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

DOI: 10.13102/sociobiology.v65i2.2844Sociobiology 65(2): 291-298 (June, 2018)

Influence of Food Resource Size on the Foraging Behavior of Nasutitermes corniger 
(Motschulsky)

Introduction

Termite foraging is a group activity composed of 
individual actions integrated with patterns organized towards a 
new food source, which involves communicating the location of 
the source to other members of the colony using chemical and 
tactile signals that stimulate the foragers to leave the nest and 
guide them to the discovered food (Traniello & Busher, 1985; 
Traniello & Leuthold, 2000; Costa-Leonardo, 2002; Andara et 
al., 2004). This activity comprises recruitment and aggregation 
events of individuals that can change over time and, therefore, is a 
dynamic process governed by the nutritional requirements of the 
colony and quantity and/or quality of available food resources, 

Abstract  
In general, termite foraging can be affected by physical and chemical factors 
linked to food. This study investigated if the wood length of Eucalyptus grandis 
W. Hill ex Maiden, as a food resource, influences the behavior of foraging events 
of Nasutitermes corniger (Motschulsky). Nests with mature and active colonies 
were collected in the field and transferred to glass cubes connected to a test 
arena under laboratory conditions. Wooden blocks of E. grandis, with a 2.5 x 2.0 
cm rectangular cross section, were offered to termites in three different lengths: 
5, 10 and 15 cm. Each test was repeated with 20 nests and lasted 60 minutes, 
when the following behavioral events and their duration were observed: initial 
exploration, initial recruitment and mass recruitment. At the end of each test, the 
quantities of termites (total, workers and soldiers) and gnawing workers were 
determined. The results show that longer blocks favored a higher occurrence 
of exploration and initial recruitment. However, the highest mass recruitment 
occurred with the 10 cm blocks. The length of the wood influenced the total 
number of termites recruited and gnawing workers; both were highest for the 
10 cm blocks. There was no significant difference in relation to exploration time 
of the blocks and number of workers and soldiers recruited. Therefore, we 
conclude that wood length is a factor that can affect N. corniger foraging.

Sociobiology
An international journal on social insects

TS Souza1, VS Gazal1,2, VJ Fernandes1, ACC Oliveira3, EL Aguiar-Menezes1,2

Article History

Edited by
Alexandre Vasconcellos, UFPB, Brazil
Received                         11 January 2018
Initial acceptance        19 March 2018
Final acceptance        04 April 2018
Publication date             09 July 2018

Keywords 
Arboreal termites, Nasutitermitinae, 
Eucalyptus grandis, foraging behavior, 
recruitment pattern.

Corresponding author
Thiago Sampaio de Souza
Postgraduate Program in Phytosanitary 
and Applied Biotechnology
Federal Rural University of Rio de Janeiro
Rodovia BR 465, km 7, Bairro UFRRJ
Zip Code: 23897-000, Seropédica
Rio de Janeiro, Brasil.
E-Mail: thiagosampaio.agro@gmail.com

as observed in some species of the genus Nasutitermes Dudley 
(Traniello & Busher, 1985; Traniello & Leuthold, 2000; Andara 
et al., 2004; Gazal et al., 2014a, b).

The arboreal termite Nasutitermes corniger (Motschulsky) 
is widely distributed in Meso-America, from southern Mexico 
to Panama, and South America (Atkinson & Adams, 1997; 
Torales, 2002; Constantino, 2002; Scheffrahn et al., 2005). In 
the last decades, N. corniger has become of great economic 
importance due to increasing reports of damage to residences 
in various Brazilian and Argentinian cities, which have 
confirmed its status as a pest (Mill, 1991; Menezes et al., 
2000; Constantino, 2002; Costa-Leonardo, 2002; Fontes & 
Milano, 2002; Torales, 2002; Albuquerque et al., 2012).

