In a male-based revision of ants of the subfamily Amblyoponinae from the Southwest Indian Ocean islands (SWIO: Comoros, Madagascar, Mauritius, Mayotte, Reunion, and Seychelles), we explore and reconsider male morphological characters that distinguish genera within the group. Our investigation redefines Amblyopone Erichson sensu Brown (1960), here referred to as Amblyopone sensu lato, into three genera: Xymmer Santschi stat. rev., Amblyopone sensu stricto, Stigmatomma Roger stat. rev. All species names under Amblyopone s. l. reassign into Xymmer and Amblyopone s. s., which are small, well-defined genera, and Stigmatomma, a large group with a generic delimitation that still needs further refinement. Based on a study of male mandible characters and our scenario for mandibular evolution of the worker caste within Amblyopone s. l, we conclude that Amblyopone s. s. nests outside of XMAS (Xymmer+Mystrium+Adetomyrma+Stigmatomma) clade. The following names are transferred from Amblyopone s. l. to Xymmer as comb. rev.: muticus. The following names are transferred from Amblyopone s. l. to Stigmatomma as comb. rev.: amblyops, armigerum, bellii, bierigi, bruni, celata, chilense, denticulatum, elongatum, emeryi, feae, impressifrons, luzonicum, minuta, normandi, oregonense, pallipes, quadratum, reclinatum, rothneyi, santschii, saundersi, silvestrii, zwaluwenburgi; as comb. nov.: agostii, annae, besucheti, boltoni, caliginosum, cleae, crenatum, degeneratum, egregium, electrinum, eminia, exiguum, falcatum, ferrugineum, fulvidum, gaetulicum, gingivalis, glauerti, gnoma, gracile, groehni, heraldoi, lucidum, lurilabes, monrosi, mystriops, noonadan, octodentatum, ophthalmicum, orizabanum, papuanum, pertinax, pluto, punctulatum, rubiginoum, sakaii, smithi, trigonignathum, trilobum, wilsoni, zaojun, and testaceum. A male-based key to the genera of Malagasy amblyoponine ants, their diagnoses, and a discussion of the evolution of the morphological character of males in the subfamily are given, and the distinguishing characters of each are illustrated. In addition, our results predict that Paraprionopelta belongs in the XMAS clade and that Concoctio should have males with two mandibular teeth.
Citation: Yoshimura M, Fisher BL (2012) A Revision of Male Ants of the Malagasy Amblyoponinae (Hymenoptera: Formicidae) with Resurrections of the Genera Stigmatomma and Xymmer. PLoS ONE 7(3): e33325. doi:10.1371/journal.pone.0033325
Editor: Stephen J. Martin, Sheffield University, United States of America
Received: October 13, 2011; Accepted: February 7, 2012; Published: March 29, 2012
Copyright: © 2012 Yoshimura, Fisher. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was supported by the National Science Foundation under grant no. DEB-0842395 (http://www.nsf.gov/funding/). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Male ants are a largely untapped resource for understanding the taxonomy, phylogeny, diversity, and biology of this important insect group. Although ants are known for having distinctive sexual dimorphism, the current taxonomy of ants is for the most part based on the morphology of female workers. Males are difficult to study because they are often characterized by short emergence periods at certain times of the year, which reduces their chances of capture. Male ant morphology can be equally valuable for identifying species, and among some groups can be even more effective than female traits for distinguishing between genera or species –. The detailed morphological examination of male ants provides new characters that demonstrate phylogenetic relationships , . However, morphological information for males is not yet usable for inter-group comparisons due to the lack of comparative studies across taxa. In fact, much of the existing information about male ants is not categorized by taxonomic hierarchy.
In the Malagasy region, we aim to complete a male-based comparative study of the major ant lineages. We have previously published male-based keys to genera and generic diagnoses for Ponerinae , Proceratiinae , and Dolichoderinae  in the Malagasy region. This report adds to the existing body of data by focusing on the subfamily Amblyoponinae.
A few generic keys and synopses for males of Amblyoponinae were found among previous studies. However, no existing key covers the genera in the Malagasy region, and morphological information in those studies was not sufficient to diagnose differences among the Malagasy amblyoponine genera. Emery  and Wheeler  provide male-based keys to three genera (i.e. Mystrium, Stigmatomma, and Myopopone), while keys by Kusnezov  cover three genera (Stigmatomma as Ericapelta, Prionopelta, and Paraprionopelta). Male-based generic synopses have been provided for Amblyopone sensu Brown  and its related names , –, for Myopopone , , , Mystrium , , , Prionopelta , , and Paraprionopelta –.
In recent years, molecular phylogenetic analyses have suggested new evolutionary relationships among ant genera and subfamilies, and synergies between molecular and morphological analyses promise to clarify the evolutionary development of ants as a group. Several large-scale studies aiming to clarify the trajectory of global ant evolution – have helped elucidate the relationships among genera in Amblyoponinae. Phylogenetic relationships uncovered via molecular analyses can help identify convergences and plesiomorphies in current taxonomic characters, recast inappropriate groupings based on uninformative characters, and evaluate the utility of morphological characters in each taxonomic rank. For example, figure 1 in the molecular analysis of Brady et al.  showed that two species of Amblyopone sensu Brown  included in their study, Am. pallipes and Am. mutica, belong to different clades, indicating that generic limits need reassessment . Reconsidering the morphological characters of males in Amblyoponinae in light of recent molecular phylogenic results will help evaluate Brown's proposal  that male wing characters could be diagnostic for groups within Amblyopone sensu Brown . At the same time, a detailed morphological comparative study of male ants will discover new characters supporting molecular phylogenetic hypotheses, helping to clarify intra-subfamilial relationships in Amblyoponinae.
1A, Adetomyrma mg02 (CASENT0079552); 1B, Stigmatomma mg01 (CASENT0080397); 1C, Mystrium mgm07 (CASENT0081390); 1D, Prionopelta mgm05 (CASENT0049679); 1E, Xymmer mgm06 (CASENT0083484).
In this study, we provided a key and diagnoses using reconsidered generic characters for five genera in the Malagasy region. Based on the results of a comparative study, we propose resurrecting two names, Stigmatomma stat. rev. and Xymmer stat. rev., as genera from synonymy within the genus Amblyopone. Male synopses for Adetomyrma and Xymmer are provided for the first time. A questionable concept for the genus Amblyopone sensu Brown  is discussed on the basis of mandibular characters.
Materials and Methods
Materials for this work were collected during arthropod surveys in Madagascar and nearby islands in the Southwest Indian Ocean conducted by B. Fisher and Malagasy ant researchers from the Madagascar Biodiversity Center in Antananarivo, Madagascar. Their work in the region includes more than 6,000 leaf litter samples, 4,000 pitfall traps, 1,000 Malaise trap collections, and 9,000 additional hand collection events throughout Madagascar from 1992 through 2009 (see Fisher  for additional details). All materials examined other than the types of Stigmatomma (Xymmer) muticum Santschi 1914 (NHMB: see below), Stigmatomma denticulatum Roger, 1859 (ZMHB: see below), Amblyopone australis Erichson, 1842 (ZMHB: see below), male specimens of Onychomyrmex sp., and Amblyopone australis (both from ANIC: see below), are at the California Academy of Sciences.
Male specimens were primarily collected with Malaise traps. Within each amblyoponine genus, specimens were sorted to morphospecies. For those species that could not be named, morphospecies codes were applied. The codes consist of a two-letter country code followed by a number, e.g. Adetomyrma mg01.
Observations and dissections were carried out under stereoscopic microscopes (LEICA MZ12 and M125). Digital color images were created using a JVC KY-F75 digital camera. Syncroscopy Auto-Montage (v 5.0) software was used for images taken at magnifications less than 100×, and a compound microscope (Leica DM4000M) and Nikon digital camera (DXm1200) Helicon Focus version 4.10.2 software were used for images taken at magnifications greater than 100×. The images were edited in Adobe Photoshop and Illustrator. Each imaged or dissected specimen is uniquely identified with a specimen-level identifier (e.g. CASENT0003099) affixed to each pin.
The male and worker specimens listed below were examined to establish a key to genera of the subfamily. A diagnosis and analysis of morphological evolution is provided for each. Taxon names are followed by a letter code indicating the source of morphological information used to establish the key, and a CASENT specimen identifier of the dissected specimens:
[g]: male specimens that were collected from a colony and associated with workers.
[m]: male specimens that were collected alone and not associated with workers, typically in Malaise traps.
[w]: worker specimen.
[r]: information about male morphologies obtained from published studies. In these cases, the references are shown in brackets.
Amblyoponinae Adetomyrma Ward
Ad. mg01 [g: CASENT0218010]; Ad. mg02 [g: CASENT0218011]; Ad. mg03 [m: CASENT0218012]; Ad. mg05 [g: CASENT0218013]; Ad. mgm01 [m: CASENT0063101]; Ad. mgm02 [m: CASENT0072301]; Ad. mgm03 [m: CASENT0111802]; Ad. mgm04 [m: CASENT0218014]; Ad. mgm05 [m: CASENT0081348].
