1205

Nestmate Recognition and Cuticular Hydrocarbons of Two 
Sympatric Species of Reticulitermes in Japan

(Isoptera: Rhinotermitidae)
by

Yoko Takematsu1* & Kohei Kambara2

ABSTRACT

The nestmate recognition of two sympatric species, R. kanmonensis and 
R. speratus, was investigated in terms of agonistic behavior and trophallactic 
behavior. R. speratus showed strong agonistic behavior against different spe-
cies, but no trophallactic contact with them. However, agonistic behavior 
against different colonies of the same species was weak, and trophallactic 
exchange of food was observed. On the other hand, R. kanmonensis showed 
strong agonistic behavior not only against different species but also against 
different colonies of the same species, and trophallactic contact was absent. 
These results indicate that R. kanmonensis does not exhibit colony fusion, 
unlike R. speratus, which is known to exhibit colony fusion. This marked dif-
ference in the occurrence of colony fusion can be related to the difference in 
the distribution pattern of the two species. Cuticular hydrocarbons of both 
species were also analyzed. Relatively high hydrocarbon homogeneity was 
observed among colonies in R. kanmonensis compared to R. speratus. 

Key words: nestmate recognition; cuticular hydrocarbons; agonistic behav-
ior; trophallaxis; colony fusion; sympatric distribution; invasive species.

INTRODUCTION

Genus Reticulitermes is one of the common genera that cause serious 
damage to woodwork in temperate regions. R. speratus is widely distributed 
throughout the Japanese mainland and had been known as the only species 
of this genus. However, it was found that another species, R. kanmonensis, 

1Department of Biological and Environmental Science, Faculty of Agriculture, Yamaguchi University, 
Yoshida 1677-1, Yamaguchi 753-8515, Japan
2The United Graduate School of Agricultural Sciences, Tottori University, Tottori 680-8553, Japan
*Corresponding author. present address: Department of Biological and Environmental Sciences, 
Yamaguchi University, 1677-1 Yoshida, Yamaguchi, 753-8515, Japan; e-mail: takematu@yamaguchi-u.
ac.jp 



1206  Sociobiolog y Vol. 59,  No. 4, 2012

is distributed sympatrically with R. speratus in southernmost Honshu and 
is thought to be an alien species (Kitade & Matsumoto 1993; Takematsu 
1999; Morimoto 2000). Since the first report of this species as R. flaviceps by 
Nawa (1911), it has not been distinguished from R. speratus morphologically 
and has been controlled using the same method as for R. speratus. However, 
Takematsu (1999) presented the characters distinguishing this species from 
R. speratus, and since then the two species have been treated separately in the 
ecological study of Reticulitermes.

Kambara & Takematsu (2009) showed that R. kanmonensis tend to choose 
less favorable habitats (less damaged wood) when coexisting with R. speratus, 
and this fact predicted that even living woods and houses are vulnerable to 
termite damage by R. kanmonensis. In order to control this species more effec-
tively, it is important to clarify the ecological features of R. kanmonensis.

Kitade & Hayashi (2002) reported the detailed distribution range of 
this species. It is remarkable that the distribution area of R. kanmonensis 
is restricted to the coastal areas on both sides of the Kanmon strait located 
between Honshu and Kyushu Islands, and that this species has not expanded 
its distribution range for a century since the first record in 1911 (Nawa 1911; 
Nawa 1912a,1912b; Nawa 1917; Kitade & Matsumoto 1993; Takematsu 
1999; Morimoto 2000). Within the whole distribution area, R. kanmonensis 
and R. speratus were distributed sympatrically. However, the local distribution 
of the two species was not homogeneous; the distribution ratio of some local 
areas was strongly biased toward R. kanmonensis (Kitade & Hayashi 2002; 
Kambara & Takematsu 2009). Why did R. kanmonensis show such a biased 
distribution pattern without expanding their distribution range? Here we 
consider whether one of the reasons for the distribution pattern might be 
associated with the interspecific and intraspecific interactions between the 
two species. Kitade et al. (2004) reported the highly aggregated distribu-
tion of incipient colonies of R. kanmonensis in a small area and the lack of 
mitochondrial haplotype variation within a mature nest, and they assumed 
the absence of worker mingling and the strong intraspecific competition 
among colonies.

In the present study, we investigate the recognitions for nestmate and non-
nestmate of R. kanmonensis and R. speratus in terms of the agonistic behav-
ior and trophallactic behavior. We also analyze the cuticular hydrocarbons 



1207 Takematsu, Y. & K. Kambara — Nestmate Recognition in Sympatric Reticulitermes sp.

of both species, which are reported to play a key role as cues for nestmate 
recognition, and discuss the relationship between nestmate recognition and 
cuticular hydrocarbon composition.

