DOI: 10.13102/sociobiology.v62i2.276-280Sociobiology 62(2): 276-280 (June, 2015)

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

Second Record and DNA Barcode of the Ant Tyrannomyrmex rex Fernández (Hymenoptera: 
Formicidae: Myrmicinae)

Introduction

The ant genus Tyrannomyrmex (Fig 1) is relatively 
small and endemic to tropical broadleaf wet forests of South 
and Southeast Asia (Indomalaya biogeographic region, Udvardy, 
1975; Olson et al., 2001). The genus was described from peninsular 
Malaysia based on a single worker, which was designated as T. 
rex (Fernández, 2003). Since then, two new species have been 
described: T. dux, from India (Borowiec, 2007), and T. legatus, 
from Sri Lanka (Alpert, 2013), both known from a single worker. 
The genus has been recently collected in Borneo (Fisher et 
al., in press), and it is possible that it has been found in the 
Philippines as well. Indeed, a single male collected in 1965 in 
the Philippines has been putatively placed in the genus based 
on the similarity of petiole shape and mandibular teeth with 
the worker described by Fernández (2003), but this placement 
needs to be confirmed (General & Alpert, 2012; Alpert, 2013).

Abstract 
Tyrannomyrmex is a rarely collected ant genus from Old World tropical forests 
comprising only three described species, all of them known from a single 
worker. Here we report the discovery of a second worker of Tyrannomyrmex 
rex from a selectively logged primary forest of Singapore, increasing the known 
distribution range of the species to nearly 250 km South-East. We also provide 
a DNA barcode for the species and a partial sequence of the wingless gene. 
Although insufficient evidence prevents us to draw any firm conclusion, the 
genus seems to be restricted to pristine or relatively undisturbed forests and, 
as a result, could be highly sensitive to habitat degradation.

Sociobiology
An international journal on social insects

J Jacquemin1, G Sonet1, T Bourguignon2, 3, TA Evans2, T Delsinne1,4

Article History

Edited by
Rodrigo M. Feitosa, UFPR, Brazil.
Received                          26 December 2014
Initial acceptance           30 January 2015
Final acceptance             12 February 2015

Keywords 
Solenopsidini, Singapore, primary forest, leaf-
litter ant, DNA barcoding, scanning electron 
microscopy.

Corresponding author
Justine Jacquemin
OD Nature (ATECO), Royal Belgian Institute 
of Natural Sciences, 29 Rue Vautier, 
B-1000 Brussels, Belgium
E-Mail: jjacquemin@naturalsciences.be

Tyrannomyrmex is placed in the Myrmicinae. The 
principal traits of this rarely collected and documented 
genus are mandibles with only two apical teeth, and inner 
margin of the edentate masticatory border of the mandibles 
with setae. These setae are modified in T. rex (i.e. thick 
and cylindrical) (Fig 2c., d.) but simple and similar to 
other setae of the body in T. dux and T. legatus. The three 
species have small eyes reduced to a few ommatidia (Fig 
2a.), 11-segmented antennae with an ill-defined 3-segmented 
club (Fig 1a., b., c.) and an apparent palpal formula 2,2 (the 
formula could not be reliably determined in T. dux). Also, the 
mesosoma does not present any groove or suture, forming a 
single broad and continuous convexity in side view (Fig 1c) 
and the metapleural gland seems to be lacking (Fernández, 
2003; Borowiec, 2007; Fig 1d., 2e., f.).

The reliable placement of Tyrannomyrmex among the 
Myrmicinae was tentative based on morphological data only. 

RESEARCH ARTICLE - ANTS

1 - Royal Belgian Institute of Natural Sciences, Brussels, Belgium 
2 - Department of Biological Sciences, National University of Singapore 
3 - Czech University of Life Sciences, Prague, Czech Republic
4 - Universidad Técnica Particular de Loja, Loja, Ecuador 



Sociobiology 62(2): 276-280 (June, 2015) 277

Based on morphological characters (i.e. presence of transformed 
setae along internal border of mandibles), Fernández (2003) 
suggested that the genus was close to the Adelomyrmecini 
and to the Solenopsidini tribes (according to the taxonomy of 
that time). Alpert (2013) suggested that Tyrannomyrmex was 
close to Monomorium, a member of the Solenopsidini, by 
using the comprehensive morphology-based treatment of the 
Formicidae described by Bolton (2003). A recent phylogeny 
of the Myrmicinae, based on 11 nuclear gene fragments, 
confirmed that Tyrannomyrmex belongs to the Solenopsidini, 
albeit this clade was somehow redefined (Ward et al., 2015). 
According to this work, Tyrannomyrmex legatus is the sister 
taxon to Monomorium latinode + M. brocha, two species 
distributed mostly in tropical Asia, similar to Tyrannomyrmex. 
It should be noted that M. brocha has been transferred to the 
genus Epelysidris and a new genus under description by Barry 
Bolton will be erected for M. latinode (Ward et al., 2015).

