Historical natural history collections allow the description of a new and presumably extinct species of dwarf gecko (Squamata: Gekkonidae: <i>Lygodactylus</i> Gray, 1864) from Fernando de Noronha Island, Brazil

CERÍACO, LUIS M.P.; PASSOS, PAULO

doi:10.1590/0001-3765202320230222

Abstract

A series of specimens of an unidentified species of the genus Lygodactylus from Fernando de Noronha Island were found in the herpetological collections of the Museu Nacional, Rio de Janeiro (Brazil). No species of this genus were known to occur in the archipelago. A review of the historical reports regarding the herpetofauna of the island failed to provide evidence regarding the presence of the species in the last centuries. Morphological comparisons with the two other species of the genus occurring in South America, L. klugei and L. wetzeli, allowed us to confidently confirm that the Fernando de Noronha population belonged to a putatively new species. Here we describe this population as a new species and discuss its possible extinction causes in the archipelago. We also debate the importance of historical natural history collections to the study of biodiversity.

Key words
Taxonomy; reptiles; Herpetofauna; species discovery; museums

INTRODUCTION

Natural history museums and its collections are a tool of uttermost importance for biological research, as they serve as an unparalleled database on the occurrence and geographic and temporal distribution of life on our planet (Suarez & Tsutsui 2004SUAREZ AV & TSUTSUI ND. 2004. The value of museum collections for research and society. BioScience 54: 66-74.). Contrary to the widespread idea that museums are mostly a place for running exhibitions or that the research interest of its collections is now mostly diminished, these institutions play an ever-growing decisive role in the study and protection of the world’s biodiversity (Watanabe 2019WATANABE ME. 2019. The evolution of natural history collections. BioScience 69: 163- 169.). Currently, novel approaches, such as museomics or computer-tomography (CT) scannings are being able to retrieve new layers of data from these collections, helping researchers worldwide to tackle both fundamental scientific research to the modern-day challenges such as climate change, pandemics or the ongoing mass extinction (Hilton et al. 2021HILTON EJ, WATKINS-COLWELL G & HUBBER SK. 2021. The expanding roles of natural history collections. Ichthyol Herpetol 109: 379-391.). Taxonomic work remains, however, one of the main activities associated with museums and natural history collections. Since the establishment of the first modern and scientifically oriented collections in the mid-eighteenth century, museums have been intrinsically associated with taxonomic works, and taxonomy itself cannot survive without such institutions. This obviously roots in the fact that taxonomists rely on the existence of collections for comparative studies, but also due to the need of the deposit the name-bearing specimens, i.e. the types, of their newly described taxa in such collections in order to fulfill the two main requirement of the scientific method: objectivity and replicability (Mayr & Ashlock 1991MAYR E & ASHLOCK PD. 1991. Principles of Systematic Zoology, Second Edition. McGraw Hill, 475 p.).

With thousands of specimens to review and a considerable small taxonomic workforce, many specimens housed in natural history museums still await to be reviewed by experts. Fontaine et al. (2012)FONTAINE B, PERRARD A & BOUCHET P. 2012. 21 years of shelf life between discovery and description of new species. Curr Biol 22: 943-944. showed that many new species wait for decades on museum shelves until they are properly studied by taxonomists and subsequently described. Proving Fontaine et al. (2012)FONTAINE B, PERRARD A & BOUCHET P. 2012. 21 years of shelf life between discovery and description of new species. Curr Biol 22: 943-944. results, in the recent years several vertebrate species have been found and described based on the reexamination of historical collections hold in natural history museums across the world (Gippoliti & Amori 2011GIPPOLITI S & AMORI G. 2011. A new species of mole-rat (Rodentia, Bathyergidae) from the Horn of Africa. Zootaxa 2918: 39-46., Helgen et al. 2013HELGEN KM, PINTO M, KAYS R, HELGEN L, TSUCHIYA M, QUINN A, WILSON D & MALDONADO J. 2013. Taxonomic revision of the olingos (Bassaricyon), with description of a new species, the Olinguito. ZooKeys 324: 1-83., Velazco & Patterson 2014VELAZCO P & PATTERSON B. 2014. Two new species of yellow-shouldered bats, genus Sturnira Gray, 1842 (Chiroptera, Phyllostomidae) from Costa Rica, Panama and western Ecuador. ZooKeys 402: 43-66., Ceríaco 2015CERÍACO LMP. 2015. Lost in the middle of the sea, found in the back of the shelf: a new giant species of Trachylepis (Squamata: Scincidae) from Tinhosa Grande islet, Gulf of Guinea. Zootaxa 3973(3): 511-527., Koch et al. 2019KOCH C, MARTINS A & SCHWEIGER S. 2019. A century of waiting: description of new Epictia Gra, 1845 (Serpentes: Leptotyphlopidae) based on specimens housed more than 100 years in the collection of Natural History Museum Vienna (NMW). PeerJ 7: e7411., Marques et al. 2020MARQUES MP, CERÍACO LMP, BUEHLER MD, BANDEIRA SA, JANOTA JM & BAUER AM. 2020. A revision of the Dwarf Geckos, genus Lygodactylus (Squamata: Gekkonidae) from Angola, with the description of three new species. Zootaxa 4853: 201-352., Ceríaco et al. 2021CERÍACO LMP, SANTOS BS, MARQUES MP, BAUER AM & TIUTENKO A. 2021. Citizen Science meets specimens in old formalin filled jars: a new species of Banded Rubber Frog, genus Phrynomantis (Anura, Phrynomeridae) from Angola. Alytes 38: 18-48.). The present study presents a similar case, in which specimens were forgotten for an extraordinary period of almost 150 years.

