Research Article |
Corresponding author: Zachary H. Griebenow ( zachary.griebenow@colostate.edu ) Academic editor: Michael Schmitt
© 2023 Zachary H. Griebenow, Adrian Richter, Thomas van de Kamp, Evan P. Economo, Ziv E. Lieberman.
This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Citation:
Griebenow ZH, Richter A, van de Kamp T, Economo EP, Lieberman ZE (2023) Comparative morphology of male genital skeletomusculature in the Leptanillinae (Hymenoptera: Formicidae), with a standardized muscular terminology for the male genitalia of Hymenoptera. Arthropod Systematics & Phylogeny 81: 945-1018. https://doi.org/10.3897/asp.81.e104810
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The male genitalia of the Insecta are famed for structural and functional diversity. Variation in this anatomical region shows ample phylogenetic signal, and this variation has proven indispensable for classification across the insects at multiple taxonomic ranks. However, in the ants (Hymenoptera: Formicidae) the male genital phenotype is ancillary to the morphology of the worker caste for systematic purposes. Ants of the enigmatic subfamily Leptanillinae are an exception, as males are easier to collect than workers. Ongoing systematic revision of the Leptanillinae must therefore rely upon the male phenotype – particularly the spectacular morphological profusion of the male genitalia. To thoroughly illuminate this anatomical region and aid comparative morphological research on ant male genitalia, we present a comparative morphological study of the male genitalia in nine exemplar lineages spanning the Leptanillinae, plus three outgroups representing other major clades of the Formicidae. We use micro-computed tomography (micro-CT) to generate 3D volumetric reconstructions of male genital skeletomusculature in these specimens. Our descriptions use new muscular terminology compatible with topographic main-group systems for the rest of the pterygote soma, and applicable to all Hymenoptera. We find that male genitalia in the Leptanillinae show an overall trend towards skeletomuscular simplification, with muscular reduction in some cases being unprecedented in ants, or even hymenopterans in general. In several lineages of the Leptanillinae we describe derivations of the male genitalia that are bizarre and unparalleled among the Hymenoptera. We conclude by discussing the functional implications of the often-extreme morphologies here observed.
Anatomy, evolutionary morphology, homology, micro-CT, pregenital abdomen, suicidal mating
“… Auteurs ne s’accordaient ni entre eux, ni avec eux-mêmes: autant de formes diverses, autant de noms différens.”
–
“… Authors agreed neither among themselves, nor with themselves: so many varied forms, so many different names.”
Pierre A. Latreille, in
The structural diversity of the male genitalia in insects (Hexapoda: Ectognatha) is famously diverse.
Compared to the general utility of male genitalia in insect taxonomy, ant classification has traditionally incorporated few male genitalic characters. Systematic myrmecology has overwhelmingly focused upon the female worker caste: workers are numerically more abundant than their reproductive counterparts, and males are short-lived, with rare exceptions (
In Formicidae, attention on the male genitalia has historically been nearly exclusively limited to sclerites. Prior to the 21st century, only three studies described ant genital musculature.
In some lineages, male morphology, including that of the genitalia, provides phylogenetic signal absent from the phenotype of corresponding workers (
The largely undescribed morphological derivation of male genital skeletomusculature seen within the Leptanillinae relative to the remaining Formicidae is of broader scientific interest, as is the conspicuous morphological disparity of the male phenotype in the Leptanillinae (Fig.
Variety of male habitus across the Leptanillinae, profile view; images from AntWeb.org. A Leptanilla zhg-my05 (CASENT042571; Zachary Griebenow). B Yavnella TH02 (CASENT0119531; April Nobile). C Leptanilla zhg-bt02 (CASENT0842612; Zachary Griebenow). D Leptanilla TH01 (CASENT0119792; April Nobile). E Scyphodon cf. anomalum (CASENT0106168; April Nobile). F Leptanilla ci01 (CASENT0102373; April Nobile). G Leptanilla zhg-mm01 (CASENT0842788; Zachary Griebenow). H Protanilla TH03 (CASENT0119791; Erin Prado). I Yavnella nr. indica (CASENT0106380; Zachary Griebenow). J Noonilla zhg-my06 (CASENT0106372; Zachary Griebenow). K Leptanilla indet. (CASENT0104306; April Nobile). L Protanilla zhg-my01 (CASENT0842734; Zachary Griebenow).
In the present study, we elucidate this “bizarre” quality by describing male genital skeletomusculature across all major subclades of the Leptanillinae for which males are known. We study male genital skeletomusculature here according to the comparative method set out by evolutionary morphology sensu
We report spectacular modifications to the male genitalia in certain lineages of the Leptanillinae relative to homologous skeletomusculature observed in other Formicidae, some apparently unique not just among ants but among the Hymenoptera as a whole. We observe numerous striking autapomorphies of the posterior pregenital segments and the genital apparatus, in clades at the tribal, generic, and lower ranks. We discuss the degree of consilience of male genital morphology with the phylogeny of the Leptanillinae, as inferred by
To connect the previous status quo for ant and Hymenopteran skeletomusculature with interordinal homology, contextualize the Leptanillinae, facilitate comparison, and link genitalic terminology to that of other anatomical regions, we provide a new muscular terminology. This system synthesizes interordinal holometabolan homologies (
Specimens are deposited at the following institutions, with abbreviations following
Collection data for all male specimens examined in this study, and the modality with which each was examined, is presented in Table S1. All image data are publicly available on Zenodo (10.5281/zenodo.7647890). All specimens are deposited as vouchers in their respective collections. Putative morphospecies are designated with numerical codes relating to their country of origin, following the generic assignments of
X-ray microtomography was performed using the following equipment and facilities: (1) Beamline 8.3.2 with a LuAD:CE scintillator and PCO.edge CMOS detector at the Lawrence Berkeley National Laboratory Advanced Light Source (ALS), University of California, Berkeley; (2) KIT Light Source of Karlsruhe Institute for Technology (KIT) using a 12-µm LSO:Tb scintillator and a 12-bit PCO.dimax detector. Laboratory X-ray microscopes used for this study were as follows: (1) a ZEISS Xradia 510 Versa 3D X-ray microscope, with the ZEISS Scout & Scan Control System (ZEISS, Oberkochen, Germany), at the Okinawa Institute of Science & Technology; (2) an XRadia 620 Versa at ZEISS X-ray Microscopy Inc., Dublin, CA; and (3) a Skyscan 2211 (Bruker, Belgium) at the Max Planck Institut for the Science of Human History Jena, equipped with a high resolution (4000 × 2600 pixel) X-ray sensitive CCD camera. Metadata for all scans published herein and relevant information on scan settings for all facilities are included in Table S2.
Segmentation of micro-CT data was performed manually with Dragonfly v.2021.1–2. Microtomographic sequences were imported as stacks of .tif or DICOM images, the latter reconstructed using XMReconstructor (v. 10.7.2936). If unwieldy for system RAM, scan data were cropped upon import into Dragonfly to include only structures that were relevant to the study. See
The minute size of most specimens belonging to the Leptanillinae largely prevented their suspension in fluid for imaging, therefore prohibiting iodine staining, except for Yavnella zhg-bt01. Therefore, leptanilline specimens were scanned dry on the end of cardstock points; if originally obtained in ethanol, these were treated with hexamethyldisilane (HMDS), preceded by two washes in absolute ethanol, to diminish distortion of muscles by desiccation. Outgroups were stained with iodine (
Photomicrographs were acquired as focus stacks, either (1) using a JVC KY-F75 digital camera (JVC, Yokohama, Japan), with manual z-stepping; or (2) 3.1-megapixel Leica DMC2900 camera (Leica Microsystems, Wetzlar, Germany) mounted on a Leica MZ16A stereomicroscope, with automated z-stepping via the Leica Application Suite software (v. 4.13.0). Image stacks were combined into full-focus montages and manually retouched using the Syncroscopy AutoMontage Program (v. 5.02.0096) (Synoptics Ltd., Cambridge, UK) or Helicon Focus (Helicon Soft. Ltd., Kharkiv, Ukraine). Additional photomicrographs were obtained from AntWeb (Version 8.68.7, California Academy of Sciences) and are attributed in figure captions. Scanning electron microscopy (SEM) was performed on uncoated specimens using a Hitachi TM4000.
We referred to Table S3 in illustrating tip states and reconstructing ancestral node states under maximum parsimony across the Hymenoptera included in that table. When multiple terminals belonging to the same family were included, they were either (1) collapsed into polymorphic tip states; (2) treated individually; or (3) omitted prior to parsimony analysis. The choice of collapsing, expanding, or omitting a terminal depended on whether its inclusion led to polymorphism including uncertainty or inapplicability, thereby precluding parsimony analysis; and whether a reliable internal topology was available for that family.
Topology was assembled manually in Newick format using cladograms from the literature (
The male pregenital metasomal segments of Formicidae are abdominal segments II–VIII. The genitalia are composed by parts of abdominal segments IX–X, specifically abdominal sternite IX and its appendages and derivative structures, and the fused appendages of abdominal segment X (primary gonopods, i.e., the penis). Following prior convention, we do not consider abdominal tergites IX–XI to be part of the genital apparatus. In Formicidae, tergites X–XI cannot be clearly distinguished from one another. To describe the extreme derivations of the genitalia in certain lineages of Leptanillinae, we include the skeletomusculature of (pregenital) abdominal segment VIII if (1) the tergite and sternite are fused to one another, or (2) when musculature of segment VIII is extrinsic and connects to genital sclerites. Visceral muscles, which have at least one non-skeletal attachment, were excluded from consideration in this study.
We caution that the muscular terminology introduced here is solely applicable to the male genitalia of Hymenoptera. For comparison of male genital skeletomusculature across the Hexapoda, we suggest retaining the system of
The terminology used for sclerites of male genitalia in the Formicidae is highly variable (Table
Terminological equivalencies in hymenopteran male genital sclerites across a selection of morphological studies. HAO URIs are unique reference identifiers; the associated webpage can be accessed by appending the URI to the URL https://purl.obolibrary.org.
