-
Ritcher, 2000; Santos et al., 2007). However, these wasps may 
return to hunt in locations of previous successful predation 
activity and feed several times on the same prey species, 
with individuals acting as facultative specialists (Raveret-
Richter, 2000; Bichara-Filho et al., 2009). In general, higher 
temperatures, higher light intensity, lower humidity and lower 
wind speed are favor foraging conditions (Lima & Prezoto, 
2003; Ribeiro-Junior et al., 2006).

Kale (Brassica oleraceae var. acephala) belongs 
to the Brassica family, which has the most oleaceous 
species, totaling 14 vegetables (Filgueira, 2008), and is of 
great importance to human nutrition, as they exhibit good 
adaptation to a variety of climates (Filgueira, 2008). Several 
species of insect pests attack kale, such as the whitefly, 
Bemisia tabaci (Genn.) (Hemiptera: Aleyrodidae), and the 
aphids Brevicoryne brassicae (L.) and Myzus persicae Sulzer 
(Hemiptera: Aphididae) (Galo et al., 2002). These insects 
weaken plants by sucking sap and introducing toxins into 
their vascular system, causing leaf tissue deformations and 
gall formation, as well as contributing to the appearance of 
sooty mold on the foliage through honeydew excretion (Galo 
et al., 2002; Van Emden, 2013).

Several Lepidoptera also attack kale crops, such as 
the black cutworm Agrotis ipsilon (Hufnagel) (Noctuidae), 
the cabbage looper Trichoplusia ni (Hübner) (Noctuidae), the 
cabbage caterpillar Ascia monuste orseis (Godart) (Pieridae) 
and the diamondback moth Plutella xylostella(L.) (Plutellidae) 
(Gallo et al., 2002). A. monuste orseis and P. xylostella 
constitutes key-pests of this crop in the Neotropical region, 
mainly in Brazil (Maranhão et al., 1998; Barros & Zucoloto, 
1999). These species larvae feed on the leaves (Gallo et al., 
2002), resulting in losses of up to 100% of crop production 
(Vendramim & Martins, 1982; Chen et al., 1996). 

The control of kale pests is mainly carried out by the 
application of insecticides (Gallo et al., 2002; Andrei, 2013). 
These synthetic chemicals can lead to a number of problems, 
such as residues in food, the death of natural enemies, 
poisoning of the applicators, and the emergence of resistant 
pest populations. Therefore, the use of biological control 
agents could be an effective, cheap and safe alternative to the 
use of these toxic products.

Social wasps have been recorded preying on kale pests 
(Picanço et al., 2010), however few studies report the importance 
of this predation or potential for the use of wasps in the biological 
control of agricultural pests (Rabb & Lawson, 1957; Morimoto, 
1961; Prezoto & Machado, 1999a,b; Freitas et al., 2015).

This research aimed to survey the species of social 
wasps that forage in kale (B. oleraceae var. acephala) crops, 
recording the influence of temperature and time of day on 
the foraging activity of these wasps and the temporal niche 
overlap of this community. With these data, we can identify 
which species have the greatest potential to be used in 
biological control programs for kale pests. 

Material and Methods

This research was carried out at the Federal Institute 
of Education, Science and Technology of Minas Gerais - 
Bambuí Campus, from July to December 2015. The campus 
has a total area of 328 ha, being a human dominated but 
diverse landscape with a predominance of agricultural areas 
and buildings. A total of 175 ha are used for agricultural 
crops (corn, beans, sugarcane, orange, banana, coffee and 
vegetables) and pastures, and 34 ha are occupied by buildings, 
most of them are close to the cultivars. The campus has a 
high diversity of social wasps, with 29 species and 8 genera 
(Jacques et al., 2015).

Twelve collections were carried out in a 5 x 10 m area 
of kale (B. oleracea var. acephala) (Adapted from Picanço 
et al., 2010) between the period from 09h00 to 15h00, in 
which the social wasps that were foraging on the crop were 
collected with an entomological net, placed in a bottle 
containing ethyl ether and preserved in 70% ethanol (adapted 
from Souza et al., 2013). The time and temperature of the day at 
the time of collection of each wasp were recorded throughout the 
experiment to be correlated with the foraging activity. Collection 
data were used to analyze the daily patterns of activity, diversity, 
dominance and temporal niche overlap of social wasp species.

