Introduction
The genus Mordellistena Costa, 1854 (Coleoptera: Mordellidae) is represented in Europe by approximately 170 species (Horák Reference Horák2008; Odnosum Reference Odnosum2009; Selnekovič and Kodada Reference Selnekovič and Kodada2019; Selnekovič and Ruzzier Reference Selnekovič and Ruzzier2019; Selnekovič and Improta Reference Selnekovič and Improta2020). Most of the common and widespread European species were described during the 19th century by Costa (Reference Costa1854), Mulsant (Reference Mulsant1856), Emery (Reference Emery1876), and Schilsky (Reference Schilsky1894, Reference Schilsky1895, Reference Schilsky1898, Reference Schilsky1899). Their work was later followed up by specialists and prolific authors such as K. Ermisch, M.E. Franciscolo, and R. Batten, who greatly contributed to the knowledge of the family with descriptions of dozens of new species. Unfortunately, during our recent studies, it became clear that the type material of some previously described taxa remained unstudied, leading to several cases of incorrect species interpretations and descriptions of taxa that already bore a name (Horák Reference Horák1990, Reference Horák1996; Selnekovič and Kodada Reference Selnekovič and Kodada2019; Selnekovič and Improta Reference Selnekovič and Improta2020). Mordellistena minima Costa, 1854 (Fig. 1A) and M. pseudorhenana Ermisch, 1977 (Fig. 1B) discussed in the present paper may serve as examples.
Mordellistena minima was described by Costa (Reference Costa1854) based on a specimen from the island of Ischia, Italy. Later, Emery (Reference Emery1876) considered the type specimen of M. minima “just a small specimen of M. micans (Germar, 1817), which varies greatly in size”. His opinion was then followed by all subsequent authors until Ermisch (Reference Ermisch1954) treated M. minima as a valid species but did not provide any description or diagnostic characters to separate it from its allies. Batten (Reference Batten1977), without seeing the type specimen, characterised M. minima based on a unique combination of characters: short antennomeres, long and pointed galea, and expanded protibiae in males. Subsequently, Batten (Reference Batten1980) examined the holotype of M. pseudorhenana Ermisch, 1977 and considered it to be conspecific with M. minima.
The re-examination of the type specimen of M. minima surprisingly revealed a unique set of characters that differ significantly from the abovementioned and currently accepted interpretation of the species as presented by Batten (Reference Batten1977). The present paper aims to resolve the confusion regarding the identity of M. minima and M. pseudorhenana and to provide redescriptions of both species based on the examined type material. We integrated morphometric and DNA barcode analyses to interpret the observed morphological variability in specimens of M. pseudorhenana. Furthermore, we have been able to add DNA barcodes for the first time to five species of the Mordellistena confinis species group, with recently re-examined and documented type material (Horák Reference Horák1996; Selnekovič and Kodada Reference Selnekovič and Kodada2019; Selnekovič and Improta Reference Selnekovič and Improta2020). This allowed us to examine the interspecific genetic divergences at the species-group level and set the baseline for future studies with the use of DNA markers.
Materials and methods
The present study is based on examination of 242 adult specimens, including a lectotype of Mordellistena minima Costa, 1854, a lectotype and paralectotypes of M. emeryi Schilsky, 1895, two syntypes of M. micans (Germar, 1813), a holotype and paratypes of M. pseudorhenana Ermisch, 1977, and a holotype of M. sajoi Ermisch, 1977. Freshly collected specimens used for the morphological observations were killed using ethylacetate, dissected, and glued on a cardboard mounting card. Specimens used for the molecular analyses were killed and stored in 96% ethanol. Observations were made using a Leica MZ16 stereomicroscope (Leica Microsystems) with magnification up to 120×, illuminated with diffuse light (neon bulb, 6400 K; Philips, Amsterdam, The Netherlands). Dry specimens were soaked in water with a small amount of acetic acid. Dissected body parts used for drawings were treated with lactic acid for several days, then washed in water or dehydrated in ethanol and mounted on slides in Berlese’s fluid (Swan Reference Swan1936) or Euparal (Paradox Co., Cracow, Poland). Drawings were made using a Leica drawing tube attached to a Leica DM 1000 microscope (Leica Microsystems), then scanned and traced in Adobe Illustrator CC (Adobe, San Jose, California, United States of America). All dissected body parts were glued with 5,5-dimethyl hydantoin formaldehyde on the same card as the respective specimen or put in the microvials filled with glycerine and pinned under the specimen. Digital photographs were made using a Canon EOS 5D mark II camera (Canon, Tokyo, Japan) attached to Zeiss Axio Zoom.V16 stereoscope (Carl Zeiss AG, Oberkochen, Germany). Image stacks were produced manually, combined using the Zerene Stacker 1.4 software (Zerene Systems LLC, Richland, Washington, United States of America), and edited in Adobe Photoshop CC (Adobe). Measurements were taken using a calibrated eyepiece graticule. Morphometric parameters are provided as range and mean ± standard deviation. The following abbreviations are used for the measured characters: BL – body length from anterior margin of pronotum to elytral apices along midline; HL – head length from anterior margin of clypeus to occipital margin along midline; HW – maximum head width; PL – pronotal length along midline; PW – maximum pronotal width; EL – elytral length from apex of scutellar shield to apices of elytra along suture; EW – maximum elytral width combined; PyL – maximum length of pygidium; RPL – maximum length of right paramere; LPL – maximum length of left paramere. Terminology used in morphological descriptions follows Franciscolo (Reference Franciscolo1957), Lu et al. (Reference Lu, Jackman and Johnson1997), and Lawrence and Ślipiński (Reference Lawrence and Ślipiński2010). All nomenclatorial acts follow regulations of the International Code of Zoological Nomenclature (International Trust of Zoological Nomenclature 1999). The examined material is deposited in the following collections: Dávid Selnekovič collection, Bratislava, Slovakia (DSBS), Hungarian Natural History Museum, Budapest, Hungary (HNHM), the Museum für Naturkunde, Humboldt-Universität zu Berlin, Berlin, Germany (MNHU), the Museo Zoologico dell’Università Federico II, Naples, Italy (MZFN), and Senckenberg Deutsches Entomologisches Institut, Müncheberg, Germany (SDEI).
Principal component analysis was performed using PAST 3.12 software (Hammer et al. Reference Hammer, Harper and Ryan2001), using log-transformed variables of three morphometric characters: elytral length, right paramere length, and left paramere length (Supplementary material, Table S1). The dataset consisted of 60 male specimens of M. pseudorhenana from Bulgaria, Cyprus, Hungary, Israel, Italy, Montenegro, Slovakia, and Turkey, including holotype and all male genetic vouchers. Plots were subsequently edited in Adobe Illustrator CC.