1 - Programa de Pós-Graduação em Fitossanidade e Biotecnologia Aplicada, Universidade Federal Rural do Rio de Janeiro (UFRRJ), 
Seropédica-RJ, Brazil
2 - Departamento Entomologia e Fitopatologia, Instituto de Ciências Biológicas e da Saúde, Universidade Federal Rural do Rio de Janeiro (UFRRJ), 
Seropédica-RJ, Brazil
3 - Graduação em Agronomia, Universidade Federal Rural do Rio de Janeiro (UFRRJ), Seropédica-RJ, Brazil

RESEARCH ARTICLE - TERMITES



TS Souza, VS Gazal, VJ Fernandes, ACC Oliveira, EL Aguiar-Menezes – Termite recruitment affected by food size292

As urban pests, Nasutitermes termites have been 
controlled using chemical insecticides on the nests or by 
removing the nests (United Nations Environment Programme 
[UNEP], 2000; Gerozisis et al., 2008), which are often high 
up in trees and difficult to access or sometimes impossible to 
locate and only the tunnels on walls of infested buildings are 
visible (Menezes et al., 2000; Fontes & Millano, 2002).

New technologies for termite control, which are 
more environmentally friendly, include a toxic bait system 
that is efficient for subterranean termites, especially against 
Coptotermes formosanus Shiraki and Reticulitermes flavipes 
(Kollar) (Rhinotermitidae); however, the effectiveness of this 
system is still unknown for arboreal termites (Su et al., 1995; 
United Nations Environment Programme [UNEP], 2000; Lee, 
2002; Su, 2002; Potter, 2004; Dow AgroSciences, 2013). 
In this system, particularly in the Sentricon™ Colony 
Elimination System, two pieces of untreated wood of equal 
size (approximately 2 cm x 20 cm) are placed in a tube-shaped 
artefact in the soil to monitor the insects. When the insects 
are detected on the wood, the pieces are substituted with bait 
impregnated with insecticide that inhibits insect growth, such 
as hexaflumuron (Potter, 2004; Ogg et al., 2006). Su et al. 
(1995) described a prototype of a monitoring station that uses 
wooden pieces of Picea sp. (Pinaceae) that are approximately 
2.5 x 4.0 x 28 cm and baited with hexaflumuron, which was found 
to be efficient at controlling subterranean termite colonies near 
buildings in Florida. However, the lack of information about 
the mechanisms of food finding by termites, particularly for 
recruitment and orientation behavior, limits the use of a toxic 
bait system for Nasutitermes (Waller & La Fage, 1987).

Despite the increasing importance of N. corniger as 
a pest, little is known about its foraging behavior in relation 
to exploration of food resources; although, there is a record 
that N. corniger selects wood based on the species and that 
it prefers the wood of Eucalyptus grandis W. Hill ex Maiden 
(Myrtaceae) more than Pinus elliottii Engelm (Pinaceae) 
(Gazal et al., 2010). In addition, the degree of decomposition 
(Gazal et al., 2012) and chemical stimuli of wood (Gazal et 
al., 2014a) also influence attraction, as well as substances of 
the salivary gland of N. corniger workers, which can have 
an aggregation or arrestant effect, and possibly pheromone 
substances in the feces that aid this species in the exploratory 
orientation of cellulosic substrates (Gazal et al., 2014b).

Other factors can also affect the selection of a food 
resource by xylophagous termites, such as size, shape, volume 
and position of the food, surface area of the wood, presence 
of chemical substances in the food that can act as nutrients 
or allelochemicals, and density, hardness and humidity of the 
wood (Usher & Ocloo, 1974; Howick, 1975; Waller & La 
Fage, 1987; Gerozisis et al., 2008). In relation to size of the 
food resource, certain xylophagous termites prefer large logs 
or trees and others like small branches (Wood, 1978). Field 
tests conducted in Ghana demonstrated that C. formosanus 
prefers to attack pieces of wood that have smaller volumes 

and larger surface areas (Usher & Ocloo, 1974; Waller & La 
Fage, 1987).

In the laboratory, Howick (1975) evaluated the 
preference of three termite species for different lengths 
of Eucalyptus regnans F. Muell. wood (with the same 
shape), which varied from 20 to 100 mm, and observed that 
Coptotermes acinacicormis (Froggatt) (Rhinotermitidae) and 
Nasutitermes exitiosus (Hill) (Termitidae) prefer longer pieces 
of eucalyptus, unlike Mastotermes darwiniensis (Froggatt) 
(Mastotermitidae). Cornelius and Osbrink (2001) observed 
the effect of wooden pieces of Picea sp., which had the same 
dimensions in cross section (3.5 x 1 cm) but varied in length 
(4 and 11 cm), on two species of subterranean termite and 
concluded that R. flavipes consumption was much higher for 
the longer pieces and that C. formosanus consumption was 
not affected by this factor.