Amblyopone australis Erichson, 1842. Lectotype [here designated]. Worker. AUSTRALIA: Tasmania. Scheyer [sic] (misspelling of Schayer) [Museum für Naturkunde der Humboldt-Universität Berlin (ZMHB): 7228, CASENT0104575. Examined based on images. Two specimens were found with same locality and collector information; one was labeled “Type.” The original description of this species does not include detailed type information; however, Erichson mentions in the same paper that Schayer provided much material from Tasmania . Original labels on this specimen seem to have been replaced by new labels, and the collector on the new label is listed as “Scheyer,” a misspelling of Schayer, the collector's name.]
Am. australis Erichson, 1842 [w]; Am. australis [m: The Australian National Insect Collection (ANIC) 32016150, CASENT0172246. Examined based on images].
Apomyrma Brown, Gotwald & Lévieux
Ap. cf01 [m: CASENT0086291, not dissected]; Ap. cf02 [m: CASENT0086073, not dissected].
M. mysticum Roger, 1862 [g: CASENT0080864]; M. oberthueri Forel, 1897 [g]; M. rogeri Forel, 1899 [g: CASENT0218102]; M. mg05 [g: CASENT0109124]; M. mgm02 [m: CASENT0078803]; M. mgm07 [m: CASENT0081493]; M. mgm08 [m: CASENT0084212]; M. mgm09 [m: CASENT0080644]; M. mgm10 [m: CASENT0498897]; M. mgm11 [m]; M. mgm12 [m]; M. mgm13 [m].
O. au02. [m: ANIC, CASENT0172370, examined based on images].
Pa. minima Kusnezov 1955 [m: CASENT0173342, not dissected].
Pr. descarpentriesi Santschi, 1924 [g: CASENT0081411]; Pr. mg01 [g: CASENT0218100]; Pr. mgm01 [m: CASENT0114588]; Pr. mgm02 [m: CASENT0218101]; Pr. mgm03 [m: CASENT0007320]; Pr. mgm04 [m: CASENT0113575]; Pr. mgm05 [m]; Pr. mgm06 [m]; Pr. mgm07 [m].
Stigmatomma denticulatum Roger, 1859. Holotype. Worker. Griechenland (Greece): Monte Scapo (Mt. Scapo), Insel Zante (Zante Is.). Von Kiesenwelter. [Museum für Naturkunde der Humboldt-Universität Berlin (ZMHB): 18992, CASENT0104566. Examined based on images. Only one specimen from Greece is in ZMHB and it is labeled “typus.” Original labels on this specimen seem to have been replaced by new labels. The new label mistakenly lists the collector as “Roger, S.” instead of Von Kiesenwelter.]
S. mg01 [g: CASENT0083104]; S. mgm01 [m: CASENT0111612]; S. mgm02 [m: CASENT0109221]; S. mgm03 [m: CASENT0007087]; S. mgm04 [m: CASENT0059491].
Non Malagasy material.
S. pallipes (Haldeman, 1844) [w]; S. denticulatum (Roger, 1859) [w].
Stigmatomma (Xymmer) muticum Santchi 1914. Lectotype [here designated]. Worker. NIGERIA: Nigerie S. lbadan (Silvestri). Det. Santchi 1913 [The Naturhistorisches Museum Basel (NHMB): CASENT0217322 not dissected)].
Non type Malagasy material.
X. mgm01 [m: CASENT0083010]; X. mgm02 [m: CASENT0052348]; X. mgm03 [m: CASENT0218103]; X. mgm04 [m: CASENT0113147]; X. mgm05 [m: CASENT0080666]; X. mgm06 [m: CASENT0083494]; X. mgm07 [m]; X. mgm08 [m]; X. mgm09 [m].
Non type material from other than the Malagasy region (not dissected).
In addition to above, several undetermined male specimens were available from Central African Republic (X. cf01: CASENT0087255), Gabon (X. gam01: CASENT0247582), and Thailand (X. th01: CASENT0119328); X. mutica worker specimens were available from Ivory Coast (CASENT0006952), Cameroon (CASENT0009095), Central African Republic (CASENT0417121), and Gabon (CASENT0004308).
Overall, our preference is for terms used generally in Hymenoptera over terms uniquely applied within Formicidae for homologous characters. Morphological terminology follows our previous work (: figures 1, 2; : figures 1–21, 25–34; : figures 1–3, 6, 11, 16–23, 34, 39, 40, 46–61, 76–81) and is based on Snodgrass , Gauld and Bolton , Bolton , and Huber and Sharkey . Use of the term pygostyle follows Snodgrass  and basimere and harpago follows Snodgrass ; terminology of wing venation follows Wootton , Gauld and Bolton , and Serna et al. ; and specialized conical setae for anterior clypeal projections follows Ward . The applications of these terms in the Amblyoponinae are illustrated in Figures 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13 and 14.
2A, Adetomyrma mg02 (CASENT0079552); 2B, Stigmatomma mg01 (CASENT0080397); 2C, Mystrium mgm07 (CASENT0081390); 2D, Prionopelta mgm05 (CASENT0049679); 2E, Xymmer mgm06 (CASENT0083484).
3A, Adetomyrma mg02 (CASENT0079552); 3B, Stigmatomma mg01 (CASENT0080397); 3C, Mystrium mgm07 (CASENT0081390); 3D, Prionopelta mgm05 (CASENT0049679); 3E, Xymmer mgm06 (CASENT0083484).
4, Stigmatomma mg01 (CASENT0080397).
5A, Prionopelta mg01 (CASENT0049809); 5B, Mystrium mg05 (CASENT0492154).
6A, Adetomyrma mg02 (CASENT0218011); 6B, Stigmatomma mg01 (CASENT0083104).
7A, Adetomyrma mg02 (CASENT0218011); 7B, Stigmatomma mgm01 (CASENT0111612); 7C, Mystrium mgm02 (CASENT0078803); 7D, Prionopelta descarpentriesi (CASENT0081411); 7E, Xymmer mgm02 (CASENT0052348).
8A, Adetomyrma mg02 (CASENT0218011); 8B, Stigmatomma mgm01 (CASENT0111612); 8C, Mystrium mgm02 (CASENT0078803); 8D, Prionopelta descarpentriesi (CASENT0081411); 8E, Xymmer mgm02 (CASENT0052348).
9A, Adetomyrma mg02 (CASENT0218011); 9B, Stigmatomma mgm01 (CASENT0111612); 9C, Mystrium mgm02 (CASENT0078803);9 D, Prionopelta descarpentriesi (CASENT0081411); 9E, Xymmer mgm02 (CASENT0052348).
10A, Adetomyrma mg05 (CASENT0218013); 10B, Stigmatomma mg01 (CASENT0083104); 10C, Mystrium rogeri (CASENT0218102); 10D, Prionopelta descarpentriesi (CASENT0081411); 10E, Xymmer mgm04 (CASENT0113147).
11A, Adetomyrma mg05 (CASENT0218013); 11B, Stigmatomma mg01 (CASENT0083104); 11C, Mystrium rogeri (CASENT0218102); 11D, Prionopelta descarpentriesi (CASENT0081411); 11E, Xymmer mgm04 (CASENT0113147).
12A, Adetomyrma mg02 (CASENT0218011); 12B, Stigmatomma mgm03 (CASENT0007087); 12C, Mystrium mgm02 (CASENT0078803); 12D, Prionopelta descarpentriesi (CASENT0081411); 12E, Xymmer mgm02 (CASENT0052348).
13A, Adetomyrma mg02 (CASENT0218011), an anomaly is observed on the left maxillary palp; 13B, Stigmatomma mgm03 (CASENT0007087); 13C, Mystrium mgm02 (CASENT0078803); 13D, Prionopelta descarpentriesi (CASENT0081411); 13E, Xymmer mgm02 (CASENT0052348). Each image is modified to clearly show its palpal segments.
14A–C, Xymmer muticus (CASENT0217322: lectotype, designated in this study); 14D, Stigmatomma mg06 (CASENT0022237). 14A, lateral view; 14B, dorsal view; 14C, 14D, full-face view.
In this study, tergosternal fusion is considered to occur when tergite and sternite are fused to each other in a manner different from the fusion seen in the proceeding posterior segment. The degree of fusion in males seems to be highly variable, with many intermediates. According to Bolton , the tergosternal fusion seen in abdominal segments III and IV was pointed out in Gotwald  for the first time. Bolton classified segments as “fused” when “the tergite and sternite of any given segment either meet edge to edge, or narrowly overlap and are immovably welded together.” In the Amblyoponinae the level of fusion is difficult to ascertain, especially when the segments overlap. Therefore, we use a relative comparison with abdominal segment V which is never fused in ants.
Abdominal sternum IX (Figure 7).
We prefer the term abdominal sternum IX rather than the subgenital plate and the hypopygium, the terms used for this sclerite in previous studies, because the latter two terms are ambiguous in homology; the subgenital plate and the hypopygium are not homologous in males and females of the same taxon. Even within the same sex, the subgenital plate is not consistent between taxa. (More detailed information is provided in the terminology section and table 1 of Yoshimura & Fisher ).
Pygostyles (Figure 4).
Pygostyle is used to refer to the pair of appendages on tergum X of the abdomen of male Hymenoptera. Cerci, on the other hand, should refer to appendages on abdominal tergum XI, not X (see also table 1 in Yoshimura & Fisher  and Yoshimura & Fisher ).
Venation and cells on the wings (Figures 10, 11).