MATERIALS AND METHODS

Termites
Four collecting sites were chosen according to the local distribution ratio 

of the two species: R. kanmonensis-area (Site1: distribution ratio of R. kan-
monensis was 100%), R. kanmonensis dominant-area (Site2: distribution ratio 
of R. kanmonensis was 85%), R. speratus dominant-area (Site3: distribution 
ratio of R. kanmonensis was 35%), and R. speratus-area (Site4: distribution 
ratio of R. kanmonensis was 0%). Sites 1-3 were in a forest in Ejio Park, Onoda 
(131°12’E, 34°2’N), Yamaguchi Prefecture. Site 4 was in Yoshida, Yamaguchi 
(131°27’E, 34°9’N), Yamaguchi Prefecture. Three colonies for each species 
were collected from each site, respectively.

Bioassay
Bioassays were conducted using a plastic container (82mm diameter x 

46mm height) with a sheet of filter paper at 25°C. To stain the termite gut 
for discriminating the test individuals and target ones, termites of each colony 
were divided into two groups and were fed a filter paper stained by red food 
coloring and blue food coloring respectively for 24 hrs. Thirty workers were 
introduced into the test arena as test individuals, and after 3 hrs a target 
individual was introduced into the arena. Survival and occurrence of body 
color change of the target individual were recorded after 24hrs. In these 
bioassays, we regarded the death of target individual as “agonistic behavior” 
(i.e. non-nestmate recognition) and body color change of a target individual 
as “trophallaxis behavior” (i.e. nestmate recognition).

The following three experiments were carried out in order to evaluate 
nestmate and non-nestmate recognitions for R. kanmonensis as well as for 
R. speratus.

Experiment 1: Recognition between individuals from the same colony 
was tested. Both test individuals and target ones were sampled from the same 
colony in each trial. For R. kanmonensis, one colony collected from each of   



1208  Sociobiolog y Vol. 59,  No. 4, 2012

sites 1 to 3 was used. One colony was used from site 4 for R. speratus. Every 
trial was replicated 15 times.

Experiment 2: Recognition between individuals from different colonies 
of the same species was tested. Test individuals and target ones were sampled 
from the same species but different colonies in each trial. Colonies collected 
from sites 1 to 3 were used for the tests of R. kanmonensis and for R. speratus 
samples from site 4 were used. In each site, 3 colonies were used for 6 possible 
combinations of test/target sets. Every set was replicated 3 times, and in total 
18 replication were done for each site.

Experiment 3: Recognition between individuals from the different species 
was tested. Test individuals and target ones were sampled from different species 
in each trial. For the tests of R. kanmonensis, individuals of one colony of R. 
kanmonensis collected from each of sites 1 to 3 were used as test individuals 
and individuals of one colony of R. speratus collected from each of sites 2 to 4 
were used as target individuals. In each site, every trial was replicated 5 times 
and in total 15 replications were done. For the tests of R. speratus, individuals 
of a colony of R. speratus collected from site 4 were used as test individuals 
and individuals of one colony of R. kanmonensis from each of sites 1 to 3 were 
used as target individuals. Every trial was replicated 10 times.

GC analysis
Cuticular hydrocarbons were extracted from 3 colonies of R. kanmonensis 

from sites 1 to 3 respectively and 3 colonies of R. speratus from sites 2 to 4 
respectively. Three replications were done for each colony except the colony 
of R. kanmonensis from site 3 which admitted no replication due to a lack 
of individuals. Cuticular hydrocarbons were extracted by immersing 100 
workers in 2 ml of n-hexane for 5 min.  After evaporation of the hexane, the 
extracts were redissolved in 1 to 10 µl of n-hexane for gas chromatography 
(GC). The gas chromatography was conducted by a Shimadzu GC-14B 
(Shimadzu, Kyoto, Japan) equipped with a flame ionization detector (FID) 
and DB-1HT capillary column (Frontier Lab; length 30m, film thickness, 
0.1 µm). Helium was used as the carrier gas. The injection temperature was 
programmed at 65°C for 0.01 min and then raised at 30°C/min to 355°C, 
with a final hold for 26.3 min. The oven temperature was kept at 60°C for 
0.1min and then raised at 20°C/min to 200°C, 10°C/min to 275°C, 5°C/
min to 355°C, with a final hold for 10 min. The detection temperature was 



1209 Takematsu, Y. & K. Kambara — Nestmate Recognition in Sympatric Reticulitermes sp.

355°C. Hydrocarbons were identified according to the results of the GC-MS 
analysis reported in Takematsu & Yamaoka (1999) and quantified as the 
percent of the total hydrocarbon component.

The differences of cuticular hydrocarbons within a colony and within a 
site were analyzed using principal component analysis (PCA), employing the 
component ratio of cuticular hydrocarbons. The calculations were performed 
using the Excel-Toukei software program (Social Survey Research Informa-
tion Co., Ltd., 2006).