With the goal of selecting E. grandis wood of adequate 
size to use as monitoring bait for N. corniger, we verified if this 
physical factor influences the foraging behavior of this termite.

Material and Methods

Collection of termite nests

Nests of N. corniger that had active and mature colonies 
(with the presence of winged individuals) and were 40 cm 
wide and 60 cm tall were removed from trees in the park 
Parque Frei Leão Vellozzo between December 2016 and May 
2017. The park is an Atlantic Forest reserve maintained by 
the Universidade Federal do Rio de Janeiro (UFRJ) that is 
located on the Catalão Peninsula in the municipality of Rio de 
Janeiro, RJ, Brazil (22°50’44”S, 43°13’19”W). Taxonomic 
identification was made using the nest architecture described 
by Thorne (1981) and collected soldiers (Scheffrahn et al., 2005). 
The nests were collected in black, 100-liter plastic bags and 
placed in cardboard boxes to avoid them from being damaged 
during transport to the laboratory at the Centro Integrado de 
Manejo de Pragas (CIMP) of the Departamento de Entomologia 
e Fitopatologia at Universidade Federal Rural do Rio de Janeiro 
(UFRRJ), in the municipality of Seropédica, RJ, Brazil.

Termite maintenance in the laboratory

In the laboratory each collected nest was placed in a 
transparent glass cube (50.0 cm x 50.0 cm x 60.0 cm tall), 
supported on a Styrofoam plate, containing a 5.0 cm layer 
of sterilized sand (Fig 1). The termites had free access to the 
foraging arena through a silicone hose (Ø = 8.0 mm; length 
= 10 cm) connected to a PVC pipe (black) inserted in the exit 
hole of the cube. Each arena consisted of a glass plate bottom 
(50.0 x 40.0 cm) and perimeter wall (5.0 cm tall). The arena 
was placed on an acrylic tube (Ø = 10.0 cm and length = 20.0 
cm) so that the exit of the cube was at the same height as the 
top of the arena wall (Gazal et al., 2010). To allow the termites 
to access the foraging arena, a glass ramp was connected from 
the end of the silicone hose to the arena. The ramp consisted 



Sociobiology 65(2): 291-298 (June, 2018) 293

of two, transparent, glass plates (4.0 cm x 4.0 cm and 6.0 cm 
x 4.0 cm) fixed together with adhesive epoxy (Durepoxi®); the 
longer plate was placed parallel to the termite exit.

Termites were prevented from escaping by placing 
transparent adhesive tape (5 cm wide) on the upper edges of 
the walls of the cube; the adhesive part was facing inward. 
Pieces of moistened Pinus sp. wood were placed in the arena 
as food. Nearby, a PET bottle cap was placed that contained 
water to maintain the humidity of the foraging arena. The 
nests were maintained in a room, at a temperature of 25 ± 
5ºC, relative humidity of 80 ± 5% and photoperiod of 10:14 
hours (light:dark), at CIMP/UFRRJ. The pieces of wood and 
the sand in each box were moistened with distilled water each 
day. The experiments were conducted a week after the nests 
were brought to the laboratory.

Termite foraging arena setup

The tests were conducted in the foraging arenas based 
on the methodology described by Gazal et al. (2010). Thirty 
minutes before the start of each test, the connection between 
the nest and arena was blocked with hydrophilic cotton 
to impede the termites from accessing the arena. Then, the 
food was removed from the arena and replaced with the 
treatments (eucalyptus blocks that were 5, 10 and 15 cm long) 
on glass plates (5.0 x 4.0 cm, 10.0 x 4.0 cm and 15.0 x 4.0 
cm, respectively). The treatments were placed in a situation 
of choice and equidistant from the termite access point to the 
arena; that is, the blocks were inside the arena, 19 cm from 
the base of the access ramp. For each test, the position of the 
treatments in the arena was randomized.

Fig 1. Cube, for the colonies of Nasutitermes corniger, connected to the foraging arena.