The collected individuals were identified with 
entomological keys (Richards, 1978; Carpenter, 2004), 
and the diversity of species calculated via Shannon-Wiener 
diversity (H’) and Berger-Parker dominance (Dpb) indices, 
using the program Past, v. 2.17c (Hammer et al., 2005).

Temporal niche overlap for each possible pair of wasp 
species was determined using the Schoener index (Schoener, 
1986). The Kolmogorov-Smirnov test for two samples was 
used to evaluate the interspecific differences between activity 
patterns for each pair of species (Siegel, 1956). Temporal 
niche overlap was calculated only for species of social wasps 
represented in the samples by more than eight specimens to 
minimize the effect of low abundance on the essay.

The results of the regression analysis were performed 
for the foraging frequency of the wasps, taking into account 
the variables “air temperature” and “time of day” with p <0.05 
(Picanço et al., 2010). For all species, it was considered the 
linear regression model or the model with quadratic effects. 
The selection of the best model was performed based on the 
determination coefficient. The assumptions of the model 
were verified through graphical analysis and through the 
Shapiro-Wilk, Durbin-Watson and White tests to verify error 
normality, residual autocorrelation and variance heterogeneity, 
respectively. All analyzes were conducted in the 3.3.1 version 
of R software (R Core Team, 2017). For the Durbin-Watson 
test, the lmtest package was used (Zeileis & Hothorn, 2002).

Results and Discussion

Three hundred and fifty-eight specimens belonging 
to six genera and 16 species of social wasps were collected 



GC Jacques, TG Pikart, VS Santos, LO Vicente, LCP Silveira – Social wasps (Vespidae: Polistinae) in kale crops314

in kale crops with a Shannon-Weiner diversity of H' = 1.84 
(Table 1). The species diversity was similar to visitation in 
cherry trees (Eugenia uniflora Linnaeus) (Souza et al., 2013) 
and higher than other studies which analyzed only one species 
of plant (De Souza et al., 2010; Santos & Presley, 2010; De 
Souza et al., 2011; Barbosa et al., 2014).

Social wasps flew over the crop and explored the kale 
plants, especially those with damaged leaves. This foraging 
behavior may be related to the presence of A. monuste orseis, 
B. brassicae and B. tabaci in kale plants. These pests belong 
to the orders of insects that are most captured by the social 
wasps (Prezoto et al., 2005; Bichara-Filho et al., 2009; Freitas 
et al., 2015). The presence of leaves damaged by herbivores 
in herbaceous plants attracted Polybia occidentalis (Olivier), 
Polybia diguetana Buysson and Polybia fastidiosuscula 
Saussure (Saraiva et al., 2017). Tobacco plants previously 
damaged by Manduca sexta (L.) (Lepidoptera: Sphingidae) 
and Trichoplusia ni (Hübner) (Lepidoptera: Noctuidae) attracted 
more foraging individuals from Mischocyttarus flavitarsis (de 
Saussure) than non-damaged plants (Cornelius, 1993).

Assumptions of error normality, autocorrelation and 
variance heterogeneity were met in all adjusted models, 
considering the graphical analysis and the appropriate usage 
of the tests (results not shown).

The foraging behavior of the social wasps was related 
to the timeof day (p = 0.025) with the maximum number 

of wasps collected between 1000 and 1100 hours (Fig 1). 
Results similar to those found in cashew trees (Anacardium 
occidentale L.) (Anacardiaceae), with greater foraging 
between 0900 and 1200 hrs (Santos & Presley, 2010). The air 
temperature directly affects foraging behavior of social wasps 
(Santos et al., 2009; De Castro et al., 2011), with foraging 
occurring mainly during warmer times of day (Picanço et al., 
2010; Barbosa et al., 2014), however air temperature was not 
an effective predictor of wasp activity (p = 0.2184). Other 
factors not analyzed, such as the amount of light, wind speed 
and humidity, also affect foraging behavior (Santos et al., 
2009; De Castro et al., 2011).