We use veins, not cells, to describe wing characters and to discuss the homology of wing characters between amblyoponine genera and genera in other subfamilies. In previous studies of Amblyoponinae , ,  other than Brown's works , , the number of closed cells on the fore- and hindwings was used to highlight differences between taxa. The focus on cells, however, diverts attention away from careful comparative studies of venation patterns as mentioned in Brown & Nutting  (see also table 1 in Yoshimura & Fisher  and the terminology section in Yoshimura & Fisher ).
In the present study, the homology of each vein across taxa was determined based on comparative studies of taxa with well-developed veins, such as species in the genus Mystrium (Figures 10C, 11C). Terms used to define veins follow the recommendation of Wootton , Gauld and Bolton , and Serna et al. . However, we use 1A on the forewing instead of A; 1rs-m on the hind wing instead rs-m. Our naming system for wing veins is summarized in Figures 10C (forewing) and 11C (hindwing). Cell names as indicated in Gauld and Bolton  are also given in Figure 10C. We provide cell names only in reference to this earlier study, and not as an endorsement for their use.
The names of wing cells in ants have been inaccurately interpreted due to homonymy. Submarginal cells 1 and 2 in Figure 10C were referred to as cubital cells in previous works for Amblyoponinae , , , ; however, cells formed between cubitus and anal, i.e. subbasal and subdiscal in Figure 10C, were also referred to as 1st and 2nd cubital cells by Huber and Sharkey . Nichols defines the cubital cells as wing cells bounded anteriorly by the cubitus or one of its branches , and agrees with the naming system by Huber and Sharkey . On the other hand, “cubital cells” in Amblyoponinae , , ,  are bounded anteriorly by subcosta and pterostigma, or Rs+M and radial sector, demonstrating the inconsistent application of the term “cubital cell(s)” in ant taxonomy.
Serna et al.  revised wing cell names proposed in their previous paper . Their new system, however, still disagrees with Gauld and Bolton's system in some areas. For example, Serna et al.  used the terms submarginal cell 3 and discal cell 2 to identify forewing cells instead of marginal 1+2 and subdiscal 1 respectively, as in Gauld and Bolton . According to Nichols's definition , cells immediately distal to pterostigma and bordering the costal margin are marginal cells. The marginal cells in Gauld and Bolton  are identical with the Nichols's definition, but the one in Serna et al.  is not. Creating new homonymies in terminology is not preferred because it could lead to more confusion in future comparative studies. Therefore, marginal 1+2 and subdiscal 1 should be used instead of submarginal cell 3 and discal cell 2 in the sense of Serna et al. .
A detailed morphological examination was carried out for 30 male characters. Some characters were chosen based on their relevance in previous studies: e.g., the presence of the pygostyles as cerci , the number of the mesotibial spurs , the presence of radial sector and position of cu-a , and the fusion of the metacoxal cavity . Morphological characters examined are listed below. Results of the examination are given as a character matrix (Table 1) and used for exploring character evolution (Figure 15: see discussion). A key and diagnoses for genera in the Malagasy region based on the matrix are provided.
Characters plotted on the topology of the XMAS presented in Brady et al. . Numbers in each box correspond to character in Table 1; numbers under the box represent character states; boxes filled in gray indicate those characters are unique to each genus or clade; dashed line is hypothetical.
A list of characters
01. Frontal carinae are absent (1); present (0)
02. Dent-like projections are present on anterior margin of the clypeus (1); no such projections on the margin (0)
03. The number of mandibular teeth (Figure 12)
04. The number of maxillary palpal segments (Figure 13)
05. The number of labial palpal segments (Figure 13)
06. The number of antennal segments
09. Metacoxal cavity completely fused (1); touches but is not fused (0)
10. The number of mesotibial spurs
11. The number of metatibial spurs (Figure 5)
14. Tergosternal fusion not found on AIII (1); found on AIII (0)
15. Tergosternal fusion not found on AIV (1); found on AIV (0)
16. Pygostyles absent (1); present (0: as in Figure 4)
18. Harpago separated from the basimere by a suture (1); separation between the harpago and basimere unclear (0)
19. Basal projection on the cuspis present (1: as in Figure 9); absent (0)
25. On the forewing, 2r-rs is connected with radial sector far distal from the pterostigma (1: as in Figure 10D); is connected with radial sector posterior to the pterostigma (0: as in Figures 10A–C, D)
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Results of the detailed morphological examination of males of five Malagasy genera Adetomyrma, Mystrium, Prionopelta, Stigmatomma, and Xymmer, based on 30 characters. The criteria used are given as a character matrix (Table 1).
Diagnosis of males of the subfamily Amblyoponinae in the Malagasy region
Males alate. Scape not reaching posterior margin of head (Figure 1). Mesopleural oblique furrow usually vestigial, and when present, reaching anterior margin of mesopleuron far ventrally from posteroventral corner of pronotum (Figure 2). Notaulus present (Figures 3B–E) or absent (Figure 3A). Scuto-scutellar suture simple or with longitudinal sculpture. Metacoxal cavity encircled by cuticle, endpoints meeting broadly but not fused. Protibia with single, well-developed spur. Mesotibia with one to two spurs or without spur. Metatibia with one to two spurs (Figure 5). Petiole attached to abdominal segment III dorsally, so that dorsal margin of petiole higher than or same height as dorsal margin of abdominal segments III in lateral view. Abdominal segment III larger than or same size as segment IV (Figure 2). Constriction present (Figure 3A) or absent (as in Figures 3B, C) between abdominal segments III and IV. With abdominal segment IV in lateral view, its dorsal margin as long as its ventral margin. Abdominal segment III with tergosternal fusion. Abdominal segment IV with tergosternal fusion except in some species of Adetomyrma. The distal margin of abdominal sternum IX either convex or concave, but never bispinose. Pygostyles present (Figure 4) or absent. Basimere not distinctly differentiated from harpago, separation between basimere and harpago sometimes unclear (Figure 9). Volsella directed ventrally, but never stout and claw-shaped nor extended dorsally. A process present on the basal portion of cuspis in most species (Figure 9).
Venation on forewing and hindwing varies. On forewing (Figure 10), costa (C), Sc+R, Media (M), cubitus (Cu), anal (1A), 1m-cu and cu-a present in all genera. On hindwing (Figure 11), Sc+R, M+Cu and anal (1A) present. Clavus developed to reduced in size, and jugum absent.
We propose that the process on the basal portion of the cuspis on the volsella (Figure 9) is a character unique to Amblyoponinae. It cannot be used as a complete diagnostic character due to the reduction of this process in some males of Prionopelta. The presence of this process has been illustrated and/or mentioned in several previous studies for Amblyopone sensu Brown (1960) (e.g. figure 24 A in Brown ; figure 21 in Gotwald ; figure 9 in Ogata ), and for Myopopone (diagnosis and figure 13 in Brown ). We confirmed the absence of this process in Proceratiinae and Ponerinae; these data and a polymorphism in Prionopelta suggest that reductions of this process in some, but not all, Prionopelta constitute a case of secondary loss.
The above character, which is difficult to confirm without dissection, is the only one unique to the subfamily Amblyoponinae. However, combinations of characters under diagnosis clearly separate the Amblyoponinae from the six other subfamilies in the Malagasy region. In the Malagasy region, Amblyoponinae differ from Cerapachyinae in lacking a bispinose abdominal sternum IX (Figure 7) and in having a moderate volsella; from Dolichoderinae in having a broader and higher attachment of the petiole to abdominal segment III and poorly differentiated basimere compared with the harpago; from Formicinae in having the petiole as above and the shorter scape of the antenna never reaching the posterior margin of the head (Figure 1); from Myrmicinae and Pseudomyrmecinae in having a slightly reduced or same-sized abdominal segment III compared with IV (as in Figure 2); from Ponerinae in having a broader and higher attachment of the petiole to abdominal segment III; and from Proceratiinae in having the dorsal margin of abdominal segment IV nearly the same length as its ventral margin in lateral view (in Proceratiinae, the dorsal margin of abdominal segment IV in lateral view is at least twice as long as its ventral margin) (Figure 2).
Amblyoponinae males have a broad, dorsal attachment of the petiole to abdominal segment III. However, this character is sometimes difficult to differentiate from the attachment in Proceratiinae, which may also appear broadly attached. The differences in the shape of abdominal segment IV mentioned above, however, will easily separate the two subfamilies.
Key to genera of males of Amblyoponinae in the Malagasy region
This key may not apply outside of the Malagasy region, as variations in genus-level characters elsewhere have not been fully explored.
2. Constriction between petiole and abdominal segment III indistinct in dorsal view (Figure 3A). Pretergite of abdominal segment IV not divided from posttergite by transverse furrow (Figure 6A). On forewing, radial sector fails to reach costal margin and is disconnected from radius (Figure 10A)… Adetomyrma
-. Constriction between petiole and abdominal segment III distinct in dorsal view (Figure 3C). Pretergite of abdominal segment IV distinctly divided from posttergite by transverse furrow (Figure 6B). On forewing, radial sector reaches costal margin and is connected with radius (Figures 10B, C, E)… 3
3. Pygostyles present (Figure 4)… Stigmatomma
-. Pygostyles absent… 4
-. Anterior margin of clypeus without dent-like projections (Figure 1E). On forewing, radial sector wholly or partially absent between M+Rs and 2r-rs (Figure 10E). On hindwing, radius absent (Figure 11E)… Xymmer
Diagnoses of males of extant genera of Amblyoponinae in the Malagasy region
Descriptions and diagnoses apply to species found in Madagascar. Diagnostic characters uniquely observed in each genus are given in italics. Male diagnoses for the genus Adetomyrma and Xymmer are proposed for the first time.