While going through historical specimens at the herpetological collections of the Museu Nacional, Universidade Federal do Rio de Janeiro (MNRJ; see Sabaj 2020SABAJ MH. 2020. Codes for Natural History collections in ichthyology and herpetology. Copeia 108(3): 593-669.), we found two jars containing specimens of an unidentified species of the genus Lygodactylus Gray, 1864, from Fernando de Noronha archipelago, northeastern Brazil. Fernando de Noronha, a small volcanic archipelago in the equatorial South Atlantic, has been inhabited since the 17th century, when the outcasts of the Pernambuco Hereditary Captaincy established there in 1612 (D’Abbeville 1874). The archipelago is an important breeding site for several marine birds, including regionally threatened species such as Puffinus lherminieri Lesson, 1839, Sula sula Linnaeus, 1766, Phaethon aethereus Linnaeus, 1758, and Phaethon lepturus Daudin, 1802 (Micheletti et al. 2020MICHELETTI T ET AL. 2020. Terrestrial invasive species on Fernando de Noronha archipelago: what we know and the way forward. In: LONDE V (Ed), Invasive Species. Nova Science Publishers, 52-94 p.). It also hosts a series of endemic species, such as the Trachylepis atlantica (Schmidt, 1945), Amphisbaena ridleyi Boulenger, 1890, or birds such as Elaenia ridleyana Sharpe, 1888, and Vireo gracilirostris Sharpe, 1890 (Micheletti et al. 2020MICHELETTI T ET AL. 2020. Terrestrial invasive species on Fernando de Noronha archipelago: what we know and the way forward. In: LONDE V (Ed), Invasive Species. Nova Science Publishers, 52-94 p.). Such as the case of other oceanic islands, Fernando de Noronha native fauna is threatened by the introduction of several invasive species, such as domestic cats, dogs, brown and black rats (Rattus norvegicus Berkenhout, 1769, and R. rattus Linnaeus, 1758), house mice (Mus musculus (Linnaeus, 1758)), cururu-toads (Rhinella diptycha (Cope, 1862)), tegu lizards (Salvator merianae Duméril & Bibron, 1839), tropical house geckos (Hemidactylus mabouia (Moreau de Jonès, 1819)), cattle egrets (Bubulcus ibis (Linnaeus, 1758)), little fire ant (Wasmannia auropunctata (Roger, 1863)), rock cavys (Kerodon rupestris (Wied-Neuwied, 1820), and the and the mimosoid tree Leucaena leucocephala (Dias et al. 2017DIAS RA ET AL. 2017. Prospects for domestic and feral cat management on an inhabited tropical island. Biol. Invasions 10: 2339-2353., Russel et al. 2018RUSSEL JC, ABRAHÃO CR, SILVA JCR & DIAS RA. 2018. Management of cats and rodents on inhabited islands: an overview and case study of Fernando de Noronha, Brazil. Perspect Ecol Conserv 16: 193-200., Micheletti et al. 2020MICHELETTI T ET AL. 2020. Terrestrial invasive species on Fernando de Noronha archipelago: what we know and the way forward. In: LONDE V (Ed), Invasive Species. Nova Science Publishers, 52-94 p., Toledo et al. 2023TOLEDO LF, ZANOTTI AP, BEZERRA LMLS, ABRAHÃO C & LISBOA CS. 2023. Occasional herpetofaunal introductions into and from the archipelago of Fernando de Noronha, Brazil. Spixiana 45: 271-275.). Zoonotic diseases, like salmonella and toxoplasmosis, have been linked to some of these invasive species (Micheletti et al. 2020MICHELETTI T ET AL. 2020. Terrestrial invasive species on Fernando de Noronha archipelago: what we know and the way forward. In: LONDE V (Ed), Invasive Species. Nova Science Publishers, 52-94 p.).

