Thursday, May 8, 2014

Glimpsing Armadillo Ants

File:The Ants (Wilson Hölldobler book).jpg
One of the favorite books of my formative years (and also the favorite, I am sure, of a few others) was Bert Hölldobler and Edward O. Wilson's tome The Ants: a synthesis of the sum total of myrmecological knowledge up to 1990, and winner of the 1991 Pulitzer Prize in non-fiction (perhaps the only straight-up textbook to have ever done so; Yee, 2004). As an incipient preadolescent entomologist, my favorite part of the book's contents was the section devoted to collated line drawings and profiles of all ant genera considered valid at the time (organized by subfamily).

Peruvian worker of T. tatusia; photograph by Erin Prado
By poring over these figures time and time again, I was gradually familiarized with the distinctive silhouettes of many an ant, solidifying the more morphologically peculiar ones in my memory (the adorably wacky Discothyrea comes to mind here). Among these more striking sketches was one detailing the morphology of a species by the name of Tatuidris tatusia, contained in the Myrmicinae: in my usual learning process, I looked the name up in the index to find if any data were contained elsewhere in the book on the taxon. But The Ants would yield no information on T. tatusia, other than that it was the sole extant member of the myrmicine (Carpenter, 1930) tribe Agroecomyrmecini. It made perfect sense to me that Tatuidris (the etymology of the name suggested the ant's epithet "armadillo"; Lacau et al., 2012) should have a tribe all to itself—what with its generally weird habitus (a combination of a prominent stinger, clubbed antennae, and distinctively heart-shaped face); but this strangeness further made me wonder whether it was genuinely myrmicine in identity (doubts that were incidentally shared by some taxonomists, as we shall see).

Aside from Tatuidris, the armadillo ants include only the extinct genera Agroecomyrmex (from Baltic amber; Wheeler, 1914) and Eulithomyrmex (from the Coloradoan Florissant Formation; Carpenter, 1935): both date to the Paleogene Period (the latter about 10 million years younger than the former; Ritzkowski, 1997; Foos & Hannibal, 1999). Their assignment to the Myrmicinae (one of the most speciose single subfamilies within the Formicidae) was made on the basis of morphological similarities to members of the tribe Phalacromyrmecini, and, to a lesser extent, Dacetini (Brown & Kempf, 1968; Brown, 1977; Bolton, 1984): these common characteristics include an expanded facial vertex and deepened scrobes* (the extension of which all the way back to the eyes is another distinctive quality of Tatuidris; Baroni Urbani & de Andrade, 2007). Right from the description of the first living agroecomyrmecine (T. tatusia) these traits were suspected of being only dubiously indicative of kinship (Brown & Kempf, 1968; Bolton, 1984): speciousness affirmed by the elevation of the Agroecomyrmecini to subfamily rank (Bolton, 2003), although the first fully cladistic analysis of T. tatusia affirmed its relation to the Dacetini and inclusion within the Myrmicinae (Baroni Urbani & de Andrade, 2007). 

Ecuadorian bullet ant (Paraponera clavata) photographed by Alex Wild (who else?)
Classifying armadillo ants within their own subfamily—as is the prevalent opinion at the moment—still begs an answer to their true phylogeny. Two opposing theories seem to have arisen on the matter of agroecomyrmecine placement within the Formicidae: one regards the subfamily as sister-group of the Myrmicinae (Bolton, 2003); the other, as within the grab-bag of "poneromorph" subfamilies (the Amblyoponinae, Ectatomminae, Heteroponerinae, Paraponerinae, Proceratiinae, and Ponerinae) which sit at the base of the "formicoid" clade in which the Myrmicinae is placed (Ward, 2009): specifically, close to the monotypic Paraponerinae (Brady et al., 2006) or near the Amblyoponinae (Rabeling et al., 2008). The results of one mainly morphological study resolve the ambiguity by deriving the Myrmicinae as both within the "poneroids" (Keller, 2011) and akin to the armadillo ants. 

Variation in pilosity patterns within T. tatusia (Donoso, 2012)
With all of this ambiguity, one can only wonder if biological data on the only extant armadillo ant would be at all informative in agroecomyrmecine phylogeny. T. tatusia has been collected throughout southern Mesoamerica and northern South America, reaching greatest abundance in upland areas (largely between 800 and 1,200 meters in altitude); the species includes multiple morphs throughout its range (which on one occasion caused the mistaken description of new species; Lacau et al., 2012) and exhibits  an unusual degree of intraspecific genetic variation: this suggests either that the population in fact consists of several cryptic species that taxonomists do not yet have the information to confidently delineate, or that it is a lineage in the process of allopatric speciation (Donoso, 2012).

