Zaretis Hübner, [1819]
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EAD57B9-11F3-4EE9-AA29-7AE257CF5C16 |
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lsid:zoobank.org:pub:EAD57B9-11F3-4EE9-AA29-7AE257CF5C16 |
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persistent identifier |
https://treatment.plazi.org/id/98128793-F12E-FFEF-FF7A-A2AFFDF6E02C |
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treatment provided by |
Plazi (2025-02-06 22:59:51, last updated by GgImagineBatch 2025-02-06 23:07:42) |
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scientific name |
Zaretis Hübner, [1819] |
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Zaretis Hübner, [1819] View in CoL is a neotropical genus of leafwing butterflies widely distributed throughout the Central and South Americas (Comstock, 1961; Willmott & Hall, 2004). More than 40 years after the preceding revision of the genus (Comstock, 1961), and 50 years since the previous description of a new species ( Bryk, 1953), the taxonomy of Zaretis was succinctly reviewed by Willmott & Hall (2004), and three new species ( Willmott & Hall, 2004; Choimet, 2009; Dias, Casagrande & Mielke, 2012) and two subspecies ( Brévignon, 2006) were described. Additionally, two taxonomic names, one previously in synonymy and another recognized as a subspecies, were recognized as valid species ( Dias et al., 2012, 2015), increasing the number of valid species to ten. Nevertheless, only three of those ten species are easily recognizable: Zaretis syene ( Hewitson, 1856) , Zaretis callidryas (R. Felder, 1869) and Zaretis delassisei Choimet, 2009 . The identification of the remaining species is complicated by a lack of consistent external diagnostic characters, owing to the high level of intraspecific variation in both sexes that occurs both within a single locality and throughout the distributional range of these species ( Pyrcz & Neild, 1996; Willmott & Hall, 2004). D’Abrera (1988) regarded Zaretis as ‘the most variable of the neotropical butterflies’. A lack of obvious interspecific differences in male genitalia and the marked sexual dimorphism complicate identification further ( Willmott & Hall, 2004). In the past, these issues caused differing views on the number of valid species and resulted in the description of 27 debatable species-level taxonomic names (e.g. Comstock, 1961; Vane-Wright, 1975; Lamas, 2004; Willmott & Hall, 2004). Despite recent efforts to facilitate the identification of some taxa ( Willmott & Hall, 2004; Dias et al., 2012, 2015), the correct association of most of those names and the species diversity within the genus have remained uncertain.
Traditional morphological taxonomic studies can be extremely time consuming or even unproductive in certain groups, especially when the subject species are superficially similar or highly variable. Such is the case with most of the species of Zaretis . To overcome these shortcomings in taxonomy as a whole, Hebert et al. (2003a) suggested the use of ‘DNA barcodes’; a short, standardized DNA fragment from the mitochondrial cytochrome c oxidase subunit I (COI) gene to facilitate the identification and discovery of new species based on differences in their sequences. Although there is some dispute on both practical and theoretical grounds about the exclusive use of this method in taxonomic studies and difficulties caused by hybridization, gene introgression and Wolbachia infections (e.g. Brower, 2006; Cong et al., 2017), the effectiveness of DNA barcodes has been confirmed repeatedly by the successful identification and discovery of species in numerous animal groups (e.g. Hebert, Ratnasingham & deWaard, 2003b; Huemer et al., 2014; Dumas et al., 2015). The use of standard phylogenetic analyses and novel statistics to infer species delimitation with single-locus molecular data, such as Poisson-tree-processes (PTP; Zhang et al., 2013) and generalized mixed Yule coalescent (GMYC) methods ( Fujisawa & Barraclough, 2013), provides further statistical support for DNA barcode species delimitation. Thus, the aim of this study was to complement morphological and molecular data and use different statistical methods to resolve the chaotic species-level taxonomy of the genus Zaretis .
Brevignon C. 2006. Description de nouveaux Charaxinae provenant de Guyane francaise (Lepidoptera: Nymphalidae). Lambillionea 106: 293-302.
Brower AVZ. 2006. Problems with DNA barcodes for species delimitation: ' ten species' of Astraptes fulgerator reassessed (Lepidoptera: Hesperiidae). Systematics and Biodiversity 4: 127-132.
Bryk F. 1953. Lepidoptera aus dem Amazonasgebiete und aus Peru gesammelt von Dr. Douglas Melin und Dr. Abraham Roman. Arkiv for Zoologi (N. S.) 5: 1-268.
Choimet X. 2009. Nouveaux Charaxinae neotropicaux (Lepidoptera: Nymphalidae). Lepidopteres (Paris) 18: 126-129.