TS Souza, VS Gazal, VJ Fernandes, ACC Oliveira, EL Aguiar-Menezes – Termite recruitment affected by food size294

Bioassay

Three lengths of blocks of E. grandis wood (heartwood 
with 6 year old and 14% of humidity), the same size in cross 
section (2.5 cm x 2.0 cm), were tested: 5 cm, 10 cm and 15 cm. 
Each test lasted 60 minutes and started when the access to the 
arena was reopened. The tests were conducted with 20 termite 
nests. During the test, the occurrence time of the following 
behavioral events was recorded with the ID, of a chronometer 
(Traniello, 1981; Gazal II, 2010): initial exploration (random 
arrival of the first soldier to the treatments); initial recruitment 
(arrival of the first worker); mass recruitment, which was 
when there was a continuous flow of workers to the substrate, 
demarcated by a trail on the glass plate of feces (mass arrival 
of workers to the treatments). The time to each behavioral 
event was measured, with the ID, of a chronometer, from 
the beginning of the test to the corresponding event. The 
occurrence percentages of these events, for each treatment, 
were calculated by the total number of blocks with the 
occurrence event divided by the total number of blocks 
available in each treatment (n = 20), multiplied by 100.

After 60 minutes of observation, the glass plates with 
the wood and respective recruited termites were removed. 
The number of termites present on each treatment, the number 
of termites (soldiers and workers) recruited to each plate of 
glass+treatment, and the number of gnawing workers (chewing 
on the wood) present on the treatments were recorded.

Statistical analysis

The experimental design was of randomized blocks, 
where each nest represents a block, using 20 nests (20 
blocks). The following dependent variables used to evaluate 
each treatment were: percentage of occurrence of each 
behavioral event (initial exploration, initial recruitment and 
mass recruitment) along the 20 nests tested, total number of 
termites recruited, time (in minutes) until the occurrence of 
each behavioral event, number of soldiers recruited, number 
of workers recruited, and number of workers gnawing wood. 
Percentage data were obtained by summing the occurrence 
of the behavioral event in each repetition divided by the total 
number of repetitions (n = 20). The occurrence percentages 
of each behavioral event, for each treatment, were not 
transformed and compared using a chi-squared test. Due to 
the absence of a normal distribution, the time data for each 
behavioral event and number of recruited workers were 
compared using the Kruskal-Wallis test (p < 0.05). The total 
number of recruited termites, the number of recruited soldiers 
and the number of gnawing workers met the assumptions 
of the analysis of variance (Kolmogorov-Smirnov and 
Lilliefors at 5%) and was analyzed using ANOVA and the 
averages were compared using Tukey’s HSD test (p < 0.05). 
The data were analyzed by STATISTICA® 10.0 and BioStat® 
5.3 programs.

Results

Nasutitermes corniger exhibited the behavior of initial 
exploration, initial recruitment and mass recruitment for all 
sizes of the E. grandis wood. However, the occurrence of 
initial exploration of the 10 and 15 cm blocks of wood was 
higher than the 5 cm blocks (test χ2 = 13.13; df = 2; p < 0.01). 
For the initial recruitment of the N. corniger workers, a higher 
occurrence for the 10 and 15 cm blocks was also observed 
when compared to the 5 cm blocks (test χ2 = 4.18; df = 2; p < 
0.05). On the other hand, for mass recruitment of N. corniger 
workers the occurrence was higher for the 10 cm blocks 
(13/20) than the 5 cm (7/20) and 15 cm (6/20) blocks. For the 
5 and 15 cm blocks, mass recruitment was similar (test χ2 = 
16.82; df = 2; p < 0.01).

The times for initial exploration, initial recruitment 
and mass recruitment of workers were not significantly 
different among the treatments (Table 1). On average, initial 
exploration lasted 8.8 ± 0.5 min after the beginning of the test, 
initial recruitment lasted 17.7 ± 0.6 min, and mass recruitment 
lasted 34.9 ± 1.1 min.

Length of 
wood (cm)

Behavioral event1

Initial 
exploration 
(min)

Initial 
recruitment 
(min)

Mass 
recruitment
(min)

5.0 x 2.5 x 2.0 5.0 ± 0.4 a 10.5 ± 0.4 a 25.0 ± 1.1 a
10.0 x 2.5 x 2,0 11.0 ± 0.6 a 19.5 ± 0.5 a 42.4 ± 1.0 a
15.0 x 2.5 x 2.0 10.4 ± 0.6 a 23.1 ± 0.8 a 37.3 ± 1.2 a

1Averages followed by the same letter in the column did not differ from 
each other by the Kruskal-Wallis test, p <0.05.

Table 1. Elapsed time (average ± SD) from the beginning of the test 
to the occurrence of initial exploration, initial recruitment and mass 
recruitment exhibited by the workers of Nasutitermes corniger (n 
= 20) on the wood of Eucalyptus grandis offered in three lengths 
in a situation of choice during 60 minutes of observation under 
laboratory conditions.

