Mirolabrichthys Herre 1927

Mirolabrichthys + Nemanthias + Pyronotanthias + Anatolanthias + Luzonichthys + Rabaulichthy s + Tosana + Pseudanthias (in part) + Hemanthias + Choranthias . This relationship is supported by a single synapomorphy. Parapophyses on first caudal vertebrae . Plesiomorphically in anthiadine fishes, the t...

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Main Author:	Gill, Anthony C.
Format:	Text
Language:	unknown
Published:	Zenodo 2022
Subjects:	Biodiversity Taxonomy Animalia Chordata Actinopterygii Perciformes Serranidae Mirolabrichthys Pacific Ida Baldwin Nares St. Helena Kendall Randall Perez Rapa Lubbock Greenfield Rapa Nui Sakhalin
Online Access:	https://dx.doi.org/10.5281/zenodo.5883171 https://zenodo.org/record/5883171

id	ftdatacite:10.5281/zenodo.5883171
record_format	openpolar
institution	Open Polar
collection	DataCite Metadata Store (German National Library of Science and Technology)
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topic	Biodiversity Taxonomy Animalia Chordata Actinopterygii Perciformes Serranidae Mirolabrichthys
spellingShingle	Biodiversity Taxonomy Animalia Chordata Actinopterygii Perciformes Serranidae Mirolabrichthys Gill, Anthony C. Mirolabrichthys Herre 1927
topic_facet	Biodiversity Taxonomy Animalia Chordata Actinopterygii Perciformes Serranidae Mirolabrichthys
description	Mirolabrichthys + Nemanthias + Pyronotanthias + Anatolanthias + Luzonichthys + Rabaulichthy s + Tosana + Pseudanthias (in part) + Hemanthias + Choranthias . This relationship is supported by a single synapomorphy. Parapophyses on first caudal vertebrae . Plesiomorphically in anthiadine fishes, the terminal pair of parapophyses are on the terminal precaudal vertebra, which is identified from the adjacent first caudal vertebra in lacking a haemal spine (Fig. 7A). In contrast, the first caudal vertebra bears a pair of parapophyses in Mirolabrichthys (Fig. 7B), Nemanthias, Pyronotanthias , Anatolanthias, Luzonichthys, Rabaulichthys , Tosana , Hemanthias , Choranthias Anderson & Heemstra, 2012 and all but three species of Pseudanthias : P. hawaiiensis (Randall, 1979), P. ventralis (Randall, 1979) and P. hangapiko Shepherd, Pinheiro, Phelps, Pérez-Matus & Rocha, 2021. Preliminary molecular studies support exclusion of these three species from Pseudanthias (Gill et al. 2021a; L. Rocha, pers. comm.). This character was first noted by Baldwin (1990) and briefly reviewed by Pogonoski & Gill (2021). Pyronotanthias + Nemanthias + Anatolanthias + Luzonichthys + Rabaulichthys . A single character supports this relationship. Longest few pectoral-fin rays bearing serrated projections. W.F. Smith-Vaniz (in Randall & Lubbock 1981) noted that Pyronotanthias lori and P. smithvanizi have distinctive serrations on the distal parts of the longest few pectoral-fin rays. Randall & Pyle (2001) subsequently recorded this character in P. privitera (Randall & Pyle, 2001). This character also occurs in all examined species of Pyronotanthias . It otherwise occurs in all examined species of Nemanthias (Fig. 9), Anatolanthias, Luzonichthys and Rabaulichthys . However, this character may be more widely distributed, as it is possibly present in Pseudanthias kashiwae (Tanaka, 1918) (other related species in the P. cooperi complex not examined; A. mooreanus Herre, 1935 is likely a junior synonym of P. kashiwae ). In P. kashiwae , some of the longest few pectoral-fin rays have ridge-like expansions dorsally or ventrally, which sometimes bear a few weak serrations. Nemanthias + Anatolanthias + Luzonichthys + Rabaulichthys . Two characters support this relationship. High number of lateral-line scales . In their key to species of the subgenus Mirolabrichthys , Randall & Lubbock (1981) differentiated the five species here newly incorporated in Nemanthias from other species in the subgenus based on their relative high numbers of lateral-line scales and pectoral-fin rays (53–64 versus 41–56 and 18–22, rarely 18 versus 15–19, rarely 19, respectively). However, N. carberryi has an intermediate number of lateralline scales (50–56). Nonetheless, the counts for N. carberryi are relatively high for anthiadines. Among genera that appear closely related (e.g. with parapophyses on the first caudal vertebra), such high counts are found only in several species of Pseudanthias (notably P. caudalis Kamohara & Katayama, 1959 and P. thompsoni , which appear to be closely