 There was high dominance (Dbp = 0.41), with Polybia 
ignobilis (Haliday) (N= 147), Protonectarina sylveirae 
(Saussure) (N= 80) and Protopolybia sedula (Saussure) (N= 
41) representing 75% of the total sampled individuals. The 
other most frequently collected species were Polybia paulista 
(R. von Ihering) (N= 22), P. occidentalis (N= 15), Polistes 
satan (Bequaert) (N= 12), Brachygastra lecheguana (N= 
11), Polistes versicolor (Olivier) (N= 9), Mischocyttarus 
drewseni (Saussure) (N= 8) and Polybia sericea (Olivier) (N= 
4). Mischocyttarus latior (Fox), Polistes simillimus (Zikán) 
and Polybia jurinei (Saussure) (N= 2) and Mischocyttarus 
labiatus (Fabricius), Polistes ferreri (Saussure) and Polybia 
fastidiosuscula (Saussure) (N= 1) were uncommon and 
considered of accidental occurrences.

Species 09:00 10:00 11:00 12:00 13:00 14:00 15:00 Total

1 Brachygastra lecheguana (Latreille, 1824) 3 4 1 2 1 - - 11

2 Mischocyttarus drewseni (Saussure, 1857) 1 1 - 2 2 1 1 8

3 Mischocyttarus labiatus (Fabricius, 1804) - - 1 - - - - 1

4 Mischocyttarus latior (Fox, 1898) - - - 1 - 1 - 2

5 Polistes ferreri (Saussure, 1853) - - - 1 - - - 1

6 Polistes simillimus (Zikán,1951) - 1 1 - - - - 2

7 Polistes versicolor (Olivier, 1971) - - 3 1 1 3 1 9

8 Polistes satan (Bequaert, 1940) 1 1 2 4 3 1 - 12

9 Polybia fastidiosuscula (Saussure, 1854) - 1 - - - - - 1

10 Polybia ignobilis (Haliday, 1836) 28 29 22 23 21 19 5 147

11 Polybia jurinei (Saussure, 1854) - - 1 - 1 - - 2

12 Polybia occidentalis (Olivier, 1971) - 5 1 2 6 1 - 15

13 Polybia paulista (R. Von. Ihering, 1896) 2 7 4 3 4 2 - 22

14 Polybia sericea (Olivier, 1971) - 2 2 - - - - 4

15 Protonectarina sylveirae (Saussure, 1854) 16 17 13 13 11 8 2 80

16 Protopolybia sedula (Saussure, 1854) 8 4 4 4 7 11 3 41

Number of individuals 59 72 55 56 57 47 12 358

Species richness (S’) 7 11 12 11 10 9 5 16

Shannon-Wiener index (H’) 1,35 1,78 1,85 1,81 1,88 1,58 1,59 1,84

Berger-Parker dominance (Dpb) 0,48 0,40 0,40 0,41 0,36 0,41 0,38 0,41

Table 1. Number of individuals, species richness (S’), Shannon-Wiener diversity (H’) and Berger-Parker dominance (Dpb) of the collected 
social wasps, per hour, in twelve collections made in kale (Brassica oleracea var. acephala) at the Federal Institute of Education, Science and 
Technology of Minas Gerais (IFMG), Bambuí Campus, Minas Gerais.



Sociobiology 65(2): 312-319 (June, 2018) 315

Polybia ignobilis is the main predator of A. monuste 
orseis (Picanço et al., 2010), and the predation of this wasp 
on the cabbage caterpillarswas recorded (Fig 2). Thus, the 
presence of this pest may have stimulated the greater presence 
of P. ignobilis in the crop. Social wasp workers forage alone 
and opportunistically (Jeanne et al., 1995; Michelutti et al., 
2017), being able to return to hunt in locations of previously 
successful hunts and feeding several times of the same species 
of prey (Raveret -Richter, 2000; Bichara-Filho et al., 2009). 
To optimize this form of foraging, signals can be exchanged 
among workers to facilitate the acquisition of resources for 
the colony (Taylor et al., 2011). This behavior was reported 
in colonies of P. occidentalis (Hrncir et al., 2007; Schueller 
et al., 2010).