With characters of Amblyoponinae. Frontal carinae absent. Anterior margin of clypeus with dent-like projections. Antenna consisting of 13 segments. Mandible with single, blunt apical tooth (Figure 12A). Palpal formula 3,3/2,3/2,2 (one specimen each of nine morphospecies dissected: Figure 13A). Notaulus distinct or absent. Mesepimeron with or without distinct posterodorsal lobe (epimeral lobe). Mesotibia with two spurs in most cases, rarely with single spur. Metatibia with two spurs. In dorsal view, no constriction present between petiole and abdominal segment III (Figure 3A). Abdominal segment IV with or without tergosternal fusion. Pretergite of abdominal segment IV not distinctly differentiated from posttergite, without transverse furrow between them (Figure 6A). Pygostyles present.
Distal margin of abdominal sternum IX concave (Figure 7A). Separation between basimere and harpago usually indistinct but distinct in some species. Basal projection on cuspis well-developed (Figure 9A). Aedeagus in lateral view, its basicoventral portion extended basally in most cases, shape of extension somewhat triangular to subtriangular, with relatively sharper distal apex; serrate denticles absent on basal portion of ventral margin of aedeagus (Figure 8A).
On forewing (Figure 10A), pterostigma well-developed, radial sector wholly or partially absent between M+Rs and 2r-rs, radial sector fails to reach costal margin, 2r-rs connected with radial sector posterior to pterostigma, 2rs-m absent, cu-a located far from junction between media and cubitus. On hindwing (Figure 11A), radius absent in most cases but rarely weakly developed, 1rs-m absent, media usually present apical to 1rs-m.
Additional genus characters other than generic diagnoses.
In full-face view, head wider than long when eyes included, ocelli well-developed, eyes well-developed and protruding laterally, situated on middle to anterior portion of lateral margin of head (as in Figure 1A). Occipital carina absent. Anterior clypeal margin distinctly or weakly convex anteriorly (Figure 1A). Antenna stout and not extremely long, scape short, never reaching posterior margin of head in full-face view. Mandibles cross when fully closed.
Mesopleural oblique furrow very weak or absent, reaching anterior margin of mesopleuron far ventrally from posteroventral corner of pronotum when the furrow is visible (Figure 2A). With mesonotum in dorsal view, parapsidal furrows deeply impressed (Figure 3A); the axilla clearly divided. Propodeum without teeth or spines on its posterodorsal portion.
Subpetiolar process developed to various degrees, absent in several species. The distal margin of abdominal tergum VIII relatively flat, not strongly protruding on middle portion.
Body sculpture weak. Body color yellow to blackish brown.
A male synopsis of the genus Adetomyrma is provided for the first time based on nine morphospecies. Genus Adetomyrma is endemic to Madagascar. Males of Adetomyrma are distinguished easily from the other four Malagasy amblyoponine genera by lack of a constriction between petiole and abdominal segment III in dorsal view (Figure 3A), lack of a transverse furrow dividing pre- and posttergite of abdominal segment IV (Figure 6A), radial sector on forewing failing to reach the costal margin, and absence of 2rs-m on forewing (Figure 10A).
Other than characters uniquely observed in Adetomyrma, absence of 1rs-m on the hindwing is shared with Xymmer.
In addition to the separable characters above, two additional characters can be useful to distinguish Adetomyrma from the other Malagasy amblyoponine males: the posterior margin of abdominal sternum IX shallowly to deeply concave (Figure 7A), and a triangular expansion on the aedeagus (Figure 8A). However, several exceptions to these features were observed. A convex posterior margin of abdominal sternum IX is common among amblyoponine males in this region, while a concave posterior margin is observed in only a few males of Stigmatomma other than Adetomyrma. A basicoventral, triangular-like expansion on the aedeagus is unique to Adetomyrma, and this character easily separates Adetomyrma from the other genera. However, only one large morphospecies, Adetomyrma mg03, has extraordinarily specialized genitalia, and the expansion in this species only is vestigial. The bizarre genital features in Ad. mg03 are not similar to any other known males in Amblyoponinae. A basicoventral expansion on the aedeagus is confirmed also in Mystrium (Figure 8C); however, the expansion in the latter has two differences from the former: 1) serrate dents are present on its ventral margin; and 2) distal margin of the expansion is rounded, never triangular.
New palpal formulae in the genus Adetomyrma were found in this study. We observed three palpal formulae in Adetomyrma males, 3,3 (Figure 13A)/2,3/2,2, although only one formula 3,3 has been reported in Adetomyrma based on workers (Ward , original description). According to Brown's observation, the palpal formula observed in males of Amblyopone sensu Brown  is frequently the same as that in conspecific workers . We confirmed this tendency in Mystrium and Prionopelta as well through observation. Two other types of palpal formulae may be observed in the workers of Adetomyrma with further observation, although 3,3 is the most common.
A lack of tergosternal fusion in abdominal segment IV was observed only in Adetomyrma among amblyoponine males in the Malagasy region. Interestingly, we found polymorphisms in this character within Adetomyrma. Tergosternal fusions in abdominal segments II (petiole) to IV were focused on in Gotwald , and redefined by Bolton . Since its discussion in Bolton , this character has been regarded as an important diagnostic character for poneromorph subfamilies (sensu Bolton ). Ward proposed the lack of tergosternal fusions in abdominal segments III and IV to be a probable case of generic autapomorphy in workers of Adetomyrma . In this work, Ward raised an interesting question for ant systematics in the form of a pair of hypotheses: either a tergosternal fusion in ants occurred independently in several lineages, or represents a reversal. Saux et al. inferred that Adetomyrma had undergone secondary reversal of tergosternal fusion, based on the distribution of character states on their phylogenic tree . In our observations, interestingly: 1) tergosternal fusion in abdominal segment III was confirmed in all males of morphospecies examined, although larger portions of tergite and sternite overlap more than in other amblyoponine males; 2) in one of these morphospecies (Adetomyrma mg02), the associated workers lacked tergosternal fusion in abdominal segment III; and 3) tergosternal fusion in abdominal segment IV is distinct in males of five of the nine morphospecies, while the other four are difficult to judge but also seem to lack tergosternal fusion in abdominal segment IV. The fact that the fusion of abdominal segment III is inconsistent between males and workers in at least one species suggests that the lack of tergosternal fusion in Adetomyrma workers is secondary. This result is consistent with the explanation proposed by Saux et al. .
With characters of Amblyoponinae. Frontal carinae present. Anterior margin of clypeus with dent-like projections. Antenna consisting of 13 segments. Mandible with single, blunt, apical tooth (Figure 12C). Palpal formula 4,3 (one specimen each of eight morphospecies dissected: Figure 13C). Notaulus absent or indistinct in many cases, but distinct in several species. Mesepimeron with distinct posterodorsal lobe (epimeral lobe). Mesotibia with one or two spurs in most cases, rarely indistinct. Metatibia with two spurs (Figure 5B). In dorsal view, distinct constriction present between petiole and abdominal segment III (Figure 3C). Abdominal segment IV with tergosternal fusion. Pretergite of abdominal segment IV distinctly differentiated from posttergite; a deep transverse furrow divides them. Pygostyles absent.
Distal margin of abdominal sternum IX convex (Figure 7C). Separation between basimere and harpago distinct. Basal projection on cuspis well-developed (Figure 9C). The basicoventral portion of aedeagus extended basally, distal margin of extension rounded (Figure 8C). Aedeagus in lateral view, serrate denticles present on basal portion of its ventral margin.
On forewing (Figure 10C), pterostigma well-developed, radial sector fully present and reaches to costal margin, 2r-rs connected with radial sector posterior to pterostigma, 2rs-m present, cu-a position variable, located close to or far from junction between media and cubitus. On hindwing (Figure 11C), radius present, 1rs-m present, media present apical to 1rs-m.
The only unique character of males of Mystrium found in this study was the basicoventral portion of the aedeagus roundly and strongly extending basally (Figure 8C) (see also the genus Adetomyrma). It is the first time a unique character for male Mystrium has been provided that distinguishes it from the other amblyoponine genera, although this character is difficult to observe without dissection.
In practice, males of Mystrium are distinguished easily from Adetomyrma by having a distinct constriction between the petiole and abdominal segment III (Figure 3C), from Stigmatomma by the lack of the pygostyle, from Prionopelta by having two metatibial spurs (Figure 5B), and from Xymmer by a complete radial sector on the forewing (Figure 10C).
In addition to a unique character in the aedeagus, the presence of clypeal dent-like projections, a palpal formula of 4,3, and a distinct epimeral lobe are provided as new diagnostic characters.
Several diagnostic characters provided in previous studies require updating. First, Emery described the notaulus in Mystrium as deeply impressed ; however, eight species/morphospecies out of the eleven examined lack the furrow. Second, Emery described the number of mesotibial spurs in Mystrium as two , and Wheeler used this number in his key to separate Stigmatomma, which had a single mesotibial spur . However, our observations revealed the number of mesotibial spurs is not useful as a separable character at the genus rank in Amblyoponinae, because intra-generic variation was found in Mystrium, Stigmatomma, and Xymmer (see Character 10 in Table 1). In fact, Bolton recorded the number of mesotibial spurs in Mystrium as one . Therefore, this character is not useful for distinguishing genera, although it may be useful at the species level.