Both of the jars bear the information that these specimens were collected by the North-American geologist John Casper Branner (1850–1922) in 1876 during the Comissão Geológica do Império (the Geological Commission of the Empire). One of the jars had a total of 10 specimens and nine eggs, presenting an old metal identification tag with the catalog number 1139. The label wrongly noted that the specimens were representatives of the Fernando de Noronha endemic Mabuya punctata [currently Trachylepis atlantica] studied by the ichthyologist Haroldo Travassos in 1942. The second jar contained a total of 42 specimens (41 adults and one neonate), also presenting an old metal identification tag with the catalog number 1194. Contrary to the first jar, there was no taxonomic identification.

According to the data available in the historical catalog of the reptile collection of the MNRJ, all the lizard specimens that Branner collected in Fernando de Noronha in 1876 were originally in a single jar with the catalog number MNRJ 1094. No information exists about how many specimens were originally in this lot, but the catalog indicates that the lot was divided and new numbers were provided to the individual specimens and other lots. Currently, besides specimen MNRJ 1094, Branner’s 1876 reptiles are distributed through the catalog numbers MNRJ 1101–1216, 12523–12568, and 12605–12632, corresponding to 192 specimens of Trachylepis atlantica and through MNRJ 27806–27815 (formerly 1139), MNRJ 27816 (formerly 1139), and MNRJ 27817–27858 (formerly 1194), corresponding to 52 specimens and nine eggs of Lygodactylus sp.

Species of the genus Lygodactylus may be characterized as small (“dwarf”) diurnal geckos, usually arboreal and/or rupicolous, which occur throughout sub-Saharan Africa (including the oceanic islands of the Gulf of Guinea and Madagascar), and parts of South America (Gippner et al. 2021GIPPNER S ET AL. 2021. A comprehensive phylogeny of dwarf geckos of the genus Lygodactylus, with insights into their systematic and morphological variation. Mol Phylogenet Evol 165: 107311.). It currently comprises 71 recognized species (Uetz et al. 2023UETZ P, FREED P & HOSEK J (Eds). 2023. The Reptile Database. Available in: http://reptile-database.org.
http://reptile-database.org... ), of which only two are endemic to continental South America. The first records of the genus in South America were provided in the late 1960s by Vanzolini (1968a, b). Vanzolini (1968a)VANZOLINI PE. 1968a. Lagartos Brasileiros da família Gekkonidae (Sauria). Arq Zool 17(1): 1-84. referred to a few Brazilian specimens from the state of Baía, in Barreiras and Senhor do Bonfim, and one specimen from the state of Mato Grosso in Urucum. Subsequent papers (Vanzolini 1968bVANZOLINI PE. 1968b. Geography of the South American Gekkonidae (Sauria). Arq Zool 17(2): 85-112., 1974) discussed the biogeographic distribution of the genus in South America and provided additional records of specimens from Carnaubeira and Fazenda Campos Bons in the state of Pernambuco, and an additional “not very well preserved juvenile” from S. Luis de Cáceres in the State of Mato Grosso (Vanzolini 1974VANZOLINI PE. 1974. Ecological and geographical distribution of lizards in Pernambuco, northeastern Brasil (Sauria). Pap Avulsos Zool 28: 61-90.). According to Vanzolini (1974)VANZOLINI PE. 1974. Ecological and geographical distribution of lizards in Pernambuco, northeastern Brasil (Sauria). Pap Avulsos Zool 28: 61-90., all of these specimens belong to the same then yet unnamed species.