A total of 30 adults were used for the DNA analyses (Table 3). Genomic DNA was extracted from whole individuals using E.Z.N.A.® Tissue DNA kit (OMEGA Bio-tek Inc., Norcross, Georgia, United States of America) according to the manufacturer’s protocol. Extracted and purified DNA is stored at –25 °C at the Department of Zoology of Faculty of Natural Sciences, Comenius University, Bratislava, Slovakia. A 568-bp-long fragment of cytochrome oxidase subunit 1 (CO1) was amplified with primers LCO1490 and HCO2198 (Folmer et al. Reference Folmer, Black, Hoeh, Lutz and Vrijenhoek1994). Standard polymerase chain reaction was performed using DreamTaq™ Green DNA Polymerase (Thermo Fisher Scientific Inc., Waltham, Massachusetts, United States of America) for a total volume of 25.0 μL, comprising 100–200 ng genomic DNA, 2.5 μL DreamTaq™ Buffer, 2.5 μL 25 mM MgCl2, 2.0 μL of dNTP (deoxynucleotide triphosphohydrolase) mix, 1.0 μL of 3.0 pmol/mL each primer, 0.4 μL (5 U/ μL) DreamTaq™ DNA polymerase and nuclease-free water to 25.0 μL. Polymerase chain reaction was carried out on an Eppendorf thermal cycler (Eppendorf, Hamburg, Germany), with initial denaturation at 94 °C for 1 minute, followed by 35 cycles of 94 °C for 30 seconds, 52 °C for 40 seconds, and 72 °C for 1 minute, and 10 minutes of final extension at 72 °C. All polymerase chain reaction products were detected on 1% agarose gel stained with GoldView (SBS Genetech, Beijing, China). Purification and Sanger sequencing were done in the commercial laboratory of Macrogen Europe Inc. (Amsterdam, The Netherlands) using both amplification primers. Consensus sequences, alignment, and final matrix were produced in Geneious 6.1.8 software (Kearse et al. Reference Kearse, Moir, Wilson, Stones-Havas, Cheung and Sturrock2012). Mordella aculeata Linnaeus, 1758 and Mordellistena variegata (Fabricius, 1798) were used as outgroups. Estimates of evolutionary divergence between CO1 sequences were calculated using the Kimura two-parameter model (Kimura Reference Kimura1980). The dendrogram was based on the maximum likelihood method, and bootstrap support values were calculated in MEGA X software (Kumar et al. Reference Kumar, Stecher, Li, Knyaz and Tamura2018). The best-fitted substitution model (GTR + I + G) was selected by jModelTest 2 (Darriba et al. Reference Darriba, Taboada, Doallo and Posada2012) using 1000 replicates. Voucher identifiers and GenBank and BOLD accession numbers are listed in Table 3.
Results
Morphology and systematics
Examination of the male lectotype of Mordellistena minima Costa, 1854 deposited in the Museo Zoologico dell’Università Federico II revealed a unique set of characters separating the species from other congeners (see differential diagnosis). The presence of yellow metatibial spurs, in combination with an entirely black body and short antennomeres, observed in the lectotype of M. minima is a rather unique condition that appears only in two other taxa from the M. confinis group: M. emeryi Schilsky, 1895 and M. lindbergi Ermisch, 1963. Re-examination of the lectotype of M. emeryi and comparison of the male genitalia with the lectotype of M. minima (Fig. 5F,G) revealed that the specimens are conspecific, and therefore we propose M. emeryi as a new junior subjective synonym of the latter. The redescription of the species provided below is based on a lectotype of M. minima, the type series of M. emeryi, and a series of specimens recently collected in the type locality, Ischia, Italy.
The identity of M. minima is not consistent with a previously accepted interpretation of the species presented by Ermisch (Reference Ermisch1963) and Batten (Reference Batten1977) and followed by subsequent authors (Odnosum Reference Odnosum1992, Reference Odnosum1993, Reference Odnosum2003, Reference Odnosum2005, Reference Odnosum2010; Horák Reference Horák2008; Ruzzier Reference Ruzzier2013). The definition of M. minima as a species, with long apically pointed galea, expanded protibiae in males with distinct clusters of extended setae, and short antennomeres 5–10, was based on a misidentification. The aforementioned species interpretation was found to correspond with the holotype of M. pseudorhenana Ermisch, 1977 previously synonymised with M. minima by Batten (Reference Batten1980). After a re-examination of the holotype, we consider M. pseudorhenana to be a valid species, which can be separated from other members of M. confinis species group by the presence of long and pointed galea (Fig. 6A) and the combination of characters listed in the differential diagnosis section. The holotype of M. sajoi Ermisch, 1977 shares the important diagnostic characters with the holotype of M. pseudorhenana, and we consider M. sajoi a new junior subjective synonym of the latter species.
Among the material examined for the present study, we were able to identify two morphotypes of M. pseudorhenana that differ in the size and shape of the parameres. Morphotype 1 is represented here by a holotype and 88 additional male specimens from several localities in Europe (Fig. 2), while morphotype 2 is represented by 27 male specimens from Cyprus, Israel, and Turkey. The two morphotypes differ in the size and shape of the parameres: morphotype 1’s parameres are shorter and smaller in proportion to the elytral length than they are in morphotype 2 (Figs. 3B, 6E, F; Table 1); basal portions of the parameres in morphotype 1 are shorter in proportion to the distal processes than they are in morphotype 2 (Fig. 6E,F); and the dorsal process of the left paramere in morphotype 1 is shorter and wider than it is in morphotype 2 (Fig. 6E, F). The differences in dimensions are also shown by the results of the principal component analysis (Fig. 3A). Despite the morphological differences, the genetic divergence in CO1 fragment between the representatives of the two morphotypes is very low (Table 5; discussed in the Molecular Analyses section).
EL, elytral length from apex of scutellar shield to apices of elytra along suture; RPL, maximum length of right paramere; LPL, maximum length of left paramere.
Morphometric analysis
For the principal component analysis, we focused on two morphotypes of M. pseudorhenana that can be distinguished based on the shape and size of the parameres. The first group representing morphotype 1 consisted of 39 male specimens from Bulgaria, Hungary, Italy, Montenegro, and Slovakia, including the holotype and voucher specimens used for the molecular analyses. The second group consisted of 21 male specimens from Cyprus, Israel, and Turkey, also including the genetic vouchers. The principal component analysis was based on a set of three characters (elytral length, right paramere length, and left paramere length) that best reflect the differences in morphology. The analysis revealed two separate clusters that represent the two morphotypes (Fig. 3 A). The first principal component explained 68.5% of the variance and correlated strongly with the length of the right paramere (Table 2). The second principal component explained 29.8% of the variance and correlated strongly with elytral length (Table 2). Results of the principal component analysis are congruent with differences in the actual measurements (Fig. 3B; Table 1; Supplementary material, Table S1).
EL, elytral length from apex of scutellar shield to apices of elytra along suture; RPL, maximum length of right paramere; LPL, maximum length of left paramere.
Molecular analyses
The sequences of CO1 gene fragment were obtained from 30 out of 35 amplified samples representing five species of M. confinis group, plus two outgroup species (Table 3). The analysed CO1 fragment was 568 bp long, with no indels and stop codons. The maximum likelihood analysis revealed all five presumed ingroup species as distinctly separate clades, each with bootstrap value of 100 (Fig. 4). The Kimura two-parameter genetic divergences between species were high and ranged from 13.9% between M. hirtipes Schilsky, 1895 and M. purpurascens Costa, 1854 to 22.4% between M. minima and M. hirtipes (Table 4; Supplementary material, Table S2). The mean interspecific distance between the five analysed species from the M. confinis species group was 18.5%. The mean intraspecific distances ranged from 0% in M. minima to 1.9% in M. hirtipes (Table 4).