With characters of Amblyoponinae. Frontal carinae present. Anterior margin of clypeus with dent-like projections. Antenna consisting of 13 segments. Mandible with two sharp teeth (Figure 12D). Palpal formula 2,2, one specimen each of one species and five morphospecies dissected (Figure 13D). Notaulus distinct (Figure 3D). Mesepimeron without distinct posterodorsal lobe (epimeral lobe). Mesotibia with single spur. Metatibia with single spur (Figure 5A). In dorsal view, distinct constriction present between petiole and abdominal segment III. Abdominal segment IV with tergosternal fusion. Pretergite of abdominal segment IV distinctly differentiated from posttergite; a deep transverse furrow divides them. Pygostyles present.
Distal margin of abdominal sternum IX convex (Figure 7D). Separation between basimere and harpago distinct. Basal projection on cuspis usually well-developed, but reduced in size in several species (as in Figure 9D). Basicoventral portion of aedeagus not extraordinarily expanded (Figure 8D). Aedeagus in lateral view, serrate denticles present on basal portion of its ventral margin.
On forewing (Figure 10D), pterostigma reduced in size, radial sector absent between M+Rs and 2r-rs, radial sector reaches to costal margin, 2r-rs connected with radial sector distal to pterostigma, 2rs-m present, cu-a located far from junction between media and cubitus. On hindwing (Figure 11D), radius present in most cases, but absent in one species, 1rs-m present, media present apical to 1rs-m.
Males of Prionopelta are distinguished from the other Malagasy amblyoponine genera by having two teeth on the mandible (Figure 12D), a single metatibial spur (Figure 5A), the pterostigma reduced in size, and the 2r-rs connecting with the radial sector distal to the pterostigma (Figure 10D). The pterostigmal character is proposed as a new diagnostic character.
We found useful male-based generic characters of Prionopelta have been provided in three previous studies –. Brown included the male characters in a diagnosis of Prionopelta , Bolton listed several male characters in his Appendix 2 , and Kusnezov proposed several characters in his male key to separate Prionopelta from Stigmatomma (as Ericapelta Kusnezov) and Paraprionopelta Kusnezov . From these studies, our observation confirmed 2,2 in palpal formula (Character 4 and 5 in Table 1) –, two-toothed mandible (Character 3 in Table 1) , , presence of notaulus (Character 7 in Table 1) , single tibial spur (Character 11 in Table 1) , and wing venations on fore- and hindwings (Characters 22–30 in Table 1)  as useful generic characters.
Of these characters, the two-toothed mandible (Character 3) may not separate Prionopelta from several groups in another region (see discussion below).
Reduction in size of the basal projection on the cuspis is observed only in Prionopelta as an intra-generic variation, and seems to be the result of a reversal. Brown's diagnosis of Prionopelta included this reduction as a lack of a “second cusp.” We observed reductions in this projection in three males of Malagasy Prionopelta. However, we also observed the following: 1) all amblyoponine genera examined, other than Prionopelta, have a well-developed projection on the basal portion of the cuspis; 2) the distinct projection was observed even in males of Malagasy Prionopelta except in the three males mentioned above. These data suggest the occurrence of this reduction is limited to a portion of the genus Prionopelta.
16A, 16-a1-a5, Malagasy Stigmatomma (Stigmatomma mg01: CASENT0227519); 16B, 16-b1-b5, Amblyopone australis (CASENT0172268). 16A, 16-a1-a4, 16B, 16-b1-b4, worker mandible; 16-a5, 16-b5, male mandible. Series represents the transformations in workers' mandibles to SS form (16-a1-a5), with males having a single-toothed mandible, or AD form (16-b1-b5), with males having double-toothed mandible; mandibular teeth are blue and basal denticles are red.
Stigmatomma Roger, 1859: 250 , original description, type-species: Stigmatomma denticulatum Roger, 1859, by subsequent designation of Bingham, 1903: 36  [Lectotype examined. See also Materials and Methods.]
Arotropus Provancher, 1881: 205 . syn. nov.
Fulakora Mann, 1919: 279 .
Lithomyrmex Clark, 1928: 30 . syn. nov.
Ericapelta Kusnezov, 1955: 273 . syn. nov.
With characters of Amblyoponinae. Frontal carinae absent. Anterior margin of clypeus with dent-like projections. Antenna consisting of 13 segments. Mandible with single, sharp, apical tooth (Figure 12B). Palpal formula 4,3/4,2/3,2 (one specimen each of five morphospecies dissected: Figure 13B). Notaulus distinct (Figure 3B). Mesepimeron with distinct posterodorsal lobe (epimeral lobe) in most cases, but rarely indistinct. Mesotibia with one or two spurs. Metatibia with two spurs. In dorsal view, distinct constriction present between petiole and abdominal segment III (Figure 3B). Abdominal segment IV with tergosternal fusion. Pretergite of abdominal segment IV distinctly differentiated from posttergite; a deep transverse furrow divides them (Figure 6B). Pygostyles present (Figure 4).
Distal margin of abdominal sternum IX concave or convex (Figure 7B). Separation between basimere and harpago usually distinct but indistinct in one species. Basal projection on cuspis well-developed (Figure 9B). Basicoventral portion of aedeagus not extraordinarily expanded. Aedeagus in lateral view, serrate denticles present on basal portion of its ventral margin (Figure 8B).
On forewing (Figure 10B), pterostigma well-developed, radial sector fully present and reaching to costal margin, 2r-rs connected with radial sector posterior to pterostigma, 2rs-m present, cu-a located close to or far from junction between media and cubitus. On hindwing (Figure 11B), radius present or absent, 1rs-m present, media present apical to 1rs-m.
We resurrect Stigmatomma here as an independent genus from a synonymy with Amblyopone based on their worker mandible characters (see Discussion of morphological evolution below for detail). No unique male character has been found in Stigmatomma. However, males of Stigmatomma are distinguished easily from Adetomyrma by having a sharper mandible (Figure 12B), constrictions between the petiole and abdominal segment III (Figure 3B) and between AIII and AIV (Figure 6B), serrate denticles on basal margin of the aedeagus (Figure 8B), a complete radial sector and 2rs-m on forewing (Figure 10B), and the 1rs-m on hindwing (Figure 11B); from Mystrium by absence of the frontal carina, sharper apex of the mandible, presence of the pygostyle (Figure 4), and less expanded posteroventral portion of the aedeagus; from Prionopelta by absence of the frontal carina, more maxillary palpal segments (two in Prionopelta, three or four in Stigmatomma), two metatibial spurs (one in Prionopelta), developed pterostigma, and complete radial sector on forewing; and from Xymmer by presence of anterior clypeal conical setae, presence of the pygostyle, having complete radial sector and 2rs-m on forewing, and having 1rs-m on hindwing.
Previous studies most often include diagnostic characters for Stigmatomma and/or Amblyopone , –, . Many of these characters are still useful for distinguishing Stigmatomma from the other amblyoponine genera, although some taxonomic changes have been made since the information was given. Among the previous diagnostic characters, one should be updated. The number of mesotibial spurs was described as single in Emery , but should be updated to one or two, as Bolton mentioned . Brown proposed a new subgeneric classification for Amblyopone and discussed the usefulness of wing venation as a diagnostic character of the genus . Brown rejected this classification in 1960  because of an exception in the wing characters observed in Amblyopone australis, and proposed a new concept for the genus Amblyopone . Yet our results suggest the wing character proposed by Brown  is useful to separate among amblyoponine genera (see also the discussion of morphological evolution below).
Combination in Stigmatomma.
The following names are transferred from Amblyopone to Stigmatomma as comb. rev.: amblyops, armigerum, bellii, bierigi, bruni, celata, chilense, denticulatum, elongatum, emeryi, feae, impressifrons, luzonicum, minuta, normandi, oregonense, pallipes, quadratum, reclinatum, rothneyi, santschii, saundersi, silvestrii, zwaluwenburgi.
The following names are transferred from Amblyopone to Stigmatomma as comb. nov.: agostii, annae, besucheti, boltoni, caliginosum, cleae, crenatum, degeneratum, egregium, electrinum, eminia, exiguum, falcatum, ferrugineum, fulvidum, gaetulicum, gingivalis, glauerti, gnoma, gracile, groehni, heraldoi, lucidum, lurilabes, monrosi, mystriops, noonadan, octodentatum, ophthalmicum, orizabanum, papuanum, pertinax, pluto, punctulatum, rubiginoum, sakaii, smithi, trigonignathum, trilobum, wilsoni, zaojun, and testaceum [testaceum is a nomen dubium; however, we preliminarily transfer it to Stigmatomma based on its locality (Sri Lanka)].
The following species, which are all restricted to Australia, New Caledonia, New Guinea, and New Zealand, remain in Amblyopone: aberrans, australis, clarki, hackeri, leae, longidens, mercovichi, michaelseni.
Stigmatomma (Xymmer) Santschi, 1914: 311 , original description, type species: Stigmatomma (Xymmer) muticum Santschi, 1914  [lectotype examined (Figure 14A–C). See also Materials and Methods.]
Stigmatomma (Ximmer [sic]): Emery, 1919 .
Xymmer: Wheeler, 1922 , in key.
Amblyopone (Xymmer): Clark, 1934 .
Amblyopone (Stigmatomma) (in part): Brown, 1949 .