The total number of termites recruited to the 10 cm 
blocks (183.4 ± 6.2) was higher than the number for the 5 
cm blocks (73.0 ± 8.6). However, the 15 cm blocks (111.2 ± 
5.3) exhibited a recruitment of termites that was similar to the 
5 cm blocks (F2.48 = 3.3; p < 0.05; Fig 2). The total number 
of recruited soldiers to the E. grandis wood did not differ 
between the 10 cm (35.1 ± 1.6), 15 cm (30.2 ± 1.5) and 5 
cm (16.8 ± 1.2) (F2.48 = 2.2; n.s.) blocks. The total number of 
recruited workers to the E. grandis wood for the 10 cm (148.4 
± 5.1), 15 cm (81.0 ± 4.2) and 5 cm (55.7 ± 7.3) blocks was 
similar (Kruskal-Wallis H2.48 = 4.7, n.s.).

The total number of workers gnawing on the 10 cm 
(144.7 ± 4.9) E. grandis blocks was higher than the 5 cm (54.7 
± 7.0) blocks. However, for the wood that was 15 cm long the 
N. corniger workers exhibited a gnawing behavior that was 
similar to the 5 cm and 10 cm blocks (77.6 ± 4.1) (F2.48 = 3.6; 
p < 0.05; Fig 3).



Sociobiology 65(2): 291-298 (June, 2018) 295

Discussion

Independent of the size of the E. grandis wood, the 
three behavioral events (initial exploration, initial recruitment 
and mass recruitment of workers) were conducted by 
N. corniger while foraging for this food resource under 
laboratory conditions, which corroborates observations made 
by other authors for this species and other species of the genus 
(Traniello, 1981; Traniello & Busher, 1985; Arab & Issa, 
2000; Gazal et al., 2010).

In the study, mass recruitment of workers and some 
soldiers to the eucalyptus blocks occurred, which indicates 
the blocks were recognized as food, seeing that, according to 
Traniello (1981), this behavioral event is only triggered when 
the food source is appropriate for consumption.

In relation to the length of the blocks of E. grandis, 
initial exploration and initial recruitment of workers were 
more intense for the 10 cm (medium length) and 15 cm 
(longest) pieces, which suggests that these sizes of wood 

represent, at the same distance, more attractive food resources 
for N. corniger. It is possible that the individuals were directed 
by a higher concentration of volatiles released by the wood, 
but this chemical stimulus needs to be further investigated. 
Mass recruitment of workers was greater for the medium 
length wood (10 cm), which allows us to infer that, after the 
termites begin to explore this food resource, discrimination 
occurs during the third stage of foraging.

Termites can measure the volume of a food source in 
a number of ways. For smaller food sources on the ground, 
some individuals need to walk or establish trails throughout 
the substrate so they can perceive the volume, since there is 
a difference in the threshold of perception for these insects 
in relation to variation in food size (Lenz, 1994). Howick 
(1975) studied how N. exitiosus consumed wooden blocks 
of E. regnans, which differed in length (20 to 100 x 1.5 x 
2.5 mm), and found that consumption was greater as the 
length of the blocks increased. Esenther (1970) and French 
et al. (1986) observed that R. flavipes modified its rate of 
consumption according to the size of the available food. 
Studies of subterranean termites conducted by Waller (1988; 
1991) and Lenz (1994) showed that the larger the food source, 
the greater the consumption, independent of the number of 
termites present. However, in the present work, we found that 
N. corniger clearly discriminated between the distinct sizes of 
wood, which was based on differences in total recruitment of 
termites and the number of gnawing workers.

Termite foraging is a group activity and composed of 
unified individual actions mediated by chemical and tactile 
stimuli (Traniello & Leuthold, 2000; Costa-Leonardo, 2002). 
The tactile stimuli come from the edges of solid objects present 
along the trail and of the food, and help the termites establish 
the trail of the colony to the food source (Swoboda & Miller, 
2004). In the case of drywood termites, some species produce 
acoustic stimuli by drumming their head against the substrate 
or shaking their body as a mechanism to attract foragers and 
to assess the size of the food source (Evans et al., 2005; 2007).