RESULTS

Bioassay
Numbers of survival and trophallaxis of target individuals of R. kanmonensis 

and R. speratus are shown in Table 1. In the assay for the individuals from the 
same colony (Experiment 1), all target individuals of both R. kanmonensis 
and R. speratus survived, and occurrences of trophallaxis were more than 86%. 
These facts indicated that both R. kanmonensis and R. speratus have strong 
nestmate recognition for individuals from the same colony. Conversely, in 
the assay for the individuals from the different species (Experiment 3), most 
individuals of both R. kanmonensis and R. speratus were dead and no trophal-

Table 1. Number of survivors and trophallaxis of target individuals of R. kanmonensis and R. 
speratus.

Experiment Species Site N
Number of 

Surviving  Targets (%)
Number of color 

changed targets (%)

   Experiment1 R. kanmonensis Site 1 15 15 (100.0) 15 (100.0)
   (Same colony) R. kanmonensis Site 2 15 15 (100.0) 15 (100.0)

R. kanmonensis Site 3 15 15 (100.0) 13 (86.7)
R. speratus Site 4 15 15 (100.0) 14 (93.3)

   Experiment 2 R. kanmonensis Site 1 18 7 (38.9) 3 (16.7)
   (Different colony) R. kanmonensis Site 2 18 9 (50.0) 2 (11.1)

R. kanmonensis Site 3 18 3 (16.7) 0 (0.0)
R. speratus Site 4 18 18 (100.0) 8 (44.4)

   Experiment 3 R. kanmonensis Site 1 15 0 (0.0) 0 (0.0)
   (Different species) R. kanmonensis Site 2 15 2 (13.3) 0 (0.0)

R. kanmonensis Site 3 15 1 (6.7) 0 (0.0)
R. speratus Site 4 10 0 (0.0) 0 (0.0)



1210  Sociobiolog y Vol. 59,  No. 4, 2012

lactic behavior was observed. These indicated that both species have strong 
agonistic behavior against the different species.

On the other hand, in the assay for the individuals from the different colonies 
of the same species (Experiment 2), the results showed a marked difference 
between the two species. In the case of R. speratus, all target individuals sur-
vived, and the ratio of trophallactic behavior was 44.4%. While, in the case 
of R. kanmonensis, more than 50% of target individuals were dead and only a 
few target individuals changed their body color: especially in site 3 (R. speratus 
dominant-area), the survival rate of target individuals of R. kanmonensis was 
remarkably low and no trophallactic behavior was observed.

GC analysis
From R. kanmonensis, 21 components of hydrocarbons were identified 

and quantified. From R. speratus, 22 components of hydrocarbons were 
identified and quantified. Cuticular hydrocarbon components of both spe-
cies were different (Takematsu & Yamaoka 1999). Nine substances were in 

Fig. 1 PCA evaluating the differences of cuticular hydrocarbons within and among colonies of R. 
kanmonensis based on the proportion of 20 major CHC components. A-C show the colony of each 
site; solid diamond, solid circle and solid triangle show Site 1, 2 and 3 respectively.



1211 Takematsu, Y. & K. Kambara — Nestmate Recognition in Sympatric Reticulitermes sp.

common. The results of the PCA were plotted using the first and second 
principal component axes. Fig. 1 shows the result of the PCA evaluating 
the differences of cuticular hydrocarbons within and among colonies of R. 
kanmonensis based on the proportion of 21 components. The first principal 
component (PC1) explained 32.08% of the total variance and the second 
principal component (PC2) explained 25.92% of the total variance. Fig. 2 
shows the result of the PCA evaluating the differences of cuticular hydro-
carbons within and among colonies of R. speratus based on the proportion 
of 22 components. The first principal component (PC1) explained 43.28% 
of the total variance and the second principal component (PC2) explained 
15.99% of the total variance.

In both species, within each colony there was a very similar cuticular hy-
drocarbon profile, and they could be separable with other colonies. On the 
other hand, variations among colonies within a site of R. kanmonensis (Fig. 

Fig. 2 PCA evaluating the differences of cuticular hydrocarbons within and among colonies of R. 
speratus based on the proportion of 20 major CHC components. A-C show the colony of each site; 
solid circle, solid triangle and solid square show Site 2, 3 and 4 respectively.



1212  Sociobiolog y Vol. 59,  No. 4, 2012

1) were much smaller than those of site 4 for R. speratus (Fig. 2 solid squares), 
which was used in the bioassays. 

DISCUSSION

R. kanmonensis and R speratus are distributed sympatrically and R. kan-
monensis is thought to be an alien species having been introduced into the 
native distribution range of R. speratus.