DSBS, Dávid Selnekovič collection, Bratislava, Slovakia.
The M. pseudorhenana morphotype 1 was represented in the analyses by 13 specimens from Bulgaria, Italy, and Slovakia. Morphotype 2 was represented by five specimens from Cyprus. The analyses revealed four haplotypes in the morphotype 1 and two haplotypes in morphotype 2 (Tables 3 and 5). Based on the Kimura two-parameter distances, M. lindbergi was recovered as the closest neighbour of M. pseudorhenana, with the smallest interspecific distance (16.5%) (Supplementary material, Table S2). The divergences between the two M. pseudorhenana morphotypes ranged from 0.2% between haplotypes from Cyprus and Bulgaria to 1.4% between haplotype 3 from Cyprus and haplotype 4 from Italy (Table 5). The highest intraspecific Kimura two-parameter distance between the two morphotypes is 11.8 times less than the smallest interspecific distance between M. pseudorhenana and M. lindbergi. The analysed CO1 fragment did not provide any evidence to consider the two morphotypes separate species.
Distribution
Distributional records for M. minima that were published by Ermisch (Reference Ermisch1963), Batten (Reference Batten1976), Odnosum (Reference Odnosum1993, Reference Odnosum2003, Reference Odnosum2010), and Horák (Reference Horák2008, Reference Horák2020) were identified to refer to M. pseudorhenana, based on the revised material and the illustrations of male genitalia presented in the publications. The large series of examined material revealed new distributional records for M. pseudorhenana from Bosnia and Herzegovina, Slovenia, and Switzerland. The range of M. pseudorhenana reaches from Spain in the west, across the whole Mediterranean basin to Turkey, from Israel and Jordan in the south, across the Pannonian basin to Hungary and Slovakia in the north, and along the Black and Caspian seas to Ukraine, Azerbaijan, and Kyrgyzstan in the east (Fig. 2). A new record from Rajecké Teplice, Slovakia marks the northernmost known extent of the species’ distribution (Fig. 2).
Mordellistena (s. str.) minima Costa, 1854
Mordellistena (s. str.) minima Costa, Reference Costa1854: 18–19, Pl. XXII, Fig. 1 [original description, figures, type locality: Ischia, Italy]; Mulsant (Reference Mulsant1856: 383–385) [description]; Gemminger and Harold (Reference Gemminger and Harold1870: 2112) [catalogue, first report from France].
Mordellistena (s. str.) micans: Emery (Reference Emery1876: 96) [as syn. of M. micans]; Heyden et al. (Reference Heyden, Reitter and Weise1883: 142) [catalogue, as var. of M. micans]; Heyden et al. (Reference Heyden, Reitter and Weise1906: 456) [catalogue, as syn. of M. micans]; Winkler (Reference Winkler1928: 885) [catalogue, as syn. of M. micans].
Mordellistena (s. str.) confinis var. emeryi Schilsky, 1895: 53 new synonymy [original description, type locality: Oesterreich [Austria]]; Heyden et al. (Reference Heyden, Reitter and Weise1906: 456) [catalogue]; Schaufuss (Reference Schaufuss1916: 766) [catalogue, first report from Germany]; Roubal (Reference Roubal1934: 5) [first report from Morocco]; Franciscolo (Reference Franciscolo1942: 7) [localities], Franciscolo (Reference Franciscolo1956: 4) [localities].
Mordellistena (s. str.) emeryi: Ermisch (Reference Ermisch1956: 286, 308–309) [new status, key, first report from Albania, Algeria, Croatia, Spain, Switzerland]; Ermisch (Reference Ermisch1969a: 847, 853) [localities]; Ermisch (Reference Ermisch1969b: 181) [key]; Köstlin and Vogt (Reference Köstlin and Vogt1971: 51) [localities]; Batten (Reference Batten1976: 167) [localities]; Ermisch (Reference Ermisch1977: 167) [localities]; Kaszab (Reference Kaszab1979: 69–70) [key, figures]; Compte (Reference Compte1985: 66) [localities]; Angelini (Reference Angelini1986: 87) [localities]; Franciscolo (Reference Franciscolo1991: 168) [localities, first report from Tunisia]; Horák (Reference Horák1996: 178) [key]; Horák (Reference Horák2008: 97) [catalogue, first report from Greece]; Ruzzier (Reference Ruzzier2013: 107) [localities]; Horák (Reference Horák2020: 93) [catalogue].
Type locality. Ischia, Italy.
Type material examined. Lectotype of M. minima (Fig. 5 A,F) by designation of Selnekovič and Improta (Reference Selnekovič and Improta2020), male, MZFN, labelled: “45.194 | Mordellistena minima, n. Ischia [original Costa’s label] | LECTOTYPUS Mordellistena minima Costa, 1854 D. Selnekovič des. 2019 [red label]”; in bad condition, pinned between elytra, right antenna, right maxillary palpus, and left metatarsus missing; left antenna, left maxilla, left elytron, abdomen, and genitalia stored in microvial with glycerine. Lectotype of M. emeryi by present designation (Fig. 5G), MNHU, male, labelled: “Austria Schuster [handwritten] | ♂ | Type [red label] | Zool. Mus. Berlin | [card with dissected genitalia] | LECTOTYPUS Mordellistena (s. str.) emeryi Schilsky J. Horák design. 2006 [red label]”. Paralectotypes of M. emeryi by present designation, MNHU, 5 males, 4 females, 2 sex undetermined, labelled: “Austria Schuster [handwritten] | Type [red label] | Zool. Mus. Berlin | PARALECTOTYPUS Mordellistena (s. str.) emeryi Schilsky J. Horák design. 2006 [red label]”.
Additional material examined. Italy: 9 ♂♂, 3 ♀♀, Ischia Island, Serrara env., 40° 43′ 17″ N, 13° 52′ 59″ E, 550 m a.s.l., 30.vi.2019, D. Selnekovič leg., dry grassland (DSBS DSBS_79, DSBS_81, DS-138 to DS-140, DS-154 to DS-158); 10 ♂♂, 7 ♀♀, Ischia Island, Serrara env., 40° 42′ 60″ N, 13° 53′ 11″ E, 517 m a.s.l., 29.vi.2019, D. Selnekovič leg., ruderal vegetation, on flowers of Daucus (DSBS DS-141 to DS-147, DS-151 to DS-153, DS-159 to DS-168).
Differential diagnosis. The species is characterised by the following combination of characters: (1) body black, metatibial spurs yellowish (Fig. 1A); (2) pubescence on most body surfaces yellowish to light-brownish with purple sheen; (3) antennomeres 5–10 ca. 1.20–1.30 times longer than wide; (4) galea short, apically rounded (Fig. 5A); (5) protibiae in males slightly expanded, sometimes with several extended setae; (6) metatibiae with 3–5 short lateral ridges, metatarsomere 1 with 3–5 ridges, metatarsomere 2 with two ridges; (7) abdominal sternite VIII in males ca. 2.00 times longer than wide, rounded at apex (Fig. 5C); in females ca. 1.60 times longer than wide, with speculum ventrale narrowly clavate (Fig. 5D); and (8) parameres as in Figure 5F,G; ovipositor rather short, with paraprocts distinctly shorter than gonocoxites, as in Figure 5E.