Here, we report the discovery of a second worker of 
T. rex, which becomes therefore the first duplicate (species 
known from two individuals) of the genus. The specimen is 
documented by high resolution pictures and SEM photographs 
and its DNA barcode is provided.

Materials and methods

We collected the ant specimen in December 2012 in 
MacRitchie Reservoir, Singapore (N 01°20’30’’, E 103°49’43’’), 
during a biodiversity survey of the ants from Singapore. It was 
found in a selectively logged primary forest not exploited for 
decades, comprising primary forest species at an intermediate 
stage of regeneration. While the plant species composition 
was that of a primary forest, it lacked large emergent trees 
present in adjacent unlogged primary forest. The site was 
located near an old growth primary forest.

Altogether, we collected 5525 ant specimens in six 
sites and 877 specimens in the site in which T. rex was 
collected. The sampling consisted of 25 samples of leaf-
litter (1 m² each) collected in each site and placed in Berlese 
extractors. The extractors consisted of a plastic funnel heated 
with a 100 Watt light bulb which we kept running for two to 
five days, until the leaf litter was completely dried out. We 
preserved all specimens in 80% ethanol until identification. 
The T. rex individual was mounted for photography and a 
hind leg was dissected immediately afterwards for DNA 
analysis.

Fig 1. High resolution pictures of the Tyrannomyrmex rex worker collected in Singapore. Dorsal (a.), frontal (b.) and lateral (c.) views, 
and a close-up lateral view of the propodeum, petiole and postpetiole (d.).



J Jacquemin, G Sonet, T Bourguignon, TA Evans, T Delsinne - New Record of Tyrannomyrmex rex278

We took high resolution digital images using a Leica 
MC170 camera attached to a Leica S8APO stereomicroscope. 
A series of images was taken by focusing the sharpness on 
different levels of the specimen, using the Leica Application 
Suite v38 (2003-2011) and combined with the stacking software 
Combine ZP (Hadley, 2010). Final editing of the images was 
done in Adobe Photoshop CS5. SEM photographs of the 
specimen were taken using a scanning electron microscope 
FEI Quanta 200. The specimen is deposited at the Royal 
Belgian Institute of Natural Sciences, Brussels, Belgium 
(SPM_ID 4904401; RBINS general inventory 33045).

We extracted DNA from one hind leg using the commercial 
NucleoSpin Tissue Kit (Macherey-Nagel, Germany) and performed 
the PCR amplification of the 5’ end of the mitochondrial cytochrome 
c oxidase subunit I (COI) marker (standard DNA barcode region) 
and a fragment of the wingless gene (Wg). PCR amplification and 
bidirectional DNA sequencing were executed according to 
the protocol described by Delsinne et al. (2012) and using 
the primer pairs LCO1490 / HCO2198 (Folmer et al., 1994) 
for COI, and Wg578F (Ward & Downie, 2005) / Wg1032R 
(Abouheif & Wray, 2002) for Wg. Using the BLAST algorithm 
(Altschul et al., 1990), we searched through GenBank and 

The Barcode of Life Data System (Ratnasingham & Hebert, 
2007) for best matches with the two sequences obtained 
here. Finally, the same two sequences were compared to all 
COI and Wg sequences available for the tribe Solenopsidini 
in GenBank. Alignments, pairwise uncorrected p-distances 
(proportion of nucleotide sites at which two sequences differ) 
and a neighbor-joining tree were calculated using MEGA 6.06 
(Tamura et al., 2013).

Results and discussion

The COI barcode of T. rex (GenBank accession number: 
KP294328) has never been sequenced before and is markedly 
different from all COI sequences available in GenBank and 
BOLD (< 86% similarity). The best matches involve species of 
the genera Pheidole and Monomorium.

The GenBank sequence that matches the best with our T. 
rex Wg (GenBank accession number: KP294329) is the single 
Wg sequence already available for the genus Tyrannomyrmex 
(accession number: KJ861941; species: Tyrannomyrmex 
legatus). On the basis of this marker, the distance between T. 
rex and T. legatus is 2.8% whereas the inter-generic distances 
between T. rex and any other Solenopsidini sequence range 
from 3.4 to 9.6% (Fig 3).

Fig 2. Close-up SEM pictures of Tyrannomyrmex rex illustrating the 
eye composed of 6 ommatidia (a.), the very short appressed hairs 
located within foveae on the pronotum (b.), the modified stout and 
cylindrical setae on the inner margin of the masticatory border of 
the mandible (dorsal view c., lateroventral view d.), the large and 
round propodeal lobe (e.), and an oblique view of the metapleuron 
(f.). Note the absence of metapleural gland orifice on (e.) and (f.).

