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

DOI: 10.13102/sociobiology.v68i2.6159Sociobiology 68(2): e6159 (June, 2021)

Termites play important roles in ecosystems, especially 
as decomposers and soil engineers (Bignell & Eggleton, 
2000; Holt & Lepage, 2000). Termites can also cause serious 
structural damage to buildings, crops, and plantation forests 
(Su & Scheffrahn, 2000; Rouland-Lefèvre, 2010). Some 
termite species have been introduced outside their native 
ranges, where they have become invasive, and caused 
substantial economic, and possible ecological impacts 
(Evans, 2010; Evans et al., 2013). Evans et al. (2013) 
recognized 28 invasive termite species and found that 
they all shared three characteristics: they eat wood, nest in  
wood, and easily generate secondary reproductives. To date, 
seven termite species, which are considered to have been 
introduced, are established in Japan: Zootermopsis nevadensis 
(Hagen), Incisitermes immigrans (Snyder), I. minor (Hagen), I. 

Abstract  
Some termites have been introduced outside their native ranges, and it has 
been suggested that both wood-eating and wood-nesting lifestyles are critical 
for the transportation of propagules. Here, we present the first record of 
the soil-feeding and soil-nesting termite Pericapritermes nitobei (Isoptera: 
Termitidae) in the Motobu Peninsula on the northern part of Okinawa Island in 
the Central Ryukyus. The fact that previous extensive surveys of termites in the 
Ryukyu Archipelago did not detect P. nitobei in the Central Ryukyus, including 
the Motobu Peninsula, and its discontinuous distribution, suggest that P. 
nitobei has been recently introduced into the Motobu Peninsula of Okinawa 
Island from the Yaeyama Islands, similar to the fungus-growing and soil-
nesting termite Odontotermes formosanus (Isoptera: Termitidae). Together 
with O. formosanus in the southern part of Okinawa Island, our findings raise 
the possibility that non-wood-feeding and non-wood-nesting termites can be 
introduced outside their native ranges by human activities.

Sociobiology
An international journal on social insects

Tomonari Nozaki1,3, Masaru Hojo2,4, Toshihisa Yashiro3*, Kenji Matsuura3

Article History

Edited by
Paulo Cristaldo, UFRPE, Brazil
Received                  24 December 2020
Initial acceptance   16 March 2021
Final acceptance    08 April 2021
Publication date     31 May 2021 

Keywords 
Biological invasions, invasive termites, 
Pericapritermes nitobei, social insects, 
the Ryukyu Archipelago.

Corresponding author 
Tomonari Nozaki
Laboratory of Evolutionary Genomics,  
Center for the Development of New 
Model Organisms, National Institute 
for Basic Biology
Okazaki 444-8585, Japan
E-Mail: tomonari64.1.8@gmail.com

schwarzi (Banks), Coptotermes formosanus Shiraki, C. gestroi 
(Wasmann), and Reticulitermes kanmonensis Takematsu 
(Morimoto & Ishii, 2000; Kitade & Hayashi, 2002; Ohmura & 
Tokoro, 2003; Ide et al., 2016; Yashiro et al., 2018). Although 
two of these termite species (I. schwarzi and R. kanmonensis) 
have not been listed as invasive by Evans et al. (2013), 
they also have the above-mentioned three characteristics of 
invasive termites (Luykx, 1986; Kitade et al., 2011).