Species of the genus Polybia (Lepeletier) are also 
dominant in cashew, mango (Mangifera indica L.) and cherry 
trees (Santos & Presley, 2010; Souza et al., 2013; Barbosa et 
al., 2014). Wasps of this genus form large colonies, founded 
by a swarm composed of dozens of queens and hundreds of 
workers, which makes their local abundance greater than that 
of species whose colonies can be founded by one or a few 
wasps (Barbosa et al., 2014).

The highest number of P. ignobilis was found at 
0930 h, using a quadratic model for time of day (Fig 3A), 
different from that observed in the same crop in Viçosa/MG, 
where the highest foraging occurred at 1330 h (Picanço et al., 
2010). Through a linear model for the air temperature it was 
observed that the amount of P. ignobilis individuals tended 
to decrease with increasing temperature (Fig 3B). In Viçosa/
MG the result was similar, with the number of individuals 
increasing up to 29ºC, and decreasing after this temperature 
(Picanço et al., 2010). Time of day was a better predictor than 
temperature and accounted for 87% of the variation in mean 
P. ignobilis abundance (Fig 3). Higher temperatures occur 
after the period of greatest foraging for predation, 0930 h, 
thus we find a smaller number of individuals after this time 
of day. In the period of higher temperatures, the wasps are 
concentrated in the collection of water to cool the colony 
(Akre, 1982; Montefusco et al., 2017).

Fig 1. Effect of time of day on average number of social wasps 
foraging in kale (Brassica oleraceae var. acephala) from July to 
November 2016, in Bambuí, MG.

 

Time of day 

W
as

ps
 

Fig 2. Social wasp Polybia ignobilis (Hymenoptera: Vespidae) 
preying on Ascia monuste orseis (Lepidoptera: Pieridae) on a kale 
plant (Brassica oleracea var. acephala).

 

Time of day 

Air Temperature (ºC) 

M
ea

n 
ab

un
da

nc
e 

of
 P

ol
yb

ia
 ig

no
bi

lis
 

M
ea

n 
ab

un
da

nc
e 

of
 P

ol
yb

ia
 ig

no
bi

lis
 

Fig 3. Average number of wasps of Polybia ignobilis (Hymenoptera: 
Vespidae) foraging in kale plants (Brassica oleracea var. acephala) 
as a function of: A -timeof day and; B - air temperature, from July to 
November 2016 in Bambuí, MG.

The quadratic model for time of day explained 96% 
of the variation in mean P. sylveirae captures, with peak 
abundance observed early in the day (0900 hr) (Fig 4). This 
time is different from the time found for all species, which 
was between 1000 and 1100hrs. Temperature did not affect 
P. sylveirae abundance. The presence of A. monuste orseis 



GC Jacques, TG Pikart, VS Santos, LO Vicente, LCP Silveira – Social wasps (Vespidae: Polistinae) in kale crops316

may attract P. sylveirae, as this is a common prey species of 
P. sylveirae (Bueno & Souza, 1993). In addition, this species 
preys on Hemiptera such as Aleurothrixus floccous (Maskell) 
(Hemiptera: Aleyrodidae) (Souza & Zanuncio, 2012), probably 
being attracted by the presence of B. brassicae and B. tabaci. 

on A. floccous (Souza & Zanuncio, 2012) and probably is also 
attracted by the presence of B. brassicae and B. tabaci.

The temporal niche overlap between pairs of species 
of social wasps varied between 0.31- 0.96 (Schoener index) 
(Table 2), being smaller between B. lecheguana and P. 
versicolor and higher between P. ignobilis and P. sylveirae. 
In general, the activity overlap was relatively high, being greater 
than 50% in 31 of the 36 pairs, and there was no significant 
difference based on Kolmogorov-Smirnov 2-sample tests. 
This high value of temporal niche overlap was also found in A. 
occidentale and E. uniflora (Santos & Presley, 2010; Souza et al., 
2013), suggesting a trend of coexistence among species of this 
group. The agricultural features of the campus, with the presence 
of many crops, and consequently many herbivores, may have 
led to a decrease in interspecific competition allowing greater 
coexistence of wasps in the crop. The division of resources by 
guild members and the resulting competitive structure can only be 
seen if they are maintained over time by competition for limiting 
resources (Pianka, 1980). Moreover, the generalist tendencies of 
social wasps allows them to have low dependence on particular 
food resources (Santos et al., 2007). This dietary flexibility likely 
facilitates coexistence by reducing interspecific competition.