Fig 3. Unrooted neighbor-joining tree based on pairwise p-distances 
among all Solenopsidini wingless sequences available in GenBank.



Sociobiology 62(2): 276-280 (June, 2015) 279

The discovery of a second specimen of T. rex expands 
the known range of the species to nearly 250 km to the South-
East of the only other known location in Malaysia. It also 
expands the known altitudinal range of the genus, from sea 
level (24 m; this study) to 1300-1500 m (T. dux) (T. legatus was 
discovered at intermediate elevation, between 432 and 571 m).

It is worth mentioning that Tyrannomyrmex rex seems 
to be rare at the scale of the country. Indeed, the specimen 
mentioned is the single one discovered despite our recent 
efforts to document leaf-litter ant assemblages from other 
Singaporean forested sites, representative of both degraded 
and pristine habitats (six sites; 25 Berlese samples per 
site). However, this apparent rarity could result from a 
methodological artifact since the morphology of the genus 
suggests subterranean habits and the Berlese extraction 
of leaf-litter fauna is not the more efficient method for 
documenting hypogean ants.

Interestingly and as anteriorly noted (Fernández, 
2003; Borowiec, 2007), the genus seems to lack a functional 
metapleural gland (Fig 1d., Fig 2e., f.), a structure unique to 
ants and playing a key role in sanitation and chemical defense 
(Yek & Mueller, 2011). This gland has been secondarily lost 
is some ant lineages, mostly in social parasites and arboreal 
formicines, probably because their life histories render them 
less exposed to pathogens than ground-dwelling species 
(Yek & Mueller, 2011 and references therein). Its absence 
in Tyrannomyrmex, a probable hypogean genus, suggests 
either that these ants could be social parasites or that they 
possess other protections against pathogens as observed for 
instance in some Camponotus (Walker & Hughes, 2011) and 
Polyrhachis species (Graystock & Hughes, 2011). Additional 
material and anatomical studies are obviously required to test 
these hypotheses.

The unique specimen of T. legatus was found in an 
undisturbed and unlogged lowland dipterocarp forest in Sri 
Lanka, and the T. rex individual studied by Fernández (2003) 
was collected in a forest reserve. We found the second T. rex 
worker in a selectively logged primary forest unexploited 
for decades, very similar in terms of vegetation composition 
to the primary forest nearby. Although information about the 
habitat where T. dux was collected is lacking, available data 
suggest that this rarely collected genus occurs in pristine 
or little disturbed tropical forests of Asia. Singapore has 
lost more than 95% of its original forest over the last two 
centuries leading to a massive extinction of its biodiversity 
(Brook et al., 2003). Fortunately, efforts were recently 
made to preserve the remaining pristine areas of the island, 
to improve the biodiversity value of secondary forests 
and urban areas, and to increase the connectivity among 
green patches (Fam et al., 2014; Tan & Hamid, 2014). The 
presence of Tyrannomyrmex rex, a species suspected to be 
restricted to well-preserved tropical forests, points out that 
efforts for maintaining Singaporean biodiversity are worth 
being pursued.

Ackowledgments

We warmly thank Julien Cillis (RBINS) for SEM 
photographs and Lee Gang for field assistance. This work 
was supported by the LHK fund of the National University of 
Singapore; by the Singapore-MIT Alliance for Research and 
Technology; by the Belgian Federal Science Policy Office 
(BELSPO) through an Action 1 Impulse for Research and 
by the SENESCYT through its Prometeo grant to TD (http://
prometeo.educacionsuperior.gob.ec/); and by the Internal Grant 
Agency of the Faculty of Forestry and Wood Sciences, Czech 
University of Life Sciences (registration number A08/14). 

References

Abouheif, E. & Wray, G.A. (2002). Evolution of the gene 
network underlying wing polyphenism in ants. Science, 297: 
249-252. DOI: 10.1126/science.1071468

Alpert, G.D. (2013). A new species of Tyrannomyrmex 
(Hymenoptera: Formicidae) from Sri Lanka. Zootaxa, 3721: 
286-290. DOI: 10.11646/zootaxa.3721.3.5

Altschul, S.F., Gish, W., Miller, W., Myers, E.W. & Lipman, 
D.J. (1990). Basic local alignment search tool. Journal of 
Molecular Biology, 215: 403-410. doi: 10.1016/S0022-
2836(05)80360-2

Bolton, B. (2003). Synopsis and Classification of Formicidae. 
Memoirs of the American Entomological Institute, 71: 1-370

Borowiec, M.L. (2007). A new species of Tyrannomyrmex 
(Hymenoptera: Formicidae: Myrmicinae) from India. 
Zootaxa, 1642: 65-68

