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Abstract The darkling beetle tribe Adesmiini (Tenebrionidae: Pimeliinae) is a prominent part of African and western Palearctic desert faunas, with most species being day-active fast-running detritivores. Taxonomic diversity within the tribe is highest in the southern Afrotropical realm (where all genera are present); only 1 genus, the species-rich Adesmia, occurs north of the Sahara. Despite notable species, such as the fog-basking beetle Onymacris unguicularis (a focal taxon in desert ecological research), Adesmiini has undergone few modern taxonomic or phylogenetic studies. Hence, generic concepts and pronounced diurnal activity, rare in the primarily nocturnal family Tenebrionidae, remain poorly explored. To investigate evolutionary relationships and diurnal origins within the tribe, we generated a genomic dataset of 529 protein-coding genes across 43 species spanning 10 of 11 Adesmiini genera. Our resulting phylogeny for the tribe rejects the monophyly of 5 currently recognized Adesmiini genera (i.e., Adesmia, Metriopus, Onymacris, Physadesmia, and Stenocara). Ancestral state reconstruction of diurnal activity using eye shape as a proxy supports the hypothesis that Adesmiini were primitively diurnal, followed by at least 4 shifts to nocturnal or crepuscular activity. 

Blapstinus Dejean is the most taxonomically challenging genus within Blapstinina Mulsant & Rey (Tenebrionidae: Opatrini). With over 120 species, it is widely distributed throughout the Americas, with representatives reaching Canada on the northern range edge, and Argentina, Chile, and Uruguay in the south. Traditionally, Blapstinus has been distinguished from other blapstinoid beetles via well-developed metathoracic wings and their lack of synapomorphies present in other genera; however, fused and tapering aedeagal parameres were recently introduced as a potential autapomorphy for the genus. This study used molecular data (nuclear ribosomal 28S, cytochrome oxidase subunit II (COII), arginine kinase (ArgK), carbomyl-phosphate synthetase domain of rudimentary (CAD), and wingless (wg)) to investigate the phylogenetic placement and taxonomic status of three Blapstinus species with distinct male genitalic morphology, i.e. Blapstinus tibialis Champion (USA), B. grandis Champion (Mexico, Nicaragua), and B. punctulatus Solier (Argentina, Bolivia, Brazil, Chile, Uruguay). Analyses highlight the phylogenetic informativeness of the aedeagal morphology within the subtribe, and support an urgent need for taxonomic studies of South American taxa. Blapstinus tibialis and B. grandis were recovered as a specific lineage within Blapstinus that can be easily distinguished from remaining congeners by having tridentate parameres. A lectotype for B. grandis is designated to fix the taxonomic status of this species. Blapstinus punctulatus was recovered outside of its current genus which, along with aedeagal morphology, supports a change of status of the species. As a result, the following synonymy and combinations are introduced: Lodinus Mulsant and Rey stat. restit. (=Austrocaribius Marcuzzi syn. nov.), Lodinus araguae (Marcuzzi) comb. et stat. nov., L. punctulatus comb. nov., L. venezuelensis (Marcuzzi) comb. nov. Lectotypes for Lodinus nigroaeneus Mulsant and Rey, L. araguae, and L. punctulatus are designated to fix the taxonomic status of these species. 

This catalogue includes all valid family-group (six subtribes), genus-group (55 genera, 33 subgenera), and species-group names (1009 species and subspecies) of Sepidiini darkling beetles (Coleoptera: Tenebrionidae: Pimeliinae), and their available synonyms. For each name, the author, year, and page number of the description are provided, with additional information (e.g., type species for genus-group names, author of synonymies for invalid taxa, notes) depending on the taxon rank. Verified distributional records (loci typici and data acquired from revisionary publications) for all the species are gathered. Distribution of the subtribes is illustrated and discussed. Several