 

M
ea

n 
ab

un
da

nc
e 

of
 P

ro
to

ne
ct

ar
in

a 
sy

lv
ei

ra
e 

Time of day 

Fig 4. Effect of time of day onaverage number of wasps of 
Protonectarina sylveirae (Hymenoptera: Vespidae) species foraging 
in kale plants (Brassica oleracea var. acephala) from July to 
November 2016 in Bambuí, MG.

None of the statistic models fit the data considering 
the time of day for P. sedula. In contrast, observations of 
colonies of this species indicate that peak foraging activity 
occurs between 1030 and 1430 (Detoni et al., 2015). For the 
air temperature, the quadratic regression model was selected, 
in which the minimum number of wasps was obtained around 
29º C (Fig 5). The climatic variables possibly have a low effect 
over the foraging rhythm of this wasp (Detoni et al., 2015). 
The presence of an envelope that protects P. sedula nests can 
generate a certain level of homogenization of the internal 
environment in terms of temperature and humidity, increasing 
the importance of internal colony stimuli when it comes to 
foraging outflows (Detoni et al., 2015). Moreover, this research 
recorded the foraging behavior only in kale, and this species 
may be foraging in another plant species. This species preys 

 

M
ea

n 
ab

un
da

nc
e 

of
 P

ro
to

po
by

bi
a 

se
du

la
 

Air Temperature (ºC) 

Fig 5. Effect of air temperature on average number of wasps of 
Protopobybia sedula (Hymenoptera: Vespidae) species foraging 
in kale plants (Brassica oleraceae var. acephala) from July to 
November 2016 in Bambuí, MG.

 Br. le. Mi. dr. Po. ve. Po. sa. Po. ig. Po. oc. Po. pa. Pr. sy. Pr. se.
Brachygastra lecheguana - NS NS NS NS NS NS NS NS
Mischocyttarus drewseni 0,61 - NS NS NS NS NS NS NS
Polistes versicolor 0,31 0,46 - NS NS NS NS NS NS
Polistes satan 0,62 0,75 0,47 - NS NS NS NS NS
Polybia ignobilis 0,77 0,71 0,54 0,70 - NS NS NS NS
Polybia occidentalis 0,72 0,58 0,36 0,60 0,61 - NS NS NS
Polybia paulista 0,82 0,63 0,49 0,73 0,81 0,77 - NS NS
Protonectarina sylveirae 0,79 0,68 0,51 0,71 0,96 0,62 0,83 - NS
Protopolybia sedula 0,64 0,69 0,65 0,62 0,79 0,50 0,65 0,75 -

Table 2. Temporal niche overlap (Schoener index) among pairs of species of social wasp (species with more than eight individuals) collected in 
kale (Brassica oleracea var. acephala) crops at the Federal Institute of Education, Science and Technology of Minas Gerais (IFMG), Bambuí 
Campus, Minas Gerais. Significance (P≤0.05) for the Kolmogorov-Smirnov test for two samples used to evaluate differences between the patterns 
of temporal activity among pairs of species of social wasps is indicated above the diagonal.



Sociobiology 65(2): 312-319 (June, 2018) 317

We recorded 4 species, M. labiatus, P. ferreri, P. 
fastidiosuscula and P. sylveirae that had not been collected 
previously at the IFMG – Bambuí Campus according to a 
diversity survey of social wasps previously performed by 
Jacques et al. (2015).

Wasp species exhibited similar temporal activity 
patterns in a small patch of kale, suggesting that interspecific 
interactions among these species did not affect their ability 
to coexistence as predators on pest species. Social wasps are 
important predators of herbivorous insects in the agricultural 
environment and the coexistence of a great diversity of these 
can lead to a greater control of the pest insects that occur on 
the crop. Furthermore, knowing the period and the factors that 
influence the foraging of the main species that occur in the 
crop is important for the effective use of these insects in the 
biological control of pests.

Acknowledgements

To the Conselho Nacional de Desenvolvimento Científico 
e Tecnológico (CNPq) for granting a PhD scholarship.

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