Brook, B.W., Sodhi, N.S. & Ng, P.K.L. (2003). Catastrophic 
extinctions follow deforestation in Singapore. Nature, 424: 
420-423. doi: 10.1038/nature01795

Delsinne, T., Sonet, G., Nagy, Z.T., Wauters, N., Jacquemin, 
J. & Leponce, M. (2012). High species turnover of the ant 
genus Solenopsis (Hymenoptera : Formicidae) along an 
altitudinal gradient in the Ecuadorian Andes, indicated by 
a combined DNA sequencing and morphological approach. 
Invertebrate Systematics, 26: 457-469. doi: 10.1071/IS12030

Fam, S.D., Lee, B.P.Y-H. & Shekelle, M. (2014). The conservation 
status of slow lorises Nycticebus spp. in Singapore. Endangered 
Species Research, 25: 69-77. doi: 10.3354/esr00599

Fernández, F. (2003). A new myrmicine ant genus from 
Malaysia with uncertain affinities (Hymenoptera: Formicidae). 
Zootaxa, 341: 1-6

Fisher, B.L., Guénard, B. & Robson, S. Borneo, fANTastique! 
Asian Myrmecology (in press)

Folmer, O., Black, M., Hoeh, W., Lutz, R. & Vrijenhoek, 
R. (1994). DNA primers for amplification of mitochondrial 
cytochrome C oxidase subunit I from diverse metazoan 



J Jacquemin, G Sonet, T Bourguignon, TA Evans, T Delsinne - New Record of Tyrannomyrmex rex280

invertebrates. Mol Mar Biol Biotech, 3: 294-299

General, D.M. & Alpert, G.D. (2012). A synoptic review of 
the ant genera (Hymenoptera, Formicidae) of the Philippines. 
ZooKeys, 200: 1-111. DOI: 10.3897/zookeys.200.2447

Graystock, P. & Hughes, W.O.H. (2011). Disease resistance 
in a weaver ant, Polyrhachis dives, and the role of antibiotic-
producing glands. Behavioral Ecology and Sociobiology, 65: 
2319-2327

Hadley, A. (2010). CombineZP, Available from: http://www.
hadleyweb.pwp.blueyonder.co.uk/CZP/News.htm [6.vi.2010]

Olson, D.M., Dinerstein, E., Wikramanayake, E.D., Burgess, 
N.D., Powell, G.V.N., Underwood, E.C., D’amico, J.A., Itoua, 
I., Strand, H.E., Morrison, J.C., Loucks, C.J., Allnutt, T.F., 
Ricketts, T.H., Kura, Y., Lamoreux, J.F., Wettengel, W.W., 
Hedao, P. & Kassem, K.R. (2001). Terrestrial ecoregions of 
the world: a new map of life on earth. Bioscience, 51: 933-938

Ratnasingham, S. & Hebert, P.D.N. (2007). BOLD: The 
Barcode of Life Data System (www.barcodinglife.org). 
Molecular Ecology Notes, 7: 355-364. doi: 10.1111/j.1471-
8286.2006.01678.x

Tamura, K., Stecher, G., Peterson, D., Filipski, A. & Kumar, 
S. (2013). MEGA6: Molecular evolutionary genetics analysis 
version 6.0. Molecular Biology and Evolution, 30: 2725-
2729. doi: 10.1093/molbev/mst197

Tan, P.Y. & Hamid, A.R.b.A. (2014). Urban ecological 
research in Singapore and its relevance to the advancement of 
urban ecology and sustainability. Landscape Urban Plan, 125: 
271-289. doi: 10.1016/j.landurbplan.2014.01.019

Udvardy, M.D.F. (1975). A classification of the biogeographical 
provinces of the world. Morges (Switzerland): International 
Union of Conservation of Nature and Natural Resources. 
IUCN Occasional Paper no. 18

Walker, T.N. & Hughes, W.O.H. (2011). Arboreality and the 
evolution of disease resistance in ants. Ecological Entomology, 
36: 588-595. doi: 10.1111/j.1365-2311.2011.01312.x

Ward, P.S. & Downie, D.A. (2005). The ant subfamily 
Pseudomyrmecinae (Hymenoptera: Formicidae): Phylogeny and 
evolution of big-eyed arboreal ants. Systematic Entomology, 
30: 310-335. doi: 10.1111/j.1365-3113.2004.00281.x

Ward, P.S., Brady, S.G., Fisher, B.L. & Schultz, T.R. (2015). 
The evolution of myrmicine ants: phylogeny and biogeography 
of a hyperdiverse ant clade (Hymenoptera: Formicidae). 
Systematic Entomology, 40: 61-80. doi: 10.1111/syen.12090

Yek, S.H. & Mueller, U.G. (2011). The metapleural gland of 
ants. Biological Review, 86: 774-791. doi: 10.1111/j.1469-
185X.2010.00170.x