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

DOI: 10.13102/sociobiology.v63i2.989Sociobiology 63(2): 855-857 (June, 2016)

Suitability of Substrate for Laboratory Studies with the Subterranean Termite Reticulitermes 
grassei Clément (Isoptera: Rhinotermitidae)

Reticulitermes grassei Clément is a subterranean termite 
species native to the northern, western and southern of the 
Iberian Peninsula and the southern-west France (Clement 
et al., 2001). Like other subterranean termites, R. grassei 
colonises both natural and urban environments. In human 
habitats, it causes damage affecting all type of constructions 
and represents a major pest problem (Gaju et al., 2002) because 
of its wide-ranging biology and the lack of implementation of 
effective treatments (Alcaide, 2010). In most Iberian forests 
R. grassei is very common but it has never been considered as 
a pest. Nevertheless, Gallardo et al. (2010) described lesions 
in cork oaks (Quercus suber L) as consequence of the feeding 
activity of these insects and indicated that nests and foraging 
areas appeared to be associated with sites having a high 
abundance of cork oaks (Cárdenas et al., 2012).

In a current research addressed to investigate the feeding 
response of R. grassei to different oak woods, the question 
of selecting the most suitable substrate for laboratory studies 
with this species prompted a prior essay to elucidate which 
of the two most frequently substrates on laboratory rearing 

Abstract 
Two substrates, sand and vermiculite, were tested in rearing 
laboratory experiments with Reticulitermes grassei at different 
culture periods (2, 4 and 6 weeks). Although information is 
available regarding procedures to keep species of Reticulitermes 
in lab, none of them is referred to the Mediterranean termite 
R. grassei. The suitability of substrate was assessed in terms 
of survival of termites. No statistically significant differences 
were obtained in the survival rate in the experiments with sand 
and vermiculite when short-time duration tests are performed, 
concluding that it seems to be indifferent using any of these 
substrates for shorter test than 8 weeks.  

Sociobiology
An international journal on social insects

P Gallardo, AM Cárdenas, R Murillo

Article History

Edited by
Astrid Kleinert, USP, Brazil
Received     27 January 2016
Initial acceptance     16 March 2016
Final acceptance     21 June 2016
Publication date          15 July 2016

Keywords 
Reticulitermes grassei, 
Rhinotermitidae, Suitability of 
substrate, Termites survival rate.

Corresponding author
Ana M Cárdenas Talaverón
Department of Zoology, 
Campus Rabanales, E-14071, 
University of Córdoba, Spain
E-Mail: ba1cataa@uco.es

species of Reticulitermes, sand and vermiculite (Haverty, 1979; 
Haverty & Howard, 1981; Perkin, 2012; EN 118, 2013), was 
more adequate in the particular case of R. grassei. In order to 
obtain successfully results on bioassays, it is crucial to know 
the optimal conditions to keep the selected species of termite, 
not only as far as the temperature and moisture requirements are 
concerned, but also the suitability of the substrate (Lenz, 2005).

Research done on this subject (Haverty, 1979; 
Fougerousse, 1973; Lenz, 2005; Gaju et al., 2010) suggests 
that both vermiculite (laminar aluminium-iron-magnesium 
silicate) and sand, are suitable substrates for experimenting 
with Reticulitermes species, but none of these surveys deals 
with R. grassei. For this species, Gaju et al. (2010) conducted 
bioassays to measure the effectiveness of different termiticides 
using vermiculite as substrate; however, other researchers 
recommend sand as preferable substrate (Nobre et al., 2007; EN 
118, 2013). Research aimed to elucidate which of recommended 
substrates is, really, the most suitable for laboratory studies 
with R. grassei are necessary in order to optimize the results of 
rearing experiments on this species of subterranean termite.  

University of Córdoba, Campus Rabanales, Córdoba, Spain

SHORT NOTE



P Gallardo, AM Cárdenas, R Murillo – Suitability of Substrate for Bioassays with Reticulitermes grassei856

Similar studies to test the suitability of substrate for laboratory 
essays for other species of Reticulitermes (R. flavipes Kollar and 
R. virginicus Banks) have been conducted by Haverty (1979). 
However, there are no studies analyzing this aspect in the case of 
R. grassei. This research has been addressed to test the suitability 
of both substrates in short duration tests with R. grassei. 

Termites used on this study were collected in April 
2014 from the surrounding of Sta. Mª de Trassierra (Central 
Sierra Morena Mountains; southern Iberian Peninsula). The 
oak fragments of timber in which the insect were found were 
transported to the laboratory in plastic perforated containers. 
Once there, the termites were manually and carefully extracted. 
The insects used in these experiments were undifferentiated 
larvae (workers) of at least the third stage.

