To be or not to be a tibial comb: A discussion on the (past) use of tibial armature in tribal/subtribal organization in Cholevinae (Coleoptera: Leiodidae)

Gnaspini, Pedro; Peck, Stewart Blaine; Antunes-Carvalho, Caio; Perreau, Michel; Gomyde, Eduardo Coutinho

doi:10.11606/1807-0205/2020.60.special-issue.18

Abstract

Detailed studies of microstructure have recently been shown to provide phylogenetic signals at several supraspecific levels within leiodid coleopterans, as well as in other insects. The tribe Ptomaphagini (Leiodidae: Cholevinae), with a Holarctic-Neotropical-Oriental distribution, has been characterized, among other things, by having a comb of equal-sized, flat spines around the apex of the tibiae of all legs, with a row of spines extending along the outer edge of the protibiae in the subtribes Baryodirina and Ptomaphaginina (but not in Ptomaphagina). A pattern similar to the one in Ptomaphaginina also occurs in the Neotropical cholevine tribe Eucatopini, and this has been used to indicate a phylogenetic relationship between the two tribes (but recent phylogenetic studies have not supported such a close relationship). We here review and revise the presence and structure of periapical (here called an ‘apical crown’) and marginal (here called an ‘external comb’) combs of spines on tibiae in Ptomaphagini, using other cholevines (with and without apical tibial combs) for comparison. We find a phylogenetic signal in an apical crown of tibial spines not interrupted at the outer spur, which seems to be an additional synapomorphy of Ptomaphagini, differing from the pattern in Eucatopini and remaining cholevines with an apical comb of spines, in which the comb is interrupted. We highlight differences not previously noticed between the apical protibial armature of Ptomaphaginina and Eucatopini.

Key-Words.
Coleoptera; Cholevinae; Ptomaphagini; Eucatopini; Tibial morphology

INTRODUCTION

The family Leiodidae, placed in the staphylinoid group of beetle families, includes more than 4,200 described species (e.g.,Newton, 2019Newton, A.F. 2019. StaphBase: Staphyliniformia world catalog database (version Nov 2018): Staphylinoidea, Hydrophiloidea, Synteliidae. In: Roskov, Y.; Ower, G.; Orrell, T.; Nicolson, D.; Bailly, N.; Kirk, P.; Bourgoin, T.; DeWalt, E.; Decock, W.; van Nieukerken, E.; Zarucchi, J. & Penev, L. (Eds.). Species 2000 & ITIS Catalogue of Life. Species 2000: Naturalis. Leiden, the Netherlands. Available at: Available at: www.catalogueoflife.org/col . Access in: 09/07/2019.
www.catalogueoflife.org/col... ), and is characterized (with a few exceptions) by having antenna with an “interrupted” 5-segmented club, antennomere 8 being smaller than 7 and 9, and a periarticular gutter on antennomeres 7, 9 and 10 (e.g.,Newton, 2016Newton, A.F. 2016. Leiodidae Fleming, 1821. In: Beutel, R.G. & Leschen, R.A.B. (Eds.). Coleoptera, Beetles, Volume 1. Morphology and Systematics (Archostemata, Adephaga, Myxophaga, Polyphaga partim). 2.ed. Berlin, Walter de Gruyter. v.1, p. 364-376. (Handbook of Zoology: Arthropoda: Insecta)). One character in particular that is present in many leiodids is a comb of flattened spines that form a ring around the apex of the tibiae, or is present along the lateral margin of the tibiae. In this paper we examine these structures in detail in one group, Ptomaphagini, and evaluate its significance as a phylogenetic character.

The tribe Ptomaphagini of Cholevinae (the most diverse subfamily in Leiodidae), with a Holarctic-Neotropical-Oriental distribution, is diagnostically characterized by having the combination of the following characters: presence of a comb of equal, flat spines surrounding the apex of the tibiae of all legs, a reduced genital segment, and an aedeagus lacking a basal lamina and having an elongate internal flagellum (e.g.,Jeannel, 1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.; Gnaspini, 1993Gnaspini, P. 1993. Brazilian Cholevidae (Coleoptera), with emphasis on cavernicolous species. II. Subgenus Iutururuca nov., subgenus of Adelopsis. Annales de la Société Entomologique de France, 29: 77-87., 1996; Newton, 1998Newton, A.F. 1998. Phylogenetic problems, current classification and generic catalog of World Leiodidae (including Cholevidae). In: International Congress of Entomology, 20º. Proceedings. Phylogeny and evolution of subterranean and endogean Cholevidae (= Leiodidae Cholevinae) Torino, Museo Regionale di Scienze Naturali di Torino. p. 41-177.). Whereas the apical tibial comb is similar in all legs in Ptomaphagina, the protibiae in Ptomaphaginina and in the monotypic Baryodirina bear a row of spines extending along the outer edge. Ptomaphagini was traditionally considered to be close to the Neotropical tribe Eucatopini (e.g.,Jeannel, 1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433., and see discussion in Gnaspini, 1994Gnaspini, P. 1994. The genus Eucatops (Coleoptera, Cholevidae, Eucatopinae) - description of new species and considerations on its systematic position. Iheringia (Zoologia), 76: 33-42.), because of the presence of the tibial comb of spines, with a similar protibial pattern to that in Ptomaphaginina and Baryodirina, and the lack of a tegmen on the aedeagus (although the general pattern of the male genitalia is very different between those tribes). But recent evidence places Ptomaphagini closer to Leptodirini and Sciaphyini, and places Eucatopini + Oritocatopini as an early branch in the evolution of Cholevinae (Antunes-Carvalho & Gnaspini, 2016Antunes-Carvalho, C. & Gnaspini, P. 2016. Pretarsus and distal margin of the terminal tarsomere as an unexplored character system for higher-level classification in Cholevinae (Coleoptera, Leiodidae). Systematic Entomology, 41: 392-415. DOI; Antunes-Carvalho et al., 2019Antunes-Carvalho, C.; Ribera, I.; Beutel, R.G. & Gnaspini, P. 2019. Morphology-based phylogenetic reconstruction of Cholevinae (Coleoptera: Leiodidae): a new view on higher-level relationships. Cladistics, 35: 1-41. DOI). Actually, although Jeannel (1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.) and followers used the comb of spines to unite Ptomaphagini and Eucatopini, they recognized combs and/or crowns of spines at the tibial apex in other groups (Anemadini Eocatopina and Paracatopina, Cholevini Cholevina, and some subtribes of Leptodirini).

Recent studies have shown that features of the legs such as the pretarsal structure and the shape and distribution of tenent setae are valuable character systems for the detection of phylogenetic signals to characterize supraspecific groups (e.g.,Antunes-Carvalho & Gnaspini, 2016Antunes-Carvalho, C. & Gnaspini, P. 2016. Pretarsus and distal margin of the terminal tarsomere as an unexplored character system for higher-level classification in Cholevinae (Coleoptera, Leiodidae). Systematic Entomology, 41: 392-415. DOI; Gnaspini et al., 2017aGnaspini, P.; Antunes-Carvalho, C. & Leschen, R.A.B. 2017a. Pretarsal structures in Leiodidae and Agyrtidae (Coleoptera, Staphylinoidea). Journal of Morphology, 278: 1354-1379. DOI, bGnaspini, P.; Antunes-Carvalho, C.; Newton, A.F. & Leschen, R.A.B. 2017b. Show me your tenent setae and I tell you who you are - Telling the story of a neglected character complex with phylogenetic signals using Leiodidae (Coleoptera) as a case study. Arthropod Structure and Development, 46: 662-685. DOI). We, therefore, study the fine morphology (as opposed to the more common approach of gross morphology) of the apex of the tibiae to address these questions in a new comparative scenario. We dedicate this study to Dr. Cleide Costa, on her 80^th birthday celebration, in recognition of her important contribution to knowledge of the morphology of Coleoptera.