HAO URI | HAO_0000238 | HAO_0000383 | HAO_0000328 | HAO_0000091 | HAO_0001084 | HAO_0000047 | HAO_0000191 | |||
HAO_0000386 | HAO_0000395 | HAO_0000703 | HAO_0000385 | |||||||
Source | Focal Taxon | |||||||||
1° | Leptanillinae | cupula | gonopodite | endophallic sclerite | penial sclerites | volsella | abdominal sternite IX | cercus | ||
gonocoxite | gonostylus | parossiculus | lateropenite | |||||||
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Formicidae | cupula | basimere | telomere | — | penisvalva | cuspis | digitus | abdominal sternite IX | — |
Yoshimura & Fisher (2011) | Proceratiinae | basal ring | basimere | harpago | — | aedeagus | cuspis | digitus | abdominal sternum IX | pygostyle |
Hymenoptera Anatomy Ontology ( |
Hymenoptera | cupula | gonopod | — | aedeagus | volsella | abdominal sternum IX | cercus | ||
gonostipes | harpe | parossiculus | digitus | |||||||
Prins (1982) | Anoplolepis | gonocardo/lamina annularis | gonostipes | — | penis cuspis |
volsella | — | — | ||
digitus | ||||||||||
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Dorylus | cupula | stipes | harpide | flap valve | aedeagus/thrysos | cuspis | digitus | sternum IX | pygostyle |
Watkins (1976) | Dorylinae sensu Ashmead | — | stipites | — | sagitta | volsella | — | — | ||
|
Paracryptocerus (= Cephalotes) | basal ring | parameral plate | paramere | — | penial valve | cuspis volsellaris | digitus volsellaris | subgenital plate | — |
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Hymenoptera | sclérite accessoire | pièce principale | palette | — | valve du pénis | pièce complementaire | pièce en trébuchet | plaque sous-génitale | cerque |
|
Insecta | gonobase | gonocoxite | gonostylus | — | penis valve | volsella | sternum IX | cercus |
Muscular terminology used in this study and equivalencies with selected systems. The
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HAO | HAO URI | Abbreviation | Homological/topographic main group | Descriptors |
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a | 1 | IXAscm* | medial S9-cupulal muscle | HAO_0000516 | 9vcm1 | sterno-coxalis | anteromedialis |
b | 2 | IXAscm | mediolateral 9th sterno-cupular muscle | HAO_0000533 | 9vcm2 | sterno-coxalis | posteromedialis |
c | 3 | IXAscl | lateral S9-cupulal muscle | HAO_0000464 | 9vcm3 | sterno-coxalis | lateralis |
g | 6 | IXAtc | dorsomedial cupulo-gonostyle/volsella complex muscle | HAO_0000279 | 9dcm1 | tergo-coxalis | dorsalis |
f | 7 | IXAtc | dorsolateral cupulo-gonostyle/volsella complex muscle | HAO_0000278 | 9dcm2 | tergo-coxalis | dorsolateralis |
e | 5 | IXAtc | ventrolateral cupulo-gonostyle/volsella complex muscle | HAO_0001074 | 9dcm3 | tergo-coxalis | ventrolateralis |
d | 4 | IXAtc | ventromedial cupulo-gonostyle/volsella complex muscle | HAO_0001075 | 9dcm4 | tergo-coxalis | ventralis |
j | 10 | IXAppd | distodorsal gonostyle/volsella complex-penisvalval muscle | HAO_0000250 | 9cppd | coxo-penialis promotor dorsalis | — |
h | 8 | IXAppv | proximoventral gonostyle/volsella complex-penisvalval muscle | HAO_0000879 | 9cppv1 | coxo-penialis promotor ventralis | anterior |
h’ | — | — | — | — | 9cppv2 | coxo-penialis promotor ventralis | posterior |
k | 11 | IXAprd | proximodorsal gonostyle/volsella complex-penisvalval muscle | HAO_0000877 | 9cprd1 | coxo-penialis remotor dorsalis | medialis |
l | 12 | — | lateral gonostyle/volsella complex-penisvalval muscle | HAO_0000472 | 9cprd2 | coxo-penialis remotor dorsalis | lateralis |
si | — | IXAppv† | parossiculo-penisvalval muscle | HAO_0000701 | 9cprv1 | coxo-penialis remotor ventralis | medialis |
i | 9 | IXAprv | distoventral gonostyle/volsella complex-penisvalval muscle | HAO_0000251 | 9cprv2 | coxo-penialis remotor ventralis | lateralis |
m | 22 | — | lateral penisvalvo-gonossiculal muscle | HAO_0002579 | 10plm1 | pene-lateropenitalis | medialis |
n | 24 | — | penisvalvo-phallotremal muscle | HAO_0000710 | 10plm2 | pene-lateropenitalis | lateralis |
s | 23 | — | gonostyle/volsella complex-gonossiculus muscle | HAO_0000517 | 9clm1 | coxo-lateropenitalis | interior medialis |
qr | 21 | IXAlp | median gonostyle/volsella complex-volsella muscle | HAO_0000473 | 9clm2 | coxo-lateropenitalis | interior lateralis |
p | 19 | IXAlm | lateral gonostyle/volsella complex-volsella muscle | HAO_0002580 | 9clm3 | coxo-lateropenitalis | exterior medialis |
o | 18 | — | gonostyle/volsella complex-parossiculal muscle | HAO_0002041 | 9clm4 | coxo-lateropenitalis | exterior lateralis |
— | — | — | — | — | 9csm1 | coxo-stylalis | anterior |
w, t | 16, 15 | IXAxad | intrinsic muscle of the gonostipes; gonostyle/volsella complex-harpal muscle | HAO_0000443; HAO_0002043 | 9csm2 | coxo-stylalis | intermedius |
u | — | IXAxab | apical gonostyle/volsella complex-harpal muscle | HAO_0000246 | 9csm3 | coxo-stylalis | posterior |
v | 17 | — | harpo-gonomaculal muscle | HAO_0000396 | 9csm4 | coxo-stylalis | interior |
x | 13 | — | interpenisvalval muscle | HAO_0000433 | 10ppm1 | pene-penialis | traversus |
z | 14 | — | penisvalvo-median sclerotized style muscle | HAO_0002582 | 10ppm2 | pene-penialis | medialis |
y | — | — | intervolsellal muscle | HAO_0000441 | 9ccm | coxo-coxalis | interior |
— | — | — | — | — | 9vvim | sterno-sternalis | interior |
*Erroneously omitted from |
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†Interpreted as a penial promotor by |
The genital appendages of males in the Ectognatha (Insecta s.str.) are derived from abdominal limbs, or coxopods, of abdominal segments IX–X, which constitute secondary and primary gonopods respectively; the protopods of gonopods X (i.e., gonocoxae) are medially fused to form the penis (
We consider homology of anatomical structures to refer to the phenomenon of morphological character states that are shared between individual organisms due to inheritance from a common ancestor. We recognize homologous structures according to the criteria presented by
The integument is here regarded as a continuous exoskeletal surface enclosing the fluid-filled haemocoel. Features situated on the exterior of this surface are called “ectal”; those within, “mesal”. For internalized sclerites which do not enclose a lumen, ectal indicates the outer surface (towards the body wall), and mesal indicates the inner surface (towards the anteroposterior axis). Along the transverse axis, features are referred to in mediolateral order.
Anatomically, sclerites are regions of the cuticle that are reinforced with exocuticle and separated by flexible conjunctivae, which consist only of endocuticle. A much more general definition is provided by the Anatomy of the Insect Skeleto-Muscular System (AISM;
For orientation of parts within the male genitalia, we divide this region into axial and appendicular anatomical categories. These categories are informed both by genital homologies across the Hymenoptera and the phenotype of genital components in the Leptanillinae. Abdominal sternite IX and the cupula are considered axial (unpaired and derived in whole or in part from segmental sclerites); the gonopodites, volsellae and penial sclerites are considered appendicular (paired and derived in whole from appendages). Axial structures are oriented along the craniocaudal axis, even when fused completely to components of the appendicular genitalia. Appendicular structures are oriented along a proximodistal axis relative to the body, with abdominal sternite IX and cupula (when present) being the collective proximal point of reference. When skeletomuscular features could not be resolved due to limitations of the dataset, these features are referred to as “not discernible”.
Abdominal segments are abbreviated A and numbered in an anteroposterior direction using Roman numerals, with AII being the petiole, and AIII–XI comprising the gaster (in some outgroup subfamilies, AIII comprises the postpetiole and AIV–XI the gaster). Abdominal tergites and sternites are abbreviated T and S, respectively. Abdominal tergite IX may be a continuous, unpaired sclerite, as in the unmodified pregenital segments, or it may be fully divided into disjunct lateral fragments, or hemitergites. In species with undivided ATIX, the distinction between ATIX and ATX is usually unclear, due to weak sclerotization and continuity of the membranous surfaces between the tergites confusing the intersegmental boundary; Richards (1934) contended that ATIX–ATX are indistinct in all male Aculeata. However, as pointed out by
We follow the skeletal terminology of
Diagrammatic summary of ♂ genital and pregenital sclerites in the Formicidae considered in the scope of this study, using Myrmica ruginodis Nylander as template. Mediolateral arrangement of overlapping sclerites in Figure
External cuticular processes which do not enclose apparent haemocoelic lumina and are compressed enough to result in transparency to visible light are termed laminae. The gonopodites are considered “inarticulate” if there is no trace of a conjunctiva separating the gonocoxite and gonostylus, and the gonostylus is not reflexed relative to the gonocoxite, which in deceased specimens implies articulation of the gonopodite (
Table
An abdominal muscle is extrinsic if it attaches two different body segments, two true segments of an appendage, or connects an appendage to the body; it is intrinsic if both attachments are within the same body segment or segment of an appendage. The origin (O) of an extrinsic muscle is the attachment on the cephalad segment of the body, the proximad segment of an appendage, or the body segment if it attaches an appendage to the body; its insertion (I) is the attachment on the caudad body segment, distad appendage segment, or the appendage if the muscle attaches an appendage to the body. For intrinsic muscles, the origin is point of putatively fixed attachment, while the insertion is the point of mobile attachment (
In our extension of
Terminology and enumeration for pregenital musculature follows
Genital musculature and context of other systems
We introduce an expansion of the homology inferences of
While the system applied here generally refers to muscle groups plesiomorphic for the Hexapoda, the numeration and descriptors of muscles apply strictly to male Hymenoptera. That is, the system used here is not intended to apply across insect orders and does not inherently imply intersexual homology with female Hymenoptera. We are aware of potential drawbacks in introducing new terminology, especially of limited scope and in systems rife with historical synonymy and terminological homonymy. Nevertheless, we consider the application of the system justifiable. We submit that considering interordinal homologies in terminology (see Section 2.3.2., and below), and constructing that terminology congruently with terms used for extralimital anatomical systems and clades, is valuable in moving towards a unified and comprehensive schema with the broadest possible taxonomic applicability. To the latter end, we explicitly orient term construction to congruent systems for the hymenopteran head (
The commonly used existing schema for male genital terminology in Hymenoptera is the homology-neutral alphabetic system of
Because most muscles of the male genitalia can be confidently identified as subsets of these homology classes, we adopt these groups where applicable. However, we make certain modifications to both convey evolutionary-anatomical information and provide an intuitive and usable shorthand for communicating spatial information. To these ends, we combine the homologies of
We enact the following additions or modifications to
Relative transverse position is stabler at deeper nodes than anteroposterior or dorsoventral position, as in the worker abdomen (
We recognize thirteen homological-topographic groups in male Hymenoptera, of which eight are known in ants. Table
For the coxo-penial muscles, the names “promotor” and “remotor” are used to indicate homology with other Neoptera, although in the Hymenoptera these muscles may not protrude or retract the genitalia. The heuristic definition of these terms is that promotors insert apically on the valvurae while remotors insert at the base of the valvurae on the mesal surface or a lateral apodeme on the ectal surface. In some cases, the insertions are secondarily expanded, as in 9cprd1 (k) which may insert broadly on the mesal surfaces of the penial sclerites, both distally, and on parts of the valvurae. Functionally, the dorsal and ventral promotors are usually antagonists of one another.
We use Latinized names to take advantage of differences in grammatical word order between Latin and English, allowing the presentation of information hierarchically while also providing cogent English names. Latin names give homological, spatial, and orientational information in order from general to specific (origin-insertion, main descriptor, detailed descriptors) and parallel the construction of abbreviations (segment of origin, origin-insertion, numeration of subsets). An English term can be derived by reading the Latin name in reverse. For example, 9clm2, Musculus coxo-lateropenitalis interior lateralis is the “lateral intrinsic coxo-lateropenital muscle [of AIX]”, while 9cprd1, M. coxo-penialis remotor dorsalis medialis is the medial dorsal coxo-penial remotor [of AIX]”.
The tribal, generic, and species-group phylogeny of the exemplars used here is provided in Fig.
Except for Noonilla zhg-my03, Leptanilla zhg-my06, and Leptanilla zhg-id04, all leptanilline morphospecies for which micro-CT data were obtained in this study have been sequenced using ultraconserved elements (UCEs;
Scans are hereby published for all major subclades of the Leptanillini, with at least two morphospecies being scanned per subclade. Males of three outgroups to the Leptanillinae were scanned and described in full (Sections 3.1.2., 3.2.2.), representing both major ant clades: the “poneroids” (Ponerinae: Ponerini: Odontomachus indet.) and the “core formicoids” (Myrmicinae: Myrmicini: Myrmica ruginodis Nylander, 1846), and the latter’s comparatively minor sister lineage, the Dorylinae (Lioponera indet.;
Descriptive sampling within the Leptanillinae in this study focuses largely on the tribe Leptanillini s.str., with a single exemplar (Protanilla zhg-vn01) of their sister clade, the former Anomalomyrmini. The only conspicuous lacuna in the phylogenetic distribution of our volumetric reconstructions of male genital skeletomusculature in the Leptanillini s.str. is the Indochinese morphospecies-group, known only from undescribed male morphospecies and was represented in previous studies by Leptanilla TH01, –7, and Leptanilla zhg-th01 (
The former Anomalomyrmini are less speciose than the Leptanillini s.str., and variation in the external morphology of all available male specimens is so limited as to obviate any apparent need for description of multiple morphospecies, with the following exceptions. Protanilla TH03 (CASENT0119791) differs from all other known males of the former Anomalomyrmini in several conspicuous morphological characters (
Males of the monotypic genus Opamyrma, which is sister to the remaining Leptanillinae (
The following is a coarse summary of the totality of variation observed in the male genital sclerites of the Formicidae, supplementing findings described in the present paper with previous literature as necessary (cited throughout Section 3.1.1.). This summary cannot be construed as representative of the ancestral condition of the male genital sclerites for the Formicidae.
The terminal pregenital segment is abdominal segment VIII (AVIII), which comprises the dorsal tergite VIII (ATVIII), and ventral sternite VIII (ASVIII), which lacks limbs. Both these sclerites bear an anterior marginal invaginated ridge, the antecosta (acs) which represents the apparent segmental boundary (i.e., secondary segmentation;
The genital skeleton comprises abdominal sternite IX (ASIX, Fig.
Axial sclerites and gonocoxites, 3D reconstructions in anterior view. A Odontomachus indet. B Myrmica ruginodis. C Lioponera indet. D Protanilla zhg-vn01. E Yavnella zhg-bt0.1 F Yavnella zhg-th03. G Leptanilla zhg-my04. H Leptanilla zhg-my02. I Noonilla zhg-my03. J Noonilla cf. copiosa. K Leptanilla zhg-id04. White arrowhead in G indicates possible cupular remnant. Abbreviations: ASVIII = abdominal sternite VIII; ASIX = abdominal sternite IX; ATIX = abdominal tergite IX; cup = cupula; fog = foramen genitale; gcx = gonocoxite; gcy = gonocondyle; spc = spiculum; stl = gonostylus; 8volm = ventral ortholateral muscles VIII-IX; 8vpmm = ventral paramedial muscles VIII-IX; 9dvim = dorsoventral intrinsic muscles IX; 9vcm1 = anteromedial sterno-coxal muscles; 9vcm2 = posteromedial sterno-coxal muscles; 9vcm3 = lateral sterno-coxal muscles; 9dcm2 = dorsolateral tergo-coxal muscles; 9dcm3 = ventrolateral tergo-coxal muscles; 9dcm4 = ventral tergo-coxal muscles.