With characters of Amblyoponinae. Frontal carinae absent. Anterior margin of clypeus flat, without dent-like projections. Antenna consisting of 13 segments. Mandible with single tooth, apex sharp or blunt (Figure 12E). Palpal formula 3,3 (Figure 13E)/3,2/4,3, one specimen each of six morphospecies dissected. Notaulus distinct (Figure 3E). Mesepimeron with distinct posterodorsal lobe (epimeral lobe: Figure 2E). Mesotibia without spur in most cases, with single spur in one species. Metatibia with two spurs. In dorsal view, distinct constriction present between petiole and abdominal segment III. Abdominal segment IV with tergosternal fusion. Pretergite of abdominal segment IV distinctly differentiated from posttergite; a deep transverse furrow divides them. Pygostyles absent.
Distal margin of abdominal sternum IX convex (Figure 7E). Separation between basimere and harpago distinct. Basal projection on cuspis well-developed (Figure 9E). Basicoventral portion of aedeagus not extraordinarily expanded (Figure 8E). Aedeagus in lateral view, serrate denticles present on basal portion of its ventral margin.
On forewing (Figure 10E), pterostigma well-developed, radial sector absent between M+Rs and 2r-rs, radial sector reaches to costal margin, 2r-rs connected with radial sector posterior to pterostigma, 2rs-m present, cu-a located far from junction between media and cubitus in most cases, located close to junction in one species. On hindwing (Figure 11E), Sc+R1 and radius (R1) absent, 1rs-m absent, media absent apical to 1rs-m.
We resurrect Xymmer here as an independent genus from a synonymy with Amblyopone based on a morphological examination of males of nine morphospecies. Males of Xymmer can be distinguished from other amblyoponine males in the Malagasy region by a lack of dent-like projections on the anterior margin of the clypeus. In addition to this unique character, Xymmer can be separated from Adetomyrma by fewer mesotibial spurs (two in Adetomyrma, 0–1 in Xymmer), absence of the pygostyles, and abdominal sternum IX convex distally; from Stigmatomma by lack of the pygostyles, the radial sector on the forewing between Rs+M and 2r-rs, the media on the hindwing apical to the cubitus, and 1rs-m on the hindwing; from Mystrium by a lack of the frontal carinae, radial sector on forewing partially absent, an absence of 1rs-m, and media apical to cubitus on hindwing; from Prionopelta by a lack of the frontal carinae, having a distinct epimeral lobe, lack of pygostyles, and lack of a vein on hindwing between radial sector and cubitus. The mesotibial spur may be useful as a separable character: the spur is absent in most males of Xymmer (only X. mgm01 has the spur on the mesotibia out of the nine morphospecies examined), while at least a single spur is present in all males of Stigmatomma.
Few morphological discussions exist regarding the taxonomic status of the name Xymmer. Xymmer was described by Santschi as a monotypic subgeneric taxon under Stigmatomma . Since Santschi's original description, Xymmer was raised to genus by Wheeler in his identification key for African Amblyoponini . Clark regarded Xymmer as a subgenus in Amblyopone  following Wheeler's suggestion ; however, distinguishing characters were not discussed in their treatments. Brown ,  discussed separable characters for Xymmer (as a junior synonym under the subgenus Stigmatomma) for the first time since Santschi's original description. Brown regarded Stigmatomma and its related names as junior synonyms of Amblyopone at that time , and this treatment constituted the recent concept of the genus Amblyopone.
We decided that the male characters proposed above and associations between the worker lectotype and our materials are sufficient to warrant designating Xymmer as an independent genus from Amblyopone. Santschi's description  misidentifies the criterion for separating Xymmer from Amblyopone as having conical setae just present or absent, as discussed in Brown (: p.165). Although Santschi proposed a lack of conical setae on the anterior clypeal margin in workers as a diagnostic character , this description did not provide enough information on the uniqueness of the character observed in Xymmer. Our examination of the lectotype of Stigmatomma (Xymmer) muticum found a distinct plate-like projection just dorsal to the junction between the clypeus and labrum, and the projection widens distally with a flat distal margin (Figure 14C). This projection seems to be located along a line slightly ventral to where the conical setae are arranged (Figure 14D), and could replace the function of the conical setae; therefore, it is different from a typical mid-clypeal projection in Amblyopone, which bears the conical setae on its anterior margin. This specialized projection in Xymmer should be emphasized as a unique character to differentiate Xymmer from Amblyopone and Stigmatomma. The same clypeal character observed in the lectotype of S. (X.) muticum was found in some worker specimens in the Malagasy region, and we confirmed that male specimens identified as Xymmer (e.g. CASENT0007085) were congeneric with worker specimens identified as Xymmer (e.g. CASENT0007090) (unpublished COI sequence data). The Malagasy workers have a “mutica-like” clypeal character.
Combination in Xymmer.
A single species name, Xymmer muticus (Santschi, 1914) comb. rev., is here transferred from the genus Amblyopone to Xymmer. The genus name Xymmer should be treated as masculine in accordance with Article 30.2.4 of the ICZN Code , because this name is an anagram for “Myrmex.”
Morphological evolution of males in the subfamily Amblyoponinae
In this study, we investigated 30 male morphological characters in five amblyoponine genera in the Malagasy region. These characters were sufficient to develop diagnoses for the genera within the Malagasy region. Ten out of 30 characters had genus-specific character states, while three characters had character states that were invariant across all Malagasy amblyoponines. Of the remaining 17 characters, character states are shared among more than one genus. It is of interest to evaluate this pattern of morphological variation in an evolutionary context using trees from recent molecular phylogenetic studies –, . One caveat of such an analysis is that our study was focused on species found in the Malagasy region and includes only a limited investigation of amblyoponine genera and species found elsewhere.
To explore character evolution, we chose to map our data on the Brady et al. 2006 tree , which includes all amblyoponine lineages from Madagascar and the well-supported trees. The Brady et al. study  did not show strong support for all relationships within Amblyoponinae but did show strong support for two clades of amblyoponines, with one group including Onychomyrmex, Concoctio, and Prionopelta (OCP clade), and the second including Stigmatomma pallipes (as Amblyopone pallipes), Adetomyrma, Mystrium, and Xymmer (as Amblyopone mutica) (XMAS clade). This study did not include Amblyopone sensu stricto such as Am. australis, but did show that S. pallipes (as Am. pallipes) and X. muticus (as Am. mutica) were both within the XMAS clade and do not form a clade exclusive of Mystrium and Adetomyrma. This study also excluded other Amblyoponine lineages: Bannapone, Myopopone, Opamyrma, and Paraprionopelta, which are not known from Madagascar.
We focused on mapping male characters among four genera present in Madagascar: Adetomyrma, Mystrium, Stigmatomma, and Xymmer from the XMAS clade; and Prionopelta from the OCP clade. Prionopelta serves as an outgroup taxon in the analysis of these characters' evolution within the XMAS clade. Adetomyrma, Mystrium, and Xymmer have at least one male character unique to each of the genera (Figure 15). The present study, however, did not find any male character unique to Stigmatomma as represented by the species from the Malagasy region. Brown , in his generic synopsis of Amblyopone (Amblyopone sensu lato), also did not indicate any unique characters in his discussion of male characters. In our work, males of Stigmatomma are distinguished from the other three taxa in this clade only by a combination of plesiomorphic characters. Stigmatomma serves as a practical short-term solution to deal with the balance of taxa placed in Amblyopone s. l. (see below). The diversity of characters present in Stigmatomma males and workers suggest that further delimitation of this genus will need a careful study as part of a global revision of the Amblyoponinae.
A lack of the pygostyle (character 16) is shared by both Mystrium and Malagasy Xymmer. Brady et al.  proposed relationships among four genera in the clade as (Stigmatomma+(Adetomyrma+(Mystrium+Xymmer))), though the relationships among them were not well-supported by high posterior probability. Our support of the (Mystrium+Xymmer) clade by a morphological character is congruent with the molecular results and provides additional evidence for a separation of Xymmer from other Stigmatomma groups. In all male specimens identified as Xymmer, only one specimen from Central African Republic (X. cf01: CASENT0087255) has a pygostyle. This exception should be examined in future studies.
No morphological characters have been proposed as synapomorphies for the OCP and XMAS clades. Our morphological study provides a chance to investigate morphological characters that may support the XMAS clade. Our results suggest that the number of teeth on the mandible of the male is a unique character that defines the XMAS clade. The character state single-tooth mandible (character 03) is shared among males in Adetomyrma, Mystrium, Stigmatomma, and Xymmer, representing a synapomorphy of the clade. On the other hand, the male of Prionopelta possesses a mandible with two teeth.
To determine whether or not this clade-defining character state holds up outside the Malagasy region, we investigated additional genera and Stigmatomma species. Onychomyrmex males from Australia clearly show a mandible with two teeth, consistent with the molecular finding that Onychomyrmex is not part of the XMAS clade. Males of Myopopone, a member of the XMAS clade based on Moreau et al. 2006 , also show the predicted single tooth in specimens observed in this study. Bolton  also records Myopopone with a single tooth; Paraprionopelta, an amblyoponine genus known only from males and not yet included in molecular analysis, shows a single tooth. Thus we predict that Paraprionopelta is a member of the XMAS clade, and not related to Prionopelta as the name implies. Also missing from molecular analysis are species of Amblyopone sensu stricto that includes the type species of the genus Amblyopone australis. Brown [: figure 8] illustrated the male mandible of Amblyopone australis with two teeth suggesting that Amblyopone australis and related species are not members of the XMAS clade and that members of Stigmatomma in the XMAS clade (S. pallipes) are not congeners with Am. australis.