Almost nothing is known of the habits of T. tatusia, given that until recently none had been observed in life: but its weirdly elongated stinger and thickly interlocking setae on the inner margins of the mandiblesnot to mention intramandibular glands clustered in a manner unknown in other ants (Billen & Delsinne, 2013)—have encouraged speculation on the ant's presumably unorthodox biology. In further tantalization, the discovery of the first live colony (containing erstwhile-unknown drones and queens) revealed only that armadillo ants have a diet that does not include the following likely items:

" ... live and dead termites, millipedes, mites, various insect parts, sugar water, tuna, biscuits, live and dead fruit flies (Drosophila), live springtails, live myriapods (Chilopoda and Diplopoda) [centipedes and millipedes], live and dead Diplura, small live spiders, small live pseudoscorpions, one small snail, uncooked hen egg ... ant larvae (Gnamptogenys sp.), and live ant workers (Cyphomyrmex sp., Brachymyrmex sp.)." (Donoso, 2012)
Hence, we can only assume that T. tatudris is a most specialized predator. Of what, precisely, remains to be seen whenever science captures its next glimpse of armadillo ants. 
                           

*Cephalic slots into which antennae can be retracted.
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Baroni Urbani, C. and de Andrade, M. L. (2007). The ant tribe Dacetini: limits and constituent genera, with descriptions of new species. Annali del Museo Civico di Storia Naturale "G. Doria", 99, 1-191.

Billen, J. and Delsinne, T. (2013). A novel intramandibular gland in the ant Tatuidris tatusia (Hymenoptera: Formicidae). Myrmecological News, 19, 61-64. Retrieved 5/8/14 from http://bio.kuleuven.be/ento/pdfs/billen_delsinne_myrmnews_2013.pdf

Bolton, B. (1984). Diagnosis and relationships of the myrmicine ant Ishakidris gen. n. (Hymenoptera: Formicidae). Systematic Entomology, 9, 373-382.

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

Brady, S. G.; Schultz, T. R.; Fisher, B. L.; and Ward, P. S. (2006). Evaluating alternative hypotheses for the early evolution and diversification of ants. Proceedings of the National Academy of Sciences of the United States of America, 103(48), 1817218177.

Brown, W. L. (1977). An aberrant new genus of myrmicine ant from Madagascar. Psyche, 84, 218-224.

Brown, W. L. and Kempf, W. W. (1968). Tatuidris, a remarkable new genus of Formicidae (Hymenoptera). Psyche, 74, 183-190.


Carpenter, F. M. (1930). The fossil ants of North America [electronic version]. Bulletin of the Museum of Comparative Zoology, 70(1), 1-66. Retrieved 5/7/14 from http://gap.entclub.org/taxonomists/Carpenter/1930.pdf

Carpenter, F. M. (1935). A new name for Lithomyrmex Carp. (Hymenoptera) [electronic version]. Psyche, 42(2), 91. Retrieved 5/6/14 from http://www.hindawi.com/journals/psyche/1935/068604/abs/   

Donoso, D. A. (2012). Additions to the taxonomy of the armadillo ants (Hymenoptera, Formcidae, Tatuidris) [electronic version]. Zootaxa, 3503, 61-81. Retrieved 5/8/14 from http://mapress.com/zootaxa/2012/f/zt03503p081.pdf 

Foos, A. and Hannibal, J. (1999). Geology of Florissant Fossil Beds National Monument. Retrieved 5/5/14 from http://www2.nature.nps.gov/geology/education/foos/flfo.pdf    

Hölldobler, B. and Wilson, E. O. (1990). The Ants. The Belknap University Press of Harvard University Press: Cambridge.

Lacau, S.; Groc, S.; Dejean, A.; de Oliveira, M. L.; and Delabie, J. H. C. (2012). Tatuidris kapasi sp. nov.: a new armadillo ant from French Guiana (Formicidae: Agroecomyrmecinae). Psyche, 2012(2012), 926089, 1-7. Retrieved 5/8/13 from http://www.hindawi.com/journals/psyche/2012/926089/ 

Rabeling, C.; Brown, J. M.; and Verhaagh, M. (2008). Newly discovered sister lineage sheds light on early ant evolution. Proceedings of the National Academy of Sciences, USA; 105, 14913-14917.

Ritzkowski, S. (1997). K-Ar-Altersbestimmungen der bernsteinführenden Sedimente des Samlandes (Paläogen, Bezirk Kaliningrad). Metalla, Bochum; 66, 19-23.

Ward, P. S. (2009). Phylogeny, classification, and species-level taxonomy of ants (Hymenoptera: Formicidae) [electronic version]. Zootaxa, 1669, 549-563. Retrieved 5/8/14 from http://wardlab.files.wordpress.com/2012/01/ward_2007c_zoootaxa.pdf 

Wheeler, W. M. (1914). The ants of the Baltic amber. Schriften der Physikalisch-Okonomischen Gesellschaft, 55(4), 56-59.

Yee, D. (2004). The Ants: Bert Hölldobler + Edward O. Wilson. Retrieved 5/7/14 from http://dannyreviews.com/h/Ants.html     

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