The following summarizes the scleritic condition across all three outgroup exemplars for which we undertook volumetric reconstruction of male genital skeletomusculature.
Abdominal sternite VIII (ASVIII) shallowly convex, not recurved dorsally, anteroposteriorly prolonged; posteriorly separate from abdominal sternite IX; without lateral fusion to abdominal tergite VIII. Abdominal sternite IX (ASIX) present, shallowly convex, anteroposterior length greater than that of abdominal sternite VIII; spiculum (spc) present; mulceators absent; antecosta present. Abdominal tergite IX (ATIX) present, either medially divided into hemitergites (Lioponera indet.) or not; cerci present or not (Lioponera indet.). Cupula (cup) present, annular. Gonopodites (gpd) articulated, or not (Lioponera indet.); if articulated, then so by ventral conjunctiva. Gonocoxites (gcx) medially articulated, sometimes (Myrmica ruginodis) with anteromedial gonocoxital arm (gct) extending from margin. Gonostyli (stl) present, apices entire, medially separated. Volsellae (vol) present, fully articulated with gonocoxites; medially separated; parossiculus (prs) and lateropenite (ltp) distinct, or indistinguishably fused (Lioponera indet.). Penial sclerites (psc) medially joined by dorsal conjunctiva along some to most proximodistal length, ventro-apical margins serrated or hooked; ventromesal septa (mes) present (M. ruginodis), arising by conjunctival connection with the ventral penial margins and sclerotic connection by a distal bridge; valvurae (vlv) present, anterior apices curving dorsally; endophallic sclerite (end) present or absent (Odontomachus sp.), dorsal outline divaricate, dorsum concave.
♂ genitalia of Odontomachus indet. (CASENT0842842), 3D reconstructions (A–D) and summary diagrams (E–H). Orthogonal caps at end of diagrammatic muscle lines signify origin; lack of caps, insertion. A dorsal view. B ventral view. C profile view. D sagittal cross-section. E ventral longitudinal muscles VIII–IX and dorsoventral extrinsic muscles VIII–IX, profile view. F intrinsic dorsoventral muscles IX and sterno-coxal muscles IX, profile view. G tergo-coxal muscles IX, profile view. H coxo-penial muscles sagittal cross-section. I coxo-stylar and coxo-lateropenital muscles, profile view. Abbreviations: ASVIII = abdominal sternite VIII; ASIX = abdominal sternite IX; ATIX = abdominal tergite IX; cer = cercus; cup = cupula; gcx = gonocoxite; psc = penial sclerite; stl = gonostylus; vol = volsella; 8vomm = ventral orthomedial muscles VIII-IX; 8vpmm = ventral paramedial muscles VIII-IX; 8volm = ventral ortholateral muscles VIII-IX; 8dvxm = dorsoventral extrinsic muscles VIII-IX; 9dvim = dorsoventral intrinsic muscles IX; 9vcm1 = anteromedial sterno-coxal muscles; 9vcm2 = posteromedial sterno-coxal muscles; 9dcm1 = dorsal tergo-coxal muscles; 9dcm2 = dorsolateral tergo-coxal muscles; 9dcm3 = ventrolateral tergo-coxal muscles; 9dcm4 = ventral tergo-coxal muscles; 9csm2 = intermediate coxo-stylar muscles; 9clm3 = medial extrinsic coxo-lateropenital muscles; 9cppd = dorsal coxo-penial promotors; 9cprd1 = dorsal coxo-penial remotors; 9cppv1 = anterior ventral coxo-penial promotors; 9cppv2 = posterior ventral coxo-penial promotors; 9cprv2 = lateral ventral coxo-penial remotors.
♂ genitalia of Odontomachus indet. (CASENT0842842), 3D reconstruction in transverse cross-section. Abbreviations: ASVIII = abdominal sternite VIII; ASIX = abdominal sternite IX; ATIX = gcx = gonocoxite; psc = penial sclerite; stl = gonostylus; vlv = valvura; vol = volsella; 8vpmm = ventral paramedial muscles VIII-IX; 9dvim = dorsoventral intrinsic muscles IX; 9vcm2 = posteromedial sterno-coxal muscles; 9csm2 = intermediate coxo-stylar muscles; 9cppd = dorsal coxo-penial promotors; 9clm3 = medial extrinsic coxo-lateropenital muscles; 9cprd1 = dorsal coxo-penial remotors; 9cprv2 = lateral ventral coxo-penial remotors.
♂ genitalia of Myrmica ruginodis (
Penial sclerites of Myrmica ruginodis, 3D reconstruction in anterior oblique view (A–B) and posterior transverse section (C–D). Section plane in C is slightly caudad that in D. Left half of 9ppcd hidden. Abbreviations: vlv = valvura; vms = ventromesal septum; 9cppd = dorsal coxo-penial promotor.
♂ genitalia of Myrmica ruginodis (
♂ genitalia of Lioponera indet. (CASENT0844684), 3D reconstructions (A–D) and summary diagrams (E–H). Orthogonal caps at end of diagrammatic muscle lines signify origin; lack of caps, insertion. A dorsal view. B ventral view. C profile view. D sagittal cross-section. E ventral longitudinal muscles IX, profile view. F intrinsic dorsoventral muscles IX and sterno-coxal muscles, profile view. IX G tergo-coxal muscles IX, profile view. H coxo-penial muscles, sagittal cross-section. I coxo-lateropenital muscles, profile view. Abbreviations: ASVIII = abdominal sternite VIII; ASIX = abdominal sternite IX; ATIX = abdominal tergite IX; cup = cupula; gcx = gonocoxite; gpd = gonopodite; psc = penial sclerite; spc = spiculum; stl = gonostylus; vol = volsella; 8vpmm = ventral paramedial muscles VIII–IX; 8volm = ventral ortholateral muscles VIII–IX; 9dvim = dorsoventral intrinsic muscles IX; 9vcm1 = anteromedial sterno-coxal muscles; 9vcm2 = posteromedial sterno-coxal muscles; 9dcm1 = dorsal tergo-coxal muscles; 9dcm2 = dorsolateral tergo-coxal muscles; 9dcm3 = ventrolateral tergo-coxal muscles; 9clm3 = medial extrinsic coxo-lateropenital muscles; 9clm4 = lateral extrinsic coxo-lateropenital muscles; 9cppd = dorsal coxo-penial promotors; 9cprd1 = medial dorsal coxo-penial remotors; 9cprd2 = lateral dorsal coxo-penial remotors; 9cppv1 = anterior ventral coxo-penial promotors; 9cprv2 = lateral ventral coxo-penial remotors.
♂ genitalia of Lioponera indet. (CASENT0844684), 3D reconstruction in transverse cross-section. Abbreviations: ASVIII = abdominal sternite VIII; ASIX = abdominal sternite IX; ATIX = abdominal tergite IX; gcx = gonocoxite; gpd = gonopodite; psc = penial sclerite; vlv = valvura; vol = volsella; 9dvim = dorsoventral intrinsic muscles IX; 9vcm2 = posteromedial sterno-coxal muscles; 9clm3 = medial extrinsic coxo-lateropenital muscles; 9clm4 = lateral extrinsic coxo-lateropenital muscles; 9cprd2 = lateral dorsal coxo-penial remotors; 9cppv2 = posterior ventral coxo-penial promotors.
Morphology of abdominal sternite IX, 3D reconstructions in dorsal view. Dashed lines represent lines of fusion to gonocoxites. A Odontomachus indet. B Myrmica ruginodis. C Lioponera indet. D Protanilla zhg-vn01. E Leptanilla zhg-id04. F Noonilla cf. copiosa. G Noonilla zhg-my03. H Leptanilla zhg-my02. Abbreviations: atpS9 = anterolateral processes of abdominal sternite IX; mul = mulceator; spc = spiculum.
Morphology of the volsella, 3D reconstructions in dorsal view. A Odontomachus indet. B Myrmica ruginodis. C Lioponera indet. D Protanilla zhg-vn01. E Yavnella zhg-th03. F Yavnella zhg-bt01. G Leptanilla zhg-my02. H Leptanilla zhg-my04. I Leptanilla cf. zaballosi. J Leptanilla zhg-id04. Abbreviations: ltp = lateropenite; prp = lateropenital recurved processes; prs = parossiculus.
3.1.3.1. Protanilla zhg-vn01 (Fig.
Abdominal sternite VIII (ASVIII; Fig.
♂ genitalia in Protanilla zhg-vn01 (CASENT0106408), 3D reconstructions (A–E) and summary diagrams (F–H). Orthogonal caps at end of diagrammatic muscle lines signify origin; lack of caps, insertion. White arrowhead in Fig.
Yavnella zhg-bt01 (Fig.
Abdominal sternite VIII (ASVIII; Fig.
♂ genitalia of Yavnella zhg-bt01 (CASENT0842743), 3D reconstructions (A–E) and summary diagram (F). Orthogonal caps at end of diagrammatic muscle lines signify origin; lack of caps, insertion. A dorsal view. B ventral view. C profile view. D sagittal cross-section. E transverse cross-section. F genital musculature, sagittal cross-section. Abbreviations: ASVIII = abdominal sternite VIII; cup = cupula; gcx = gonocoxite; gpd = gonopodites; pht = phallotreme; ppp = posterior penial process; psc = penial sclerite; stl = gonostylus; vol = volsella; 9clm3 = medial extrinsic coxo-lateropenital muscles; 9cprd1 = medial dorsal coxo-penial remotors.
Yavnella zhg-th03 (Fig.
Abdominal sternite VIII (ASVIII; Fig.
♂ genitalia of Yavnella zhg-th03 (CASENT0842741), 3D reconstructions (A-E) and summary diagram (F). Orthogonal caps at end of diagrammatic muscle lines signify origin; lack of caps, insertion. A dorsal view. B ventral view. C profile view. D sagittal cross-section. E transverse cross-section. F genital musculature, sagittal cross-section. Abbreviations: ASVIII = abdominal sternite VIII; cup = cupula; gcx = gonocoxite; gpd = gonopodite; pht = phallotreme; psc = penial sclerite; stl = gonostylus; vol = volsella; 9clm3 = medial extrinsic coxo-lateropenital muscles; 9dcm4 = ventral tergo-coxal muscles; 9cprd1 = medial dorsal coxo-penial remotors.
Noonilla zhg-my03 (Fig.
Abdominal sternite VIII (ASVIII; Fig.
♂ genitalia of Noonilla zhg-my03 (CASENT0842609), 3D reconstructions (A-E) and summary diagram (F). Orthogonal caps at end of diagrammatic muscle lines signify origin; lack of caps, insertion. A dorsal view. B ventral view. C profile view. D sagittal cross-section. E transverse cross-section. F genital musculature, sagittal cross-section. Abbreviations: ASVIII = abdominal sternite VIII; ASIX = abdominal sternite IX; ATIX = abdominal tergite IX; gcx = gonocoxite; pht = phallotreme; psc = penial sclerite; stl = gonostylus; 9dvim = dorsoventral intrinsic muscles IX; 9csm2 = intermediate coxo-stylar muscles; 9cprv2 = lateral ventral coxo-penial remotors.
Noonilla cf. copiosa (Fig.
Abdominal sternite VIII (ASVIII; Fig.
♂ genitalia of Noonilla cf. copiosa (CASENT0842844), 3D reconstructions (A–E) and summary diagram (F). Orthogonal caps at end of diagrammatic muscle lines signify origin; lack of caps, insertion. A dorsal view. B ventral view. C profile view. D sagittal cross-section. E transverse cross-section. F genital musculature, sagittal cross-section; abdominal segments VIII–IX are shown rotated 180° relative to its position in situ. Abdominal sternite VIII is shown without sagittal cross-section. Abbreviations: AVIII = abdominal segment VIII; ASVIII = abdominal sternite VIII; ATVIII = abdominal tergite VIII; ASIX = abdominal sternite IX; ATIX = abdominal tergite IX; atpS9 = anterolateral processes of abdominal sternite IX; gcx = gonocoxite; pht = phallotreme; psc = penial sclerite; stl = gonostylus; 8volm = ventral ortholateral muscles VIII-IX; 9dvim = dorsoventral intrinsic muscles IX; 9csm2 = intermediate coxo-stylar muscles; 9cprd1 = medial dorsal coxo-penial remotors; 9cprv2 = lateral ventral coxo-penial remotors.
Leptanilla zhg-my02 (Fig.