We also predict that males of the genus Concoctio have two mandibular teeth, because this genus is nested in the OCP clade with strong support , . Though Brady et al.  had strong support for the placement of Apomyrma in Amblyoponinae, its placement within the subfamily is not clear . The mandible of Apomyrma males (CASENT0086291, CASENT0086073) appears to be distinctly reduced with no teeth, and thus differs from all other Amblyoponinae species we studied.
Mandible evolution in Amblyopone australis and XMAS clades
This difference in mandibular dentition in males in the OCP and XMAS clades is also reflected in the morphology of their respective worker castes. A comparison of the mandibles of workers of Malagasy Stigmatomma and Amblyopone australis suggests a possible scenario for worker mandible evolution which involves the parallel evolution of elongate mandibles in the Stigmatomma and Amblyopone sensu stricto. In Stigmatomma, which has single-toothed males, we refer to the worker mandible form as SS (Stigmatomma Single) and in Amblyopone australis, which has double-toothed males, the worker mandible form is referred to as AD (Amblyopone Double).
We propose that the both SS and AD forms developed to hold larger prey, though each acquired this function in a different way as described in the mandible transformations series in Figure 16. It is important to realize that, in both SS and AD forms, the dent-like projections on the basal margin of the mandible (basal denticles) are not on the same plane as teeth on the masticatory margin. The masticatory margin can be further distinguished from the basal margin by the presence of teeth or a ridge along the dorsal side of the mandibular inner face. In some species, however, the angle dividing the basal and masticatory margins is not apparent.
Transformation of worker mandible of Malagasy Stigmatomma (SS form with single-toothed mandible in males):
- Apical teeth curve inwards, such that they remain opposite when mandibles are open (Figure 16-a2).
- Mandibles become narrower, and basal denticles extend towards apex, below masticatory teeth (Figure 16-a3).
- Teeth are reduced in size and, at times, form bifurcating teeth when adjacent to basal denticles (Figure 16-a4).
- The basal-most of the basal denticles (the basal projection) becomes larger (Figure 16-a4).
The basal denticles on the masticatory margin are larger than true masticatory teeth because the basal projections, and not the teeth, are used to hold prey.
Transformation of worker mandible of Amblyopone australis (AD form with double-toothed males):
- Apical teeth do not curve inward and are not opposite when mandibles are open (Figure 16-b2).
- Mandibles become narrower, the basal denticles do not extend toward apex and remain at base of mandible (Figure 16-b3).
- Some teeth become larger, never fusing with basal denticles to form bifurcated teeth (Figure 16-b4).
Across the Amblyoponinae, the number of teeth on the male mandible is correlated with the number of major teeth on the masticatory margin of conspecific workers. The male mandible in Amblyoponinae can be interpreted as a “reduced worker mandible” with the following features in comparison with conspecific workers: (a) smaller in length; (b) disappearance of the basal denticles; and (c) disappearance of the masticatory teeth except those which are well-developed on the worker mandible (Figures 16-a4 and a5; b4 and b5). Fusions of adjoining masticatory teeth can occur on the male mandible. On the worker mandible of Malagasy Stigmatomma (SS form), only the apical tooth or adjoining apical teeth are well-developed, and all of the others are reduced in size (16-a4). On the other hand, in Amblyopone australis (AD form), more than one tooth is distantly developed on the masticatory margin of workers, i.e. the basal tooth and the apical teeth. The difference in the development of masticatory teeth on worker mandibles is reflected in the difference in the number of teeth on the male mandible.
The point on the worker mandible used to hold prey moves distally as this transformation occurs in the AD form. The form of the anterior clypeal margin in workers of Amblyopone australis may reflect this change. In workers of Am. australis, the anterior margin of the clypeus is somewhat flattened, with smaller conical setae along the margin than in Malagasy species. The SS form mandible might perform better at catching larger prey than the AD form mandible, because the gape of mandibles in the former is wider than in the latter when the basal denticles or teeth on the masticatory margins are opposite each other.
In addition, we found a worker character uniquely observed in Malagasy Stigmatomma which distinguishes this genus from the other amblyoponine genera in the Malagasy region: the basal projection on the mandible is distinctly larger than the others arranged on the same margin. This large basal projection was not observed in Amblyopone australis. We also confirm that a worker of Stigmatomma pallipes, which was used as material in Brady et al. , has the SS form mandible and the large basal projection. That S. pallipes and Malagasy Stigmatomma share these mandibular characters suggests they belong in a common clade; the presence of a large basal mandibular projection is likely to be a synapomorphy of this shared group. The large basal mandibular projection seems to function as a stopper when the mandibles are closed.
Worker mandibles similar to the SS form were also observed in workers of Adetomyrma, Mystrium, and Xymmer. In Adetomyrma, the length of the mandible is secondarily shortened; in addition, most of the mandibular teeth are combined with the basal denticles on the masticatory margin, and as a result are unrecognizable. However, we confirm that some mandibular teeth remain separated into two layers along dorsal and ventral lines. In Mystrium, the mandibles are twisted mesally so that the basal denticles are arranged along the ventral margin of the mandible; the apical tooth is reduced in size and directed ventrally; both the mandibular teeth and the basal denticles are reduced in size and increased in number. Despite this further transformation, all elements of structures typical of the SS form are easily recognizable. In Xymmer, both the mandibular teeth and the basal denticles on the masticatory margin are distinct and appear similar to those seen in Malagasy Stigmatomma; however, all workers in Xymmer lack a large basal projection on the mandible.
Amblyopone species sensu Brown  with a SS form mandible is separated as a genus rank taxon from the genus Amblyopone represented by Amblyopone australis, the type species of the genus, based on the following: 1) the SS form mandible is shared among members of the XMAS clade (Stigmatomma pallipes, Malagasy Stigmatomma, Adetomyrma, Mystrium, and Xymmer workers; 2) SS form mandibles developed independently from AD form mandibles. These findings suggest that Amblyopone species with the AD form mandible nest outside the XMAS clade (Figure 15), and that Malagasy Stigmatomma belongs in the same clade with S. pallipes. Molecular studies support these morphological studies and place Am. australis as sister to Prionopelta (Ward et al., unpubl.; Figure 15). Stigmatomma Roger, 1859 is the oldest available name in synonymy under Amblyopone and we confirm the SS form mandible and the basal large projection in its type species Stigmatomma denticulatum Roger, 1859. Therefore, we resurrect Stigmatomma as genus name from synonymy of Amblyopone and transfer all species names from Amblyopone s. l. with SS form mandibles (including S. pallipes+S. denticulatum+Malagasy Stigmatomma) to Stigmatomma.
The mandibular transformations in these two lineages must have occurred after the development of two characters shared between the groups. Amblyoponinae have distinctive anterior clypeal conical setae, which have transformed into a plate-like projection in Xymmer. These conical setae are thought to be an apomorphic character of the subfamily Amblyoponinae , and are shared in all members of the subfamily. In addition, “the basal denticles” on the basal margin of the mandible are observed not only in Malagasy Stigmatomma, Adetomyrma, Mystrium, and Xymmer, but also in Am. australis, although the denticles in Am. australis did not extend to the masticatory margin of the mandible. Both the conical setae and the basal denticles seem to function to hold something large between widely opened mandibles, suggesting that the ancestor might have preyed on animals larger than itself.
Outside the XMAS clade
Outside the XMAS (Adetomyrma+Mystrium+Stigmatomma+Xymmer) clade, the male of Prionopelta has character states different from the other four Malagasy amblyoponine genera, some of which appear unique to Prionopelta. However, these character states cannot be regarded as unique to the genus, due to the shortage of available morphological data on the males of Concoctio and Onychomyrmex. Concoctio is the sister of Prionopelta, and relationships among three genera in the OCP clade ((Prionopelta+Concoctio)+Onychomyrmex) have been strongly supported in Brady et al.  and Moreau et al. . Thus, the discovery of males of Concoctio is necessary to evaluate the character states of Prionopelta. Using data from Brown's synopsis , Onychomyrmex shares the same character states with Prionopelta: two-segmented maxillary and labial palpi; radial sector on the forewing partially lacking between Rs+M and 2r-rs; hindwing lacking media apical to 1rs-m. These character states are probably shared with Concoctio as well. On the other hand, Onychomyrmex has different character states from Prionopelta in the development of the pterostigma and the location of the 2r-rs radial sector connection on the forewing. These two wing characters, which are seen in Prionopelta and are different from those in Onychomyrmex, may be generic characters unique to Prionopelta.
Advances in molecular ant systematics are creating a new opportunity and demand for morphological studies. Molecular studies will never be able to sequence all species and lineages, and therefore a need to discover morphological characters to diagnose molecular based clades remains. This study demonstrates that males have characters rich and useful for advancing our understanding of ant systematics. For example, the pattern of the number of mandibular teeth in males presents us with a possible scenario for worker mandible evolution that involves the parallel evolution of elongate worker mandibles in Amblyoponinae. We predict that Paraprionopelta belongs in the XMAS clade and that Concoctio in the OCP clade should have males with two mandibular teeth. These hypotheses can be tested when fresh material is available for sequencing or when males are found for Concoctio.