METHODS AND MATERIALS

The methods used here follow the ones of previous studies on the group (e.g.,Antunes-Carvalho & Gnaspini, 2016Antunes-Carvalho, C. & Gnaspini, P. 2016. Pretarsus and distal margin of the terminal tarsomere as an unexplored character system for higher-level classification in Cholevinae (Coleoptera, Leiodidae). Systematic Entomology, 41: 392-415. DOI; Gnaspini et al., 2017aGnaspini, P.; Antunes-Carvalho, C. & Leschen, R.A.B. 2017a. Pretarsal structures in Leiodidae and Agyrtidae (Coleoptera, Staphylinoidea). Journal of Morphology, 278: 1354-1379. DOI, bGnaspini, P.; Antunes-Carvalho, C.; Newton, A.F. & Leschen, R.A.B. 2017b. Show me your tenent setae and I tell you who you are - Telling the story of a neglected character complex with phylogenetic signals using Leiodidae (Coleoptera) as a case study. Arthropod Structure and Development, 46: 662-685. DOI). We used part of the material studied in the cited references and additional specimens (Table 1). In addition to ptomaphagines and eucatopines, we analysed at least one representative of tribes/subtribes of Cholevinae where a tibial comb of spines was recorded in Jeannel (1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.) and Newton (1998Newton, A.F. 1998. Phylogenetic problems, current classification and generic catalog of World Leiodidae (including Cholevidae). In: International Congress of Entomology, 20º. Proceedings. Phylogeny and evolution of subterranean and endogean Cholevidae (= Leiodidae Cholevinae) Torino, Museo Regionale di Scienze Naturali di Torino. p. 41-177.), namely (following the taxonomic structure used in Newton, 1998Newton, A.F. 1998. Phylogenetic problems, current classification and generic catalog of World Leiodidae (including Cholevidae). In: International Congress of Entomology, 20º. Proceedings. Phylogeny and evolution of subterranean and endogean Cholevidae (= Leiodidae Cholevinae) Torino, Museo Regionale di Scienze Naturali di Torino. p. 41-177.), Anemadini: Eocatopina and Paracatopina, Cholevini: Cholevina, Leptodirini: Leptodirina and Bathysciotina. For comparison, we examined additional taxa, namely, Anemadini: Anemadina and Eunemadina, Cholevini: Catopina, Leptodirini: Pholeuina, and Oritocatopini. We studied the mesotibiae (as a representative of the patterns found on both midlegs and hindlegs) of the taxa listed above and we additionally studied the protibiae in Eucatopini and Ptomaphagini: Ptomaphaginina, where the comb of spines extends along the external margin. The dissected legs of additional specimens were mounted on metallic stubs using carbon adhesive pads, and sputter-coated with gold. The specimens were examined in a Zeiss DSM 940 scanning electron microscope in IBUSP [Instituto de Biociências, Universidade de São Paulo]. Except when noted, the left leg was illustrated.

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Table 1
List of species of Leiodidae Cholevinae examined in this study [¹ specimens used in Antunes-Carvalho & Gnaspini (2016Antunes-Carvalho, C. & Gnaspini, P. 2016. Pretarsus and distal margin of the terminal tarsomere as an unexplored character system for higher-level classification in Cholevinae (Coleoptera, Leiodidae). Systematic Entomology, 41: 392-415. DOI); ² specimens used in Gnaspini et al. (2017aGnaspini, P.; Antunes-Carvalho, C. & Leschen, R.A.B. 2017a. Pretarsal structures in Leiodidae and Agyrtidae (Coleoptera, Staphylinoidea). Journal of Morphology, 278: 1354-1379. DOI); ³ specimens used in Antunes-Carvalho et al. (2019Antunes-Carvalho, C.; Ribera, I.; Beutel, R.G. & Gnaspini, P. 2019. Morphology-based phylogenetic reconstruction of Cholevinae (Coleoptera: Leiodidae): a new view on higher-level relationships. Cladistics, 35: 1-41. DOI); ⁴images from M. Perreau (either in Perreau, 2000Perreau, M. 2000. Catalogue des Coléoptères Leiodidae Cholevinae et Platypsyllinae. Memoires de la Societé Entomologique de France, 4: 1-460. or unpublished)], with a summary of the main morphological characteristics observed on the mesotibial apex among the studied taxa. TC denotes if mesotibiae have (‘Y’ (yes) [or ‘~Y’ if it bears small differences from that in Ptomaphagini]) or not (‘N’ (no), although a series of spines may be present) an apical crown of spines; IN denotes the number of ‘interstitial spines’. See text for explanation of characters and character states and for discussion. ‘?’ indicates that that feature was not examined in that species.

Terminology

The apex of the tibiae is generally armed with spines and spurs. Both are elements of the integumental armature (e.g.,Jeannel, 1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.). Spines are more robust than setae and frequently with similar length (e.g., circle in Fig. 1A). Spurs, in turn, are much longer and stronger than spines, and frequently exhibit additional armature, for instance being serrate and/or bearing small spines, tubercles or microtrichia (e.g., ‘is’ and ‘os’ [for inner spur and outer spur, respectively] in Figs. 1A, B). In some taxa, there is a row of short and equal (and frequently flat) spines placed at the apex of the tibiae. These spines may either appear (a) in the form of a ‘periapical comb’ (as in Newton, 1998Newton, A.F. 1998. Phylogenetic problems, current classification and generic catalog of World Leiodidae (including Cholevidae). In: International Congress of Entomology, 20º. Proceedings. Phylogeny and evolution of subterranean and endogean Cholevidae (= Leiodidae Cholevinae) Torino, Museo Regionale di Scienze Naturali di Torino. p. 41-177., who also used ‘apical basket’, as in ‘corbeille apicale’ of Jeannel, 1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.) (for instance on the meso- and metatibiae of Ptomaphagini and Eucatopini and the protibiae of Ptomaphagini: Ptomaphagina) - we here prefer to use ‘apical crown’; or (b) as a ‘comb along the external edge’ (as in Newton, 1998Newton, A.F. 1998. Phylogenetic problems, current classification and generic catalog of World Leiodidae (including Cholevidae). In: International Congress of Entomology, 20º. Proceedings. Phylogeny and evolution of subterranean and endogean Cholevidae (= Leiodidae Cholevinae) Torino, Museo Regionale di Scienze Naturali di Torino. p. 41-177., as in ‘peigne apical externe’ or ‘peigne sur le bord externe’ of Jeannel, 1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.) (for instance on the protibiae of Ptomaphagini: Ptomaphaginina and Eucatopini) - for brevity, we here use ‘external comb’.