The Ryukyu Archipelago of Japan is located in 
the subtropical zone of the western Pacific Ocean between 
mainland Japan and Taiwan. Faunistically, the Ryukyu 
Archipelago is classified into three regions: the Northern, 
Central, and Southern Ryukyus, based on their relation to 
the Tokara and Kerama gaps (Fig 1A, Kimoto, 1967; Ota, 
1998; Motokawa, 2000). It has been known that the higher 

1 - Laboratory of Evolutionary Genomics, National Institute for Basic Biology, Japan
2 - Global Education Institute, University of the Ryukyus, Japan
3 - Laboratory of Insect Ecology, Graduate School of Agriculture, Kyoto University, Japan
4 - National Cheng Kung University, Taiwan
*Present address: Division of Agro-Environment Research, Kyushu Okinawa Agricultural Research Center, NARO, Koshi, Japan

SHORT  NOTE

First Record of the Soil-feeding Higher Termites (Isoptera: Termitidae) from Okinawa 
Island, the Central Ryukyus, Japan

ID           

https://orcid.org/0000-0003-4358-8118


Tomonari Nozaki, Masaru Hojo, Toshihisa Yashiro, Kenji Matsuura – First record of Pericapritermes on Okinawa Island in Japan2

termites (family Termitidae) of the Ryukyu Archipelago are 
distributed only in the southern Ryukyus, including Ishigaki 
and Iriomote Islands, which are part of the Yaeyama 
Islands with one exception, the fungus-growing termite 
Odontotermes formosanus (Shiraki), which is distributed not 
only on the Yaeyama Islands, but also on the Okinawa 
Islands in the Central Ryukyus (Ikehara, 1966; Yasuda et 
al., 2000). It is suggested that the O. formosanus found on 
the Okinawa Islands has been introduced from the Yaeyama 
Islands (presumably from Iriomote Island), based on its 
discontinuous and restricted distribution on Okinawa Island 
(Hojo, 2019). In this study, we report the unusual findings of a 
population of the soil-feeding higher termite Pericapritermes 
nitobei (Shiraki) (Isoptera: Termitidae) on the northern part 
of Okinawa Island in the Central Ryukyus, as this species is 
native to the Yaeyama Islands and other regions (Taiwan, 
mainland China, and Southeast Asia) (Ikehara, 1966; Yasuda 
et al., 2000; Krishna et al., 2013).

On February 6th, 2017, we found a termite colony 
having soldiers with a twisted left mandible and curved right 
mandible (i.e., asymmetric snapping mandibles) from the 
soil in the Motobu Peninsula in the northern part of Okinawa 
Island (Fig 1B). Based on the soldier morphology, termites 
from that colony were suggested to belong to Pericapritermes 
(Bourguignon et al., 2008). This genus contains only one known 
species in the Ryukyu Archipelago, P. nitobei (Ikehara, 1966; 
Yasuda et al., 2000). During the second survey conducted on 
June 3rd and 4th, 2019, we successfully collected six colonies 
of Pericapritermes from the soil and observed egg piles in 
three of the six colonies (Table 1). These colonies were at least 
100 m apart; the distribution was limited in the roadside forest 
(Fig 1C). The collected termites were fixed in absolute ethanol 
and brought back to the laboratory.

In order to confirm the identity of the termite species 
collected in the Motobu Peninsula and to clarify its relationship 
to other Pericapritermes species, we performed a phylogenetic 
analysis based on the sequences of the mitochondrial cytochrome 
c oxidase subunit II (COII) gene. One randomly chosen worker 
from the six colonies of the termite from the Motobu Peninsula 
was used for the phylogenetic analysis. Termite DNA was 
extracted from the head using the DNeasy Prep kit (QIAGEN) 
according to the manufacturer’s protocol and used as a template 
for polymerase chain reaction (PCR). A fragment of COII 
was amplified by PCR using the primer set, modified A-tLeu 
(5′-CAGATAAGTGCATTGGATTT-3′) (Miura et al., 1998) 
and B-tLys (5′- GTTTAAGAGACCAGTACTTG -3′) (Liu & 
Beckenbach, 1992). The PCR amplification was performed in 
20 μL total reaction volumes containing 10 μL of PrimeSTAR 
HS DNA Polymerase (Takara), 0.6 μL of each primer 
(10 μM), 1 μL of template DNA, and 7.8 μL of high-purity 
water. The PCR cycling conditions consisted of 35 cycles 
of denaturation (98°C, 10 s), annealing (50°C, 5 s), and 
extension (72°C, 1 min). Amplified double-stranded DNA 
was purified using a QIAquick PCR purification kit (Qiagen) 