R. speratus showed strong agonistic behavior against different species and 
no trophallactic contact with them. However, agonistic behavior against dif-
ferent colonies of the same species was weak and trophallactic behaviors were 
often observed. On the other hand, R. kanmonensis, a sympatric species with 
R. speratus, showed strong agonistic behavior against different colonies of the 
same species as well as of different species and no trophallactic contact was 
observed. These results suggest that R. speratus has colony fusion as already 
described in Matsuura & Nishda (2001), while R. kanmonensis so strongly 
exclude non-nestmate individuals that colony fusion can not occur. Kitade 
et al. (2004) showed the lack of mitochondrial haplotype variation in R. 
kanmonensis within a mature nest and the aggregated distribution of found-
ing colonies nested in small branches. This indicated that worker mingling 
did not occur in R. kanmonensis and founding colonies were under a strong 
intraspecific competition with mature colonies, resulting in a low survival rate 
of incipient colonies. In agreement with these results of Kitade et al. (2004), 
our data showed strong intraspecific competition and at the same time a lack 
of colony fusion in the case of R. kanmonensis. 

For some Reticulitermes species, occurrences of colony fusion have been 
reported, and it is known that the frequency of the phenomenon is highly 
variable depending on populations (Bulmer & Traniello 2002; DeHeer & 
Vargo 2004,2008; Leniaud et al. 2009; Matsuura & Nishida 2001; Nobre 
et al. 2008; Perdereau et al. 2010a). Perdereau et al. (2010a), among others, 
investigated the social organization of R. flavipes with a special interest in 
invading species and reported that colony fusion occurred more frequently in 
introduced populations of France than in native populations of North America. 
The occurrence of colony fusion may be thought of as a key to lowering the 
cost for the intraspecific competition. This provides one possible mode of 
ecological advantage. In invaded habitats, colony fusion can be understood 



1213 Takematsu, Y. & K. Kambara — Nestmate Recognition in Sympatric Reticulitermes sp.

as a mechanism that is favorable for the invasive success to attaining high 
worker densities and interspecific dominance. In many social insects, shifts in 
the social organization have already been observed and thought to contribute 
to invasive success (as was summarized by Perdereau et al. 2010a). Leniaud 
et al. (2009) also reported unicoloniality and low intraspecific aggression 
of R. urbis, an invading species in France, resulting in invasive success in the 
introduced region.

Since this is a case of R. kanmonensis being introduced into ranges where 
another ecologically more potent species is dominant, then it might have been 
thought that R. kanmonensis without the ability of colony fusion is unlikely to 
survive in such ecologically recessive environments. However, R. kanmonensis 
persisted for more than a century in such an area. The present result suggests 
that this long-term persistence was attained without resort to the ability of 
colony fusion. In this respect, it is to be noted that R. kanmonensis has a 
specific flexibility in the choice of habitats; that is R. kanmonensis tends to 
choose less favorable habitats (houses or living woods) when coexisting with 
R. speratus (Kambara & Takematsu 2009). To date, the original distribution 
of R. kanmonensis is not clear. It may be of interest to clarify the original 
distribution of R. kanmonensis and the social organization in that area. 

Cuticular hydrocarbons are generally considered as an important cue for 
interspecific and colony recognition (Clément & Bagnères 1998). It has 
been well accepted that the cuticular hydrocarbon compositions are different 
qualitatively at the specific level, whereas there are quantitative differences 
at the intraspecific level (Howard 1993; Haverty et al. 1997). Perdereau et 
al. (2010b) investigated the cuticular hydrocarbons of native and intro-
duced populations of R. flavipes and reported the remarkable hydrocarbon 
homogeneity observed within the introduced populations compared to the 
native populations due to a reduction of genetic diversity through a genetic 
bottleneck or a selective process for the less common alleles of recognition. 
Perdereau et al. (2010b) also assumed that the homogeneity of cuticular hy-
drocarbons in introduced populations of R. flavipes could explain the lack of 
intraspecific aggression and, indirectly, the high rate of colony fusion within 
these introduced populations

The present study shows the homogeneity of cuticular hydrocarbons in R. 
kanmonensis compared to R. speratus. This phenomenon can be explained 



1214  Sociobiolog y Vol. 59,  No. 4, 2012

as a reduction of genetic diversity in the invading species as reported in Per-
dereau et al. (2010b). However, based on the results of agonistic behavior, R. 
kanmonensis, an invading species, showed strong intraspecific competition in 
spite of the homogeneity of cuticular hydrocarbons. Therefore in the pres-
ent study, the intensity of agonistic behavior seems to depend not only on 
cuticular hydrocarbon-related factors but on other features of each species 
such as ecological or genetic traits.

ACKNOWLEDGMENTS

We thank Dr. O. Kitade (Faculty of Science, Ibaraki University) for use-
ful and valuable comments on field sampling. This study is supported by 
KAKENHI (No. 16580039).

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