Abdominal sternite VIII (ASVIII; Fig.
♂ genitalia of Leptanilla zhg-my02 (CASENT0106416), 3D reconstructions (A–E) and summary diagram (F). Orthogonal caps at end of diagrammatic muscle lines signify origin; lack of caps, insertion. A dorsal view. B ventral view. C profile view. D sagittal cross-section. E transverse cross-section. F genital musculature, sagittal cross-section. Abbreviations: ASVIII = abdominal sternite VIII; ASIX = abdominal sternite IX; mul = mulceator; ATIX = abdominal tergite IX; gcx = gonocoxite; all = apicolateral lamina; vol = volsella; psc = penial sclerites; pht = phallotreme; 8volm = ventral ortholateral muscles VIII–IX; 9dvxm = dorsoventral extrinsic muscles IX–VIII; 9dvim = dorsoventral intrinsic muscles IX; 9clm3 = medial extrinsic coxo-lateropenital muscles.
Leptanilla zhg-my04 (Fig.
Abdominal sternite VIII (ASVIII; Fig.
♂ genitalia of Leptanilla zhg-my04 (CASENT0842565), 3D reconstructions (A–E) and summary profile diagram (F). Orthogonal caps at end of diagrammatic muscle lines signify origin; lack of caps, insertion. A dorsal view. B ventral view. C profile view. D sagittal cross-section. E transverse cross-section. F genital musculature, sagittal cross-section. Abbreviations: ASVIII = abdominal sternite VIII; ASIX = abdominal sternite IX; ATIX = abdominal tergite IX; gcx = gonocoxite; mul = mulceator; pht = phallotreme; psc = penial sclerites; vol = volsella; 9dvim = intrinsic dorsoventral muscles IX; 9clm = medial extrinsic coxo-lateropenital muscles; 9cprv2 = lateral ventral coxo-penial remotors.
Leptanilla zhg-id04 (Fig.
Abdominal sternite VIII (ASVIII; Fig.
♂ genitalia of Leptanilla zhg-id04 (CASENT0106357), 3D reconstructions (A–E) and summary diagram (F). Orthogonal caps at end of diagrammatic muscle lines signify origin; lack of caps, insertion. A dorsal view. B ventral view. C profile view. D sagittal cross-section. E transverse cross-section. F genital musculature, external profile view. Abbreviations: ASVIII = abdominal sternite VIII; ASIX = abdominal sternite IX; gcx = gonocoxite; pht = phallotreme; psc = penial sclerites; stl = gonostylus; vol = volsella; 9csm1 = anterior coxo-stylar muscle; 9csm2 = intermediate coxo-stylar muscle; 9cprv2 = lateral ventral coxo-penial remotors.
Leptanilla cf. zaballosi (Fig.
Abdominal sternite VIII present, posteriorly separate from abdominal sternite IX, but not discernible in toto. Abdominal sternite IX (ASIX; Fig.
♂ genitalia of Leptanilla cf. zaballosi (CASENT0842782), 3D reconstructions (A–E) and summary diagram (F). Orthogonal caps at end of diagrammatic muscle lines signify origin; lack of caps, insertion. A dorsal view. B ventral view. C profile view. D sagittal cross-section. E transverse cross-section. F genital musculature, sagittal cross-section. Abbreviations: ASVIII = abdominal sternite VIII; ASIX = abdominal sternite IX; gcx = gonocoxite; pht = phallotreme; ppp = posterior penial process; psc = penial sclerites; stl = gonostylus; vol = volsella; 9csm1 = anterior coxo-stylar muscles; 9csm2 = intermediate coxo-stylar muscles; 9clm3 = medial extrinsic lateropenital muscles; 9cprv2 = lateral ventral coxo-penial remotors
As in Section 3.1.1., the following summarizes the totality of muscular variation in the male genitalia of the Formicidae, based upon previous literature (
Ventral longitudinal muscles VIII–IX (8vlm) originate on abdominal sternite VIII and insert on abdominal sternite IX. These include the ventral longitudinal orthomedial (8vomm), paramedial (8vpmm) and ortholateral (8volm) muscles. The ventral paramedial muscles VIII–IX (8vpmm) originate on abdominal sternite VIII posterior to their insertion on abdominal sternite IX and are therefore reversed in position relative to the orthomedial and -lateral ventral longitudinal muscles. In many cases sampled in this study, these subsets of 8vlm cannot be distinguished. Intrinsic dorsoventral muscles IX (9dvim) originate on abdominal tergite IX (ATIX) and insert on abdominal sternite IX; extrinsic dorsoventral muscles IX–VIII (9dvxm) originate on abdominal tergite IX and insert on abdominal sternite VIII. Median sterno-coxal muscles (9vcm1–2; a, b; M. sterno-coxalis antero-, posteromedialis) and lateral sterno-coxal muscles (9vcm3; c; M. sterno-coxalis lateralis) originate on abdominal sternite IX and insert on the cupula (cup); 9vcm1 (a) are paired, originating on the anterior end of the spiculum (spc) and inserting on the anteroventral margin of the cupula (cup); 9vcm2 (b) is unpaired, originating posteriorly or around the longitudinal midpoint of abdominal sternite IX, sometimes on a transverse carina or lamella (“cranial apodeme”,
Ventral longitudinal muscles AVIII–IX: 8vomm, ventral orthomedial muscles. Present (Odontomachus indet.) or absent. O: narrowly on ASVIII, anteromediad O: 8vpmm. I: narrowly on ASIX at the anterior apex of the spiculum. 8vpmm, ventral paramedial muscles. O: broadly on median or lateral surface of ASVIII. I: narrowly or broadly on ventral surfaces of anterolateral extremities of ASIX. 8volm, ventral ortholateral muscles. O: broadly or narrowly on mesal surfaces of anterolateral margins or apodemes of ASVIII. I: broadly on anterolateral margins of ASIX, posterad anterolateral apodemes of ASIX, if present (Lioponera indet.).
Dorsoventral muscles AVIII: 8dvxm, dorsoventral extrinsic muscles VIII–IX. Present (Odontomachus indet.) or absent. O: broadly on dorsolateral margins of ATVIII. I: narrowly on anterolateral corners of ASIX.
Dorsoventral muscles AIX: 9dvim, dorsoventral intrinsic muscles IX. O: narrowly or broadly on anterolateral margin of ATIX. I: narrowly or broadly on mesal surfaces of anterolateral processes of ASIX.
Sterno-coxal muscles IX: 9vcm1 (a), anteromedial sterno-coxal muscles. O: narrowly on anterior apex of spiculum, or along lateral edges of spiculum (Myrmica ruginodis). I: broadly on anteroventral surfaces of cupula, or narrowly on anteroventral rim of cupula. 9vcm2 (b), O: broadly on posteromesal surface of ASIX, or on mesal surface of ASIX near middle of anteroposterior length (M. ruginodis). I: narrowly or broadly on the ectal ventral surface of the cupula, or posterior margin of spiculum and antecosta of ASIX laterad spiculum (M. ruginodis). 9vcm3 (c), present or absent (Odontomachus indet.). O: broadly on lateromesal surface of ASIX (Odontomachus indet.), or on anterior margins of diverging anterolateral processes of abdominal sternite IX (Lioponera indet.). I: broadly on anteroventral rim of cupula.
Tergo-coxal muscles IX: 9dcm1 (g), dorsal tergo-coxal muscles. O: broadly on posterodorsal margin of cupula (Odontomachus indet.) or dorsomedian mesal surface of cupula. I: broadly on posterodorsal surfaces of the gonocoxites, or narrowly on anterodorsal edge of the anterior gonocoxital margin (Myrmica ruginodis). 9dcm2 (f), dorsolateral tergo-coxal muscles. O: broadly on mesal dorsolateral or anterior (Lioponera indet.) surface of cupula, in Myrmica ruginodis partially overlapping O:9dcm1. I: narrowly or broadly on proximal margins of the gonocoxites. 9dcm3), ventrolateral tergo-coxal muscles. O: broadly on anteromesal or ventrolateral (Myrmica ruginodis) mesal surfaces of the cupula. I: broadly on ventro-ectal margins of the gonocoxites, or (Myrmica ruginodis) more narrowly on the anterodorsal edges of the proximal processes of the gonocoxites, thus muscles triangular and transverse in orientation. 9dcm4 (d), ventral tergo-coxal muscles. Absent or present (Myrmica ruginodis). O: ventromedially on the cupula, ventromediad O:9dcm3, I: on the anterior surfaces of the proximal processes of the gonocoxites, ventromediad 9dcm3.
Coxo-stylar muscles: 9csm2 (t), intermediate coxo-stylar muscles. Present or absent (Lioponera indet.) O: broadly on distal margins of the gonocoxites, or partly slightly beyond (Myrmica ruginodis). I: narrowly on anterior mesal surface of the gonocoxites (Odontomachus indet.) or (Myrmica ruginodis) distodorsally on the mesomedial surfaces of the gonostyli.
Coxo-lateropenital muscles: 9clm2 (qr), lateral intrinsic coxo-lateropenital muscles. Absent or present (Myrmica ruginodis). O: at the junctions of the distoventral gonocoxites and the proximoventral parossiculi, I: on the mesal surfaces of the parossiculi, slightly distad (and mesad) I:9clm3. 9clm3 (p), medial extrinsic coxo-lateropenital muscles. O: one bundle, broadly on ventromesal or (Lioponera indet.) dorsomesal surfaces of the gonocoxites I: on parossiculi or (Lioponera indet.) narrowly on ectal surface of volsellae. 9clm4 (o), lateral extrinsic coxo-lateropenital muscles. Present or absent (Lioponera indet.). O: broadly on ventral dorsal surfaces of the gonopodites. I: narrowly on ectal surfaces of the proximal volsellar apices.
Dorsal coxo-penial promotors: 9cppd (j). O: broadly on the dorsomesal surfaces of the gonopodites I: narrowly on posterior apices of the valvurae.
Dorsal coxo-penial remotors: 9cprd1 (k), medial dorsal coxo-penial remotors. O: on proximodorsal surfaces of gonocoxites. I: broadly on mesal surfaces of the penial sclerites, sometimes (Myrmica ruginodis) bundles located intrinsic to penial sclerites, divided by medial sclerotic septum. 9cprd2 (l), lateral dorsal coxo-penial remotors. Present or absent (Odontomachus indet.) O: broadly on dorsomesal surfaces of the gonopodites. I: narrowly on the ventro-ectal surfaces of the penial sclerites.
Ventral coxo-penial promotors: 9cppv1 (h), anterior ventral coxo-penial promotors. O: broadly on mesal ventromedian surface of the cupula, or (Myrmica ruginodis) on the gonocoxital arms. I: at apices of the valvurae. 9cppv2, posterior ventral coxo-penial promotors. Present or absent (Lioponera indet.). O: broadly on mesal ventral surfaces of the gonocoxites. I: narrowly distad I: 9cppv1. I: apically on the ectal surfaces of the valvurae, laterad apical parts of I:9cppv1.
Ventral coxo-penial remotors: 9cprv2 (i), lateral ventral coxo-penial remotors. O: broadly on mesal surfaces or (Odontomachus indet.) proximolateral margins of the gonocoxites. I: broadly on the bases of the valvurae, or (Lioponera indet.) broadly along margin of the lateral posterior penial processes, proximad and ventrad I: 9cprd2.
Protanilla zhg-vn01 (Fig.
Dorsoventral muscles AIX: 9dvim, dorsoventral intrinsic muscles. O: narrowly on anterior margin of abdominal hemitergites IX. I: narrowly on anterolateral corners of ASIX.
Sterno-coxal muscles: 9vcm1 (a), anteromedial sterno-coxal muscles. O: on anterior half of spiculum. I: posterolaterally on cupula. 9vcm2 (b), posteromedial sterno-coxal muscles. O: on posterior margin of cupula. I: posterolaterally on disc of ASIX.
Tergo-coxal muscles: 9dcm4 (d), ventral tergo-coxal muscles. Unpaired. O: widely on cupula, I: on the ectal anteroventral surfaces of the gonocoxites.
Coxo-lateropenital muscles: 9clm2 (qr), lateral intrinsic coxo-lateropenital muscles. O: at base of parossiculi. I: narrowly basad the base of the lateropenite. 9clm3 (p), medial extrinsic coxo-lateropenital muscles. O: broadly on posterolateral mesal surfaces of the gonocoxites. I: narrowly basad the base of the lateropenites, adjacent to I: 9clm2.
Dorsal coxo-penial promotors: 9cppd (j). O: on the mesal anterodorsal surfaces of the gonocoxites. I: broadly on anterodorsal surfaces of valvurae.
Dorsal coxo-penial remotors: 9cprd1 (k), medial dorsal coxo-penial remotors. O: on gonocoxites, mediad O: 9cppd. I: broadly on mesal surfaces of the penial sclerites.