Mordellistena minima may be assigned to the M. confinis species group as defined by Ermisch (Reference Ermisch1956). Within this group, the combination of yellowish metatibial spurs and completely black body, including legs and antennae, is shared by three other species: M. lindbergi Ermisch, 1963, M. eversi Ermisch, 1965, and M. canariensis Ermisch, 1965. The species most closely resembles M. lindbergi and can be distinguished by the following characters: (1) the pubescence on elytra in M. minima has a distinct purple sheen, whereas that of M. lindbergi has a distinct greenish sheen; (2) protibiae are, in males of M. minima, slightly expanded, sometimes with several extended setae, compared to those of M. lindbergi, which are not expanded and are without extended setae; (3) the metatibiae in M. minima usually possess 4–5 lateral ridges, whereas those of M. lindbergi usually possess three lateral ridges, the last of which is very short; (4) abdominal sternite VIII in males of M. minima is ca. 2.00 times longer than wide with a rounded apex (Fig. 5C), whereas that of M. lindbergi is approximately 1.60 times longer than wide, with lateral margins distinctly convergent and a slightly emarginated apex; (5) the parameres of M. minima are as illustrated in Figure 5F,G, and those of M. lindbergi are as shown in Horák (Reference Horák1996); (6) the species are separated by ca. 19% divergence in the barcoding fragment of the CO1 gene (Table 3). Both M. eversi and M. canariensis are known only from the Canary Islands and differ from M. minima by having distinctly longer antennae, with antennomeres 5–10 almost twice as long as wide.
Redescription. Body slender (Fig. 1A), wedge-shaped, widest before middle of elytra, dorsum moderately convex, venter strongly so. Basic metric characters are listed in Tables 1 and 6. Colour of almost entire integument black, with very fine bluish sheen; maxillary palpi and four basal antennomeres sometimes dark reddish-brown; metatibial spurs yellowish with black apices. Vestiture consisting of dense, decumbent, dorso-ventrally flattened setae; colour uniformly yellowish on head and sternal thoracic parts; in anterior portions of pronotum yellowish, somewhat darkened posteriorly; in anterior portions of elytra yellowish, gradually darkened posteriorly to completely black at apices; on first to abdominal ventrites yellowish, on following ventrites gradually darkened to completely black on ventrite 5 and pygidium; on legs yellowish, somewhat darkened towards apices; vestiture on pronotum and elytra with distinct purple sheen.
BL, body length from anterior margin of pronotum to elytral apices along midline; HL, head length from anterior margin of clypeus to occipital margin along midline; HW, maximum head width; PL, pronotal length along midline; PW, maximum pronotal width; EL, elytral length from apex of scutellar shield to apices of elytra along suture; EW, maximum elytral width combined; PyL, maximum length of pygidium; RPL, maximum length of right paramere; LPL, maximum length of left paramere.
Head on dorsum moderately convex; surface finely microreticulated with minute, round, setiferous punctures; frontoclypeus with anterior margin straight; occipital carina evenly rounded in dorsal aspect, straight to slightly concave in posterior aspect; tempora absent. Labrum with antero-lateral angles broadly rounded, transverse with exposed portion ca. 1.30 times wider than long, microreticulate, bearing setiferous punctures. Eyes broadly oval, ca. 1.30 times longer than wide, finely faceted with distinct interfacetal setae. Antennae moderately long, feebly serrate (Fig. 1A); scapus and pedicel cylindrical, subequal; antennomeres 3–4 subequal, slightly shorter than pedicel, distinctly shorter than following segments; antennomeres 5–10 subequal, in males ca. 1.30 times and in females ca. 1.20 times longer than wide; antennomere 11 elongate oval, ca. 2.00 times longer than wide. Mandibles slightly asymmetrical in molar parts, bidentate, with exposed lateral portion setose; mola denticulate; prostheca with thin, medially oriented trichoid sensilla. Maxilla as in Figure 5 A,B, galea distinctly shorter than maxillary palpus, rounded or subtruncate at apex, densely covered with trichoid and apically widened, spoon-like sensilla; lacinia with trichoid sensilla arranged in longitudinal row and scattered in apical portion; palpifer cylindrical, setose laterally; maxillary palpomere 1 short, setose ventrally; palpomere 2 moderately widened apically, in males not expanded and with few extended setae; palpomere 3 ca. 0.50 times as long as previous one; terminal palpomere narrowly securiform, ca. 2.50 times longer than wide, with inner angle situated behind middle. Terminal labial palpomere broadly fusiform.
Pronotum moderately convex, slightly wider than long (Table 6), widest behind middle, finely microreticulate with dense rasp-like punctures; anterior margin slightly produced in middle, margination complete, anterior angles rounded; lateral carinae rounded in dorsal aspect and very slightly concave in lateral aspect, margination inapparent but complete; posterior angles obtuse and rounded in lateral aspect. Prosternal process obliterated. Scutellar shield triangular, with rasp-like setiferous punctures. Mesoventral process truncate at apex, as wide as mesotibia. Metaventral discrimen distinct, reaching shortly before middle. Metanepisternite rather wide, with lateral margin concave and mesal margin straight.
Elytra moderately convex, about twice as long as combined width (Table 6), widest around end of anterior one-third, moderately narrowed, with lateral carinae convergent behind middle (Fig. 1A); apices separately rounded; surface with rasp-like, setiferous punctures, and with fine microreticulation consisting of transverse, undulate lines.
Protibiae straight, in males expanded basally and sometimes with few extended setae; mesotibiae slightly bent medially; metatibiae with short apical ridge and 3–5 short lateral ridges parallel to apical tibial margin, reaching ca. one-quarter of tibial width, subequal in length except the last one usually shorter, sometimes inapparent; metatibial spurs yellowish with black apices, outer one ca. 0.60 times as long as inner one. Protarsi slightly longer than protibiae, first protarsomere slightly longer than following two segments combined, penultimate protarsomere distinctly longer than wide, with anterior margin slightly concave, claws tridentate; mesotarsi ca. 1.30 times as long as mesotibiae; metatarsomere 1 with 3–5 ridges, metatarsomere 2 with two ridges, metatarsomere 3 without ridges.