related to each other, as well as P. calloura Ida & Sakaue, 2001 (51–53 scales) and P. cooperi and relatives (collectively with 46–55 scales; Randall & Pyle, 2001)), and in species of Anatolanthias (62–64 lateral-line scales; gill arch characters not yet confirmed for the genus), Luzonichthys (51–78 lateral-line scales) and Rabaulichthys (51–59 lateral-line scales). High number of epineural bones. Anderson et al. (1990) had previously suggested a close relationship between Anatolanthias , Luzonichthys and Rabaulichthys on the basis of several derived features: anterior and posterior nares well separated from each other; vomerine dentition reduced or absent; sum of numbers of pairs of epipleural and epicaudal ribs 16–19. I identify the last-mentioned collectively as epineural bones, following the terminology of Johnson & Patterson (1993, 2001) and Patterson & Johnson (1995). Except for N. bicolor with 12 epineurals, Nemanthias also has relatively high numbers of epineurals (15–17; Table 4). Conflicting characters. The following characters have been used to diagnose Mirolabrichthys in the broad sense, or to suggest relationships within the genus. I here consider them to be homoplastic but acknowledge that they suggest relationships or generic classifications alternative to those proposed herein. Hypertrophied upper lip of males. Mirolabrichthys has been traditionally diagnosed by the presence in males of a hypertrophied upper lip. Randall & Lubbock (1981) noted that similar morphology was also found in Nemanthias carberryi . Hypertrophy of the upper lip is characteristic of all species included here in Mirolabrichthys , Nemanthias and Pyronotanthias , although it is variable in degree depending on species (Figs. 1, 8, 10). Similar morphology is not known in Anatolanthias , Luzonichthys or Rabaulichthys , which suggests conflict with the relationships implied by the above characters. Males of Pseudanthias flavicauda Randall & Pyle, 2001, P. pulcherrimus (Heemstra & Randall, 1986), P. randalli (Lubbock & Allen, 1978) and P. tequila Gill, Tea & Senou, 2017, have variously developed hypertrophy of the upper lip, which suggests a closer relationship of Mirolabrichthys , Nemanthias and Pyronotanthias with these species (and presumably also P. oumati Williams, Delrieu-Trottin & Planes, 2013, for which males are unknown, but which groups with P. randalli and P. pulcherrimus in analyses of COI sequences; Williams et al. 2013). Papillae on orbital rim. Two species of Mirolabrichthys and all species of Pyronotanthias are distinctive in having large fleshy papillae on the posterior part of the orbit (Fig. 4). They are not present in M. evansi or in species of Nemanthias . Among anthiadines, similar orbital papillae are found in species of Anatolanthias , Luzonichthys and Rabaulanthias , as well as one species of Pseudanthias , P. calloura . The character therefore implies relationships and a generic classification counter to the current proposal. However, the character is difficult to interpret in some specimens, and is possibly present in P. kashiwae , in which weakly developed papillae-like projections are apparent in some specimens. Moreover, fleshy orbital papillae are also present in the planktivorous pomacentrids Lepidozygus tapeinosoma (Bleeker, 1856), Chromis pamae Randall & McCosker, 1992a and C. randalli Greenfield & Hensley, 1970, in the serranine serranid genus Schultzea Woods, 1958 and in the anomalopid genus Anomalops Kner, 1868. According to a recent phylogenetic study, the two species of Chromis are sister taxa, which are only distantly related to Lepidozygus (Tang et al. 2021). Johnson & Rosenblatt (1988) suggested the papillae may be associated with maintaining laminar flow of water over the eyeball. Similarly, Randall & McCosker noted the occurrence of orbital papillae in the three pomacentrids and certain anthiadines and suggested the following: “All of these fishes are slender-bodied; they feed on zooplankton well above the substratum but must swim swiftly to cover with the approach of predaceous fishes. We believe the papillae may function to ensure a smooth flow of water over the eye when swimming rapidly” (Randall & McCosker 1992a: 333). If these explanations are correct, orbital papillae might be expected to occur more widely in anthiadines, as well as perhaps in other taxa with similar behaviour and general morphology such as symphysanodontids, but