Two experiments were performed to determine the 
suitability of the substrate (Haverty, 1979; Ho & Kirton, 
2007). For each experiment, 15 rearing containers measuring 
18x15x7 cm were used. These containers corresponded to 
an experimental design with three treatments (of 2, 4 and 6 
weeks duration) and 5 replications each. 

As humidity is a decisive factor in the survival of 
these insects, the proportions of water/substrate used for 
these experiments were: 1 volume of water to 4 volumes of 
sand, and 3 ml of water to 1g of vermiculate, proportions 
recommended in literature for Reticulitermes species (Nobre 
et al., 2007; Munizaga, 2007; Munizaga et al., 2008; Arinana 
et al., 2012; EN 118, 2013).

Eight sapwood blocks (approximately 2x2x1cm in 
size) of pine (Pinus pinea L.) were provided as food. The 
wood of pine is considered the most adequate for laboratory 
studies with termites (Perkins, 2012; Smythe & Carter, 1970).

A total of 150 termite workers randomly selected were 
introduced into each container, which were kept in a rearing 
chamber in permanent darkness at a constant temperature of 
26±1 ºC and at 80±5% relative humidity. After 2, 4 and 6 weeks, 
the sapwood blocks were removed and the surviving termites 
were censused. The survival rate was estimated as percentage 
of surviving workers found for each treatment (Table 1).

To jointly analyse the results and to elucidate possible 
interaction between the variables substrate and time, a Factorial 
ANOVA was performed using the SPSS statistical software 
(SPSS 20.0, 2011). 

The results of the statistical analysis are displayed on 
Table 2. From this, it could be observed that the Factorial 
ANOVA did no find significant differences between variables, 
or in their interaction. That’s to say, the survival rate of the 
different treatments of the experiment with vermiculite does no 
vary significantly from those obtained in the experiment using 
sand as substrate.

 However, if the values of the survival rate in the two 
experiments are examined (Table 1), it can be observed that in 
sand this value decreases over time, and that the worst results 
are obtained after six weeks exposure (but lacking of statistical 
significance). This trend has not been observed in vermiculite, 
and could be related with the moisture level, because the sand has 
a minor water-holding capacity throughout time that vermiculite. 

Our results are consistent with those provided by Haverty 
(1979) for closer species as R. flavipes and R. virginicus, who 
suggested that it seems to be indifferent the use of vermiculite 
or sand as substrate for shorter test than 8 weeks. 

Nevertheless, in experiments of longer duration (12 
weeks or more) performed with other Reticulitermes species, 
the use of vermiculite resulted to be the most appropriate 
substrate (Haverty, 1979). More research is necessary in order 
to know the response to the kind of substrate of R. grassei, in 
long-term tests.

Survival rate
Vermiculite Sand

T1 T2 T3 T1 T2 T3

R
ep

lic
at

io
ns

1 89.33 56.67 30 84.67 84.67 66
2 49.33 82.67 72.67 89.33 93.33 30.67
3 86.67 68 96 94.67 90 81.33
4 97.33 84.67 80.67 92 79.33 81.33
5 65.33 48 84 83.33 85.33 84.67
 77.60 68 72.67 88.80 86.53 68.80

DS 19.74 15.98 25.29 4.79 5.36 22.52

Table 1. Survival rate (%), survival rate mean () and Standard 
Deviation (SD) of five replications of each treatment (T1, T2 and 
T3: 2, 4 and 6 weeks duration, respectively) for the substrates tested 
(vermiculite and sand).

Statistics values

Variable F P

Substrate 1.815 0.191

Time 1.266 0.300

Interaction substrate-time 1.061 0.362

Table 2. Results of the Factorial ANOVA of comparison of survival 
rates between the variables substrate, time of treatment, and their 
interaction. P: probability for α = 0.05; F: values of Factorial 
ANOVA. Dependent variable: survival rate; R2= 0.212 (Adjusted 
R2= 0.048).

Acknowledgements   

This research has been financially supported by ACUAES 
(Ministry of Agriculture, Food and Environment, Government of 
Spain) and by Ingeniería y Gestión del Sur, S.L. (Grupo IG-IPA).

References

Alcaide, M.E. (2010). Estudio del control integral de una 
plaga urbana de termitas en el sur de España. Dissertation, 
Universidad de Córdoba, España.



Sociobiology 63(2): 855-857 (June, 2016) 857

Arinana, L., Tsunoda, K., Herliyana, E.N. & Hadi, Y.S. 
(2012). Termite-susceptible species of wood for inclusion 
as a reference in Indonesian standardized laboratory testing. 
Insects, 3: 396-401. doi: 10.3390/insects3020396.