and then sent to an outside sequence service (FASMAC Inc., 
Kanagawa, Japan). We obtained 684 bp COII sequences. 
Consensus sequences were aligned using the ClustalX 
algorithm (Thompson et al., 1997) from the BioEdit 7.0.4.1 
sequence editor (Hall, 1999) and corrected manually. The 
COII sequences of P. nitobei in its native range (including 
Ishigaki Island, Iriomote Island, Taiwan, and mainland 
China) (GenBank accession numbers (GB#) AB109517, 
MH194575, and MW073093–MW073099) and other termitid 
species (GB# AB109518, DQ442140, DQ442217, KP026278, 
and KY224616) were also used in the analysis. Bayesian 
inference was performed using MrBayes 3.1.2 (Ronquist 
et al., 2003) with the GTR + G model selected by the 
hierarchical likelihood ratio test (hLRT) in MrModeltest 2.3 
(Nylander et al., 2004). Homallotermes eleanorae Emerson 
(GB# DQ442140) was used as an outgroup. The phylogenetic 
analysis methods have been described in a previous report 
(Yashiro et al., 2010). Additionally, we analyzed the obtained 
nuclear internal transcribed spacer 2 (ITS2) sequences (264 
bp) of the termite from the Motobu Peninsula and the ITS2 
sequences of P. nitobei in its native range (GB#MW067661–
MW067667). Primer sequences and PCR conditions are 
detailed in a previous report (Maryańska-Nadachowska et 
al., 2010), and PCR product purification and sequencing were 
conducted as described above. The COII and ITS2 sequences 
obtained in this study were deposited in the DDBJ/EMBL/
GenBank nucleotide sequence databases (GB# MW073087–
MW073092 and MW067655–MW067660).

All of the mitochondrial COII sequences of individuals 
from the six colonies obtained from the Motobu Peninsula 
of Okinawa Island were identical to each other (GB# 
MW073087–MW073092), and to one of two haplotypes of 
P. nitobei on Ishigaki and Iriomote of the Yaeyama Islands 
(GB# MW073093–MW073096, and MW073098) (Fig 2). 
Therefore, the termite collected from the Motobu Peninsula 
were phylogenetically identified as P. nitobei. Phylogenetic 
trees based on mitochondrial COII sequences showed the 
monophyly of P. nitobei, including individuals from the 
Motobu Peninsula, the Yaeyama Islands, Taiwan, and mainland 
China populations (Bayesian posterior probability = 0.93), 
where individuals from the six colonies from the Motobu 
Peninsula formed a clade with those from the Yaeyama Islands 
(Bayesian posterior probability = 0.91) (Fig 2). In addition, all 
of the nuclear ITS2 sequences of individuals from 12 colonies 
of P. nitobei in the Ryukyu Archipelago (six in the Motobu 
Peninsula, one on Ishigaki Island, and five on Iriomote Island) 
were identical to each other (GB# MW067655–MW067666), 
but these sequences were different from the ITS2 sequence 
of P. nitobei in Taiwan (GB# MW067667) (98% sequence 
identity). Considering the fact that the previous extensive 
surveys of termites in the Ryukyu Archipelago (including 
the Motobu Peninsula) did not detect P. nitobei on Okinawa 
Island (Fig 1A, Ikehara 1966; Yasuda et al., 2000), and its 
discontinuous distribution, approximately 350 km east of the 



Sociobiology 68(2): e6159 (June, 2021) 3

Fig 1. The soil feeding termite collected in the Motobu Peninsula of Okinawa Island. (A) The map of the Ryukyu Archipelago. (B) A photo 
of the termite, which was phylogenetically identified as Pericapritermes nitobei. The inset is an enlarged view of soldier head with a twisted 
left mandible and curved right mandible. (C) The map showing Motobu peninsula and the collection sites in the survey on June 2019. Filled 
and open circles indicate the presence and absence of the termite, respectively. Maps were drawn by the “maptools” in the R software (version 
3.6.2; http://cran.r-project.org/) with the data provided by National Land Numerical Information, Ministry of Land, Infrastructure, Transport 
and Tourism, Japan (https://nlftp.mlit.go.jp/index.html).