this is apparently not the case. Supraneural number and anterior dorsal-fin pterygiophore formula. Plesiomorphically in anthiadines, there are three supraneural bones, arranged in an ADPF of S/S+S/3/1+1. Departures from this condition include loss of one or more supraneurals, and anterior migration of dorsal-fin pterygiophores (autapomorphic for N. carberryi ). Of the three genera considered here, only Mirolabrichthys has the plesiomorphic condition (Fig. 3A; Table 2). In the remaining two genera, either the third or second and third supraneurals are absent (the third is sometimes present as a vestige in some Pyronotanthias species, and all supraneurals are autapomorphically absent in N. carberryi Figs. 3B–D; Table 2). Reduction or loss of the third supraneural is not at odds with the proposed relationship of Nemanthias and Pyronotanthias to Anatolanthias (ADPF S/S/3/1+1), Luzonichthys (ADPF S/S/3/1+1 or S//3/1+1) and Rabaulichthys (ADPF S/S/3/1+1). However, although this character has been considered important in anthiadine systematics (e.g., Katayama 1959; Kendall 1976; Katayama & Masuda 1980; Anderson & Heemstra 2012), it appears to be homoplastic within the subfamily, occurring in all species of Anthias , Baldwinella, Choranthias , Hemanthias, Holanthias Günther, 1868, Meganthias , Odontanthias , Pronotogrammus , Sacura and Tosana , and some species of Plectranthias , Pseudanthias and Tosanoides (Pogonoski & Gill 2021). : Published as part of Gill, Anthony C., 2022, Revised definitions of the anthiadine fish genera Mirolabrichthys Herre and Nemanthias Smith, with description of a new genus (Teleostei: Serranidae), pp. 41-66 in Zootaxa 5092 (1) on pages 58-62, DOI: 10.11646/zootaxa.5092.1.2, http://zenodo.org/record/5869488 : {"references": ["Anderson, W. D. Jr. & Heemstra, P. C. (2012) Review of Atlantic and eastern Pacific anthiine fishes (Teleostei: Perciformes: Serranidae), with descriptions of two new genera. Transactions of the American Philosophical Society, 102 (2), i - xviii + 1 - 173.", "Randall, J. E. (1979) A review of the serranid fish genus Anthias of the Hawaiian Islands, with descriptions of two new species. Contributions in Science (Natural History Museum of Los Angeles County), 302, 1 - 13. https: // doi. org / 10.5962 / p. 208189", "Shepherd, B., Pinheiro, H. T., Phelps, T. A. Y., Perez-Matus, A. & Rocha, L. A. (2021) Pseudanthias hangapiko, a new anthiadine serranid (Teleostei, Serranidae, Anthiadinae) from Rapa Nui (Easter Island). ZooKeys, 1054, 1 - 13. https: // doi. org / 10.3897 / zookeys. 1054.64508", "Gill, A. C., Pogonoski, J. J., Johnson, J. W. & Tea, Y. K. (2021 a) Three new species of Australian anthiadine fishes, with comments on the monophyly of Pseudanthias (Teleostei: Serranidae). Zootaxa, 4996 (1), 49 - 82. https: // doi. org / 10.11646 / zootaxa. 4996.1.2", "Baldwin, C. C. (1990) Morphology of the larvae of American Anthiinae (Teleostei: Serranidae), with comments on relationships within the subfamily. Copeia, 1990 (4), 913 - 955. https: // doi. org / 10.2307 / 1446477", "Pogonoski, J. J. & Gill, A. C. (2021) Taxonomy of the genus Dactylanthias Bleeker (Teleostei: Serranidae: Anthiadinae). Zootaxa, 4926 (3), 417 - 430. https: // doi. org / 10.11646 / zootaxa. 4926.3.6", "Linnaeus, C. (1758) Systema naturae per regna tria naturae, secundum classes, ordines, genera, species, cum characteribus, differentiis, synonymis, locis. Vol. 1. 10 th Revised Edition. Laurentius Salvius, Holmiae, ii + 824 pp. https: // doi. org / 10.5962 / bhl. title. 542", "Kamohara, T. (1953) Marine fishes newly found in Prov. Tosa, Japan, with descriptions of a new genus and species. Research Reports of the Kochi University, 2 (11), 1 - 10, figs. 1 - 6.", "Randall, J. E. & Lubbock, R. (1981) A revision of the serranid fishes of the subgenus Mirolabrichthys (Anthiinae: Anthias), with description of five new species. Contributions in Science (Natural History Museum of Los Angeles County), 333, 1 - 27. https: // doi. org / 10.5962 / p. 241267", "Randall, J. E. & Pyle, R. L. (2001) Four new serranid fishes of the anthiine genus Pseudanthias from the South Pacific. Raffles Bulletin of Zoology, 49 (1), 19 - 34.", "Tanaka, S. (1918) Figures and Descriptions of the Fishes of Japan Including Riukiu Islands, Bonin Islands, Formosa, Kurile Islands, Korea, and Southern Sakhalin. Vol. 29. Daichi Shoin, Tokyo, pp. 515 - 538, pls. 138 - 139.", "Herre, A. W. C. T. (1935) New fishes obtained by the Crane Pacific expedition. Field Museum of Natural History Publications, Zoological Series, 18 (12), 383 - 438. https: // doi. org / 10.5962 / bhl. title. 