In the late 1970s Smith et al. (1977)SMITH HM, MARTIN RL & SWAIN TA. 1977. A new genus and two new species of South American geckos (Repilia: Lacertilia). Pap Avulsos de Zool 30: 195-213. described a new South American genus, Vanzoia Smith, Martin & Swain, 1877, which included two new species, Vanzoia klugei Smith, Martin & Swain, 1877, and V. wetzeli Smith, Martin & Swain, 1877. According to the authors, the new genus was “most closely related to Lygodactylus” from which it was “trenchantly distinctive in one respect – the possession of a very distinct escutcheon in males”. The species descriptions were based on part of the specimens previously reported by Vanzolini (1968a, b, 1974). Vanzoia klugei was described based on specimens from the State of Pernambuco, of which 9 where from Carnaubeira (holotype + 8 paratypes) and one specimen (one paratype) from Fazenda Campos Bons in Floresta do Navio. Vanzoia wetzeli was described based on the specimen from Urucum, state of Mato Grosso, previously referred by Vanzolini (1968a)VANZOLINI PE. 1968a. Lagartos Brasileiros da família Gekkonidae (Sauria). Arq Zool 17(1): 1-84., and which became the holotype, and an additional specimen (paratype) from Colonia Fenheim Filadelfia, in Paraguay. Vanzolini et al. (1980)VANZOLINI PE, RAMOS-COSTA AMM & VITT LJ. 1980. Répteis das caatingas. Academia Brasileira de Ciências, 161 p. presented additional morphological and natural history data for Vanzoia klugei, noting that the species was distributed in the Caatingas habitat, from Paraíba to northern Baía.

The validity of the genus Vanzoia has been questioned since its creation (Bons & Pasteur 1977BONS J & PASTEUR G. 1977. Solution histologique a un probleme de taxinomie herpetologique interessant les rapports paleobiologiques de l’Amerique du Sud et de l’Afrique. C R Acad Sci Paris 248: 2547-2750.). The first molecular confirmation that the South American species belonged to the genus Lygodactylus was presented by Gamble et al. (2011)GAMBLE T, BAUER AM, COLLI GR, GREENBAUM E, JACKMAN TR, VITT LJ & SSIMONS AM. 2011. Coming to America: multiple origins of New World geckos. J Evolution Biol 24: 231-244., who noted that the genus has arrived to the continent via trans-Atlantic dispersal around 25 Mya. Lanna et al. (2018)LANNA FM, WERNECK FP, GEHARA M, FONSECA EM, COLLI GR, SITES JR JW, RODRIGUES MT & GARDA AA. 2018. The evolutionary history of Lygodactylus lizards in the South American open diagonal. Mol Phylogenet Evol 127: 638-645. results confirmed the monophyly of South American Lygodactylus, estimating the divergence between the African and South American taxa in about 29 Mya, reaching South American from a single colonization event. Lanna et al. (2018)LANNA FM, WERNECK FP, GEHARA M, FONSECA EM, COLLI GR, SITES JR JW, RODRIGUES MT & GARDA AA. 2018. The evolutionary history of Lygodactylus lizards in the South American open diagonal. Mol Phylogenet Evol 127: 638-645. also found considerable cryptic divergence within South American Lygodactylus, with three putative new species (two in the Caatinga - L. sp. 1 and L. sp. 2 – and one endemic to the seasonally dry tropical forest enclaves within the Cerrado habitat - L. sp. 3). In the most recent and complete molecular phylogeny of the genus, Gippner et al. (2021)GIPPNER S ET AL. 2021. A comprehensive phylogeny of dwarf geckos of the genus Lygodactylus, with insights into their systematic and morphological variation. Mol Phylogenet Evol 165: 107311. grouped the L. klugei group within a group including African taxa, such as the L. picturatus, L. fischeri and L. angularis groups. Gippner et al. (2021)GIPPNER S ET AL. 2021. A comprehensive phylogeny of dwarf geckos of the genus Lygodactylus, with insights into their systematic and morphological variation. Mol Phylogenet Evol 165: 107311. estimated that the trans-Atlantic dispersal event of the South American Lygodactylus took place during the early Miocene (21.9 mya; 15.1-29.7 mya), about 7 my earlier than estimated by Lanna et al. (2018)LANNA FM, WERNECK FP, GEHARA M, FONSECA EM, COLLI GR, SITES JR JW, RODRIGUES MT & GARDA AA. 2018. The evolutionary history of Lygodactylus lizards in the South American open diagonal. Mol Phylogenet Evol 127: 638-645.. Gippner et al. (2021)GIPPNER S ET AL. 2021. A comprehensive phylogeny of dwarf geckos of the genus Lygodactylus, with insights into their systematic and morphological variation. Mol Phylogenet Evol 165: 107311. also suggested that the divergence between some of the putative new species presented by Lanna et al. (2018)LANNA FM, WERNECK FP, GEHARA M, FONSECA EM, COLLI GR, SITES JR JW, RODRIGUES MT & GARDA AA. 2018. The evolutionary history of Lygodactylus lizards in the South American open diagonal. Mol Phylogenet Evol 127: 638-645. (e.g. L. wetzeli and L. sp. 3) could be too low to represent a species level divergence. This is apparently also supported by the results of Lanna et al. (2020)LANNA FM, GEHARA M, WERNECK FP, FONSECA EM, COLLI GR, SITES JR J, RODRIGUES MT & GARDA AA. 2020. Dwarf geckos and giant rivers: the role of the São Francisco River in the evolution of Lygodactylus klugei (Squamata: Gekkonidae) in the semi-arid Caatinga of north-eastern Brazil. Biol J Linn Soc 129: 88-98.. In the last decades, the number of known localities where the South American Lygodactylus taxa occur increased considerably (see Lanna et al. 2018LANNA FM, WERNECK FP, GEHARA M, FONSECA EM, COLLI GR, SITES JR JW, RODRIGUES MT & GARDA AA. 2018. The evolutionary history of Lygodactylus lizards in the South American open diagonal. Mol Phylogenet Evol 127: 638-645., 2020).