Ventral coxo-penial promotors: 9cppv1 (h), anterior ventral coxo-penial promotors. O: on mesal proximoventral surfaces of the gonocoxites, proximomediad O:9cprv2. I: narrowly on ventral surfaces of the proximal apices of the valvurae.
Ventral coxo-penial remotors: 9cprv2 (i), lateral ventral coxo-penial remotors. O: on the mesal proximoventral surfaces of the gonocoxites, I: broadly on ectal ventral surfaces of the penial sclerites, at and distal to the base of valvurae.
Yavnella zhg-bt01 (Fig.
Coxo-lateropenital muscles: 9clm3 (p), medial extrinsic coxo-lateropenital muscles. O: broadly on posterior and medial mesal surfaces of the gonocoxites. I: narrowly at proximoventral margins of the volsellae.
Dorsal coxo-penial remotors: 9cprd1 (k), medial dorsal coxo-penial remotors. O: narrowly on the proximodorsal mesal margin of the penial sclerites. I: narrowly on proximodorsal margins and distodorsal mesal surfaces of the penial sclerites.
Yavnella zhg-th03 (Fig.
Tergo-coxal muscles: 9dcm4 (d), ventral tergo-coxal muscles. Paired. O: narrowly along dorsoventral length of anterior cupular rim (Fig.
Coxo-lateropenital muscles: 9clm3 (p), medial extrinsic coxo-lateropenital muscles: O: broadly on posterior and medial mesal surfaces of the gonocoxites, along with proximoventral surfaces of the penial sclerites. I: narrowly within the volsellae.
Dorsal coxo-penial remotors: 9cprd1 (k), medial dorsal coxo-penial remotors: O: on proximodorsal mesal surfaces of the penial sclerites, apical to ventral posterior penial processes. I: broadly on distodorsal mesal surfaces of the penial sclerites.
Noonilla zhg-my03 (Fig.
Dorsoventral muscles AIX: 9dvim, dorsoventral intrinsic muscles. O: narrowly on ATIX. I: broadly on most anterior ventral surface of the sterno-gonocoxital complex (ASIX+gcx+psc), anterior to antecosta of ASIX.
Coxo-stylar muscles: 9csm2 (t), intermediate coxo-stylar muscles. O: broadly on mesal gonocoxital surface, both dorsally and ventrally. I: along median edge of gonostyli.
Ventral coxo-penial remotors: 9cprv2 (i), lateral ventral coxo-penial remotors (Section 4.1.2.). O: broadly on mesal proximal surfaces of the gonocoxites, origin forming dorsoventral parabola proximad O: 9csm2. I: narrowly on anatomical venter of posterior penial processes.
Noonilla cf. copiosa (Fig.
Ventral longitudinal muscles AVIII–AIX: One pair of 8vlm present and extremely reduced, identity uncertain (Section 4.1.2.), here identified as 8volm, ventral ortholateral muscles. O: on medial apodemes of ASVIII. I: on apodeme of ASIX near most proximolateral extent of anterolateral processes.
Dorsoventral muscles AIX: 9dvim, dorsoventral intrinsic muscles. O: narrowly on abdominal hemitergites IX. I: narrowly on anteromedian region of antecosta ASIX.
Coxo-stylar muscles: 9csm2 (t), intermediate coxo-stylar muscles. O: broadly on mesal dorsal surface of sterno-gonocoxital complex, along entire length of sterno-gonocoxital complex. I: along median edge of gonostyli.
Dorsal coxo-penial remotors: 9cprd1 (k), medial dorsal coxo-penial remotors (Section 4.1.2.). O: broadly on mesal dorsal surface of the sterno-gonocoxital complex, proximomediad O: 9csm2. I: narrowly along mesal ventral surfaces of the penial sclerites, at base of ventromedian “trigger.”
Ventral coxo-penial remotors: 9cprv2 (i), lateral ventral coxo-penial remotors (Section 4.1.2.). O: broadly along distal third of the mesal ventral surfaces of the gonocoxites. I: on the penial sclerites. Medial to bases of gonostyli.
Leptanilla zhg-my02 (Fig.
Ventral longitudinal muscles AVIII–AIX: 8volm, ventral ortholateral muscles. O: on ASVIII and I: on ASIX dorsal to bases of mulceators.
Dorsoventral muscles AIX: 9dvim, dorsoventral intrinsic muscles. O: on abdominal hemitergites IX. I: mediad I: 8volm. 9dvxm, dorsoventral extrinsic reversed muscles: O: on abdominal hemitergites IX. I: on dorsal surfaces of ASVIII.
Coxo-lateropenital muscles: 9clm3 (p), medial extrinsic coxo-lateropenital muscles. O: broadly on dorsomesal surfaces of the gonocoxites. I: broadly on apical margin of proximal volsellar aperture.
Leptanilla zhg-my04 (Fig.
Dorsoventral muscles AIX: 9dvim, dorsoventral intrinsic muscles. O: along entire lateromedial lengths of abdominal hemitergites IX. I: narrowly posterior to antecosta of ASIX, medial to bases of mulceators.
Coxo-lateropenital muscles: 9clm3 (p), medial extrinsic coxo-lateropenital muscles. O: broadly on mesal ventral surfaces of the gonocoxites. I: narrowly on proximomedian processes of the volsellae.
Ventral coxo-penial remotors: 9cprv2 (i), lateral ventral coxo-penial remotors. O: broadly on distomedian mesal surfaces of the gonocoxites. I: narrowly on the ventrolateral margins of the penial sclerites, proximad the proximomedial volsellar condyles.
Leptanilla zhg-id04 (Fig.
Ventral longitudinal muscles AVIII–IX and dorsoventral intrinsic muscles AIX not discernible.
Coxo-stylar muscles: 9csm1, intrinsic coxo-stylar muscles. O: broadly on mesolateral surfaces of the gonocoxites. I: broadly on mesomedial surfaces of the gonocoxites. 9csm2 (t), intermediate coxo-stylar muscles. O: on the distal mesolateral surfaces of the gonocoxites. I: narrowly at proximoventral margins of gonostyli.
Ventral coxo-penial remotors: 9cprv2 (i), lateral ventral coxo-penial remotors. O: narrowly on mesal proximomedian apodemes of the gonocoxites. I: broadly on mesal proximal surfaces of the penial sclerites.
Leptanilla cf. zaballosi (Fig.
Ventral longitudinal muscles AVIII–IX: One pair of 8vlm present, identity indeterminate between 8vomm, 8vpmm, 8volm, but likely not 8vpmm.
Dorsoventral intrinsic muscles AIX not discernible.
Coxo-stylar muscles: 9csm1, intrinsic coxo-stylar muscles. O: broadly on mesolateral surfaces of the gonocoxites. I: broadly on mesomedial surfaces of the gonocoxites. 9csm2 (t), intermediate coxo-stylar muscles. O: on the distal mesolateral surfaces of the gonocoxite. I: narrowly at proximomedial margins of gonostyli.
Coxo-lateropenital muscles: 9clm3 (p), medial extrinsic coxo-lateropenital muscles. O; broadly on ventral proximomesal surfaces of the gonocoxites and on proximoventral surfaces of the penial sclerites. I: narrowly on medial surfaces of proximomedial condyles of the volsellae.
Ventral coxo-penial remotors: 9cprv2 (i), lateral ventral coxo-penial remotors. O; narrowly on ventromedian apodemes of the gonocoxites. I: broadly on mesal proximoventral surfaces of the penial sclerites.
The extremely small size of many of the structures described herein, and the inability to confirm some observations based on micro-CT using manual dissection or SEM, means that the interpretation of these primary observations is sometimes uncertain. Moreover, extreme derivation of male genital skeletomusculature in certain lineages of the Leptanillinae means that assertion of primary homology (
Axial sclerites. The transverse posterior mesal carina of abdominal sternite IX in Scyphodon s.l. may not correspond to the antecosta of abdominal sternite IX, rather being an invagination of abdominal sternite IX derived in Scyphodon s.l. independently from the antecosta of abdominal sternite IX that is plesiomorphic for the Formicidae, which appears to have been ancestrally lost in male Leptanillinae. This reasoning assumes that the antecosta of abdominal sternite IX is sufficiently complex to not be regained once lost (
While the cupula appears unambiguously present, albeit heavily reduced and fused to adjacent sclerites, in Leptanilla zhg-id01 (not fully described; Table
Appendicular sclerites. 1.
2. In Leptanilla zhg-my03 and -04, which together are the sister clade to the remainder of the Bornean morphospecies-group, confirmation of gonostylar condition is unfeasible. The gonopodites are completely fused along their entire proximodistal length, forming a capsule without suture. Given the precedent of gonostylar absence in Leptanilla zhg-my02 and -my05 established by
Conjunctival ambiguity. Relative contrast between sclerite and conjunctiva in micro-CT data is sometimes insufficient to discriminate these forms of the integument from each other. At the gonostylar base, this could sometimes (e.g., Protanilla) be disambiguated by external examination (
1. The tergosternal fusion of abdominal segment VIII in Noonilla cf. copiosa (Fig.
2. Abdominal sternites VIII–IX may be sternosternally fused in Leptanilla zhg-my02 and -my05. The extreme median anteroposterior compression of abdominal sternites VIII-IX, and their adjacency (Fig.
3. It is uncertain if the endophallic sclerite is indeed absent in Odontomachus indet., as opposed to present but weakly developed. The endophallic sclerite is widely reported in the Formicidae (
The homology of the penial muscles present in Scyphodon s.l. is open to debate since the reduction of the penial sclerites in this clade removes topological points of reference necessary for the assertion of primary homology. This is likewise the case for the ventral longitudinal muscles VIII–IX in Noonilla cf. copiosa. In both instances, homologies were inferred based on our best judgment given the limited information available.
A pronounced tendency towards skeletomuscular simplification is apparent in the Leptanillinae relative to the remainder of the Formicidae (Figs
Muscular observations across the 12 exemplars described in detail in this study. 1 = presence; 0 = absence; — = inapplicable (sclerite hosting muscle origin or insertion absent).
1° | 8vomm | 8vpmm | 8volm | 8dvxm | 9dvim | 9dvxm | 9vcm1 | 9vcm2 | 9vcm3 | 9dcm1 | 9dcm2 | 9dcm3 | 9dcm4 | 9csm1 | 9csm2 | 9clm2 | 9clm3 | 9clm4 | 9cppd | 9cppv1 | 9cppv2 | 9cprd1 | 9cprd2 | 9cprv2 | |||
|
— | — | — | — | — | — | a | b | c | g | f | e | d | — | t–w | qr | p | o | j | h | h’ | k | l | i | |||
Subfamily | Specimen | Exemplar | |||||||||||||||||||||||||
Dorylinae | CASENT0844684 | Lioponera indet. | 0 | 1 | 1 | 0 | 1 | 0 | 1 | 1 | 1 | 1 | 1 | 1 | 0 | 0 | 0 | 0 | 1 | 1 | 1 | 1 | 0 | 1 | 1 | 1 | |
Myrmicinae |
|
Myrmica ruginodis | 0 | 1 | 1 | 0 | 1 | 0 | 1 | 1 | 1 | 1 | 1 | 1 | 1 | 0 | 1 | 1 | 1 | 0 | 1 | 1 | 1 | 1 | 1 | 1 | |
Ponerinae | CASENT0842842 | Odontomachus indet. | 1 | 1 | 1 | 1 | 1 | 0 | 1 | 1 | 0 | 1 | 1 | 1 | 0 | 0 | 1 | 0 | 1 | 0 | 1 | 1 | 1 | 1 | 0 | 1 | |
Leptanillinae | CASENT0842782 | Leptanilla cf. zaballosi | ? | ? | ? | ? | ? | ? | — | — | — | — | — | — | — | 1 | 1 | 0 | 1 | 0 | 0 | 0 | 0 | 0 | 0 | 1 | |
Leptanillinae | CASENT0106357 | Leptanilla zhg-id04 | ? | ? | ? | ? | ? | 0 | — | — | — | — | — | — | — | 1 | 1 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 1 | |
Leptanillinae | CASENT0106416 | Leptanilla zhg-my02 | 0 | 0 | 1 | 0 | 1 | 1 | — | — | — | — | — | — | — | 0 | — | 0 | 1 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | |
Leptanillinae | CASENT0842565 | Leptanilla zhg-my04 | 0 | 0 | 0 | 0 | 1 | 0 | — | — | — | — | — | — | — | 0 | — | 0 | 1 | 0 | 0 | 0 | 0 | 0 | 0 | 1 | |
Leptanillinae | CASENT0842844 | Noonilla cf. copiosa | 0 | 0 | 1 | 0 | 1 | 0 | — | — | — | — | — | — | — | 0 | 1 | — | — | — | 0* | 0* | 0* | 1* | 0* | 1* | |
Leptanillinae | CASENT0842609 | Noonilla zhg-my03 | 0 | 0 | 0 | 0 | 1 | 0 | — | — | — | — | — | — | — | 0 | 1 | — | — | — | 0* | 0* | 0* | 0* | 0* | 1* | |
Leptanillinae | CASENT0106408 | Protanilla zhg-vn01 | ? | ? | ? | 0 | 1 | 0 | 1 | 1 | 0 | 0 | 0 | 0 | 1 | 0 | 0 | 1 | 1 | 0 | 1 | 1 | 0 | 1 | 0 | 1 | |
Leptanillinae | CASENT0842743 | Yavnella zhg-bt01 | ? | ? | ? | 0 | 0 | 0 | ? | ? | ? | ? | ? | ? | ? | 0 | 0 | 1 | 1 | 0 | 0 | 0 | 0 | 1 | 0 | 0 | |
Leptanillinae | CASENT0842741 | Yavnella zhg-th03 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 1 | 0 | 0 | 1 | 1 | 0 | 0 | 0 | 0 | 1 | 0 | 0 | |
*Homology of the coxo-penial muscles (9cpm) present in Scyphodon s. l. tentative (Section 4.1.2). |
Diagrammatic cladogram of genital and pregenital sclerites, ventral view. Sclerites bounded by dotted lines were indiscernible; those bounded with dotted lines were discernible, but not fully segmented. Extraneous sclerites were beyond the scope of this study. A Lioponera indet. B Myrmica ruginodis. C Odontomachus indet. D Protanilla zhg-vn01. E Yavnella zhg-th03. F Yavnella zhg-bt01. G Leptanilla zhg-my04. H Leptanilla zhg-my02. I Noonilla zhg-my03. J Noonilla cf. copiosa. K Leptanilla zhg-id04. L Leptanilla cf. zaballosi. Abbreviations: ASVIII = abdominal sternite VIII; ASIX = abdominal sternite IX; ATIX = abdominal tergite IX; cup = cupula; gcx = gonocoxite; psc = penial sclerite; stl = gonostylus; vol = volsella.