Pygidium moderately long, conical, narrowly truncate at apex (Fig. 1A), about half as long as elytra (Table 6) and about twice as long as ventrite 5. Ventrite 5 with apical margin convex. Sternite VIII in males ca. twice as long as wide, setose apically, with lateral margins convergent and evenly rounded, apex rounded (Fig. 5C); in females ca. 1.60 times longer than wide, setose apico-laterally, with apex shallowly concave, spiculum ventrale narrowly clavate (Fig. 5D). Sternite IX in males slender, arrow shaped. Phallobase moderately long, ca. 0.40 times as long as elytra, with distal arms ca. 2.80 times as long as tubular part. Median lobe long and slender, almost as long as elytra, with apex slightly expanded and pointed. Dimensions of parameres are provided in Table 1. Right paramere (Fig. 5F,G) with basal part distinctly shorter than distal processes; ventral process subequal in length to dorsal process and curved dorsally with pointed apex; dorsal process rather narrow, expanded, and rounded apically, setose. Left paramere (Fig. 5F,G) with basal part slightly shorter to slightly longer than dorsal process and setose dorso-medially; ventral process narrowly rounded at apex; dorsal process wide, obliquely truncate, and setose apically; medial process small. Ovipositor short and wide (Fig. 5E), slightly sclerotised except for baculi; paraprocts distinctly shorter than gonocoxites, with heavily sclerotised baculi and several trichoid sensilla dorso-laterally; proctiger short, truncate at apex, with sclerotised baculi; gonocoxite entire, with sclerotised, oblique baculi, setose apico-laterally; gonostyli cylindrical, attached before apices of gonocoxites, with three trichoid sensilla at apex. Proximal portion of vagina spirally twisted (Fig. 5E).
Sexual dimorphism. Females generally larger than males, with elytra somewhat wider in proportion to length (Table 6). Protibiae in males slightly expanded basally, sometimes with several extended setae; in females not expanded and without longer setae. Terminal maxillary palpomere in males wider than in females (Fig. 5A,B).
Variability. The individual variability is, besides the dimensions (Table 6), most strongly pronounced in the colouration of the pubescence, which may be pale yellowish on most of the dorsal surfaces or darkened to various extent in posterior portions of pronotum and elytra or entirely brownish. The number of lateral ridges on metatibiae varies from three to five and those on metatarsomere 1 also from three to five.
DNA sequences. Two DNA sequences of 568-bp CO1-gene fragment are deposited in GenBank and BOLD databases with accession numbers listed in Table 3.
Distribution. Albania, Algeria, Austria, Croatia, Italy, France, Germany, Greece, Morocco, Spain, Switzerland, and Tunisia.
Natural history. The adults were collected on the xeric Mediterranean grasslands (Fig. 7A) and ruderal vegetation on the flowers of Apiaceae plants. The larva is not known.
Mordellistena (s. str.) pseudorhenana Ermisch, 1977, status restituted
Mordellistena (s. str.) pseudorhenana Ermisch, 1977: 164 [original description as part of identification key, type locality: Érd, Hungary, first report from Hungary, Croatia, Bulgaria, and Macedonia]; Kaszab (Reference Kaszab1979: 41–42, Fig. 21C) [identification key, figures]; Batten (Reference Batten1980: 43) [synonymised with M. minima, description of M. nessebarica Batten, 1980 based on paratypes of M. pseudorhenana from Bulgaria].
Mordellistena (s. str.) minima: Ermisch (Reference Ermisch1963: 61–62) [first report from Cyprus]; Batten (Reference Batten1976: 167, 169, Fig. 5) [localities, first report from France and Spain, figure]; Batten (Reference Batten1977: 172–175, Figs. 20, 26) [figures, identification key, localities]; Odnosum (Reference Odnosum1992: 523, Pl. 251, Figs. 5–6) [identification key, figures, first report from Russian Far East]; Odnosum (Reference Odnosum1993: 24–26, Pl. 3, Fig. 26) [identification key, figure, first report from Ukraine]; Odnosum (Reference Odnosum2003: 36, 40, 46, Pl. 4, Fig. 5) [identification key, figures, first report from Kyrgyzstan]; Odnosum (Reference Odnosum2005: 95–108, Figs. 19, 45, 110) [identification key, figures, localities]; Horák (Reference Horák2008: 99) [catalogue, first report from Azerbaijan, Bulgaria, Greece, Israel, Turkey]; Odnosum (Reference Odnosum2010: 154, 195–197, Fig. 76) [identification key, description, figure, first report from Jordan]; Ruzzier (Reference Ruzzier2013: 108) [localities]; Horák (Reference Horák2020: 96) [catalogue, first report from Slovakia].
Mordellistena sajoi Ermisch, 1977: 165 new synonymy [original description as part of identification key, type locality: Őrszentmiklós, Nyáras [Őrbottyán, Hungary]]; Kaszab (Reference Kaszab1979: 45) [identification key].
Type locality. Érd, Hungary.
Type material examined: Holotype of M. pseudorhenana , HNHM, male, labelled: “♂ | Genitalpräparat | Érd Csiki | Coll. E. Csiki | Mordellistena nana Motsch. [handwritten] | Typus [red label] | pseudorhenana [handwritten] | Holotypus 1978 Mordellistena pseudorhenana Ermisch [handwritten, white label with red margins] | Mordellistena minima Costa det R. Batten 1977”. A photograph of the holotype is available on Flickr (Selnekovič Reference Selnekovič2020). Paratype of M. pseudorhenana , HNHM, female, labelled: “Lesina [Hvar island] 1914 Horváth”. Holotype of M. sajoi , HNHM, female, labelled: “Örszentmiklós Nyáras, Sajó | Holotypus 1978 Mordellistena sajoi Ermisch [handwritten; white label with red margins] | Staatl. Museum für Tierkunde. Dresden | MORDELLISTENA (s. str.) MINIMA Costa J. Horák det. 2017 | Mordellistena (s. str.) pseudorhenana Ermisch, 1977 D. Selnekovič det. 2020”. A photograph of the holotype is available on Flickr (Selnekovič Reference Selnekovič2020).