Hedlund and Henderson (1999) verified that for C. 
formosanus the larger the size of the food source, the greater 
the consumption. In the present work, the shortest block 
(5 cm) had the lowest number of gnawing workers when 
compared to the medium length (10 cm) block; although, for 
the longest block (15 cm), the number of feeding workers 
was equivalent to the 5-cm block. This suggests that, for N. 
corniger, size is a factor that influences the exploration of a 
food source. However, apparently, starting at a certain size 
of the food source, the attributes responsible for recruitment 
would be reduced.

On the other hand, the recruitment of Cryptotermes 
domesticus (Haviland) (Kalotermitidae) workers is greater for 
smaller pieces of wood, a preference that could be related to 
food competition (Evans et al., 2005). Experiments conducted 
with the arboreal termites Microcerotermes turneri (Froggatt) 
(Termitidae), Nasutitermes graveoleus (Hill) (Termitidae) and 

Fig 2. Number of termites of Nasutitermes corniger recruited 
(average ± SD) after 60 minutes of the test (n = 20) of three lengths 
of Eucalyptus grandis wood: 1) 5.0 x 2.5 x 2.0 cm (Size 1); 2) 10.0 x 
2.5 x 2.0 cm (Size 2); and 3) 15.0 x 2.5 x 2.0 cm (Size 3). Different 
letters indicate a significant difference between the treatments based 
on Tukey’s HSD test, p < 0.05.

Fig 3. Number of feeding Nasutitermes corniger workers (average ± 
SD) after 60 min. of the test (n=20) for the wooden blocks Eucalyptus 
grandis: 1) 5.0 x 2.5 x 2.0 cm (Size 1); 2) 10.0 x 2.5 x 2.0 cm (Size 2); 
and 3) 15.0 x 2.5 x 2.0 cm (Size 3). Different letters indicate a significant 
difference between the treatments based on Tukey’s HSD test, p < 0.05. 



TS Souza, VS Gazal, VJ Fernandes, ACC Oliveira, EL Aguiar-Menezes – Termite recruitment affected by food size296

Nasutitermes walkeri (Hill) (Termitidae), and two lengths 
of wood (2.5 cm and 10 cm), found that the three species 
preferred the longer pieces (Gerozisis et al., 2008).

In general, the present study found that wood of 
distinct sizes, which are potential food sources, present 
differences in attractiveness and can be discriminated by 
N. corniger. This discrimination occurs during the process 
of exploring the resource through a preference mechanism 
that results in differences in the total number of termites 
recruited and the number of workers feeding on the wood. 
Wood size could play an important role in determining the 
food preference of N. corniger. Future research should focus 
on quantifying this possible importance, as well as the role 
of the number (quantity) of wooden pieces in relation to N. 
corniger foraging.

However, additional observations made while collecting 
the nests found that N. corniger forages in tunnels built on and 
a few centimeters below the soil surface, which allows us to 
infer that buried pieces of eucalyptus wood could be used as 
attractive bait. In addition, Fontes and Millano (2002) cite that, 
similar to subterranean termites, N. corniger can infest buildings 
through the soil. Thus, this bait could aid in surveys of this 
species under field conditions, as occurs for some subterranean 
species, such as Coptotermes gestroi (Wasmann) (Santos et al., 
2010), and could also be used in monitoring stations in a toxic 
bait system to detect this termite in urban centers. Based on the 
results of the laboratory tests, 10 cm pieces would be the most 
adequate size for this because they attracted the greatest mass 
recruitment. However, more studies are needed to support these 
hypotheses, since in addition to foraging behavior inherent to 
the species, other factors might interfere with termite foraging, 
such as edaphoclimatic conditions, presence of other food 
sources and predators, soil structure and humidity, and level of 
soil disturbance (Hu & Appel, 2004; Souza et al., 2009; Santos 
et al., 2010; Dow AgroSciences, 2013). 

Acknowledgments

We thank CAPES (Coordenação de Aperfeiçoamento 
de Pessoal de Nível Superior) for the magister science scholarship 
to the first author. Thanks also to Angela Iaffe (Agronomic 
Engineer of the Horto Florestal at UFRJ) for acting as an 
intermediary with Parque Frei Leão Vellozzo so the termite 
colonies could be collected, Flávio (employee of the staff of 
the park), the Divisão de Segurança (DISEG) at UFRJ, Prof. 
João Vicente de Figueiredo Latorraca for allowing to use 
of the carpentry at the Departamento de Produtos Florestais 
(DPF) at UFRRJ, and we are also grateful to its carpentry staff.

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