Figure 1
Apex of tibiae in Ptomaphagini. (A-D) Adelopsis leo Gnaspini, (A-B) Mesotibia, (A) ventro-lateral-internal and (B) lateral-external views; (C-D) Metatibia, (C) lateral-external and (D) lateral-internal views; (E-F) Amplexella dimorpha Gnaspini, mesotibia, (E) ventral and (F) dorso-lateral-external views; (G-H) Parapaulipalpina sp., right mesotibia (mirrored image), (G) lateral-internal and (H) ventral views; (I) Paulipalpina claudicans (Szymczakowski), right mesotibia (mirrored image), lateral-internal view; (J) Ptomaphagus (Appadelopsis) cumberlandus (Peck), mesotibia, ventro-lateral-internal view; (K) Ptomaphaminus chapmani (Peck), mesotibia, ventral view. bg = ‘body guard’ seta; gp = ‘gap’ on the apical crown of spines around base of spur; is = inner spur; os = outer spur; the circles highlight the progressively smaller spines near spur.

Although Jeannel (1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.) was precise in the use of ‘corbeille apicale’, he used ‘peigne’ to refer either to the ‘external comb’ (mostly) or to the ‘apical crown’ (frequently when he wanted to refer to both, for instance in the case of taxa which have both, as the Eucatopini), mainly in keys (where, for the opposite state, he was frequently precise in using ‘sans peigne ni corbeille apicale’ [‘without either comb or basket’]).

RESULTS AND DISCUSSION

Crown of spines on mesotibial apex

In the following descriptions, where we add some details about this feature, we will restrict our analysis of the structures of interest in this discussion, focusing on the mesotibiae (summarized in Table 1). It is important for our discussion to highlight the presence of a pair of spurs latero-ventrally on the apex of all tibiae of cholevines as a general rule. For a more complete description of the sets of spines and patterns of distribution of spines and spurs, please refer, e.g., to Jeannel (1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.) or Newton (1998Newton, A.F. 1998. Phylogenetic problems, current classification and generic catalog of World Leiodidae (including Cholevidae). In: International Congress of Entomology, 20º. Proceedings. Phylogeny and evolution of subterranean and endogean Cholevidae (= Leiodidae Cholevinae) Torino, Museo Regionale di Scienze Naturali di Torino. p. 41-177.); spur patterns have also been discussed and illustrated in Fresneda et al. (2011Fresneda, J.; Grebennikov, V.V. & Ribera, I. 2011. The phylogenetic and geographic limits of Leptodirini (Insecta: Coleoptera: Leiodidae: Cholevinae), with a description of Sciaphyes shestakovi sp. n. from the Russian Far East. Arthropod Systematics and Phylogeny, 69: 99-123.) and Antunes-Carvalho et al. (2019Antunes-Carvalho, C.; Ribera, I.; Beutel, R.G. & Gnaspini, P. 2019. Morphology-based phylogenetic reconstruction of Cholevinae (Coleoptera: Leiodidae): a new view on higher-level relationships. Cladistics, 35: 1-41. DOI).

In Ptomaphagini, the inner spur [‘is’] is varyingly shorter than the outer spur [‘os’] (Figs. 1E, K). The spines of the apical crown have a flat appearance [which is probably given by the parallel sides of the spines, except for the rounded or pointed tip] and of approximately the same height (Figs. 1B, F). The spines closer to the inner spur, however, are progressively reduced in size at both sides of the spur - for instance, 3-4 spines in Adelopsis Portevin, 1907 (Fig. 1A, circle), 6-7 spines in PaulipalpinaGnaspini & Peck, 1996Gnaspini, P. 1996. Phylogenetic analysis of the tribe Ptomaphagini, with description of new Neotropical genera and species (Coleoptera, Leiodidae, Cholevinae, Ptomaphagini). Papéis Avulsos de Zoologia, 39: 509-556. (Fig. 1I, circle) -, leaving a small gap [‘gp’] for the insertion of the inner spur (Figs. 1G, J, K). On the other hand, the spines close to the outer spur do not change in size or position, and the outer spur is placed inside the apical crown of spines (Figs. 1A, B, E, H, J, K). The sockets of both spurs bear a (usually) long seta, here called the ‘body guard’ seta [‘bg’] (Figs. 1A, K), placed more laterally towards the midventral axis of the mesotibiae in Adelopsis and PtomaphaminusPerreau, 2000Perreau, M. 2000. Catalogue des Coléoptères Leiodidae Cholevinae et Platypsyllinae. Memoires de la Societé Entomologique de France, 4: 1-460.. In the latter, the sockets of the spurs seem to be fused together, probably because the spurs are placed closer to each other when compared to other species (Fig. 1K). The same pattern of the mesotibial apical crown appears on the metatibiae (Figs. 1C, D).

In the remaining groups analysed, the inner spur is longer than the outer spur (e.g.,Figs. 2A, 4C, D), except in Leptodirini (e.g.,Fig. 3C), and there is also a ‘body guard’ seta at the midline of the spurs (e.g.,Figs. 2B, 4C). Antunes-Carvalho et al. (2019Antunes-Carvalho, C.; Ribera, I.; Beutel, R.G. & Gnaspini, P. 2019. Morphology-based phylogenetic reconstruction of Cholevinae (Coleoptera: Leiodidae): a new view on higher-level relationships. Cladistics, 35: 1-41. DOI) have a discussion about size, patterns and armature of spurs and their phylogenetic signals in Cholevinae.

Figure 2
Apex of mesotibiae in Eucatopini, Eucatops (Napocatops) giganteus Salgado, (A-B) ventro-lateral-external (B = detail) and (C) ventral views. bg = ‘body guard’ seta; in = ‘interstitial spines’; is = inner spur; os = outer spur; circle = smaller spine near spur.

Figure 3
Apex of mesotibiae in Leptodirini (A-C) and Sciaphyini (D). (A) Bathysciotes khevenhuelleri tergestinus Müller, lateral-external view; (B) Leptodirus hochenwarti Schmidt, lateral-internal view; (C) Diaprysius serullazi Peyerimhoff, ventral view; (D) Sciaphyes sibiricus (Reitter), lateral-internal view. is = inner spur; os = outer spur; the ellipses highlight the longer spines on the dorsal portion of the apical crown of spines.

Figure 4
Apex of mesotibiae in Anemadini. (A-B) Anemadus italicus Zoia, (A) lateral-internal and (B) dorsal views; (C) Dissochaetus vanini Gnaspini, ventral view; (D-E) Eunemadus chilensis Portevin, (D) ventral and (E) lateral-external views. bg = ‘body guard’ seta; in = ‘interstitial spines’; is = inner spur; os = outer spur; the ellipses highlight the longer spines on the dorsal portion of the apical crown of spines.

The mesotibial apical crown of Eucatopini follows the same pattern as in Ptomaphagini, with some differences. Only the last spine closer to the spurs (in this case, of both spurs, and at both sides of the spurs) is shorter than the rest of the apical crown (Fig. 2B, circle). The apical crown is interrupted at both spurs, and there is a series of three spines placed between the spurs, and clearly inserted slightly away from the apical margin of the mesotibia - this series is here called the ‘interstitial spines’ [‘in’] (Fig. 2C). Except in Ptomaphagini (as above), the ‘interstitial spines’ are present in all groups analysed (e.g.,Figs. 4D, 5A), in variable numbers (see Table 1), meaning that, when there is an apical row of spines, it is interrupted at both spurs.