Additional material examined: Bosnia and Herzegovina: 1 ♂, Mostar env., in collection as M. minima (HNHM). Bulgaria: 3 ♂♂, 3 ♀♀, Kiten, 42° 13′ 47″ N, 27° 46′ 20″ E, 10 m a.s.l., 26.vii.2014, D. Selnekovič leg., ruderal vegetation, on flowers of Daucus carota (DSBS DS-37 to DS-42); 5 ♂♂, 1 ♀, Lilyanovo env., 41° 36′ 39″ N, 23° 18′ 36″ E, 460 m a.s.l., 26.vi.2015, D. Selnekovič, dry grassland (DSBS DS-51 to DS-56); 2 ♂♂, 1 ♀, Lilyanovo env., 41° 37′ 23″ N, 23° 19′ 41″ E, 570 m a.s.l., 26.vi.2015, D. Selnekovič (DSBS DS-57 to DS-59); 6 ♂♂, 2 ♀♀, Melnik env., 41° 30′ 43″ N, 23° 22′ 46″ E, 335 m a.s.l., 27.vi.2015, D. Selnekovič, dry grassland, on flowers of Daucus carota (DSBS DS-43 to DS-50); 5 ♂♂, 1 ♀, Rozhen env., 41° 31′ 51″ N, 23° 25′ 23″ E, 630 m a.s.l., 25.vii.2018, D. Selnekovič & Z. Peczová leg., xeric sandy steppe (DSBS DSBS_6 to DSBS_8 and DS-148 to DS-150). Croatia: 1 ♂, “Curzola” [Korčula island], 1914, Horváth leg., in collection as M. minima (HNHM); 2 ♂♂, Dubrovnik, Lokrum island, 2.viii.1958, Endrödy-Younga leg., in collection as M. minima (HNHM); 2 ♂♂, Dubrovnik, 16.viii.1967, S. Horvatovich leg., “Meeresküste” [seashore], in collection as M. minima (HNHM); 1 ♂, 3 ♀♀, Jablanac, 27–28.vii.1969, S. Horvatovich leg., in collection as M. minima (HNHM). Cyprus: 1 ♂, 1 ♀, Larnaka, Glaszner leg., R. Batten identified as M. grisea Mulsant, 1856 in 1979 (HNHM); 24 ♂♂, 7 ♀♀; Limassol, Germasogeia reservoir, 34° 45′ 19″ N, 33° 05′ 36″ E, 80 m a.s.l., 27.iv.2018, D. Selnekovič leg., dry grassland, on flowers of Apiaceae (DSBS DS-73 to DS-84, DS-112 to DS-113, DS-170 to DS-180, DSBS_9, DSBS_10, DSBS_12 to DSBS_14). Israel: 1 ♂, Jerusalem, Reitter leg., in collection as M. minima (HNHM DS-187). Italy: 4 ♂♂, 1 ♀, Ischia Island, Serrara env., 40° 42′ 60″ N, 13° 53′ 11″ E, 517 m a.s.l., 29.vi.2019, D. Selnekovič leg., ruderal vegetation, on flowers of Daucus (DSBS DS-169, DSBS_51 to DSBS_54); 6 ♂♂, 2 ♀♀, Ischia Island, Serrara env., 40° 43′ 17″ N, 13° 52′ 59″ E, 550 m a.s.l., 30.vi.2019, D. Selnekovič leg., dry grassland, on flowers of Daucus (DSBS DS-116 to DS-118, DS-181 to DS-185). Montenegro: 1 ♂, 1 ♀, Sutorman, Apfelbeck leg., in collection as M. minima (HNHM); 1 ♀, Zelenika, viii.1906, Horváth leg. (HNHM); 1 ♂, 1 ♀, Budva, 9.vii.1958, Kaszab & Székessy leg. (HNHM); 2 ♂♂, 3 ♀♀, Bar, 42° 06′ N, 19° 06′ E, 19.vii.2011, D. Selnekovič leg., ruderal vegetation, on flowers of Daucus carota (DSBS DS-12 to DS-16); 2 ♂♂, 2 ♀♀, Bar, Stari Bar, 42° 05′ 31″ N, 19° 07′ 58″ E, 120 m a.s.l., 19.vi.2011, D. Selnekovič leg. (DSBS DS-22 to DS-25); 2 ♂♂, 1 ♀, Bar, Volujica hill, 42° 04′ 16″ N, 19° 06′ 10″ E, 110 m a.s.l., 20.vi.2011, D. Selnekovič leg., dry grassland (DSBS DS-26 to DS-28); 3 ♂♂, 3 ♀♀, Virpazar env., 42° 14′ 40″ N, 19° 05′ 36″ E, 30 m a.s.l., 21.vi.2011, D. Selnekovič leg. (DSBS DS-29 to DS-34); 3 ♂♂, 2 ♀♀, Bar, Ribnyak monastery env., 42.13222° N, 19.12583° E, 215 m a.s.l., 22.vi.2011, D. Selnekovič leg., dry grassland, on flowers of Helichrysum (DSBS DS-17 to DS-21). Slovakia: 6 ♂♂, 3 ♀♀, Bratislava, Lamač, 48° 11′ 20″ N, 17° 03′ 30″ E, ca. 280 m a.s.l., 15.vii.2008, O. Šauša leg. (DSBS DS-02 to DS-10); 1 ♂, Rajecké Teplice env., 4.vii.2009, O. Šauša leg. (DSBS DS-01); 1 ♀, Štúrovo env., Vŕšok NR, 47° 49′ 10.0″ N, 18° 39′ 28.4″ E, 190 m a.s.l., 10.vi.2011, D. Selnekovič leg., Pannonian steppe (DSBS DS-11); 1 ♀, Bratislava, Ostrov Kopáč NR, 48° 06′ 04″ N, 17° 09′ 34″ E, 130 m a.s.l., 7.viii.2011, D. Selnekovič leg., Pannonian steppe (DSBS DS-35); 1 ♀, Hajnačka env., Tilič hill, 48° 12′ 28″ N, 19° 55′ 53″ E, 450 m a.s.l., 13.vii.2013, D. Selnekovič leg., dry steppe (DSBS DS-36); 1 ♀, Tvrdošovce env., 48° 05′ 30″ N, 18° 02′ 03″ E, 110 m a.s.l., 23.vii.2015, D. Selnekovič leg., ruderal vegetation along field margin (DSBS DS-60); 6 ♂♂, 5 ♀♀, Tvrdošovce env., 48° 06′ 01″ N, 18° 01′ 59″ E, 110 m a.s.l., 26.vii.2016, D. Selnekovič leg., salt marsh (DSBS DS-61 to DS-71); 24 ♂♂, 18 ♀♀, Chotín env., 47° 48′ 28″ N, 18° 11′ 53″ E, 106 m a.s.l., 12–18.vii.2017, D. Selnekovič leg., ruderal vegetation (DSBS DS-85 to DS-111, DS-123 to DS-137); 3 ♂♂, 1 ♀, Chotín env., 47° 48′ 28″ N, 18° 11′ 53″ E, 106 m a.s.l., 20.vi.2019, D. Selnekovič leg., ruderal vegetation (DSBS DSBS_43 to DSBS_46); 1 ♀, Virt env., 47° 45′ 35″ N, 18° 20′ 21″ E, 115 m a.s.l., 10.viii.2017, D. Selnekovič leg., ruderal vegetation along field margin, on flowers of Daucus carota (DSBS DS-72); 2 ♂♂, Virt env., 47° 45′ 36″ N, 18° 20′ 26″ E, 110 m a.s.l., 9.vii.2019, D. Selnekovič leg., ruderal vegetation along field margin, on flowers of Daucus carota (DSBS DSBS_59, DSBS_62); 1 ♀, Virt env., Mašan NR, 47° 46′ 10″ N, 18° 19′ 09″ E, 120 m a.s.l., 30.vii.2019, D. Selnekovič leg., sandy steppe, on flowers of Seseli (DSBS DS-122); 1 ♂, Iža env., Bokroš salt marsh NR, 47° 44′ 53″ N, 18° 15′ 38″ E, 107 m a.s.l., 29.vii.2019, D. Selnekovič leg., grazed salt marsh, on flowers of Daucus carota (DSBS DS-120). Slovenia: 3 ♂♂, Drežnica, Apfelbeck leg., in collection as M. minima (HNHM). Switzerland: 1 ♀, “Helvetia”, in collection as M. perroudi (SDEI Col-11369). Turkey: 1 ♂, 1 ♀, Istanbul, 20.vi.1925, Biró leg., in collection as M. minima (HNHM DS-186). Ukraine: 2 ♀♀, Krim, Alusta, 18.vi.1956, L. Horváth leg., in collection as M. minima (HNHM).