3007", "Kamohara, T. & Katayama, M. (1959) A new and a rare anthinid fishes from Kochi Prefecture, Japan. Reports of the Usa Marine Biological Station, 6 (1), 1 - 4, 1 pl.", "Ida, H. & Sakaue, J. (2001) Pseudanthias calloura (Teleostei: Perciformes), a new serranid fish from Palau, Central Pacific. Ichthyological Research, 48 (3), 263 - 268. https: // doi. org / 10.1007 / s 10228 - 001 - 8144 - 3", "Anderson, W. D. Jr., Parin, N. V. & Randall, J. E. (1990) A new genus and species of anthiine fish (Pisces: Serranidae) from the eastern South Pacific with comments on anthiine relationships. Proceedings of the Biological Society of Washington, 103 (4), 922 - 930.", "Johnson, G. D. & Patterson, C. (1993) Percomorph phylogeny: a survey of acanthomorphs and a new proposal. Bulletin of Marine Science, 52 (1), 554 - 626.", "Johnson, G. D. & Patterson, C. (2001) The intermuscular system of acanthomorph fishes: a commentary. American Museum Novitates, 3312, 1 - 24. https: // doi. org / 10.1206 / 0003 - 0082 (2001) 312 % 3 C 0001: TISOAF % 3 E 2.0. CO; 2", "Patterson, C. & Johnson, G. D. (1995) The intermuscular bones and ligaments of teleostean fishes. Smithsonian Contributions to Zoology, 559, 1 - 83. https: // doi. org / 10.5479 / si. 00810282.559", "Heemstra, P. C. & Randall, J. E. (1986) Family No. 166: Serranidae. In: Smith, M. M. & Heemstra, P. C. (Eds.), Smiths' Sea Fishes. Macmillan South Africa, Johannesburg, pp. 509 - 537.", "Lubbock, R. & Allen, G. R. (1978) A distinctive new Anthias (Teleostei: Serranidae) from the western Pacific. Records of the Western Australian Museum, 6 (2), 259 - 268.", "Gill, A. C., Tea, Y. K. & Senou, H. (2017) Pseudanthias tequila, a new species of anthiadine serranid from the Ogasawara and Mariana Islands. Zootaxa, 4341 (1), 67 - 76. https: // doi. org / 10.11646 / zootaxa. 4341.1.5", "Williams, J. T., Delrieu-Trottin, E. & Planes, S. (2013) Two new fish species of the subfamily Anthiinae (Perciformes, Serranidae) from the Marquesas. Zootaxa, 3647 (1), 167 - 180. https: // doi. org / 10.11646 / zootaxa. 3647.1.8", "Bleeker, P. (1856) Zevende bijdrage tot de kennis der ichthyologische fauna van Ternate. Natuurkundig Tijdschrift voor Nederlandsch Indie, 10, 357 - 386.", "Randall, J. E. & McCosker, J. E. (1992 a) Two new damselfishes of the genus Chromis (Perciformes: Pomacentridae) from the South Pacific. Proceedings of the California Academy of Sciences, 47 (12), 329 - 337.", "Greenfield, D. W. & Hensley, D. A. (1970) Damselfishes (Pomacentridae) of Easter Island, with descriptions of two new species. Copeia, 1970 (4), 689 - 695. https: // doi. org / 10.2307 / 1442311", "Woods, L. P. (1958) A new genus and species of fish from the Gulf of Mexico (family Emmelichthyidae). Fieldiana Zoology, 39 (22), 249 - 252. https: // doi. org / 10.5962 / bhl. title. 3792", "Kner, R. (1868) Uber neue Fische aus dem Museum der Herren Johann Casar Godeffroy & Sohn in Hamburg. (IV. Folge). Sitzungsberichte der Kaiserlichen Akademie der Wissenschaften. Mathematisch-Naturwissenschaftliche Classe, 58 (1 - 2), 26 - 31.", "Tang, K. L., Stiassny, M. L., Mayden, R. L. & DeSalle, R. (2021). Systematics of damselfishes. Ichthyology & Herpetology, 109 (1), 258 - 318. https: // doi. org / 10.1643 / i 2020105", "Johnson, G. D. & Rosenblatt, R. H. (1988) Mechanisms of light organ occlusion in flashlight fishes, family Anomalopidae (Teleostei: Beryciformes), and the evolution of the group. Zoological Journal of the Linnean Society, 94 (1), 65 - 96. https: // doi. org / 10.1111 / j. 1096 - 3642.1988. tb 00882. x", "Katayama, M. (1959) Studies on the serranid fishes of Japan (I). Bulletin of the Faculty of Education Yamaguchi University, 8, 103 - 180.", "Kendall, A. W. Jr. (1976) Predorsal and associated bones in serranid and grammistid fishes. Bulletin of Marine Science, 26 (4), 585 - 592.", "Katayama, M. & Masuda, H. (1980) Two new anthiine fishes from Sagami Bay, Japan. Japanese Journal of Ichthyology, 27 (3), 185 - 190.", "Gunther, A. (1868) Report on a collection of fishes made at St. Helena by J. C. Melliss, Esq. Proceedings of the Scientific Meetings of the Zoological Society of London, 1868, 225 - 228, pls. 18 - 19."]}
format	Text
author	Gill, Anthony C.