Diagrammatic cladogram of genital and pregenital sclerites of exemplars, profile view. Sclerites bounded by dotted lines were indiscernible; those bounded with dotted lines were discernible, but not fully segmented. Extraneous sclerites were beyond the scope of this study. Abdominal sternite IX of Noonilla cf. copiosa is rotated 180° relative to in situ position. A Lioponera indet. B Myrmica ruginodis. C Odontomachus indet. D Protanilla zhg-vn01. E Yavnella zhg-th03. F Yavnella zhg-bt01. G Leptanilla zhg-my04. H Leptanilla zhg-my02. I Noonilla zhg-my03. J Noonilla cf. copiosa. K Leptanilla zhg-id04. L Leptanilla cf. zaballosi. Abbreviations: ASVIII = abdominal sternite VIII; ASIX = abdominal sternite IX; ATIX = abdominal tergite IX; cup = cupula; end = endophallic sclerite; gcx = gonocoxite; psc = penial sclerite; stl = gonostylus; vol = volsella.
Diagrammatic cladogram of coxo-stylar skeletomusculature, profile view. Abdominal sternite IX of Noonilla cf. copiosa is rotated 180° relative to in situ position. Orthogonal caps at end of diagrammatic muscle lines signify origin; lack of caps, insertion. A Lioponera indet. B Myrmica ruginodis. C Odontomachus indet. D Protanilla zhg-vn01. E Yavnella zhg-th03. F Yavnella zhg-bt01. G Leptanilla zhg-my04. H Leptanilla zhg-my02. I Noonilla zhg-my03. J Noonilla cf. copiosa. K Leptanilla zhg-id04. L Leptanilla cf. zaballosi. Abbreviations: ASIX = abdominal sternite IX; gcx = gonocoxite; stl = gonostylus; 9csm1 = anterior coxo-stylar muscles; 9csm2 = intermediate coxo-stylar muscles.
Diagrammatic cladogram of coxo-lateropenital skeletomusculature, profile view. Orthogonal caps at end of diagrammatic muscle lines signify origin; lack of caps, insertion. A Lioponera indet. B Myrmica ruginodis. C Odontomachus indet. D Protanilla zhg-vn01. E Yavnella zhg-th03. F Yavnella zhg-bt01. G Leptanilla zhg-my04. H Leptanilla zhg-my02. I Noonilla zhg-my03. J Noonilla cf. copiosa. K Leptanilla zhg-id04. L Leptanilla cf. zaballosi. Abbreviations: gcx = gonocoxite; stl = gonostylus; vol = volsella; 9clm2 = lateral intrinsic coxo-lateropenital muscles; 9clm3 = medial extrinsic coxo-lateropenital muscles; 9clm4 = lateral extrinsic coxo-lateropenital muscles.
Diagrammatic cladogram of coxo-penial skeletomusculature, profile view. Abdominal sternite IX of Noonilla cf. copiosa is rotated 180° relative to in situ position. Orthogonal caps at end of diagrammatic muscle lines signify origin; lack of caps, insertion. A Lioponera indet. B Myrmica ruginodis. C Odontomachus indet. D Protanilla zhg-vn01. E Yavnella zhg-th03. F Yavnella zhg-bt01. G Leptanilla zhg-my04. H Leptanilla zhg-my02. I Noonilla zhg-my03. J Noonilla cf. copiosa. K Leptanilla zhg-id04. L Leptanilla cf. zaballosi. Abbreviations: ASIX = abdominal sternite IX; cup = cupula; gcx = gonocoxite; psc = penial sclerite; stl = gonostylus; 9cppd = dorsal coxo-penial promotors; 9cprd1 = medial dorsal coxo-penial remotors; 9cprd2 = lateral dorsal coxo-penial remotors; 9cppv1 = anterior ventral coxo-penial promotors; 9cppv2 = posterior ventral coxo-penial promotors; 9cprv2 = lateral ventral coxo-penial remotors.
Several of these skeletal or muscular simplifications are homoplasious. The intermediate coxo-stylar muscles (9csm2, t) are lost in Protanilla zhg-vn01, the Bornean morphospecies-group and Yavnella; concomitantly, the gonopodite is fully to partly inarticulate in all these lineages, while in the remaining sampled lineages the presence of the intermediate coxo-stylar muscles is always associated with articulated gonopodites. It can be inferred that the intermediate coxo-stylar muscles are absent in all Yavnella and members of the Bornean morphospecies-group, and may be absent in many, if not all, male Protanilla. The gonostyli themselves have been lost on four different occasions in the tribe Leptanillini s.str.: once in Yavnella (Yavnella TH03), twice in the Bornean morphospecies-group (Leptanilla zhg-my03 + L. zhg-my04 and L. zhg-my02 + L. zhg-my05), and in Leptanilla santschii Wheeler and Wheeler (
In terms of scleritic simplification, there is a tendency towards median fusion of paired structures. In addition to the synapomorphic fusion of the penial sclerites in Leptanillini s.str., the gonocoxites are medially fused along their entire anteroposterior length in the Bornean morphospecies-group and Scyphodon s.l., and partial gonocoxital fusion is observed in Yavnella; while the complete medial fusion of the volsellae is an autapomorphy of the Bornean morphospecies-group, observed nowhere else in male Formicidae. The medial fusion of the gonostyli in Noonilla zhg-my03 is apparently unique to that morphospecies throughout the entire Hymenoptera, providing a serial parallel to the medial fusion of the volsellae in the Bornean morphospecies-group. The apparent tergosternal fusion of abdominal segment VIII in Noonilla cf. copiosa (see Section 4.4.1.) is unique among the Hymenoptera.
Anteroposterior fusion of sclerites is also a notable tendency. Abdominal sternite IX is at least partly fused to the gonocoxites in all sampled representatives of Scyphodon s.l. and the Bornean morphospecies-group, with this fusion probably being homoplasious between the two clades (Section 4.4.2.). The fusion of abdominal sternite IX to the gonocoxites was confirmed by manual dissection only in N. copiosa (
Although these homoplasies appear straightforward at a coarse comparative scale, further examination may show noteworthy functional differences. An example is the parallel fusion of the penial sclerites to the gonocoxites in Scyphodon s.l. and the clade comprising Leptanilla zhg-my03 and -4. In both cases, the penial sclerites are musculated by a single muscle pair. In Leptanilla zhg-my03 and -my04, the penial sclerites are narrowly but firmly fused to the medially fused gonocoxites at the most proximal penial extremity (Fig.
Based upon the micro-CT data for the 22 exemplars for which micro-CT scans are here published, and physical examination of additional specimens, along with the published description of male Opamyrma hungvuong (
Sclerite character states for primarily observed taxa as inferred transformations. Circles and fill colors correspond to characters as shown in legend at top left. Characters in left-to right order: (top row) ASVIII = abdominal sternite VIII; ASIX = abdominal sternite IX; spc = spiculum; cup = cupula; (bottom row) gpd = gonopodite; gcx = gonocoxite; vol = volsella; psc = penial sclerite. Numbers correspond to states in Table
Morphology of the genitalia, abdominal sternite IX hidden, 3D reconstructions in ventral view. Dashed lines represent lines of fusion to abdominal sternite IX. A Lioponera indet. B Odontomachus indet. C Protanilla zhg-vn01. D Myrmica ruginodis. E Leptanilla zhg-id04. F Leptanilla cf. zaballosi. G Leptanilla zhg-my09. H Noonilla cf. copiosa. I Noonilla zhg-my03. Abbreviations: all = apicolateral lamina; gct = gonocoxital arm; gcx = gonocoxite; gpd = gonopodite; ltp = lateropenite; pht = phallotreme; psc = penial sclerite; prs = parossiculus; stl = gonostylus; vol = volsella; 9csm2 = intermediate coxo-stylar muscles; 9clm2 = lateral intrinsic coxo-lateropenital muscles; 9clm3 = medial extrinsic coxo-lateropenital muscles; 9cprd1 = medial dorsal coxo-lateropenital remotors; 9cppv2 = posterior ventral coxo-penial promotors; 9cprv2 = lateral ventral coxo-penial remotors.
State (semi-ordered) | ASVIII | ASIX | Spiculum | Cupula | Gonopodites | Gonocoxites | Volsellae | Penial sclerites |
0 | ASVIII separate from ASIX. | ASIX unfused to distal sclerites. | Spiculum absent. | Cupula present, separate from gonocoxites, annular. | Gonopodites articulated. | Gonocoxites demarcated medially. | Volsellae present, parossiculus and lateropenite distinct. | Penial sclerites medially articulated, proximally articulated to gonocoxites. |
1 | ASVIII fused with ASIX. | ASIX fused to cupula. | Spiculum present. | Cupula present, separate from gonocoxites, anteriorly fused to ASVIII, annular. | Gonopodites inarticulate. | Gonocoxites not demarcated medially. | Volsellae present, parossiculus and lateropenite not distinct, basivolsella and distivolsella not distinct. | Penial sclerites medially fused, proximally articulated to gonocoxites. |
2 | N/A | ASIX fused to gonocoxites. | N/A | Cupula present, separate from gonocoxites, non-annular. | Gonostyli absent. | N/A | Volsellae present, parossiculus and lateropenite not distinct, basivolsella and distivolsella not distinct, volsellae fused medially. | Penial sclerites medially fused, proximally fused to gonopodites. |
3 | N/A | ASIX absent. | N/A | Cupula present, annular, fused to gonocoxites. | Gonostyli present, articulate, medially fused. | N/A | Volsellae absent. | N/A |
4 | N/A | N/A | N/A | Cupula absent. | N/A | N/A | N/A | N/A |
Although the phylogeny of the Leptanillini s.str. is well-resolved, with subclades readily diagnosed by multiple non-genital male morphological characters (
The male genitalia of Hymenoptera have been studied from anatomical and comparative morphological perspectives for at least 300 years, since the early microscopist and seminal entomologist Jan Swammerdam (1637–1680) examined the dissected genitalia of bees (Swammerdam 1775). The great advances that attended improvements in imaging and communication technologies, the introduction of Linnaean taxonomy, and the rise in collections and descriptions were also accompanied by the proliferation of parallel systems of terminology and homology hypotheses or comparative models (cf. epigraph). In the 20th century, the exhaustive studies of
Homology hypotheses have simultaneously developed over the last century, from unstructured observations of correspondence of parts, to the concepts of Snodgrass (1936,
Our understanding of muscle evolution is generally based in a modification of the inferential guidelines of
While insect muscles are frequently arranged in discrete groups, they lack an epimysial sheath like that of vertebrates, such that recognition of specific bundles of fibers as separate sets is somewhat subjective. Here, we consider both the degree of separation at both origin and insertion, and implied transformations, as evidence to discern subsets of the homological-topographic main groups, but acknowledge that there is no solid, global criterion for recognizing individual subgroups. In terms of subdivisions within a main group, we consider that distinct lack of overlap of attachments of bundles within a main group indicates a mechanical reorganization, implying a semi-independent ontogenetic and therefore evolutionary program, which may be captured through terminology. Part of our aim in designing the numeration is that future authors may further expand our schema by addition of numbers, if necessary, based on additional splits in particular taxa. Nevertheless, we performed an exhaustive review of the literature (
In two cases, we observe partial differentiation of dorsal coxo-penial muscles into anterior and posterior partitions, which we do not designate separately. In M. ruginodis¸ the origins of 9cprd2 (l) are widely separated, with the anterior partition originating in the gonocoxite and the posterior part in the gonostylus; however, the partitions coalesce into unified insertions (Fig.