Figure 5
Apex of mesotibiae in Anemadini (continued). (A) Eocatops ophidianus Szymczakowski, ventral view; (B-C) Paracatops alacris (Broun), (B) ventral and (C) lateral-external views.

In Leptodirini, the apical crown in Bathysciotina (Fig. 3A) follows a very similar pattern to that of Ptomaphagini, with the spines also having a flat appearance (with 1 dorsal spine longer than the neighbours in the species studied, Fig. 3A, ellipse). The apical crown in Leptodirina (Fig. 3B) and in the Pholeuina Diaprysius Abeille de Perrin, 1878 (Fig. 3C) is formed by slender, rounded and pointed spines, more spaced and of irregular size, and with 2-3 longer dorsal spines in the latter species (Fig. 3C, ellipse). The apical crown in Sciaphyini is like that of Bathysciotina, but the spines are somewhat conical and there are 2-3 longer dorsal spines (Fig. 3D, ellipse).

The apical crown in Anemadini: Anemadina and Eocatopina is also similar to that in Ptomaphagini, but the spines are conical (Figs. 4A-B, 5A; and they are more spaced on the dorsal margin in the former). In the Anemadini: Eunemadina: Eunemadus Portevin, 1914 (with the spines of the apical crown also having parallel sides; Figs. 4D, E) and in Paracatopina (Figs. 5B, C), the apical crown is similar to that in Ptomaphagini, but it is interrupted by (three or four, respectively) long spines, slightly displaced from the margin (Fig. 4E, ellipses).

In the Eunemadina: Dissochaetus Reitter, 1884 (Fig. 4C), the apical row of spines also covers the dorsal and both lateral margins, but the spines do not have parallel sides and they do not form a proper apical crown, with (four) long spines intercalated with a small series of short (rounded) spines (Fig. 4C, ellipse). A similar pattern was observed in Cholevini: Catopina (Figs. 6A, B) and Oritocatopini (Fig. 6D).

Figure 6
Apex of mesotibiae in Cholevini (A-C) and Oritocatopini (D). (A-B) Catops fuliginosus Erichson, (A) ventral and (B) dorsal views; (C) Nargus (s. str.) badius (Sturm), fronto-lateral-external view; (D) Afrocatops sp., ventral view. in = ‘interstitial spines’; the ellipse highlights the longer spines on the dorsal portion of the apical crown of spines.

The apical crown in Cholevini: Cholevina (Nargus C.G. Thomson, 1867 - Fig. 6C) is formed by slender, rounded and pointed spines, with two dorsal spines (separated by three small spines) slightly longer than the neighbours in the species here studied (Fig. 6C, ellipse).

Row of spines on protibial apex in Ptomaphagini and Eucatopini

Jeannel (1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.: 43) stated that the ‘apical comb’ of the protibiae occupies all the apical margin and the external lateral margin in Eucatopini and Ptomaphaginus Portevin, 1914 (at that time the only genus of the later named subtribe Ptomaphaginina, of Ptomaphagini). Newton (1998Newton, A.F. 1998. Phylogenetic problems, current classification and generic catalog of World Leiodidae (including Cholevidae). In: International Congress of Entomology, 20º. Proceedings. Phylogeny and evolution of subterranean and endogean Cholevidae (= Leiodidae Cholevinae) Torino, Museo Regionale di Scienze Naturali di Torino. p. 41-177.: 132) offered a similar statement: ‘Protibia with comb of short spines along external edge as well as around apex’. We noticed that those statements were not precise, and we also noticed that the condition differs between those taxa.

In the Ptomaphagini: Ptomaphaginina: Ptomaphaminus (e.g.,Figs. 7A, B; a species formerly placed in Ptomaphaginus), starting from the inner spur, the protibial apical row of spines goes (following the ventral margin) towards the outer spur, passes around it (as aforementioned for the meso- and metatibiae of Ptomaphagini) and continues until the dorsal region; at this point (Fig. 7A, arrow), instead of going back ventrad and forming a complete apical crown (as occurs on meso- and metatibiae [see above]), the spines follow the external margin of the protibiae. A similar pattern was observed in another species of Ptomaphaminus here studied, but we should note that the morphology is variable in species of this genus, which may be a non-monophyletic taxon (Schilthuizen et al., 2018Schilthuizen, M.; Perreau, M. & Njunjić, I. 2018. A review of the Cholevinae from the island of Borneo (Coleoptera, Leiodidae). Zookeys, 777: 57-108.). The same general pattern can be observed in the species of Ptomaphaginus, but, in this genus, there is an additional row of strong setae following the external margin of the protibiae ventrally (Perreau, 2000Perreau, M. 2000. Catalogue des Coléoptères Leiodidae Cholevinae et Platypsyllinae. Memoires de la Societé Entomologique de France, 4: 1-460.: 30, fig. 18; Wang & Zhou, 2015Wang, C.-B. & Zhou, H.-Z. 2015. Taxonomy of the genus Ptomaphaginus Portevin (Coleoptera: Leiodidae: Cholevinae: Ptomaphagini) from China, with description of eleven new species. Zootaxa, 3941: 301-338., several figures). In other words, there is no complete periapical comb of spines, as described in Jeannel (1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.) and Newton (1998Newton, A.F. 1998. Phylogenetic problems, current classification and generic catalog of World Leiodidae (including Cholevidae). In: International Congress of Entomology, 20º. Proceedings. Phylogeny and evolution of subterranean and endogean Cholevidae (= Leiodidae Cholevinae) Torino, Museo Regionale di Scienze Naturali di Torino. p. 41-177.). However, in Proptomaphaginus Szymczakowski, 1969 (Fig. 7C), although the general pattern is similar to that described for Ptomaphaminus, it is possible to recognize a series of very small spines that extends from the internal portion of the apical crown of spines towards the external comb of spines (Fig. 7C, rectangle). These spines are not equally sized and not specifically placed around the apex of the protibiae, but diagonally placed.

Figure 7
Apex of protibiae. (A-B) Ptomaphaminus chapmani (Peck), right leg (mirrored image), (A) ventral and (B) dorsal views; (C) Proptomaphaginus puertoricensis Peck, ventral view (used with permission and modified from fig. 19 in Perreau, 2000Perreau, M. 2000. Catalogue des Coléoptères Leiodidae Cholevinae et Platypsyllinae. Memoires de la Societé Entomologique de France, 4: 1-460.); (D-E) Eucatops sp., (D) dorsal (note the serrate nature of the external margin of the protibia in this species) and (E) ventral views; (F-H) Eucatops (Napocatops) giganteus Salgado, (F) lateral-external, (G) ventro-lateral-external, and (H) lateral-internal views. gp = ‘gap’ on the apical crown of spines around base of spur; is = inner spur; os = outer spur; the arrow shows the point where the spines stop circling the apical margin of the protibia and start to follow the external margin of the protibia, instead of making a complete apical crown; the rectangle highlights the presence of a series of small spines that extends from the internal portion of the apical crown of spines (to the left of the figure) towards the external comb of spines (to the right of the figure); the circle highlights the series of spines at the inner face of the protibia; the ellipse highlights the longitudinal row of strong spines along the outer margin of the protibia.