Tomonari Nozaki, Masaru Hojo, Toshihisa Yashiro, Kenji Matsuura – First record of Pericapritermes on Okinawa Island in Japan4

previous easternmost record of the species (Ishigaki Island, 
the Yaeyama Islands) (Fig 1A, Ikehara, 1966; Yasuda et al., 
2000; Krishna et al., 2013), our results strongly suggest that P. 
nitobei in the Motobu Peninsula has been recently introduced 
from the Yaeyama Islands. 

We found the soil feeding higher termite P. nitobei in 
the Motobu Peninsula in the Central Ryukyus in 2017 and 
2019, and observed egg piles, indicating the establishment 
of a population. The termite is most likely to have been 
recently introduced from the Yaeyama Islands in the 
Southern Ryukyus, as is suspected for the fungus-growing 
higher termite O. formosanus on Okinawa Island (Hojo, 
2019). Interestingly, both are soil-nesting species (Chiu et 
al., 2015; Chiu et al., 2018). Trade in live plants with soil is 
an important pathway facilitating long-distance invasions of 
soil-borne insects (Meurisse et al., 2019). So far, several tree 
and shrub species have been introduced from the Yaeyama 

Islands into public parks on Okinawa Island, as well as in 
the Motobu Peninsula (Ocean Expo. Commemorative Park 
Management Foundation (1997)); therefore, soil transferred 
with live plants is one of the possible introduction pathways 
for these termites.

Our finding raised the possibility that not only wood-
feeding and wood-nesting termites, but also soil-feeding 
termites can be introduced and established outside their 
native ranges by human activities. Although many aspects of 
its biology (including the capability of producing secondary 
reproductives) and its impact on other organisms in the 
ecosystem remains to be investigated, the population of P. 
nitobei on the Motobu Peninsula of Okinawa Island, together 
with the population of O. formosanus on Okinawa Island, 
would provide a promising model system for the study of 
biological invasion by non-wood-feeding and non-wood-
nesting termites.

Fig 2. Bayesian phylogenetic tree of Pericapritermes termites based on mitochondrial COII sequences, including the soil 
feeding termite in the Motobu Peninsula, which was identified as P. nitobei (presented in bold). The corresponding posterior 
probabilities (≥ 0.70) are shown by the branches. GenBank accession numbers are shown in parentheses.



Sociobiology 68(2): e6159 (June, 2021) 5

Acknowledgments

We thank S. Shigenobu for the experimental equipment 
and the space, and N. Idogawa, W. Yao, and K. Watanabe 
for sample collection. We also appreciate M. Ohkuma for 
providing information about P. nitobei on Iriomote Island, and 
anonymous reviewers for critical review of the manuscript. 
This study was supported by funding from the Japan Society 
for the Promotion of Science to T.N. (Research Fellowship for 
Young Scientists No. 16J08955 and No. 19J01756) and K.M. 
(Kiban Kenkyu S No. 25221206 and No. 18H05268).

Authors Contribution

TN: Conceptualization, Validation, Investigation, Resources, 
Data Curation, Writing – Original Draft, Writing - Review & 
Editing, Visualization, Supervision, Funding acquisition.
MH: Conceptualization, Investigation, Resources, Writing – 
Original Draft, Writing - Review & Editing.
TY: Validation, Formal analysis, Investigation, Resources, Data 
Curation, Writing – Original Draft, Writing – Review & Editing.
KM: Conceptualization, Investigation, Writing - Review & 
Editing, Funding acquisition.
TN and MH were equally contributed.

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