We would like to acknowledge Isabelle Zürcher-Pfander and Daniel Burckhardt (NHMB) for the loan of type materials, Tamas Szuts, Barry Bolton, Philip S. Ward, Doug Yanega, Francisco Hita Garcia, Robert Zuparko, and Steve Savage for their useful suggestions, Erin Prado and April Nobile for creating images, Michele Esposito for help with database management and for the arrangement of images, and Charles Griswold for supporting the use of the compound microscope imaging system. The fieldwork on which this study is based could not have been completed without the gracious support of the Malagasy people and the Arthropod Inventory Team (Balsama Rajemison, Jean Claude Rakotonirina, Jean-Jacques Rafanomezantsoa, Chrislain Ranaivo, Coco Randriambololona, Hanitriniana Rasoazanamavo, Nicole Rasoamanana, Clavier Randrianandrasana, Valerie Rakotomalala, and Dimby Raharinjanahary).
Conceived and designed the experiments: MY BLF. Performed the experiments: MY. Analyzed the data: MY BLF. Contributed reagents/materials/analysis tools: BLF MY. Wrote the paper: MY BLF.
- 1. Eguchi K, Yoshimura M, Yamane S (2006) The Oriental species of the ant genus Probolomyrmex (Insecta: Hymenoptera: Formicinae: Proceratiinae). Zootaxa 1376: 1–35.
- 2. Fisher BL, Smith MA (2008) A revision of Malagasy species of Anochetus Mayr and Odontomachus Latreille (Hymenoptera: Formicidae). PLoS ONE 3: e1787.
- 3. Yoshimura M, Fisher BL (2007) A revision of male ants of the Malagasy region (Hymenoptera: Formicidae): Key to subfamilies and treatment of the genera of Ponerinae. Zootaxa 1654: 21–40.
- 4. Yoshimura M, Fisher BL (2009) A revision of male ants of the Malagasy region (Hymenoptera: Formicidae): Key to genera of the subfamily Proceratiinae. Zootaxa 2216: 1–21.
- 5. Yoshimura M, Fisher BL (2011) A revision of male ants of the Malagasy region (Hymenoptera: Formicidae): Key to genera of the subfamily Dolichoderinae. Zootaxa 2794: 1–34.
- 6. Emery C (1911) pp. 1–125. Hymenoptera. Fam. Formicidae. Subfam. Ponerinae; Wytsman P, editor. Brussels.
- 7. Wheeler WM (1922) Ants of the American Museum Congo expedition. A contribution to the myrmecology of Africa. VII. Keys to the genera and subgenera of ants. Bull Am Mus Nat Hist 45: 631–710.
- 8. Kusnezov N (1955) Zwei neue Ameisengattungen aus Tucuman (Argentinien). Zool Anz 154: 268–277.
- 9. Brown WL Jr (1960) Contributions toward a reclassification of the Formicidae. III. Tribe Amblyoponini (Hymenoptera). Bull Mus Comp Zool 122: 143–230.
- 10. Bolton B (2003) Synopsis and classification of Formicidae. Mem Am Entomol Inst 71: 1–370.
- 11. Ogata K (1987) A generic synopsis of the poneroid complex of the family Formicidae in Japan (Hymenoptera). Part 1. Subfamilies Ponerinae and Cerapachyinae. Esakia 25: 97–132.
- 12. Smith MR (1943) A generic and subgeneric synopsis of the male ants of the United States. Am Midl Nat 30: 273–321.
- 13. Brady SG, Schultz TR, Fisher BL, Ward PS (2006) Evaluating alternative hypotheses for the early evolution and diversification of ants. Proc Natl Acad Sci U S A 103: 18172–18177.
- 14. Moreau CS, Bell CD, Vila R, Archibald SB, Pierce NE (2006) Phylogeny of the ants: Diversification in the age of angiosperms. Science 312: 101–104.
- 15. Ouellette GD, Fisher BL, Girman DJ (2006) Molecular systematics of basal subfamilies of ants using 28S rRNA (Hymenoptera: Formicidae). Mol Phylogenet Evol 40: 359–369.
- 16. Ward PS (2011) Integrating molecular phylogenetic results into ant taxonomy (Hymenoptera: Formicidae). Myrmecol News 15: 21–29.
- 17. Brown WL Jr (1949) A new American Amblyopone, with notes on the genus (Hymenoptera: Formicidae). Psyche 56: 81–88.
- 18. Fisher BL (2005) A model for a global inventory of ants: A case study in Madagascar. In: Jablonski NG, editor. Biodiversity: A symposium held on the occasion of the 150th anniversary of the California Academy of Sciences June 17–18, 2003. San Francisco, California: 295 p: Proceedings of the California Academy of Sciences, ser. 4, vol. 56, Suppl. I. pp. 78–89.
- 19. Erichson WF (1842) Beitrag zur Insecten-Fauna von Vandiemensland, mit besonderer Berücksichtigung der geographischen Verbreitung der Insecten. Arch Naturgesch 8(1): 83–287. Taf. IV-V.
- 20. Snodgrass RE (1935) Principles of insect morphology, with a new foreword by G. C Eickwort. (1993). New York: Cornell University Press. pp. 1–86 p. +33 pls.
- 21. I. GauldB. Bolton 1988 The Hymenoptera Oxford Oxford University Pressxii+322
- 22. Bolton B (1994) Identification guide to the ant genera of the world. Cambridge, Mass.: Harvard University Press. 222 p.
- 23. Huber JT, Sharkey MJ (1993) Structure. In: Goulet H, Huber TJ, editors. Hymenoptera of the World: An identification guide to families. Ottawa: Research Branch Agriculture Canada Publication 1894/E. pp. 13–59.
- 24. Snodgrass RE (1941) The male genitalia of Hymenoptera. Smithson Misc Collect 99: 1–86.
- 25. Snodgrass RE (1957) A revised interpretation of the external reproductive organs of male insects. Smithson Misc Collect 135: 1–60.
- 26. Wootton RJ (1979) Function, homology and terminology in insect wings. Syst Entomol 4: 81–93.
- 27. Serna F, Bolton B, Mackay W (2011) On the morphology of Procryptocerus (Hymenoptera: Formicidae). Some comments and corrigenda. Zootaxa 2923: 67–68.
- 28. Ward PS (1994) Adetomyrma, an enigmatic new ant genus from Madagascar (Hymenoptera: Formicidae) and its implications for ant phylogeny. Syst Entomol 19: 159–175.
- 29. Bolton B (1990) Abdominal characters and status of the cerapachyine ants (Hymenoptera, Formicidae). J Nat Hist 24: 53–68.
- 30. Gotwald WH Jr (1969) Comparative morphological studies of the ants, with particular reference to the mouthparts (Hymenoptera: Formicidae). Memoir of the Cornell University Agricultural Experiment Station No. 408.
- 31. Brown WL Jr, Nutting WL (1950) Wing venation and the phylogeny of the Formicidae. Trans Am Entomol Soc 75: 113–132.
- 32. SW Nichols 1989 The Torre-Bueno glossary of entomology New York The New York Entomological Society incorporating the Brooklyn Entomological Society in cooperation with the American Museum of Natural History xvii+840
- 33. Serna F, Mackay W (2010) A descriptive morphology of the ant genus Procryptocerus (Hymenoptera: Formicidae). J Insect Sci 10: 137.
- 34. International Commission on Zoological Nomenclature 1999 International Code of Zoological Nomenclature, Fourth Edition London International Trust for Zoological NomenclatureXXIX+306
- 35. Gotwald WH Jr, Lévieux J (1972) Taxonomy and biology of a new West African ant belonging to the genus Amblyopone (Hymenoptera: Formicidae). Ann Entomol Soc Am 65: 383–396.
- 36. Saux C, Fisher BL, Spicer GS (2004) Dracula ant phylogeny as inferred by nuclear 28S rDNA sequences and implications for ant systematics (Hymenoptera: Formicidae: Amblyoponinae). Mol Phylogenet Evol 33: 457–468.
- 37. Roger J (1859) Beiträge zur Kenntniss der Ameisenfauna der Mittelmeerländer. I. Berl Entomol Z 3: 225–259.
- 38. Bingham CT (1903) The fauna of British India, including Ceylon and Burma. Hymenoptera, Vol. II. Ants and Cuckoo-wasps. London: Taylor and Francis. 506 p.
- 39. Provancher L (1881) Faune canadienne. Les insectes - Hyménoptères. (Continué de la page 180.). Nat Can (Que) 12: 193–207.
- 40. Mann WM (1919) The ants of the British Solomon Islands. Bull Mus Comp Zool 63: 273–391.
- 41. Clark J (1928) Australian Formicidae. J R Soc West Aust 14: 29–41.
- 42. Bolton B (1995) A new general catalogue of the ants of the world. Cambridge, Mass.: Harvard University Press. 504 p.
- 43. Santschi F (1914) Formicides de l'Afrique occidentale et australe du voyage de M. le Professeur F. Silvestri. Boll Lab Zool Gen Agrar Fac Agrar Portici 8: 309–385.
- 44. Emery C (1919) Notes critiques de myrmécologie. [I–IV.]. Ann Soc Entomol Belg 59: 100–107.
- 45. Clark J (1934) New Australian ants. Mem Natl Mus Vic 8: 21–47.
- 46. Wheeler WM (1927) Ants of the genus Amblyopone Erichson. Proc Am Acad Arts Sci 62: 1–29.