In Eucatops Portevin, 1903 (Figs. 7D-H), the protibial apical spines show the same distribution as above, with two differences. First, there is a gap in the spines close to the outer spur (as described above for the mesotibiae of Eucatopini) (Fig. 7F). Second, there is indeed a series of spines at the inner face of the protibiae (Figs. 7E, G, H, circle), but it does not follow or even reach the apical margin, and therefore does not form an apical crown (or periapical comb). Instead, originating close (but not next) to the inner spur, the series of spines continues away from the apex, makes a curved/parabolic trajectory, and ends at a row of strong spines (Figs. 7E, H, ellipse) placed parallel to the comb of flat spines that comes from the dorsal portion of the protibial apex. The same pattern can be observed in the species of Eucatops studied in Perreau (2000Perreau, M. 2000. Catalogue des Coléoptères Leiodidae Cholevinae et Platypsyllinae. Memoires de la Societé Entomologique de France, 4: 1-460.: 30, fig. 17). Therefore, in this genus there is indeed a comb of spines that goes almost all around the protibiae, but not completely periapically.

In the Ptomaphagini: Ptomaphagina; these are known to have an apical crown not extending as an external comb also on the protibiae (e.g.,Jeannel, 1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.; Newton, 1998Newton, A.F. 1998. Phylogenetic problems, current classification and generic catalog of World Leiodidae (including Cholevidae). In: International Congress of Entomology, 20º. Proceedings. Phylogeny and evolution of subterranean and endogean Cholevidae (= Leiodidae Cholevinae) Torino, Museo Regionale di Scienze Naturali di Torino. p. 41-177.). Here we illustrate the subtribe based on Adelopsis (Figs. 8A-C; but a similar pattern was also observed, for instance, in Paulipalpina and Ptomaphagus Hellwig, 1795; and see also Perreau, 2000Perreau, M. 2000. Catalogue des Coléoptères Leiodidae Cholevinae et Platypsyllinae. Memoires de la Societé Entomologique de France, 4: 1-460.: 30, fig. 20, Ptomaphagus subvillosus Goeze). We observed that the protibial apical crown is complete - i.e., not interrupted at the inner spur, differently from the meso- and metatibiae of Ptomaphagini (see previous topic). In other words, both outer and inner spurs are placed inside the area delimited by the apical crown. The spines of the protibial apical crown are also progressively shorter in size closer to the inner spur, as observed for the mesotibiae (see previous topic). Also differently from the meso- and metatibiae, the apical crown of spines is not perpendicular to the axis of the protibiae, but is diagonal (as in Fig. 8A), in a similar manner to Ptomaphaminus (compare, e.g., to Fig. 7B), but it does not extend onto the lateral margin of the protibiae.

Figure 8
Apex of protibiae, Adelopsis leo Gnaspini, (A) dorsal, (B) ventral, and (C) frontal views. is = inner spur; os = outer spur.

Concerning the other tribes, Bathysciotes Jeannel, 1910 (Leptodirini: Bathysciotina) clearly shows a protibial external comb of spines (Fig. 9A) and it also has a row of ventro-external spines (Fig. 9B, ellipse), which are not flat (as are those of the typical external comb of spines) but are clearly separated from the other setae and spines along the ventro-lateral face of the protibiae. The protibial external comb of spines appears in all genera of Bathysciotina (and in some Leptodirina) but with different degrees of development - very short combs, restricted to the apical portion of the protibiae have been recorded (as in Perreau, 2019Perreau, M. 2019. Phylogeny of Bathysciotina Guéorguiev, 1974, based on morphology with a special emphasis to Italian genera and with the description of a new species of Halbherria (Coleoptera Leiodidae Cholevinae Leptodirini). Zootaxa, 4590: 367-381.). On the other hand, a similar ventral row of strong spines, although more diagonally placed, appears also in representatives of the leptodirine tribes Bathysciina and Pholeuina - e.g., Oryotus L. Miller, 1856, Perriniella Jeannel, 1910, Quaestus L.W. Schaufuss, 1861, and Speonomus Jeannel, 1908 (Fig. 9C; see also Perreau, 2000Perreau, M. 2000. Catalogue des Coléoptères Leiodidae Cholevinae et Platypsyllinae. Memoires de la Societé Entomologique de France, 4: 1-460.: 30, fig. 21; Perreau & Tronquet, 2002Perreau, M. & Tronquet, M. 2002. Révision du genre Perriniella Jeannel et description d’une nouvelle espèce des Pyrénées françaises (Coleoptera: Leiodidae, Cholevinae, Leptodirini). Annales de la Societé Entomologique de France, 37: 481-490.: 483, fig. 10), but those tribes do not have a protibial external comb of spines. The leptodirines Leptodirus F.J. Schmidt, 1832 (Leptodirina) and Diaprysius (Pholeuina) and the sciaphyine Sciaphyes Jeannel, 1910 (Fig. 9D) show an apical row of spines (similar to the one on the mesotibiae) with a small gap close to the internal lateral margin.

Figure 9
Apex of protibiae. (A-B) Bathysciotes khevenhuelleri tergestinus Müller, (A) dorsal and (B) ventral views; (C) Oryotus ausmeieri Perreau, right protibia (mirrored image), ventral view; (D) Sciaphyes sibiricus (Reitter), ventral view; (E) Eocatops ophidianus Szymczakowski, ventral view; (F) Eunemadus chilensis Portevin, ventral view; (G-H) Paracatops alacris (Broun), (G) ventro-lateral-external and (H) ventral views. The rectangle highlights the presence of small spines that connect the internal and external portions of the apical crown of spines; the circle highlights the series of spines at the inner face of the protibia; the ellipse highlights the longitudinal row of strong spines along the ventral outer margin of the protibia.

In Anemadini, the Eocatopina Eocatops Peyerimhoff, 1924 (Fig. 9E) has a gap between the internal and the external portions of the apical crown, as in the Ptomaphaginina Ptomaphaminus (see Fig. 7A), and the spines of the external portion of the apical margin start to follow the external margin of the protibiae, but an external comb of spines is not formed (see also, e.g.,Jeannel, 1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.: 175, fig. 347 and Latella, 2010Latella, L. 2010. Redescription of Eocatops ambiguus, Peyerimhoff, 1924 (Coleoptera, Cholevidae, Catopinae, Eucatopinae) from Libya. Bollettino del Museo Civico di Storia Naturale di Verona, Botanica, Zoologia, 34: 87-91.: 90, fig. 7). The Eunemadina Eunemadus (Fig. 9F) has a complete, diagonal apical crown of spines, similar to that of the Ptomaphagina Adelopsis (see Fig. 8). Finally, the Paracatopina Paracatops Portevin, 1907 (Figs. 9G-H) shares both (a) the series of spines (which does not follow or reach the apical margin or the external lateral margin of the protibiae) at the inner face of the protibiae (Figs. 9G-H, circle) observed in the Eucatopini Eucatops (see Figs. 7E, G, H, circle) and (b) the diagonal series of very small spines that connects the internal and the external portions of the apical crown of spines (Figs. 9G-H, rectangle), as the one observed in the Ptomaphaginina Proptomaphaginus (Fig. 7C, rectangle).