author_facet	Gill, Anthony C.
author_sort	Gill, Anthony C.
title	Mirolabrichthys Herre 1927
title_short	Mirolabrichthys Herre 1927
title_full	Mirolabrichthys Herre 1927
title_fullStr	Mirolabrichthys Herre 1927
title_full_unstemmed	Mirolabrichthys Herre 1927
title_sort	mirolabrichthys herre 1927
publisher	Zenodo
publishDate	2022
url	https://dx.doi.org/10.5281/zenodo.5883171 https://zenodo.org/record/5883171
long_lat	ENVELOPE(170.483,170.483,-83.583,-83.583) ENVELOPE(163.300,163.300,-72.250,-72.250) ENVELOPE(158.167,158.167,-81.450,-81.450) ENVELOPE(8.575,8.575,63.621,63.621) ENVELOPE(-59.828,-59.828,-63.497,-63.497) ENVELOPE(167.667,167.667,-72.800,-72.800) ENVELOPE(-69.117,-69.117,-68.517,-68.517) ENVELOPE(15.539,15.539,69.033,69.033) ENVELOPE(169.133,169.133,-73.217,-73.217) ENVELOPE(-27.635,-27.635,-80.759,-80.759) ENVELOPE(-60.800,-60.800,-62.450,-62.450)
geographic	Pacific Ida Baldwin Nares St. Helena Kendall Randall Perez Rapa Lubbock Greenfield Rapa Nui
geographic_facet	Pacific Ida Baldwin Nares St. Helena Kendall Randall Perez Rapa Lubbock Greenfield Rapa Nui
genre	Sakhalin
genre_facet	Sakhalin
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spelling	ftdatacite:10.5281/zenodo.5883171 2023-05-15T18:09:24+02:00 Mirolabrichthys Herre 1927 Gill, Anthony C. 2022 https://dx.doi.org/10.5281/zenodo.5883171 https://zenodo.org/record/5883171 unknown Zenodo http://zenodo.org/record/5869488 http://publication.plazi.org/id/E743FFBCFFB2FFCBB73C186CFFFEFFE3 http://table.plazi.org/id/C7AC665AFFA1FFD8B7AB1C70FF12FBBB http://table.plazi.org/id/C7AC665AFFBBFFC2B7AA1A4CFD2CFDBD http://zoobank.org/A546CCCB-6072-434B-B366-1AFB1BE20CD8 https://zenodo.org/communities/biosyslit https://dx.doi.org/10.11646/zootaxa.5092.1.2 http://zenodo.org/record/5869488 http://publication.plazi.org/id/E743FFBCFFB2FFCBB73C186CFFFEFFE3 https://dx.doi.org/10.5281/zenodo.5869506 https://dx.doi.org/10.5281/zenodo.5869510 https://dx.doi.org/10.5281/zenodo.5869492 https://dx.doi.org/10.5281/zenodo.5869508 https://dx.doi.org/10.5281/zenodo.5869512 https://dx.doi.org/10.5281/zenodo.5869500 https://dx.doi.org/10.5281/zenodo.5869498 http://table.plazi.org/id/C7AC665AFFA1FFD8B7AB1C70FF12FBBB http://table.plazi.org/id/C7AC665AFFBBFFC2B7AA1A4CFD2CFDBD http://zoobank.org/A546CCCB-6072-434B-B366-1AFB1BE20CD8 https://dx.doi.org/10.5281/zenodo.5883170 https://zenodo.org/communities/biosyslit Open Access info:eu-repo/semantics/openAccess Biodiversity Taxonomy Animalia Chordata Actinopterygii Perciformes Serranidae Mirolabrichthys Taxonomic treatment article-journal Text ScholarlyArticle 2022 ftdatacite https://doi.org/10.5281/zenodo.5883171 https://doi.org/10.11646/zootaxa.5092.1.2 https://doi.org/10.5281/zenodo.5869506 https://doi.org/10.5281/zenodo.5869510 https://doi.org/10.5281/zenodo.5869492 https://doi.org/10.5281/zenodo.5869508 https: 2022-02-09T12:53:13Z Mirolabrichthys + Nemanthias + Pyronotanthias + Anatolanthias + Luzonichthys + Rabaulichthy s + Tosana + Pseudanthias (in part) + Hemanthias + Choranthias . This relationship is supported by a single synapomorphy. Parapophyses on first caudal vertebrae . Plesiomorphically in anthiadine fishes, the terminal pair of parapophyses are on the terminal precaudal vertebra, which is identified from the adjacent first caudal vertebra in lacking a haemal spine (Fig. 7A). In contrast, the first caudal vertebra bears a pair of parapophyses in Mirolabrichthys (Fig. 7B), Nemanthias, Pyronotanthias , Anatolanthias, Luzonichthys, Rabaulichthys , Tosana , Hemanthias , Choranthias Anderson & Heemstra, 2012 and all but three species of Pseudanthias : P. hawaiiensis (Randall, 1979), P. ventralis (Randall, 1979) and P. hangapiko Shepherd, Pinheiro, Phelps, Pérez-Matus & Rocha, 2021. Preliminary molecular studies support exclusion