Differential diagnosis. Mordellistena pseudorhenana can be characterised by the following combination of characters: (1) body including mouthparts, antennae, and legs black (Fig. 1B); (2) pubescence on dorsal surfaces yellowish or pale brownish with purple sheen; (3) galea long, apically pointed (Fig. 6A); (4) antennomeres 5–10 ca. 1.20–1.30 times longer than wide; (5) protibiae in males expanded basally, with distinct clusters of extended setae; (6) metatibiae with three lateral ridges, the second one being the longest and the third one usually the shortest; (7) abdominal sternite VIII in males 1.50–1.60 times longer than wide, with ca. parallel lateral margins (Fig. 6C); in females, apically produced and rounded, with spiculum ventrale narrowly clavate (Fig. 6C); and (8) parameres and ovipositor as in Figure 6E,F,G.
Based on the morphology, the species can be assigned to the M. confinis species group as defined by Ermisch (Reference Ermisch1956). From other members of the group, it can be differentiated based on the long and pointed galea (Fig. 6A), in combination with short antennomeres 5–10, expanded protibiae with distinct clusters of extended setae in males, and completely black-coloured body. Such form of galea is also present in M. grisea Mulsant, 1856 (sensu Batten Reference Batten1977), but it can be differentiated from M. pseudorhenana by its protibiae not being expanded in males and by parameres of different shape.
Redescription. Body slender, wedge-shaped, widest at proximal one-half of elytra, dorsum moderately convex, venter strongly so (Fig. 1B). Metric characters are provided in Tables 1 and 6. Colour of almost all surfaces uniformly black with fine bluish sheen; anterior margin of frontoclypeus, mandibles, lacinia, galea, and labium, including palpi, brownish. Vestiture consisting of dense, decumbent, dorso-ventrally flattened setae; colour uniformly light-yellowish on head and sternal thoracic parts; in anterior one-half of pronotum light-yellowish and slightly darkened postero-medially; in antero-lateral portions of elytra light-yellowish and gradually darkened postero-medially to completely black in apical portions; on femora and proximal portions of tibiae light-yellowish and gradually darkened distally; on abdominal ventrites 1–2 light-yellowish, gradually darkened on following ventrites to entirely black on ventrite 5 and pygidium; vestiture on elytra with strong purple sheen.
Head moderately convex dorsally; anterior margin of frontoclypeus straight; occipital carina evenly rounded in dorsal view, straight to slightly concave in posterior view; tempora absent; dorsal surface very finely microreticulated, with minute, round setiferous punctures. Labrum transverse, microreticulate, with setiferous punctures, exposed portion ca. 2.50 times wider than long, anterior margin and antero-lateral angles rounded. Eyes broadly oval, ca. 1.40 times longer than wide, not extending onto ventral surfaces, finely faceted with distinctly apparent interfacetal setae. Antennae moderately long, feebly serrate (Fig. 1B); scapus and pedicel cylindrical, subequal; antennomeres 3–4 slightly shorter than previous and distinctly shorter than following, subequal; antennomeres 5–10 subequal, in males ca. 1.20–1.30 times and in females ca. 1.10 times longer than wide; antennomere 11 oval, ca. 1.80 times longer than wide. Mandibles symmetrical except in molar parts, bidentate, with lateral exposed portion setose; mola denticulate; prostheca with thin, medially oriented setae. Maxilla as in Figure 6A,B; galea almost as long as maxillary palp, pointed at apex, densely covered with trichoid and distally expanded, spoon-like sensilla; lacinia with trichoid sensilla arranged in longitudinal row and scattered in apical portions; palpifer subcylindrical, setose antero-laterally; maxillary palpomere 1 short, setose ventrally; maxillary palpomere 2 cylindrical, widened apically, in males wider than in females; maxillary palpomere 3 short, widened apically; maxillary palpomere 4 securiform, ca. 2.40 times longer than wide, with inner angle situated behind middle; maxillary palpomeres 2–3 in males with very long setae on ventral surfaces. Terminal labial palpomere broadly fusiform.
Pronotum convex, slightly transverse (Table 6), widest around middle; anterior margin slightly produced in middle, anterior margination complete, anterior angles rounded; lateral carinae rounded in dorsal aspect, slightly concave in lateral aspect, lateral margination inapparent but complete; posterior angles slightly obtuse, narrowly rounded; surface finely microreticulate, with rasp-like setiferous punctures. Hypomeron with large concavity for reception of procoxae. Prosternal process obliterated. Scutellar shield triangular, punctuate, and setose. Mesoventral process as wide at apex as mesotibia, truncate. Metaventral discrimen inapparent. Metanepisternite with exposed portion rather wide, distally narrowed; lateral margin concave, mesal margin straight.
Elytra moderately convex, evenly and strongly narrowed posteriorly, widest at end of first one-quarter, EL/EW ratio in Table 6; lateral carinae rounded, strongly convergent behind first one-quarter (Fig. 1B); apices separately rounded; surface with fine microreticulation formed by transverse, undulate lines and with rasp-like setiferous punctures.
Protibiae straight, distinctly dilated basally and with fringe of long, medially oriented setae in males; mesotibiae slightly bent medially; metatibiae with one apical and three lateral ridges parallel to apical tibial margin; second lateral ridge is usually distinctly longer than first one, not reaching beyond one-half of tibial width; third lateral ridge often short and inapparent; metatibial spurs black, outer one ca. 0.70 times as long as inner one. Protarsi about as long as protibiae, protarsomere 1 as long as following two tarsomeres combined; protarsomere 4 distinctly longer than wide with anterior margin slightly concave; protarsal claws tridentate; mesotarsi ca. 1.30 times as long as mesotibiae; metatarsomere 1 with three ridges, metatarsomere 2 with two ridges, metatarsomere 3 without ridges.
Pygidium moderately long (Table 6), slightly bent ventrally in lateral aspect, about twice as long as ventrite 5. Ventrite 5 with apical margin rounded. Sternite VIII in males ca. 1.50–1.60 times longer than wide, setose apically, with lateral margins slightly convergent, postero-lateral angles distinct, rounded, apical margin slightly sinuated in middle (Fig. 6C); in females, ca. 1.50–1.60 times longer than wide, setose apico-laterally, strongly produced and narrowly rounded apically, with basal margin broadly concave, spiculum ventrale narrowly clavate (Fig. 6D). Sternite IX in males slender, arrow-shaped. Phallobase long, ca. 0.60 times as long as elytra, with distal arms ca. 4.00 times as long as tubular part. Median lobe very long and narrow, ca. 1.20 times as long as elytra, slightly expanded, and pointed apically. Dimensions of parameres as in Table 1. Right paramere (Fig. 6E,F) with basal part subequal to distinctly longer than the branches, setose dorso-medially; ventral branch shorter than dorsal one, slightly bent dorsally; dorsal branch wide, setose, rounded apically. Left paramere (Fig. 6E,G) with basal part about as long as dorsal branch, setose dorso-medially; ventral branch rather long, narrowly rounded apically; dorsal branch setose, moderately expanded, and obliquely truncate apically; medial process large, bent ventrally. Ovipositor (Fig. 6G) slightly sclerotised except for baculi; paraprocts slightly shorter than gonocoxites, with narrow, heavily sclerotised baculi; proctiger rather long with heavily sclerotised baculi, with apical margin sinuate; gonocoxites rather long and narrow, not divided, setose, with heavily sclerotised, oblique baculi; gonostyli cylindrical, attached well before apices of gonocoxites, bearing three trichoid sensilla at apices.