General remarks

Considering the meso- and metatibiae, firstly, we here recognize apical crowns of spines similar to those of Ptomaphagini, in addition to Eucatopini, for instance also in some Anemadini Eunemadina (which were not previously cited as bearing apical crowns) and in Leptodirini: Bathysciotina and Leptodirina. On the other hand, other groups which were considered to bear apical crowns (for instance, Cholevini: Cholevina - e.g., in Jeannel, 1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.) do not show the same pattern as the taxa cited above. Secondly, the apical crown of Ptomaphagini was found here to differ from the others cited above (also from that of Eucatopini) by being uninterrupted at the outer spur. This seems to be an additional synapomorphy of Ptomaphagini. The general pattern discussed above is also valid for the protibiae, except in Eucatopini and Ptomaphagini: Ptomaphaginina and Baryodirina, when the literature is considered, but see the previous topic and the next paragraphs.

In conclusion, we see no reason, as has historically been done, to identify the tibial apical crown of spines as evidence supporting Ptomaphagini and Eucatopini as closely related sister tribes. A second character that has also been used as a character supporting the relationship between Ptomaphagini and Eucatopini is the lack of a tegmen on the aedeagus, which may be a convergence, considering the overall different pattern of the aedeagus in both tribes, as already commented in Newton (1998Newton, A.F. 1998. Phylogenetic problems, current classification and generic catalog of World Leiodidae (including Cholevidae). In: International Congress of Entomology, 20º. Proceedings. Phylogeny and evolution of subterranean and endogean Cholevidae (= Leiodidae Cholevinae) Torino, Museo Regionale di Scienze Naturali di Torino. p. 41-177.). Still concerning the aedeagus, Jeannel (1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.) also cited an elongate flagellum in the endophallus as a typical character of both tribes, but this is very variable and many cases a short flagellum is recorded in both tribes, even in figures in Jeannel (1936Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.). The only character that they consistently share is a protibial external comb of spines in Eucatopini and only part of Ptomaphagini.

However, differences were also observed in the structure of the series of spines forming the apical crown and the external comb of spines on the protibiae of Eucatopini and Ptomaphagini Ptomaphaginina. This may be related to an independent acquisition of an external comb of spines, which would agree with a recent phylogenetic study placing those tribes far apart from each other (Antunes-Carvalho et al., 2019Antunes-Carvalho, C.; Ribera, I.; Beutel, R.G. & Gnaspini, P. 2019. Morphology-based phylogenetic reconstruction of Cholevinae (Coleoptera: Leiodidae): a new view on higher-level relationships. Cladistics, 35: 1-41. DOI). In that study, Eucatopini together with Oritocatopini appear as the sister group to the remaining Cholevinae. Moreover, an external comb of spines occurs also in Leptodirini: Bathysciotina. Thus, all these data suggest that the apical crown and the external combs in Ptomaphagini and Eucatopini may be convergent (homoplasies), deriving from separate ancestries, as similar adaptive responses to possibly similar selective pressures.

We also detected similarities between Ptomaphagini and other groups here studied as well as between Eucatopini and other groups. A good example is the Anemadini, whose subtribes were tentatively (and ‘for convenience’) grouped in a single tribe by Newton (1998Newton, A.F. 1998. Phylogenetic problems, current classification and generic catalog of World Leiodidae (including Cholevidae). In: International Congress of Entomology, 20º. Proceedings. Phylogeny and evolution of subterranean and endogean Cholevidae (= Leiodidae Cholevinae) Torino, Museo Regionale di Scienze Naturali di Torino. p. 41-177.), and which, in our study, show differences among themselves and similarities either to Ptomaphagini and/or to Eucatopini. A close relationship between Anemadini (or its subtribes, independently) and Ptomaphagini and/or Eucatopini has never been proposed in the literature, and is not assumed here (because we believe that a complete analysis should be conducted by adding the characters here studied to the ones already studied in the literature, and surely with a more robust sample of taxa).

Our goal here was not to exhaustively explore this system of characters, or to propose a new taxonomic scheme for Cholevinae, but to discuss the (in)convenience of or questionable grouping of Ptomaphagini and Eucatopini based mainly on the tibial comb of spines, as has been done in the literature. We suggest that we have shown the morphological complexity and potential for the character system to detect phylogenetic signals in Cholevinae (and also in Leiodidae and other coleopterans as a whole).

ACKNOWLEDGEMENTS

We thank Prof. Sônia Casari for the invitation to submit a manuscript to this special issue celebrating the 80th birthday of Prof. Cleide Costa, who is meritoriously recognized for her contribution to the knowledge of the morphology of Coleoptera, especially its immature stages, and training of several generations of Brazilian researchers. This study was funded by grant from FAPESP (Fundação de Amparo à Pesquisa do Estado de São Paulo, Brazil) #2013/06314-7 to PG. We thank Dr. A.A.G.F.C. Ribeiro, M.V. Cruz, E. Mattos, and P. Lenktaitis for access and help in the use of the facilities of the Electronic Microscopic Laboratory of IBUSP; A.F. Newton for his comments on a first draft of this manuscript; and R. Leschen for the review and constructive comments on the manuscript. We thank the following researchers for the access/loan/donation of additional studied material: Alfred Newton and Crystal Maier (Field Museum of Natural History, Chicago, U.S.A.), Andrea Colla (Museo Cívico di Scienze Naturali, Trieste, Italy), Cristiano Lopes Andrade (Universidade Federal de Viçosa, Viçosa, Brazil), Jan Růžička (Czech University of Life Sciences, Praha, Czech Republic), Richard Leschen (New Zealand Arthropod Collection, Auckland, New Zealand), and Stefano Zoia (Museo Civico di Storia Naturale di Milano, Milano, Italy).