of these three species from Pseudanthias (Gill et al. 2021a; L. Rocha, pers. comm.). This character was first noted by Baldwin (1990) and briefly reviewed by Pogonoski & Gill (2021). Pyronotanthias + Nemanthias + Anatolanthias + Luzonichthys + Rabaulichthys . A single character supports this relationship. Longest few pectoral-fin rays bearing serrated projections. W.F. Smith-Vaniz (in Randall & Lubbock 1981) noted that Pyronotanthias lori and P. smithvanizi have distinctive serrations on the distal parts of the longest few pectoral-fin rays. Randall & Pyle (2001) subsequently recorded this character in P. privitera (Randall & Pyle, 2001). This character also occurs in all examined species of Pyronotanthias . It otherwise occurs in all examined species of Nemanthias (Fig. 9), Anatolanthias, Luzonichthys and Rabaulichthys . However, this character may be more widely distributed, as it is possibly present in Pseudanthias kashiwae (Tanaka, 1918) (other related species in the P. cooperi complex not examined; A. mooreanus Herre, 1935 is likely a junior synonym of P. kashiwae ). In P. kashiwae , some of the longest few pectoral-fin rays have ridge-like expansions dorsally or ventrally, which sometimes bear a few weak serrations. Nemanthias + Anatolanthias + Luzonichthys + Rabaulichthys . Two characters support this relationship. High number of lateral-line scales . In their key to species of the subgenus Mirolabrichthys , Randall & Lubbock (1981) differentiated the five species here newly incorporated in Nemanthias from other species in the subgenus based on their relative high numbers of lateral-line scales and pectoral-fin rays (53–64 versus 41–56 and 18–22, rarely 18 versus 15–19, rarely 19, respectively). However, N. carberryi has an intermediate number of lateralline scales (50–56). Nonetheless, the counts for N. carberryi are relatively high for anthiadines. Among genera that appear closely related (e.g. with parapophyses on the first caudal vertebra), such high counts are found only in several species of Pseudanthias (notably P. caudalis Kamohara & Katayama, 1959 and P. thompsoni , which appear to be closely related to each other, as well as P. calloura Ida & Sakaue, 2001 (51–53 scales) and P. cooperi and relatives (collectively with 46–55 scales; Randall & Pyle, 2001)), and in species of Anatolanthias (62–64 lateral-line scales; gill arch characters not yet confirmed for the genus), Luzonichthys (51–78 lateral-line scales) and Rabaulichthys (51–59 lateral-line scales). High number of epineural bones. Anderson et al. (1990) had previously suggested a close relationship between Anatolanthias , Luzonichthys and Rabaulichthys on the basis of several derived features: anterior and posterior nares well separated from each other; vomerine dentition reduced or absent; sum of numbers of pairs of epipleural and epicaudal ribs 16–19. I identify the last-mentioned collectively as epineural bones, following the terminology of Johnson & Patterson (1993, 2001) and Patterson & Johnson (1995). Except for N. bicolor with 12 epineurals, Nemanthias also has relatively high numbers of epineurals (15–17; Table 4). Conflicting characters. The following characters have been used to diagnose Mirolabrichthys in the broad sense, or to suggest relationships within the genus. I here consider them to be homoplastic but acknowledge that they suggest relationships or generic classifications alternative to those proposed herein. Hypertrophied upper lip of males. Mirolabrichthys has been traditionally diagnosed by the presence in males of a hypertrophied upper lip. Randall & Lubbock (1981) noted that similar morphology was also found in Nemanthias carberryi . Hypertrophy of the upper lip is characteristic of all species included here in Mirolabrichthys , Nemanthias and Pyronotanthias , although it is variable in degree depending on species (Figs. 1, 8, 10). Similar morphology is not known in Anatolanthias , Luzonichthys or Rabaulichthys , which suggests conflict with the relationships implied by the above characters. Males of Pseudanthias flavicauda Randall & Pyle, 2001, P. pulcherrimus (Heemstra & Randall, 1986), P. randalli (Lubbock & Allen, 1978) and P. tequila Gill, Tea & Senou, 2017, have variously developed hypertrophy of the upper lip, which suggests a closer relationship of Mirolabrichthys , Nemanthias and Pyronotanthias with these species (and presumably also P. oumati Williams, Delrieu-Trottin & Planes, 2013, for which males are unknown, but which groups with P. randalli and P. pulcherrimus in analyses of COI sequences; Williams et al. 2013). Papillae on orbital rim. Two species of Mirolabrichthys and all species of Pyronotanthias are distinctive in having large fleshy papillae on the posterior part of the orbit (Fig. 4). They are not present in M. evansi or in species of Nemanthias . Among anthiadines, similar orbital papillae are found in species of Anatolanthias , Luzonichthys and Rabaulanthias , as well as one species of Pseudanthias , P. calloura . The character therefore implies relationships and a generic classification counter to the current proposal. However, the character is difficult to interpret in some specimens, and is possibly present in P. kashiwae , in which weakly developed papillae-like projections are apparent in some specimens. Moreover, fleshy orbital papillae are also present in the planktivorous pomacentrids Lepidozygus tapeinosoma (Bleeker, 1856), Chromis pamae Randall & McCosker, 1992a and C. randalli Greenfield & Hensley, 1970, in the serranine serranid genus Schultzea Woods, 1958 and in the anomalopid genus Anomalops Kner, 1868. According to a recent phylogenetic study, the two species of Chromis are sister taxa, which are only distantly related to Lepidozygus (Tang et al. 2021). Johnson & Rosenblatt (1988) suggested the papillae may be associated with maintaining laminar flow of water over the eyeball. Similarly, Randall & McCosker noted the occurrence of orbital papillae in the three pomacentrids and certain anthiadines and suggested the following: “All of these fishes are slender-bodied; they feed on zooplankton well above the substratum but must swim swiftly to cover with the approach of predaceous fishes. We believe the papillae may function to ensure a smooth flow of water over the eye when swimming rapidly” (Randall & McCosker 1992a: 333). If these explanations are correct, orbital papillae might be expected to occur more widely in anthiadines, as well as perhaps in other taxa with similar behaviour and general morphology such as symphysanodontids, but this is apparently not the case. Supraneural number and anterior dorsal-fin pterygiophore formula. Plesiomorphically in anthiadines, there are three supraneural bones, arranged in an ADPF of S/S+S/3/1+1. Departures from this condition include loss of one or more supraneurals, and anterior migration of dorsal-fin pterygiophores (autapomorphic for N. carberryi ). Of the three genera considered here, only Mirolabrichthys has the plesiomorphic condition (Fig. 3A; Table 2). In the remaining two genera, either the third or second and third supraneurals are absent (the third is sometimes present as a vestige in some Pyronotanthias species, and all supraneurals are autapomorphically absent in N. carberryi Figs. 3B–D; Table 2). Reduction or loss of the third supraneural is not at odds with the proposed relationship of Nemanthias and Pyronotanthias to Anatolanthias (ADPF S/S/3/1+1), Luzonichthys (ADPF S/S/3/1+1 or S//3/1+1) and Rabaulichthys (ADPF S/S/3/1+1). However, although this