Most muscles named here are clearly homologous across Hymenoptera. Specifically, the sterno-coxal, tergo-coxal, and most coxo-lateropenital and coxo-penial muscles are most certainly homologous. However, some exceptions can be postulated in which topographic correspondence does not indicate homology. The most probable such case is the exact correspondences of the coxo-stylar muscles 9csm1 and 9csm2 (t). Three main states of these muscles are observed in various hymenopteran lineages: (1) in the plesiomorphic condition, there is a single 9csm2 (which may be bifid distally) which connects the gonocoxite to the gonostylus; (2) in a few taxa, there is a single muscle intrinsic to the gonocoxite; and (3) there may be both an intrinsic (anterior) gonocoxital muscle and extrinsic coxo-stylar muscle.
Coxo-stylar skeletomusculature, 3D reconstructions in coronal cross-section. A Myrmica ruginodis. B Odontomachus indet. C Protanilla zhg-vn01. D Leptanilla zhg-id04. E Leptanilla cf. zaballosi. Abbreviations: gcx = gonocoxite; stl = gonostylus; 9csm1 = anterior coxo-stylar muscles; 9csm2 = intermediate coxo-stylar muscles.
For two other muscles (9cppv2, 9clm4; h’, o), our primary observations were too limited to confidently assert homology at the ordinal scale. The posterior subdivision of the ventral coxo-penial promotors, 9cppv2, occurs in a few ant taxa and in at least Stenobracon deesae (Cameron, 1902) (Braconidae; Alam, 1952), most probably having derived independently from 9cppv1 (h) in Formicidae and Braconidae, and perhaps multiply within ants. It is also probable that the lateral extrinsic coxo-lateropenital muscle 9clm4 (o), which we observe in Lioponera (Figs
Based on the evolutionary sequence inferred by
Ancestral state reconstruction and sampled tip states of coxo-penial musculature across the Hymenoptera. Blue = Formicidae; yellow = Leptanillinae Left and right topologies are identical. Node reconstructions not shown when all sampled descendants were scored as uncertain or inapplicable. See Supplementary Document 1 for explanation of inapplicability and additional notes. Cells represent characters. Cell fill represents character states: white = absent; black = present; diagonal lines = polymorphic absent/present; grey dots = uncertain; solid grey = inapplicable. Left tree: coxo-penial promotors; cells in left-to-right order: 9cppd (j), 9cppv1 (h), 9cppv2 (h’). Right tree: coxo-penial remotors; cells in left-to-right order: 9cprd1 (k), 9cprd2 (l), 9cprv1 (si), 9cprv2 (i).
Ancestral state reconstruction and sampled tip states of sterno-coxal and tergo-coxal musculature across the Hymenoptera. Blue = Formicidae; yellow = Leptanillinae. Left and right topologies are identical. Node reconstructions not shown when all sampled descendants were scored as uncertain or inapplicable. See Supplementary Document 1 for explanation of inapplicability and additional notes. Cells represent characters. Cell fill represents character states: white = absent; black = present; diagonal lines = polymorphic absent/present; grey dots = uncertain; solid grey = inapplicable. Left tree: sterno-coxal muscles; cells in left-to-right order: 9vcm1 (a), 9vcm2 (b), 9vcm3 (c). Right tree: tergo-coxal muscles; cells in left-to-right order: 9dcm1 (g), 9dcm2 (f), 9dcm3), 9dcm4 (d).
Ancestral state reconstruction and sampled tip states of coxo-lateropenital and coxo-stylar musculature across the Hymenoptera. Blue = Formicidae; yellow = Leptanillinae. Left and right topologies are identical. Node reconstructions not shown when all sampled descendants were scored as uncertain or inapplicable. See Supplementary Document 1 for explanation of inapplicability and additional notes. Cells represent characters. Cell fill represents character states: white = absent; black = present; diagonal lines = polymorphic absent/present; grey dots = uncertain; solid grey = inapplicable. Left tree: coxo-lateropenital muscles; cells in left-to-right order: 9clm1 (s), 9clm2 (qr), 9clm3 (p) , 9clm4 (o). Right tree: coxo-stylar muscles; cells in left-to-right order: 9csm1, 9cms2 (t), 9csm3 (u), 9csm4 (v).
We interpret muscles both muscles 9cprd1 (k) and 9cprd2 (l) to be dorsal coxo-penial remotors derived from a single pair of ancestral muscles (IXAprd in
The main difference between our muscular interpretations and those of
The pene-lateropenital (10plm1–1; m, n) and pene-penial muscles (10ppm1–2; x, z) are considered muscles of AX, since they originate on the penial sclerites, which derive from the tenth gonocoxae. Both groups can be considered intrinsic to the penis, since the lateropenite is a penial fragment. However, the homology of these muscles cannot be definitely asserted based on our review of the literature or our primary observations (these muscles are absent in ants), so it is possible, though unparsimonious, that they truly derive from ninth segmental muscles, having moved their origin during the evolution of ontogenetic integration of gonopods X with gonopods IX in the endopterygote ancestor (
Within Hymenoptera, the pene-lateropenital muscles occur much more frequently than the pene-penials, the latter being mostly restricted to Siricidae and Cephidae (Table S3, Fig. S1). The most commonly retained muscle, 10plm2 (n), often inserts partially or entirely on the membranes of the primary gonopore (nb, nd,
Of the 28 species of Formicidae for which the genital muscles have been completely described or coded (
Leptanilloides males are unusual among the Formicidae in equaling the small size of certain leptanilline males. Skeletomuscular simplification of the male genitalia in the Leptanillinae and across the Formicidae as a whole may therefore correlate with miniaturization. Male genital skeletomuscular simplification as correlate of miniaturization in the Leptanillinae could be corroborated by the extreme scleritic simplification observed in male genitalia throughout the Chalcidoidea (
Male genitalia in Leptanilloides show far less morphological derivation than the Leptanillini s.str., meaning that the skeletomuscular simplification of leptanilline male genitalia cannot be attributed to miniaturization per se. Trends of skeletomuscular simplification paralleled in multiple anatomical regions across the phylogeny of the Endopterygota also coincide with evolutionary factors beyond miniaturization (
The pregenital abdominal sternite VIII is peculiarly modified in some lineages of the Leptanillinae, associated with derivation of abdominal sternite IX (see Section 4.4.2.).
Abdominal sternite VIII is completely fused to the cupula in Yavnella zhg-th01, -th03, zhg-my02, and Yavnella nr. indica, encircling the entire foramen genitale (Fig.
Posterior fusion of abdominal sternite VIII to abdominal sternite IX has evolved at least once in Scyphodon s.l., and the Bornean morphospecies-group, respectively. This is comparable to the condition observed in Dolichovespula maculata (Linn., 1763) and Dolichovespula adulterina (du Buysson, 1905) (Vespidae: Vespinae), in which ASVIII–ASIX are fused, but remain distinguishable by the retention of antecostae (Fig.
Diagrammatic comparison of fusion of male abdominal sternites VIII-IX in the Hymenoptera, ventral view. Figure
In Yavnella zhg-bt01, abdominal sternite VIII is medially bifurcated (Fig.
We speculate that the structural reinforcement afforded by tergosternal fusion of abdominal segment VIII in Noonilla cf. copiosa aids the maneuverability of the genital capsule. This maneuverability is presumably greater in Noonilla cf. copiosa relative to other Scyphodon s.l. included in this study, which have lost all ventral longitudinal muscles VIII–IX, and thus the capacity for movement of the genital capsule along the craniocaudal or transverse axes.
The modification of abdominal sternite IX is diverse across the Leptanillinae sampled herein (Fig.
Morphology of the axial sclerites, gonopodites, and associated musculature, 3D reconstructions, coronal cross-sections in dorsal view. A Protanilla zhg-vn01. B Yavnella zhg-th03. C Noonilla cf. copiosa. D Noonilla zhg-my03. E Leptanilla zhg-my04. F Leptanilla zhg-my02. Abbreviations: ASVIII = abdominal sternite VIII; acsS8 = antecosta of abdominal sternite VIII; ASIX = abdominal sternite IX; ATIX = abdominal tergite IX; all = apicolateral lamina; acsS9 = antecosta of abdominal sternite IX; cup = cupula; gpd = gonopodite; gcx = gonocoxite; mul = mulceator; stl = gonostylus; 8volm = ventral ortholateral muscles VIII–IX; 9dvim = dorsoventral intrinsic muscles IX; 9vcm2 = posteromedial sterno-coxal muscles; 9dcm4 = ventral tergo-coxal muscles.
In Leptanilla s.str., abdominal sternite IX is unmodified relative to the ancestral condition for Leptanillini s.str. (Fig.
In most examined Yavnella abdominal sternite IX is judged to be absent, in what is perhaps the most extreme derivation of this sclerite among the Leptanillinae. This conclusion is drawn from Yavnella zhg-th03, using the proctiger as topographical reference, and considering the absence both of dorsoventral intrinsic muscles IX and sterno-coxal muscles. No putative trace of abdominal sternite IX whatsoever can be argued in this exemplar (Figs
In the Bornean morphospecies-group, abdominal sternite IX is reduced to an anteroposteriorly narrow strip and posterolaterally produced into mulceators (Figs
In sampled Scyphodon s.l., abdominal sternite IX is indistinguishably fused with the medially fused gonocoxites along the ventral gonocoxital margin, with abdominal sternite IX being definitively identified by the origin of unambiguous dorsoventral intrinsic muscles IX thereon. The “reversed v-shaped, strongly sclerotized structure in firm connection with the genitalia” described by
In most ants, the cupula forms a “basal ring” (sensu
Otherwise, we infer that the cupula is absent in almost all sampled exemplars of Leptanilla s.l. (Fig.
Morphology of the terminal sternites, cupula, and gonopodites, 3D reconstructions in slightly oblique dorsal view. A Lioponera indet. B Leptanilla zhg-id04. C Leptanilla cf. zaballosi. D Noonilla zhg-my03. E Leptanilla zhg-my02. F Leptanilla zhg-my04. G Noonilla cf. copiosa. Arrowheads with white fill in A, G indicate anterior boundary of gonocoxites; arrow with black fill in D indicates mesal transverse carina (Section 4.1.1.). Abbreviations: ASVIII = abdominal sternite VIII; ASIX = abdominal sternite IX; cup = cupula; gcx = gonocoxite; gpd = gonopodite; mul = mulceator, stl = gonostylus.
As noted in Section 4.2., the reduction or total absence of the cupula averred here for most Leptanilla s.l. is associated with the absence of tergo-coxal and sterno-coxal muscles IX. In Yavnella zhg-th03, and by extension the Southeast Asian radiation of Yavnella that comprises most of the species-level diversity in this genus, the cupula and 9dcm4 are present, but this muscle is intrinsic to the cupula. (Resolution in the scan data for Yavnella zhg-bt03 was insufficient to discern the condition of tergo-coxal or sterno-coxal muscles IX.) Meanwhile, the cupula and sterno-coxal muscles IX are observed in Leptanilla zhg-mm03, but the tergo-coxal muscles IX are absent in that morphospecies. In most Leptanillini s.str., therefore, the genitalia are not musculated from abdominal segment IX. Taxon sampling within Yavnella is here insufficient to determine if this is a synapomorphy of the Leptanillini s.str., or evolved separately within Yavnella and in Leptanilla s.l. Although the cupula is extremely reduced in other ant lineages, e.g., the Old World army ants (Dorylinae: Aenictogiton, Aenictus, Dorylus;
The variation observed in volsellar anatomy across the Leptanillinae is dramatic, ranging from presence and complete articulation of the parossiculus and lateropenite in O. hungvuong to complete absence of the volsella in Scyphodon s.l. (Fig.
The volsella in the Leptanillini s.str. therefore consists of a single article (Fig.
In the remainder of the Leptanillini s.str. the volsella (if present) exhibits no trace of a transverse sulcus (Fig.
The complete medial fusion of the penial sclerites is a synapomorphy of the Leptanillini s.str. (Fig.
Despite the tendency towards fusion of the penial sclerites with the gonocoxites in scanned exemplars of the Leptanillini s.str., at least one pair of coxo-penial muscles is retained in those scanned specimens in which partial (Yavnella zhg-th03) to complete fusion (Scyphodon s.l., Leptanilla zhg-my03, -4) is observed. Complete loss of penial musculature is observed among scanned male Leptanillinae in certain members of the Bornean morphospecies-group (Leptanilla zhg-my02, -my05, -my06, and Leptanilla zhg-id01), which display remarkable modification of the penial sclerites: these are proximally recurved (less so in Leptanilla zhg-id01 than the others), with paired penial condyles articulating to the gonocoxites, and the recessed phallotreme situated on the anatomical venter proximal to the penial apex.