There are currently no known records of the presence of a population of the genus Lygodactylus in the island of Fernando de Noronha and Branner’s specimens appear to belong to a population that has been extirpated from the island, similar to what happened to several other Fernando de Noronha endemic vertebrate (Olson 1981OLSON DC. 1981. Natural history of vertebrates of the Brazilian islands of the mid south Atlantic. Natl Geogr Res 13: 481-492., Carleton & Olson 1999CARLETON MD & OLSON SL. 1999. Amerigo Vespucci and the Rat of Fernando de Noronha: a new genus and species of Rodentia (Muridae: Sigmodontinae) from a volcanic island off Brazil’s continental shelf. Am Mus Novit 3256: 1-59.). Here we review the specimens and present evidence that support that they belong to undescribed and possibly extinct species from Fernando de Noronha.

The ZooBank Life Science Identifier (LSID) of this publication is: urn:lsid:zoobank.org:pub:20A1CB84-857C-470B-A8DD-2A1D4482CE47.

MATERIALS AND METHODS

We combined historical analysis with traditional morphological examination of the specimens. For the historical analysis, we reviewed the reports of previous naturalists who explored and provided data regarding the herpetofauna of Fernando de Noronha since the early 1500 to the present day (Webster 1834aWEBSTER WHB. 1834a. Narrative of a voyage to the Southern Atlantic ocean in the years 1828, 29, 30, performed in H. M. Sloop Chanticleer, under the command of the late Captain Henry Foster, F.R.S. &c. Vol. I, London: Richard Bentley, 398 p., bWEBSTER WHB. 1834b. Narrative of a voyage to the Southern Atlantic ocean in the years 1828, 29, 30, performed in H. M. Sloop Chanticleer, under the command of the late Captain Henry Foster, F.R.S. &c. Vol. II, London: Richard Bentley, 398 p., Thomson & Murray 1885THOMSON CW & MURRAY J. 1885. Report on the scientific results of the voyage of H.M.S. Challenger during the years 1873-76. Narrative – Vol. I. London: Longmans & Co., 509 p., Branner 1888BRANNER JC. 1888. Notes on the fauna of the islands of Fernando de Noronha. Am Nat 22(262): 861-871., Ridley 1888RIDLEY HN. 1888. A visit to Fernando do Noronha. Zoologist 12: 41-49., 1890, Olson 1981OLSON DC. 1981. Natural history of vertebrates of the Brazilian islands of the mid south Atlantic. Natl Geogr Res 13: 481-492., Oren 1984OREN DC. 1984. Resultados de uma nova expedição zoológica a Fernando de Noronha. Bol Mus Para Emílio Goeldi Zool 1(1): 19-44.).