Cong Q, Shen J, Borek D, Robbins RK, Opler PA, Otwinowski Z, Grishin NV. 2017. When COI barcodes deceive: complete genomes reveal introgression in hairstreaks. Proceedings of the Royal Society B: Biological Sciences 284: 20161735.
D'Abrera BL. 1988. Butterflies of the neotropical region. Part V. Nymphalidae (Conc.) & Satyridae. Black Rock: Hill House.
Dias FMS, Casagrande MM, Mielke OHH. 2012. Description of a new species of the genus Zaretis Hubner, [1819], with taxonomic notes on Z. itys and Z. itylus, stat. rev. (Lepidoptera: Nymphalidae: Charaxinae) and illustration of a gynandromorph. Zootaxa 3382: 29-40.
Dias FMS, Oliveira-Neto JF, Casagrande MM, Mielke OHH. 2015. External morphology of immature stages of Zaretis strigosus (Gmelin) and Siderone galanthis catarina Dottax and Pierre comb. nov., with taxonomic notes on Siderone (Lepidoptera: Nymphalidae: Charaxinae). Revista Brasileira de Entomologia 59: 307-319.
Dumas P, Barbut J, Le Ru B, Silvain JF, Clamens AL, d'Alencon E, Kergoat GJ. 2015. Phylogenetic molecular species delimitations unravel potential new species in the pest genus Spodoptera Guenee, 1852 (Lepidoptera, Noctuidae). PLoS One 10: e 0122407.
Felder R. 1869. Diagnosen neuer von dem k. k. Oberlieutenant H. v. Hedemann in Mexico in den Jahren 1865 - 1867 gesammelter Lepidopteren. Verhandlungen der kaiserlich-koniglichen zoologisch-botanischen Gesell-schaft in Wien 19: 465-580.
Fujisawa T, Barraclough TG. 2013. Delimiting species using single-locus data and the Generalized Mixed Yule Coalescent approach: a revised method and evaluation on simulated data sets. Systematic Biology 62: 707-724.
Hebert PDN, Cywinska A, Ball SL, deWaard JR. 2003 a. Biological identifications through DNA barcodes. Proceedings of the Royal Society B: Biological Sciences 270: 313-321.
Hebert PDN, Ratnasingham S, deWaard JR. 2003 b. Barcoding animal life: cytochrome c oxidase subunit 1 divergences among closely related species. Proceedings of the Royal Society B: Biological Sciences. 270: S 96 - S 99.
Hewitson WC. 1856. Illustrations of new species of exotic butterflies, selected chiefly from the collections of W. Wilson Saunders and William C. Hewitson, Vol. 2. London: John Van Voorst. (17): [3 - 4], [17 - 18], pls. [2], [9], (18): [47 - 50], [107 - 110], pls. [24 - 25], [54 - 55], (19): [51 - 52], [111 - 112], pls. [26], [56], (20): [53-56], [91 - 94] + i - v + [121 - 124], pls. [27 - 28], [46 - 47].
Huemer P, Mutanen M, Sefc KM, Hebert PD. 2014. Testing DNA barcode performance in 1000 species of European lepidoptera: large geographic distances have small genetic impacts. PLoS One 9: e 115774.
Lamas G. 2004. Nymphalidae. Charaxinae. In: Lamas G, ed. Checklist: part 4 A. Hesperioidea - Papilionoidea. In: Heppner JB, ed. Atlas of neotropical Lepidoptera, Vol. 5 A. Gainesville: Association for Tropical Lepidoptera, Scientific Publishers, 224-234.
Pyrcz TW, Neild AFE. 1996. Tribe Anaeini. In: Neild AFE, ed. The Butterflies of Venezuela. Part 1: Nymphalidae I (Limenitidinae, Apaturinae, Charaxinae). A comprehensive guide to the identification of adult Nymphalidae, Papilionidae, and Pieridae. London: Meridian Publications, 99-116
Vane-Wright RI. 1975. The butterflies named by J. F. Gmelin (Lepidoptera: Rhopalocera). Bulletin of the British Museum (Natural History) (Entomology) 32: 17-64, 6 pls.
Willmott KR, Hall JPW. 2004. Taxonomic notes on the genus Zaretis, with the description of a new species (Lepidoptera: Nymphalidae: Charaxinae). Tropical Lepidoptera 12: 29-34.
Zhang J, Kapli P, Pavlidis P, Stamatakis A. 2013. A general species delimitation method with applications to phylogenetic placements. Bioinformatics (Oxford, England) 29: 2869-2876.
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