REFERENCES

Antunes-Carvalho, C. & Gnaspini, P. 2016. Pretarsus and distal margin of the terminal tarsomere as an unexplored character system for higher-level classification in Cholevinae (Coleoptera, Leiodidae). Systematic Entomology, 41: 392-415. DOI
Antunes-Carvalho, C.; Ribera, I.; Beutel, R.G. & Gnaspini, P. 2019. Morphology-based phylogenetic reconstruction of Cholevinae (Coleoptera: Leiodidae): a new view on higher-level relationships. Cladistics, 35: 1-41. DOI
Fresneda, J.; Grebennikov, V.V. & Ribera, I. 2011. The phylogenetic and geographic limits of Leptodirini (Insecta: Coleoptera: Leiodidae: Cholevinae), with a description of Sciaphyes shestakovi sp. n. from the Russian Far East. Arthropod Systematics and Phylogeny, 69: 99-123.
Gnaspini, P. 1993. Brazilian Cholevidae (Coleoptera), with emphasis on cavernicolous species. II. Subgenus Iutururuca nov., subgenus of Adelopsis. Annales de la Société Entomologique de France, 29: 77-87.
Gnaspini, P. 1994. The genus Eucatops (Coleoptera, Cholevidae, Eucatopinae) - description of new species and considerations on its systematic position. Iheringia (Zoologia), 76: 33-42.
Gnaspini, P. 1996. Phylogenetic analysis of the tribe Ptomaphagini, with description of new Neotropical genera and species (Coleoptera, Leiodidae, Cholevinae, Ptomaphagini). Papéis Avulsos de Zoologia, 39: 509-556.
Gnaspini, P.; Antunes-Carvalho, C. & Leschen, R.A.B. 2017a. Pretarsal structures in Leiodidae and Agyrtidae (Coleoptera, Staphylinoidea). Journal of Morphology, 278: 1354-1379. DOI
Gnaspini, P.; Antunes-Carvalho, C.; Newton, A.F. & Leschen, R.A.B. 2017b. Show me your tenent setae and I tell you who you are - Telling the story of a neglected character complex with phylogenetic signals using Leiodidae (Coleoptera) as a case study. Arthropod Structure and Development, 46: 662-685. DOI
Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.
Latella, L. 2010. Redescription of Eocatops ambiguus, Peyerimhoff, 1924 (Coleoptera, Cholevidae, Catopinae, Eucatopinae) from Libya. Bollettino del Museo Civico di Storia Naturale di Verona, Botanica, Zoologia, 34: 87-91.
Newton, A.F. 1998. Phylogenetic problems, current classification and generic catalog of World Leiodidae (including Cholevidae). In: International Congress of Entomology, 20º. Proceedings. Phylogeny and evolution of subterranean and endogean Cholevidae (= Leiodidae Cholevinae) Torino, Museo Regionale di Scienze Naturali di Torino. p. 41-177.
Newton, A.F. 2016. Leiodidae Fleming, 1821. In: Beutel, R.G. & Leschen, R.A.B. (Eds.). Coleoptera, Beetles, Volume 1. Morphology and Systematics (Archostemata, Adephaga, Myxophaga, Polyphaga partim). 2.ed. Berlin, Walter de Gruyter. v.1, p. 364-376. (Handbook of Zoology: Arthropoda: Insecta)
Newton, A.F. 2019. StaphBase: Staphyliniformia world catalog database (version Nov 2018): Staphylinoidea, Hydrophiloidea, Synteliidae. In: Roskov, Y.; Ower, G.; Orrell, T.; Nicolson, D.; Bailly, N.; Kirk, P.; Bourgoin, T.; DeWalt, E.; Decock, W.; van Nieukerken, E.; Zarucchi, J. & Penev, L. (Eds.). Species 2000 & ITIS Catalogue of Life. Species 2000: Naturalis. Leiden, the Netherlands. Available at: Available at: www.catalogueoflife.org/col Access in: 09/07/2019.
» www.catalogueoflife.org/col
Perreau, M. 2000. Catalogue des Coléoptères Leiodidae Cholevinae et Platypsyllinae. Memoires de la Societé Entomologique de France, 4: 1-460.
Perreau, M. 2019. Phylogeny of Bathysciotina Guéorguiev, 1974, based on morphology with a special emphasis to Italian genera and with the description of a new species of Halbherria (Coleoptera Leiodidae Cholevinae Leptodirini). Zootaxa, 4590: 367-381.
Perreau, M. & Tronquet, M. 2002. Révision du genre Perriniella Jeannel et description d’une nouvelle espèce des Pyrénées françaises (Coleoptera: Leiodidae, Cholevinae, Leptodirini). Annales de la Societé Entomologique de France, 37: 481-490.
Schilthuizen, M.; Perreau, M. & Njunjić, I. 2018. A review of the Cholevinae from the island of Borneo (Coleoptera, Leiodidae). Zookeys, 777: 57-108.
Wang, C.-B. & Zhou, H.-Z. 2015. Taxonomy of the genus Ptomaphaginus Portevin (Coleoptera: Leiodidae: Cholevinae: Ptomaphagini) from China, with description of eleven new species. Zootaxa, 3941: 301-338.

1
Edited by: Sônia A. Casari / Gabriel Biffi
Published with the financial support of the "Programa de Apoio às Publicações Científicas Periódicas da USP"

Publication Dates

Publication in this collection
03 June 2020
Date of issue
2020

History

Received
29 Oct 2019
Accepted
03 Dec 2019
Published
04 Mar 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Antunes-Carvalho, C. & Gnaspini, P. 2016. Pretarsus and distal margin of the terminal tarsomere as an unexplored character system for higher-level classification in Cholevinae (Coleoptera, Leiodidae). Systematic Entomology, 41: 392-415. DOI

[2] Antunes-Carvalho, C.; Ribera, I.; Beutel, R.G. & Gnaspini, P. 2019. Morphology-based phylogenetic reconstruction of Cholevinae (Coleoptera: Leiodidae): a new view on higher-level relationships. Cladistics, 35: 1-41. DOI

[3] Fresneda, J.; Grebennikov, V.V. & Ribera, I. 2011. The phylogenetic and geographic limits of Leptodirini (Insecta: Coleoptera: Leiodidae: Cholevinae), with a description of Sciaphyes shestakovi sp. n. from the Russian Far East. Arthropod Systematics and Phylogeny, 69: 99-123.

[4] Gnaspini, P. 1993. Brazilian Cholevidae (Coleoptera), with emphasis on cavernicolous species. II. Subgenus Iutururuca nov., subgenus of Adelopsis. Annales de la Société Entomologique de France, 29: 77-87.

[5] Gnaspini, P. 1994. The genus Eucatops (Coleoptera, Cholevidae, Eucatopinae) - description of new species and considerations on its systematic position. Iheringia (Zoologia), 76: 33-42.

[6] Gnaspini, P. 1996. Phylogenetic analysis of the tribe Ptomaphagini, with description of new Neotropical genera and species (Coleoptera, Leiodidae, Cholevinae, Ptomaphagini). Papéis Avulsos de Zoologia, 39: 509-556.

[7] Gnaspini, P.; Antunes-Carvalho, C. & Leschen, R.A.B. 2017a. Pretarsal structures in Leiodidae and Agyrtidae (Coleoptera, Staphylinoidea). Journal of Morphology, 278: 1354-1379. DOI

[8] Gnaspini, P.; Antunes-Carvalho, C.; Newton, A.F. & Leschen, R.A.B. 2017b. Show me your tenent setae and I tell you who you are - Telling the story of a neglected character complex with phylogenetic signals using Leiodidae (Coleoptera) as a case study. Arthropod Structure and Development, 46: 662-685. DOI

[9] Jeannel, R. 1936. Monographie des Catopidae. Mémoires du Muséum National d’Histoire Naturelle (n.s.), 1: 1-433.

[10] Latella, L. 2010. Redescription of Eocatops ambiguus, Peyerimhoff, 1924 (Coleoptera, Cholevidae, Catopinae, Eucatopinae) from Libya. Bollettino del Museo Civico di Storia Naturale di Verona, Botanica, Zoologia, 34: 87-91.

[11] Newton, A.F. 1998. Phylogenetic problems, current classification and generic catalog of World Leiodidae (including Cholevidae). In: International Congress of Entomology, 20º. Proceedings. Phylogeny and evolution of subterranean and endogean Cholevidae (= Leiodidae Cholevinae) Torino, Museo Regionale di Scienze Naturali di Torino. p. 41-177.