Cárdenas, A.M., Moyano, L., Gallardo, P. & Hidalgo, J.M. 
(2012). Field activity of Reticulitermes grassei (Isoptera: 
Rhinotermitidae) in oak forests of the Southern Iberian Peninsula. 
Sociobiology, 59: 493-509. doi: 10.13102/sociobiology.v59i2613.

Clément, J.L., Bagnères, A.G., Uva, P., Wilfert, L., Quintana, 
A., Reinhard, J. & Dronnet, S. (2001). Biosystematics of 
Reticulitermes termites in Europe: morphological, chemical 
and molecular data. Insectes Sociaux, 48: 202-215. doi: 
10.1007/PL00001768.

EN 118 (2013). Wood preservatives: Determination of preventive 
action against Reticulitermes species (European termites) 
(laboratory method). European Committee for Standardization, 
BSI Standards Publication, CEN-CENELEC, Brussels, Belgium.

Fougerousse, M. (1973). Some aspects of laboratory and field 
testing methods of antitermite wood preservatives. Holzforsch, 
27(4): 137-142. doi: 10.1515/hfsg.1973.27.4.137.

Gaju, M., Notario, M.J., Mora, R., Alcaide, E., Moreno, T., 
Molero, R. & Bach, C. (2002). Termite damage to buildings 
in the province of Córdoba, Spain. Sociobiology, 40: 75-85.

Gaju, M., Moyano, L., Alcaide, E., Patiño, C., Diz, J., Nunes, 
L., Bach, C. & Molero, R. (2010). Laboratory study of fipronil 
baits against Reticulitermes grassei (Isoptera: Rhinotermitidae). 
Proceeding of 41st Annual Meeting the International Research 
group on wood protection, Biarritz, France.

Gallardo, P., Cárdenas, A.M. & Gaju, M. (2010). Ocurrence of 
Reticulitermes grassei (Isoptera: Rhinotermitidae) on cork oaks 
in the southern Iberian Peninsula: identification, description 
and incidence of the damage. Sociobiology, 56: 675-687. 

Haverty, M.I. (1979). Selection of tunnelling substrates for 
laboratory studies with three subterranean termite species. 
Sociobiology, 4: 315-320. 

Haverty, M.I. & Howard, R.W. (1981). Production of soldiers and 
maintenance of soldier proportions by laboratory experimental 
groups of Reticulitermes flavipes (Kolar) and Reticulitermes 
virginicus (Banks) (Isoptera: Rhinotermitidae). Insectes Sociaux, 
28: 32-39. doi: 10.1007/BF02223620.

Ho, T.H. & Kirton, L.G. (2007). Effects of different substrates 
and activated charcoal on the survival of the subterranean 
termite Coptotermes curvignathus in laboratory experiments 
(Isoptera: Rhinotermitidae). Sociobiology, 50: 479-497. 

Lenz, M. (2005). Laboratory bioassays with termites-the 
importance of termite biology. Proceeding the 2ª Conference 
of Pacific Rim Termite Research Group on Wood Protection, 
Bangkok, Thailand.

Munizaga, M.J. (2007). Estudio de alimentación y de sustancias 
tóxicas potenciales para Reticulitermes flavipes (Kollar) (Isoptera: 
Rhinotermitidae). Dissertation, University of Chile.

Munizaga, M.J., Araya, J.E., Karsulovic, T. & Bozo, A. 
(2008). ¿Afecta la exposición previa a ninfas el consumo de 
madera de pino radiata de Reticulitermes flavipes (Kollar) 
(Isoptera: Rhinotermitidae)? Boletín de Sanidad Vegetal Plagas, 
34: 533-536.

Nobre, T., Nunes, L. & Bignell, D.E. (2007). Tunnel geometry of 
the subterranean termite Reticulitermes grassei (Isoptera: Rhino-
termitidae) in response to sand bulk density and the presence 
of food. Insect Science, 14: 511-518. doi: 10.1111/j.1744-
7917.2007.00180.x

Perkins, G.D. (2012). Reticulitermes feeding preference and 
experimental design. Dissertation, University of Georgia.

Smythe, R.V. & Carter, F.L. (1970). Feeding responses to 
sound wood by Coptotermes formosanus, Reticulitermes flavipes, 
and R. virginicus (Isoptera: Rhinotermitidae). Annals of the 
Entomological Society of America, 63: 841-847. doi: 10.1093/
aesa/63.3.841. 

SPSS Inc. (2011). SPSS 20.0 for Windows Use Manual 
(version 20.0).