For mensural and meristic comparisons we examined 73 specimens of Lygodactylus specimens deposited in the collections of the MNRJ as well as in the collection of Museu de Zoologia da Universidade de São Paulo (MZSP), the Carnegie Museum of Natural History (CM), the American Museum of Natural History (AMNH), and the University of Colorado Museum of Natural History (UCM). All specimens examined are listed in the taxonomic accounts below and in the Appendix. Information on morphological characters of species that could not be examined, as well as supplemental data was obtained from the relevant literature (e.g., Smith et al. 1977SMITH HM, MARTIN RL & SWAIN TA. 1977. A new genus and two new species of South American geckos (Repilia: Lacertilia). Pap Avulsos de Zool 30: 195-213., Vanzolini et al. 1980VANZOLINI PE, RAMOS-COSTA AMM & VITT LJ. 1980. Répteis das caatingas. Academia Brasileira de Ciências, 161 p.).

External morphological analyses followed the procedures of Marques et al. (2020)MARQUES MP, CERÍACO LMP, BUEHLER MD, BANDEIRA SA, JANOTA JM & BAUER AM. 2020. A revision of the Dwarf Geckos, genus Lygodactylus (Squamata: Gekkonidae) from Angola, with the description of three new species. Zootaxa 4853: 201-352.. Dorsal and ventral background color and pattern, including throat were also observed. Morphometric data were recorded from preserved specimens, using Mitutoyo® digital calipers (0.1 mm) under a Zeiss® Stemi 2000C stereo-microscope. Measurements were collected on the right side of each specimen, or on the left side if the specimen was damaged: snout–vent length (SVL), measured from the tip of snout to anterior margin of vent; trunk length (TrunkL), distance between the fore- and hindlimbs; tail length (TL), measured from cloaca to tip of tail; tail width (TW), measured in the most thickness part of tail; head length (HL), measured form tip of snout to anterior tympanum border; head width (HW), measured at the broadest part; head height (HH), measured from the base of the lower jaw to the top of head; ear length (EarL); forearm length (ForeaL), measured from the elbow to the wrist; eye diameter (ED); nostrils-eye distance (NE), measured from the nostril to the anterior margin of eye; snout-eye distance (SE), measured from the tip of snout to the anterior margin of eye; eye-ear distance (EE) distance between the posterior margin of eye to the anterior margin of ear; inter-nostril distance (IN). Meristic data were also collected on the right side of each specimen, or on the left side if the specimen was damaged, except for precloacal pores and generation gland counts if field/museum tags obscured the right thigh. Scale counts included: number of precloacal pores (PCL); midbody row of dorsal scales (MRDS); midbody row of ventral scales (MRVS); fourth finger lamellae (FFingL), number of divided subdigital lamellae below fourth finger; fourth toe lamellae (FToeL), number of divided subdigital lamellae below fourth toe; conditions of mental scale: undivided or semi-divided by a suture; number of scales entering nostril; number of postmental; number of supralabials (SL); number of infralabials (IL); condition of contact of first infralabial with postmental or postpostmental. Terminology for hemipenis description follows Puente et al. (2009)PUENTE M, GLAW F, VIEITES DR & VENCES M. 2009. Review of the systematics, morphology and distribution of Malagasy dwarf geckos, genera Lygodactylus and Microscalabotes (Squamata: Gekkonidae). Zootaxa 2103(1): 1-76.. Locality data are reported in the form of decimal degrees and use the WGS 84 map datum.

RESULTS

The revision of the available historical records on the herpetofauna of Fernando de Noronha archipelago fails to provide any previous record regarding the existence of a population of Lygodactylus on the island. Most of the authors extensively refer the population of the two currently known endemic species, the skink Trachylepis atlantica and the amphisbaenid Amphisbaena ridleyi and the introduced population of the tropical house gecko, Hemidactylus mabouia. Records a species currently not known to exist in the island, such as basilisks (genus Basiliscus Laurenti, 1768) are reported in some of the early nineteenth century reports, while the presence other invasive vertebrates (rats, cats, other reptiles and amphibians) start to be thoroughly reported. A detailed description of these reports is provided below.