Certain outgroup taxa exhibit sclerotized structures mediad the penial sclerites, which are almost certainly non-homologous with the fused penial sclerites in Leptanillini s.str. but may provide informative comparative data.
Musculation of abdominal sternites VIII–IX is diverse among those lineages in which these sclerites have derived morphologies. Ventral longitudinal muscles VIII–IX are absent in Noonilla zhg-my03, Yavnella zhg-th03, Leptanilla zhg-my03, and -my04, concomitant with the anteroposterior fusion of abdominal sternites VIII–IX. This is unlike Dolichovespula, in which abdominal sternites VIII–IX are anteroposteriorly fused and sternosternal musculature is retained (
Based on outgroup sampling, the ancestral insertion of the dorsoventral intrinsic muscles IX in Formicidae is at the anterolateral corners of abdominal sternite IX, and this condition is retained in Protanilla zhg-vn01. Dorsoventral intrinsic muscles IX are indiscernible in sampled Leptanilla s.str. and absent in Yavnella, but where discernible in the Leptanillini s.str. show varying degrees of derivation, in conjunction with often extreme modifications to abdominal sternite IX. In Noonilla zhg-my01, -my02, -my03, and -my06 the insertions of the dorsoventral intrinsic muscles IX retain their ancestral position (Fig.
Leptanilla zhg-my02 and -my05 exhibit unique extrinsic dorsoventral muscles IX that insert on abdominal sternite VIII from origins on abdominal hemitergites IX (9dvxm) (Fig.
The orientation of the dorsoventral muscles that are here termed 9dvxm is confounding, and the lack of descriptions of pregenital musculature in male Hymenoptera further obscures evolutionary derivation. We therefore emphasize the importance of descriptions of at least some of the muscles of AVIII–AIX in treatments of the male genitalia. These are largely absent from the literature, with a few notable exceptions (Birket-Smith, 1981; Boulangé, 1924; Kempf, 1956; Youssef, 1969) and occasional mention of 9dvim.
Leptanilline ants are rarely observed alive, and only the males of Leptanilla japonica Baroni Urbani (
Any case of recurved serration, or recurved processes, presumably serves an anchoring function, extrapolating from
An anchoring function is inferred for the volsellae of examined Protanilla and Yavnella zhg-th03, in which ventral penial serration is not observed: this is indicated in both Protanilla sampled in this study by recurved medial processes of the parossiculus (Fig.
Morphology of the coxo-lateropenital musculature and associated sclerites, 3D reconstructions, coronal cross-sections in dorsal view. A Odontomachus indet. B Leptanilla zhg-id04. C Myrmica ruginodis. D Leptanilla cf. zaballosi. E Protanilla zhg-vn01. F Leptanilla zhg-my02. G Yavnella zhg-bt01. H Yavnella zhg-th03. Abbreviations: gpd = gonopodite; gcx = gonocoxite; ltp = lateropenite; prp = lateropenital recurved processes; prs = parossiculus; psc = penial sclerite; stl = gonostylus; vol = volsella; 9clm2 = lateral intrinsic coxo-lateropenital muscles; 9clm3 = medial extrinsic coxo-lateropenital muscles.
It can be surmised that the ancestral function of the volsellae for the Hymenoptera was a pincing one (
The medial fusion of the volsellae in the Bornean morphospecies-group is intriguing from a functional standpoint. In Leptanilla zhg-my03 and -my04, the volsellar apices are dorsally recurved (Fig.
Morphology of the coxo-lateropenital musculature and associated sclerites, 3D reconstructions in sagittal cross-section. A Lioponera indet. B Protanilla zhg-vn01. C Yavnella zhg-bt01. D Yavnella zhg-th03. E Leptanilla zhg-id04. F Leptanilla cf. zaballosi. G Leptanilla zhg-my04. H Leptanilla zhg-my02. Abbreviations: ASIX = abdominal sternite IX; gcx = gonocoxite; gpd = gonopodite; ltp = lateropenite; prs = parossiculus; psc = penial sclerites; vol = volsella; 9clm2 = lateral intrinsic coxo-lateropenital muscles; 9clm3 = medial extrinsic coxo-lateropenital muscles; 9clm4 = lateral extrinsic coxo-lateropenital muscles.
The absence of the volsellae in Scyphodon s.l. is associated among the exemplars of that clade sampled in this study with irregular ventral serration or a recurved process proximoventrad the penial apex, as noted above. Noonilla zhg-my03 is an exception, with a penial venter that is unsculptured and lacks any recurved processes proximad the apex. Notably, the gonostylar apex in Noonilla zhg-my03 is unique among known Scyphodon s.l. in its bifurcation into recurved lobes; we infer that in the absence of penial serration, the gonostyli in this morphospecies act in an anchoring capacity, unlike the clasping observed in other ants. Moreover, the exceptional medial fusion of the gonostyli in Noonilla zhg-my03 constitutes serial parallelism with the volsellae of the Bornean morphospecies-group, suggesting a similar function. Curiously, the complete absence of the volsellae in Leptanilla zhg-mm03 is not concurrent with any penial serration.
Although we do not examine membranous structures in detail here, a few observations of apparently derived skeletomusculature likely relate to the function of the endophallus through direct or indirect muscular action. First is the presence and expression of the endophallic sclerite, which is located within the ejaculatory duct at or near the primary gonopore, i.e., the point at which the paired ducti ejaculatorii merge to form the endophallus. This sclerite may or may not be homologous in the various ants in which it occurs, or with the endophallic sclerite in other orders, including Coleoptera (see, e.g.,
Inferring the evolutionary origin of the endophallic sclerite is complicated by the lack of intermediate forms indicating that it is, e.g., derived by fragmentation and internalization of an existing penial sclerite, or represents a novel sclerotization of the endophallus itself. The ducti ejaculatorii and endophallus are ectodermal organs with cuticular surfaces and thus may be expected to display ontogenetic plasticity between conjunctiva and sclerite as in exoskeletal surfaces, albeit within a different set of constraints, for example, of optimum flexibility and space-filling.
The endophallic sclerite is not directly musculated in any known ants, and therefore likely functions through indirect action of muscles associated ectally with the endophallus. Contraction of 9cppv1 (h) in Myrmica ruginodis, for example, close the endophallus and allow accumulation of potential energy through pressure on the endophallic sclerite, the release of which could increase the velocity of ejaculation. An alternate hypothesis is that the endophallic sclerite serves as simple reinforcing structure against pressure during ejaculation, or more specifically as a stent to keep the endophallus dilated during contractions of other powerful genital muscles, a situation which may be more probable in lineages that lack muscles near the primary gonopore.
In many sawflies, the lateral pene-lateropenital muscles 10plm2 (n) are frequently associated medially with the endophallic membrane, probably playing a role in closing or opening the genital tract (
As noted above, copulation in the Leptanillinae has never been observed. Given that the queens of Opamyrma, Protanilla, and Anomalomyrma are usually alate (
The loss of extrinsic genital musculature in the Leptanillini s.str., whether due to the remaining tergo-coxal muscles IX becoming intrinsic to the cupula (e.g., Yavnella zhg-th03), the loss of tergo-coxal muscles (Leptanilla zhg-mm03), or the complete loss of the cupula by fusion to adjacent sclerites (Leptanilla s.l. except for the Indochinese morphospecies-group), is presumably associated with suicidal mating – manifesting male-male competition for mating time. This is analogous to copulation in Apis (Apidae: Apinae: Apini), in which suicidal mating by detachment of the male genital capsule (
In metazoans that use internal fertilization, genital morphology is often conspicuously varied relative to other anatomical regions, with the male genitalia having received more descriptive study than the female counterparts (
Qualitatively, the male genitalia of Scyphodon s.l. and the Bornean morphospecies-group show increased morphological disparity relative to that observed in Leptanilla s.str. or the Indochinese morphospecies-group. This could indicate that posterior fusion of abdominal sternite IX to the genital capsule is associated with an increased tempo of morphological evolution in the genitalia – an observation that invites macroevolutionary scrutiny. Quantitative tests of this hypothesis would require phylogenetic comparative analyses utilizing landmark-based geometric morphometrics, applied to scleritic structures. Such an enterprise is conceivable given the scan data published here but may be theoretically challenging, due to operational obstacles and analytical conundrums presented by phylogenetic variance in articulation of adjacent sclerites (
Male genitalia in the insects are diverse in morphology and corresponding function, with this profusion of form often covarying with phylogenetic structure. The male genitalia are therefore of enduring functional, evolutionary, and taxonomic interest. Despite the ecological prevalence and diversity of the Formicidae, little comparative work has focused on the male genitalia of this clade for either classificatory or comparative morphological purposes, compared to the scientific attention that the male genitalia in other insect taxa have received. The ant subfamily Leptanillinae deserves further scrutiny in this regard, since the male genitalia in this clade show high morphological disparity and sometimes spectacular derivation, which have hitherto received only piecemeal description (e.g.,
In this study we provide the first descriptions of male genital skeletomusculature within the Leptanillinae, from the perspective of comparative morphology. These descriptions are guided by phylogeny, as inferred from molecular and morphological data (
Taxonomy in the Leptanillinae relies on male morphological characters, especially those of the genitalia, due to the scarcity of female specimens and lack of phylogenetic signal from worker morphology; our observations clarify and expand our understanding of male genital morphology in the Leptanillinae, therefore aiding future systematic revision of this clade. We find that male genital skeletomusculature in the Leptanillinae is characterized by an overall trend of skeletomuscular reduction relative to the remainder of the Formicidae, in some lineages to an extreme otherwise not observed among ants. Many apomorphic scleritic fusions and muscular losses are homoplasious amongst different lineages of the Leptanillinae and are therefore examples of evolutionary parallelism sensu
Despite our inability to observe copulation in most leptanilline ants, and the complete absence to date of such observations, we extrapolate the function of some derived skeletomuscular character states observed in this study. Noteworthy among these in its behavioral implications is the lack of extrinsic musculation to the male genitalia that is synapomorphic for the Leptanillini s.str., to our knowledge unique among the ants. The loss of extrinsic musculation of the genital capsule would mechanically oblige detachment of the genitalia during copulation. Certain subclades of the Leptanillini s.str. are here found to exhibit posterior fusion of abdominal sternite IX to the genital capsule; by consequence, the genital capsule is extrinsically musculated in these clades by ventral longitudinal and dorsoventral abdominal muscles, with this musculation therefore being a secondary derivation of these subclades.
While provincial in scope – focusing upon a species-poor clade of ants, sister to nearly all other members of the formicid crown-group (
Zachary Griebenow: Conceptualization, Methodology, Data Curation, Writing – Original Draft, Writing – Review and Editing, Visualization Adrian Richter: Investigation, Resources, Data Curation, Writing – Review and Editing, Visualization Thomas van de Kamp: Investigation Evan Economo: Data Curation, Funding Acquisition, Writing – Review and Editing Ziv Lieberman: Conceptualization, Writing – Original Draft, Writing – Review and Editing, Visualization
We thank Dilworth Parkinson, Douglas Rowland and Georg Fischer for their help in obtaining additional scan data for ingroup exemplars, despite the perpetually challenging minuteness of these specimens. We thank Lars Vilhelmsen and an anonymous reviewer for their insightful critiques of an initial draft of this manuscript. We also thank Phil Ward for advice and enduring support throughout the course of this project. We are grateful to Elias Hamann and Mathias Hurst for their assistance during the tomographic measurements at KIT and thank Tomáš Faragó for tomographic raw data reconstruction. Lastly, we thank all who provided specimens included in this study: Bonnie Blaimer (ZMHB), José María Gómez-Durán, Brian Fisher (CASC), Jadranka Rota (
Tables S1–S4
Data type: .zip
Explanation note: Table S1. Collection data for the specimens included in this study. Micro-CT data are published for the specimens highlighted in green; those in yellow were not examined with that method. Skeletomuscular descriptions are provided for specimens highlighted in dark green. — Table S2. Scan settings for all 22 datasets here published. Fundamental differences in modality between X-ray microscopes and synchrotrons result in reciprocal inapplicability of some scan parameters here reported. — Table S3. Presence and absence of male genital musculature across Hymenoptera. See Supplementary Document 1 for explanation of coding schema. — Table S4. Recoding of characters from
Supplementary Document 1
Data type: .docx
Explanation note: Extended description of coding schema for Table S3.
Figure S1
Data type: .tif
Explanation note: Ancestral state reconstruction and sampled tip states of pene-lateropenital and pene-penial musculature across the Hymenoptera. See Supplementary Document 1 for explanation of inapplicability and additional notes. Cells represent characters. Cell fill represents character states: white=absent; black=present; diagonal lines=polymorphic absent/present; gray dots=uncertain; solid gray=inapplicable. Cells in left-to-right order: 10plm1 (m), 10plm2 (n), 10ppm1 (x), 10ppm2 (z).