[12] Newton, A.F. 2016. Leiodidae Fleming, 1821. In: Beutel, R.G. & Leschen, R.A.B. (Eds.). Coleoptera, Beetles, Volume 1. Morphology and Systematics (Archostemata, Adephaga, Myxophaga, Polyphaga partim). 2.ed. Berlin, Walter de Gruyter. v.1, p. 364-376. (Handbook of Zoology: Arthropoda: Insecta)

[13] Newton, A.F. 2019. StaphBase: Staphyliniformia world catalog database (version Nov 2018): Staphylinoidea, Hydrophiloidea, Synteliidae. In: Roskov, Y.; Ower, G.; Orrell, T.; Nicolson, D.; Bailly, N.; Kirk, P.; Bourgoin, T.; DeWalt, E.; Decock, W.; van Nieukerken, E.; Zarucchi, J. & Penev, L. (Eds.). Species 2000 & ITIS Catalogue of Life. Species 2000: Naturalis. Leiden, the Netherlands. Available at: Available at: www.catalogueoflife.org/col Access in: 09/07/2019.
» www.catalogueoflife.org/col

[14] Perreau, M. 2000. Catalogue des Coléoptères Leiodidae Cholevinae et Platypsyllinae. Memoires de la Societé Entomologique de France, 4: 1-460.

[15] Perreau, M. 2019. Phylogeny of Bathysciotina Guéorguiev, 1974, based on morphology with a special emphasis to Italian genera and with the description of a new species of Halbherria (Coleoptera Leiodidae Cholevinae Leptodirini). Zootaxa, 4590: 367-381.

[16] Perreau, M. & Tronquet, M. 2002. Révision du genre Perriniella Jeannel et description d’une nouvelle espèce des Pyrénées françaises (Coleoptera: Leiodidae, Cholevinae, Leptodirini). Annales de la Societé Entomologique de France, 37: 481-490.

[17] Schilthuizen, M.; Perreau, M. & Njunjić, I. 2018. A review of the Cholevinae from the island of Borneo (Coleoptera, Leiodidae). Zookeys, 777: 57-108.

[18] Wang, C.-B. & Zhou, H.-Z. 2015. Taxonomy of the genus Ptomaphaginus Portevin (Coleoptera: Leiodidae: Cholevinae: Ptomaphagini) from China, with description of eleven new species. Zootaxa, 3941: 301-338.

Systematic assignment		Species	Provenance	TC	IN	Fig.
Anemadini	Anemadina	Anemadus italicus Zoia, 1990	Italy: Calabria	~Y	4	4A-B
	Eocatopina	Eocatops ophidianus Szymczakowski, 1976³	Turkey: Akdamar Island, Van Gölü	~Y	3	5A, 9E
	Eunemadina	Dissochaetus vanini Gnaspini, 1993Gnaspini, P. 1993. Brazilian Cholevidae (Coleoptera), with emphasis on cavernicolous species. II. Subgenus Iutururuca nov., subgenus of Adelopsis. Annales de la Société Entomologique de France, 29: 77-87. ^{1, 2, 3}	Brazil: São Paulo: Iporanga	N	2	4C
		Eunemadus chilensis Portevin, 1914²	Chile: Osorno: near Puaucho	~Y	4	4D-E, 9F
	Paracatopina	Paracatops alacris (Broun, 1880)^{2, 3}	New Zealand: AK: Duck Creek SR	~Y	3	5B-C, 9G-H
Cholevini	Catopina	Catops fuliginosus Erichson, 1837^{1, 2, 3}	Italy: Friuli Venezia Giulia	N	4	6A-B
		Catops nigricans (Spence, 1815)⁴		N	?	-
	Cholevina	Nargus (s. str.) badius (Sturm, 1839)^{1, 3}	Italy: Liguria	~Y	4	6C
Eucatopini	-	Eucatops sp.^{1, 3}	Peru: Madre de Dios	Y	?	7D-E
		Eucatops (Napocatops) giganteus Salgado, 2005²	Ecuador: Napo: near Baeza	Y	4	2, 7F-H
Leptodirini	Bathysciina	Oryotus ausmeieri Perreau, 2003⁴	Slovenia: Slap ob Idrijci, Jama Krasnica	?	?	9C
	Bathysciotina	Bathysciotes khevenhuelleri tergestinus Müller, 1922^{1, 3}	Italy: Friuli Venezia Giulia	~Y	1	3A, 9A-B
	Leptodirina	Leptodirus hochenwarti Schmidt, 1832^{1, 3}	Italy: Friuli Venezia Giulia	~Y	1	3B
	Pholeuina	Diaprysius serullazi Peyerimhoff, 1904²	France: Ardeche: grt. des Assiettes	~Y	2	3C
		Quaestus noltei (Coiffat, 1965)⁴		?	?	-
Oritocatopini	-	Afrocatops sp.²	South Africa: Natal; near Estcourt	N	2	6D
Ptomaphagini	Ptomaphagina	Adelopsis leo Gnaspini, 1993Gnaspini, P. 1993. Brazilian Cholevidae (Coleoptera), with emphasis on cavernicolous species. II. Subgenus Iutururuca nov., subgenus of Adelopsis. Annales de la Société Entomologique de France, 29: 77-87.	Brazil: São Paulo: Guapiara	Y	0	1A-D, 8
		Amplexella dimorpha Gnaspini, 1996Gnaspini, P. 1996. Phylogenetic analysis of the tribe Ptomaphagini, with description of new Neotropical genera and species (Coleoptera, Leiodidae, Cholevinae, Ptomaphagini). Papéis Avulsos de Zoologia, 39: 509-556. ^{1, 2, 3}	Venezuela: Aragua	Y	0	1E-F
		Parapaulipalpina sp.^{1, 2, 3}	Venezuela: Bolívar	Y	0	1G-H
		Paulipalpina claudicans (Szymczakowski, 1980)^{1, 2, 3}	Brazil: Santa Catarina	Y	0	1I
		Ptomaphagus (Appadelopsis) cumberlandus (Peck, 1979)	U.S.A.: Alabama	Y	0	1J
		Ptomaphagus (s. str.) sericatus (Chaudoir, 1845)³	Slovenia: Lower Carniola, Trebnje	Y	0	-
	Ptomaphaginina	Ptomaphaginus palpalis Szymczakowski, 1974³	Nepal: Kathmandu, Phulchoki	Y	0	-
		Ptomaphaminus bengalominus (Perreau, 1991)⁴	India: Bengale occidental	Y	0	-
		Ptomaphaminus chapmani (Peck, 1981)^{1, 2}	Malaysia: Sarawak	Y	0	1K, 7A-B
		Ptomaphaminus fagei Perreau, 2009⁴	Indonesia: Marang Mts., Gua Sedepan	Y	0	-
		Proptomaphaginus puertoricensis Peck, 1971^{3, 4}	Puerto Rico: Aguas Buenas, Aguas Buenas Cave	Y	0	7C
Sciaphyini	-	Sciaphyes sibiricus (Reitter, 1887)²	Russia: Siberia	~Y	2	3D, 9D

Brasil