Sexual dimorphism. Antennomeres 5–10 in males slightly longer, ca. 1.20–1.30 times longer than wide, whereas in females they are ca. 1.10 times longer than wide. Maxillary palpomeres 1–3 in males bearing very long setae on the ventral surface; palpomeres 2 and 4 in males wider than in females (Fig. 6 A,B). Protibiae in males basally expanded, with group of longer, medially oriented setae; in females, simple, without extended setae.
Variability. The colour of pubescence on the dorsal surfaces varies from pale yellowish to darkened to various extents in posterior portions of pronotum and elytra to completely brownish. Rather distinct differences can be found in the shape and dimensions of the parameres between the morphotype 1 represented by holotype plus all the examined male specimens from Europe and the morphotype 2 represented by male specimens from Cyprus, Israel, and Turkey (Figs. 2, 3, 6 E,F; Table 1; Supplementary material, Table S1). The specimens of morphotype 2 have their parameres longer (Table 1), with the basal part of the right paramere longer and the dorsal process of the left paramere longer and narrower than in the morphotype 1 (Fig. 6 E,F). The barcoding region of CO1 gene shows very small differences between the representatives of the two morphotypes (0.18–1.43%; Table 5).
DNA sequences. Eighteen DNA sequences of the 568-bp CO1 gene fragment are deposited in GenBank and BOLD databases, with accession numbers listed in Table 3.
Distribution. Azerbaijan, Bosnia and Herzegovina (first record), Bulgaria, Croatia, Cyprus, France, Greece, Hungary, Italy, Israel, Jordan, Kyrgyzstan, Macedonia, Montenegro (first record), Slovakia, Slovenia (first record), Spain, Switzerland (first record), Turkey, and Ukraine. Horák (Reference Horák2008, Reference Horák2020) reports this species from the former Yugoslavia (present Serbia and Montenegro) without specifying the country. The report from Russian Far East by Odnosum (Reference Odnosum1992) is probably based on misidentification. Mordellistena pseudorhenana is reported here for the first time from Bosnia and Herzegovina, Montenegro, Slovenia, and Switzerland.
Natural history. The adults were found on the flowers of herbaceous plants, for example, Daucus carota Linnaeus, Seseli sp. (Apiaceae), Galium sp. (Rubiaceae), and Helichrysum sp. Miller (Asteraceae), in various grassland and ruderal habitats (Fig. 7) from June to August in altitudes 10–630 m above sea level. The larva of M. pseudorhenana is not known. The first author’s efforts to obtain and rear larvae from the stems of Cirsium arvense (Linnaeus), Centaurea sp. (Asteraceae), and Daucus carota Linnaeus (Apiaceae) collected from two localities – Chotín (Fig. 7C) and Tvrdošovce, Slovakia – with abundant populations of the species were unsuccessful.
Remarks. Mordellistena sajoi Ermisch, 1977 was briefly described in the identification key based on a single female specimen. The re-examination of the holotype revealed it is conspecific with M. pseudorhenana, and we consider it a new junior subjective synonym of the latter.
Discussion
Revision of the type material is of great importance for future research in the European Mordellidae. Results of our recent studies show that re-examination of type material can reveal surprising findings regarding the identity and status of the taxa, including the common and widespread species (Horák Reference Horák1990, Reference Horák1996; Selnekovič and Kodada Reference Selnekovič and Kodada2019; Selnekovič and Improta Reference Selnekovič and Improta2020). Naturally, searching for and obtaining the type material from museum collections can complicate the taxonomic work, especially when specimens cannot be found – for example, much of E. Mulsant’s material. However, once the type specimens are documented and the species are redescribed and properly delimited based on morphological and molecular markers, modern identification methods such as DNA barcoding allow easier recognition of the species and can provide the basis for further studies in different fields, such as ecology, phylogeography, or development.
We used DNA barcodes for the first time to examine the genetic divergences between European Mordellidae species and to interpret the morphological variability observed in M. pseudorhenana. We were able to provide the DNA barcodes of CO1 gene fragments conventionally used for species identification from five species of the Mordellistena confinis species group with revised and documented type material (Horák Reference Horák1996; Selnekovič and Kodada Reference Selnekovič and Kodada2019). The species showed wide genetic divergence even between morphologically similar species – for example, M. minima and M. lindbergi (19.3%), and M. hirtipes and M. purpurascens (13.8%; Table 4) – corresponding to results in other beetle groups (e.g., Raupach et al. Reference Raupach, Astrin, Hannig, Peters, Stoeckle and Wägele2010; Pentinsaari et al. Reference Pentinsaari, Hebert and Mutanen2014). In contrast to high divergence between species, the mean intraspecific divergences were considerably less, up to 1.9% in M. hirtipes. The incongruence between morphological and molecular evidence appeared in M. pseudorhenana. Based on the differences in the shape and dimensions of parameres, we were able to identify two distinct morphotypes (Figs. 2, 3A, 6E,F; Table 1). To help us with the interpretation of such differences in morphology, we compared the intra- and interspecific Kimura 2-parameter divergences. Although no universal threshold exists for separating species based on the genetic divergences, the comparison of intra- and interspecific distances with the presence of a distinct genetic gap proved to be useful for species separation in beetles (e.g., Raupach et al. Reference Raupach, Astrin, Hannig, Peters, Stoeckle and Wägele2010; Woodcock et al. Reference Woodcock, Boyle, Roughley, Kevan, Labbee and Smith2013; Pentinsaari et al. Reference Pentinsaari, Hebert and Mutanen2014). The highest intraspecific Kimura 2-parameter distance within M. pseudorhenana (1.4%) was 11.8 times less than the smallest interspecific distance between M. pseudorhenana and M. lindbergi (16.8%). Furthermore, the intraspecific Kimura 2-parameter distances within M. pseudorhenana ranged from 0.2 to 1.4%, with no distinct gap. Such low genetic divergence between the two morphotypes does not provide evidence for establishing the morphotypes as separate species.
The discrepancy between the morphological and molecular evidence opens the discussion about the efficiency of using the conventional DNA barcoding marker (CO1) for testing the taxonomic boundaries and verifying the status of the species within the family Mordellidae. It also raises questions about the validity of species that have been defined by rather weak morphological differences. The broader datasets, a combination of multiple genes, and the use of more advanced tools in molecular taxonomy such as character-based DNA barcoding should yield more insights into the taxonomy of this problematic group.
Acknowledgements
The authors thank Ottó Merkl (Hungarian Natural History Museum), Brend Jäger (Museum für Naturkunde, Humboldt-Universität zu Berlin), and Mandy Schröter (Senckenberg Deutsches Entomologisches Institut) for providing access to museal collections and landing the material. The authors thank Jan Horák, Michal Šagát, and two anonymous reviewers for their valuable comments and suggestions. The present study was supported by the Slovak Research and Development Agency under the contract No. APVV-19-0076 and by the European Commission programme LIFE12 NAT/SK/001137: BeeSandFish, action D1.
Supplementary material
To view supplementary material for this article, please visit https://doi.org/10.4039/tce.2021.3.