new nomenclatural acts are included. The generic names Phanerotomea Koch, 1958 [= Ocnodes Fåhraeus, 1870] and Parmularia Koch, 1955 [= Psammodes Kirby, 1819] are new synonyms (valid names in square brackets). The following new combinations are proposed: Ocnodesacuductusacuductus (Ancey, 1883), O. acuductusufipanus (Koch, 1952), O. adamantinus (Koch, 1952), O. argenteofasciatus (Koch, 1953), O. arnoldiarnoldi (Koch, 1952), O. arnoldisabianus (Koch, 1952), O.barbosai (Koch, 1952), O.basilewskyi (Koch, 1952), O.bellmarleyi (Koch, 1952), O. benguelensis (Koch, 1952), O. bertolonii (Guérin-Méneville, 1844), O. blandus (Koch, 1952), O. brevicornis (Haag-Rutenberg, 1875), O. brunnescensbrunnescens (Haag-Rutenberg, 1871), O. brunnescensmolestus (Haag-Rutenberg, 1875), O. buccinator (Koch, 1952), O. bushmanicus (Koch, 1952), O. carbonarius (Gerstaecker, 1854), O. cardiopterus (Fairmaire, 1888), O. cataractus (Koch, 1952), O. cinerarius (Koch, 1952), O. complanatus (Koch, 1952), O. confertus (Koch, 1952), O. congruens (Péringuey, 1899), O. cordiventris (Haag-Rutenberg, 1871), O. crocodilinus (Koch, 1952), O. dimorphus (Koch, 1952), O. distinctus (Haag-Rutenberg, 1871), O. dolosus (Péringuey, 1899), O. dorsocostatus (Gebien, 1910), O. dubiosus (Péringuey, 1899), O. ejectus (Koch, 1952), O. epronoticus (Koch, 1952), O. erichsoni (Haag-Rutenberg, 1871), O. ferreiraeferreirae (Koch, 1952), O. ferreiraezulu (Koch, 1952), O. fettingi (Haag-Rutenberg, 1875), O. fistucans (Koch, 1952), O. fraternus (Haag-Rutenberg, 1875), O. freyi (Koch, 1952), O. freudei (Koch, 1952), O. fulgidus (Koch, 1952), O. funestus (Haag-Rutenberg, 1871), O. gemmeulus (Koch, 1952), O. gibberosulus (Péringuey, 1908), O. gibbus (Haag-Rutenberg, 1879), O. globosus (Haag-Rutenberg, 1871), O. granisterna (Koch, 1952), O. granulosicollis (Haag-Rutenberg, 1871), O.gridellii (Koch, 1960), O. gueriniguerini (Haag-Rutenberg, 1871), O. guerinilawrencii (Koch, 1954), O. guerinimancus (Koch 1954), O. haemorrhoidalishaemorrhoidalis (Koch, 1952), O. haemorrhoidalissalubris (Koch, 1952), O. heydeni (Haag-Rutenberg, 1871), O. humeralis (Haag-Rutenberg, 1871), O. humerangula (Koch, 1952), O. imbricatus (Koch, 1952), O.imitatorimitator (Péringuey, 1899), O. imitatorinvadens (Koch, 1952), O. inflatus (Koch, 1952), O. janssensi (Koch, 1952), O. javeti (Haag-Rutenberg, 1871), O. junodi (Péringuey, 1899), O. kulzeri (Koch, 1952), O. lacustris (Koch, 1952), O. laevigatus (Olivier, 1795), O. lanceolatus (Koch, 1953), O. licitus (Peringey, 1899), O. luctuosus (Haag-Rutenberg, 1871), O. luxurosus (Koch, 1952), O. maputoensis (Koch, 1952), O. marginicollis (Koch, 1952), O. martinsi (Koch, 1952), O. melleus (Koch, 1952), O. mendicusestermanni (Koch, 1952), O. mendicusmendicus (Péringuey, 1899), O. miles (Péringuey, 1908), O. mimeticus (Koch, 1952), O. misolampoides (Fairmaire, 1888), O. mixtus (Haag-Rutenberg, 1871), O. monacha (Koch, 1952), O. montanus (Koch, 1952), O. mozambicus (Koch, 1952), O. muliebriscurtus (Koch, 1952), O. muliebrismuliebris (Koch, 1952), O. muliebrissilvestris (Koch, 1952), O. nervosus (Haag-Rutenberg, 1871), O.notatum (Thunberg, 1787), O. notaticollis (Koch, 1952), O. odorans (Koch, 1952), O. opacus (Solier, 1843), O. osbecki (Billberg, 1815), O. overlaeti (Koch, 1952), O. ovulus (Haag-Rutenberg, 1871), O. pachysomaornata (Koch, 1952), O. pachysomapachysoma (Péringuey, 1892), O. papillosus (Koch, 1952), O. pedator (Fairmaire, 1888), O. perlucidus (Koch, 1952), O. planus (Koch, 1952), O. pretorianus (Koch, 1952), O. procursus (Péringuey, 1899), O. protectus (Koch, 1952), O. punctatissimus (Koch, 1952), O. puncticollis (Koch, 1952), O. punctipennisplanisculptus (Koch, 1952), O. punctipennispunctipennis (Harold, 1878), O. punctipleura (Koch, 1952), O. rhodesianus (Koch, 1952), O. roriferus (Koch, 1952), O. rufipes (Harold, 1878), O. saltuarius (Koch, 1952), O.scabricollis (Gerstaecker, 1854), O. scopulipes (Koch, 1952), O. scrobicollisgriqua (Koch, 1952), O. scrobicollissimulans (Koch, 1952), O. semirasus (Koch, 1952), O. semiscabrum (Haag-Rutenberg, 1871), O. sericicollis (Koch, 1952), O.similis (Péringuey, 1899), O. sjoestedti (Gebien, 1910), O. spatulipes (Koch, 1952), O. specularis (Péringuey, 1899), O. spinigerus (Koch, 1952), O. stevensoni (Koch, 1952), O. tarsocnoides (Koch, 1952), O. temulentus (Koch, 1952), O. tenebrosusmelanarius (Haag-Rutenberg, 1871), O. tenebrosustenebrosus (Erichson, 1843), O. tibialis (Haag-Rutenberg, 1871), O. torosus (Koch, 1952), O. transversicollis (Haag-Rutenberg, 1879), O. tumidus (Haag-Rutenberg, 1871), O. umvumanus (Koch, 1952), O. vagus (Péringuey, 1899), O. vaticinus (Péringuey, 1899), O. verecundus (Péringuey, 1899), O. vetustus (Koch, 1952), O. vexator (Péringuey, 1899), O. virago (Koch, 1952), O. warmeloi (Koch, 1953), O. zanzibaricus (Haag-Rutenberg, 1875), Psammophanesantinorii (Gridelli, 1939), and P.mirei (Pierre, 1979). The type species [placed in square brackets] of the following genus-group taxa are designated for the first time, Ocnodes Fåhraeus, 1870 [ Ocnodesscrobicollis Fåhraeus, 1870], Psammodophysis Péringuey, 1899 [ Psammodophysisprobes Péringuey, 1899], and Trachynotidus Péringuey, 1899 [ Psammodesthoreyi Haag-Rutenberg, 1871]. A lectotype is designated for Histrionotusomercooperi Koch, 1955 in order to fix its taxonomic status. Ulamus Kamiński is introduced here as a replacement name for Echinotus Marwick, 1935 [ Type species. Aviculaechinata Smith, 1817] (Mollusca: Pteriidae) to avoid homonymy with Echinotus Solier, 1843 (Coleoptera: Tenebrionidae). 

Abstract The taxonomic concepts of Blapimorpha and Opatrinae (informal and traditional, morphology‐based groupings among darkling beetles) are tested using molecular phylogenetics and a reassessment of larval and adult morphology to address a major phylogeny‐classification gap in Tenebrionidae. Instead of a holistic approach (family‐level phylogeny), this study uses a bottom‐up strategy (tribal grouping) in order to define larger, monophyletic lineages within Tenebrioninae. Sampling included representatives of 27 tenebrionid tribes: Alleculini, Amarygmini, Amphidorini, Blaptini, Bolitophagini, Branchini, Cerenopini, Coniontini, Caenocrypticini, Dendarini, Eulabini, Helopini, Lagriini, Melanimini, Opatrini, Pedinini, Phaleriini, Physogasterini, Platynotini, Platyscelidini, Praociini, Scaurini, Scotobiini, Tenebrionini, Trachyscelini, Triboliini and Ulomini. Molecular analyses were based on DNA sequence data from four non‐overlapping gene regions: carbamoyl‐phosphate synthetase domain ofrudimentary(CAD) (723 bp),wingless(wg) (438 bp) and nuclear ribosomal 28S (1101 bp) and mitochondrial ribosomal 12S (363 bp). Additionally, 15 larval and imaginal characters were scored and subjected to an ancestral state reconstruction analysis. Results revealed that Amphidorini, Blaptini, Dendarini, Pedinini, Platynotini, Platyscelidini and Opatrini form a clade which can be defined by the following morphological features: adults—antennae lacking compound/stellate sensoria; procoxal cavities externally and internally closed, intersternal membrane of abdominal ventrites 3–5 visible; paired abdominal defensive glands present, elongate, not annulated; larvae—prolegs enlarged (adapted for digging); ninth tergite lacking urogomphi. To accommodate this monophyletic grouping (281 genera and ∼4000 species), the subfamily Blaptinaesens. nov.is resurrected. Prior to these results, all of the tribes within Blaptinae were classified within the polyphyletic subfamily Tenebrioninae. The non‐monophyletic nature of Terebrioninae has already been postulated by previous authors, yet no taxonomic decisions were made to fix its status. The reinstatement of Blaptinae, which groups ∼50% of the former Tenebrioninae, helps to clarify phylogenetic relations among the whole family and is the first step towards a complete higher‐level revision of Tenebrionidae. The Central Asian tribe Dissonomini (two genera, ∼30 species) was not included in Blaptinae due to a lack of representatives in the performed phylogenetic analyses; however, based on morphological features, the tribe is listed as a potential addition to the subfamily.