character has been considered important in anthiadine systematics (e.g., Katayama 1959; Kendall 1976; Katayama & Masuda 1980; Anderson & Heemstra 2012), it appears to be homoplastic within the subfamily, occurring in all species of Anthias , Baldwinella, Choranthias , Hemanthias, Holanthias Günther, 1868, Meganthias , Odontanthias , Pronotogrammus , Sacura and Tosana , and some species of Plectranthias , Pseudanthias and Tosanoides (Pogonoski & Gill 2021). : Published as part of Gill, Anthony C., 2022, Revised definitions of the anthiadine fish genera Mirolabrichthys Herre and Nemanthias Smith, with description of a new genus (Teleostei: Serranidae), pp. 41-66 in Zootaxa 5092 (1) on pages 58-62, DOI: 10.11646/zootaxa.5092.1.2, http://zenodo.org/record/5869488 : {"references": ["Anderson, W. D. Jr. & Heemstra, P. C. (2012) Review of Atlantic and eastern Pacific anthiine fishes (Teleostei: Perciformes: Serranidae), with descriptions of two new genera. 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(1990) Morphology of the larvae of American Anthiinae (Teleostei: Serranidae), with comments on relationships within the subfamily. Copeia, 1990 (4), 913 - 955. https: // doi. org / 10.2307 / 1446477", "Pogonoski, J. J. & Gill, A. C. (2021) Taxonomy of the genus Dactylanthias Bleeker (Teleostei: Serranidae: Anthiadinae). Zootaxa, 4926 (3), 417 - 430. https: // doi. org / 10.11646 / zootaxa. 4926.3.6", "Linnaeus, C. (1758) Systema naturae per regna tria naturae, secundum classes, ordines, genera, species, cum characteribus, differentiis, synonymis, locis. Vol. 1. 10 th Revised Edition. Laurentius Salvius, Holmiae, ii + 824 pp. https: // doi. org / 10.5962 / bhl. title. 542", "Kamohara, T. (1953) Marine fishes newly found in Prov. Tosa, Japan, with descriptions of a new genus and species. Research Reports of the Kochi University, 2 (11), 1 - 10, figs. 1 - 6.", "Randall, J. E. & Lubbock, R. 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L., Stiassny, M. L., Mayden, R. L. & DeSalle, R. (2021). Systematics of damselfishes. Ichthyology & Herpetology, 109 (1), 258 - 318. https: // doi. org / 10.1643 / i 2020105", "Johnson, G. D. & Rosenblatt, R. H. (1988) Mechanisms of light organ occlusion in flashlight fishes, family Anomalopidae (Teleostei: Beryciformes), and the evolution of the group. Zoological Journal of the Linnean Society, 94 (1), 65 - 96. https: // doi. org / 10.1111 / j. 1096 - 3642.1988. tb 00882. x", "Katayama, M. (1959) Studies on the serranid fishes of Japan (I). Bulletin of the Faculty of Education Yamaguchi University, 8, 103 - 180.", "Kendall, A. W. Jr. (1976) Predorsal and associated bones in serranid and grammistid fishes. Bulletin of Marine Science, 26 (4), 585 - 592.", "Katayama, M. & Masuda, H. (1980) Two new anthiine fishes from Sagami Bay, Japan. Japanese Journal of Ichthyology, 27 (3), 185 - 190.", "Gunther, A. (1868) Report on a collection of fishes made at St. Helena by J. C. Melliss, Esq. Proceedings of the Scientific Meetings of the Zoological Society of London, 1868, 225 - 228, pls. 18 - 19."]} Text Sakhalin DataCite Metadata Store (German National Library of Science and Technology) Pacific Ida ENVELOPE(170.483,170.483,-83.583,-83.583) Baldwin ENVELOPE(163.300,163.300,-72.250,-72.250) Nares ENVELOPE(158.167,158.167,-81.450,-81.450) St. Helena ENVELOPE(8.575,8.575,63.621,63.621) Kendall ENVELOPE(-59.828,-59.828,-63.497,-63.497) Randall ENVELOPE(167.667,167.667,-72.800,-72.800) Perez ENVELOPE(-69.117,-69.117,-68.517,-68.517) Rapa ENVELOPE(15.539,15.539,69.033,69.033) Lubbock ENVELOPE(169.133,169.133,-73.217,-73.217) Greenfield ENVELOPE(-27.635,-27.635,-80.759,-80.759) Rapa Nui ENVELOPE(-60.800,-60.800,-62.450,-62.450)

Mirolabrichthys Herre 1927

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