The morphological revision of the extant specimens indicates that the Fernando de Noronha specimens differ from their mainland counterparts (L. klugei and L. wetzeli) in several diagnostic morphological characters (see Systematic account below). The combination of its geographic distribution and morphological distinctiveness, we confidently consider the Fernando de Noronha population as distinct taxon.

Historical reports on the herpetofauna of Fernando de Noronha

The first explorer to land on Fernando de Noronha was the Italian-born navigator Americo Vespúcio (1451–1512) in 1503. Vespúcio provided a brief report on the fauna of the island in which he noted that he had observed “green lizards with two tails and some snakes” (Vespúcio in Carleton & Olson 1999CARLETON MD & OLSON SL. 1999. Amerigo Vespucci and the Rat of Fernando de Noronha: a new genus and species of Rodentia (Muridae: Sigmodontinae) from a volcanic island off Brazil’s continental shelf. Am Mus Novit 3256: 1-59.). The “green lizards with two tails” can be confidently assigned to the endemic Trachylepis atlantica, while the snake almost may represent the endemic Amphisbaena ridleyi.

In the early nineteenth century the expedition of the H.M.S. Chanticleer landed on the Island on two occasions, the first in 20 June 1828, with the party being in the island for six days and a second time between 12 June and 18 July 1830. The trip was reported by Webster (1834a, b), but there was no reference to the observation or collection of reptile specimens. However, some specimens were collected, as Gray (1845)GRAY JE. 1845. Catalogue of the specimens of lizards in the collection of the British Museum. Trustees of the British Museum/Edward Newman, London, 289 p. makes reference to the presence of some specimens “half grown, in spirits” of Thysanodactylus bilineatus [currently a synonym of Basiliscus basiliscus (Linnaeus, 1758)] and an adult and a juvenile “in spirits” of Euprepis punctatus [= Trachylepis atlantica] in the collections of the British Museum and collected in Fernando de Noronha by the team of the H.M.S. Chanticleer.

A subsequent report was made by Thomson & Murray (1885)THOMSON CW & MURRAY J. 1885. Report on the scientific results of the voyage of H.M.S. Challenger during the years 1873-76. Narrative – Vol. I. London: Longmans & Co., 509 p., from the H.M.S. Challenger expedition, who visited the Island on 1 and 2 September 1873. According to this report:

“Two Lizards which are South American in their affinities occur in the islands, Thysanodactylus bilineatus, one of the Iguanidae, occurs also in South America; the genus is distinguished by a scaly projection on the outer side of the hinder toes; this Lizard, which was originally obtained on the island by the officers of H.M.S. “Chanticleer”, was not met with. The other Lizard, Euprepes punctatus, belongs to the Scincidae, and is peculiar to Fernando Noronha, its nearest ally, Euprepes maculatus, inhabiting Demerara; it is very abundant on the main Island, and especially so on Mount St. Michael; some specimens are more than a foot in length.”

While the records of the presence of T. atlantica on the island are unsurprising, the records of a juvenile Basiliscus basiliscus are considerably strange, as the species is endemic to Central America and not known to occur in the region (see Uetz et al. 2023UETZ P, FREED P & HOSEK J (Eds). 2023. The Reptile Database. Available in: http://reptile-database.org.
http://reptile-database.org... ). The specimens reported to Gray (1845)GRAY JE. 1845. Catalogue of the specimens of lizards in the collection of the British Museum. Trustees of the British Museum/Edward Newman, London, 289 p. are apparently lost, so we can either speculate if they represented indeed some juveniles of B. basiliscus with a mislabeled locality, another possible currently extinct form, or simply a case of misidentification.

As part of his report on the 1876 Geological Commission of the Empire, Branner (1888)BRANNER JC. 1888. Notes on the fauna of the islands of Fernando de Noronha. Am Nat 22(262): 861-871. dedicates a good trench of text to his observations of the reptiles in Fernando de Noronha:

“Perhaps the most interesting vertebrate found on Fernando is a species of lizard – Mabina [sic] punctatas [=Trachylepis atlantica]. The cultivation of almost all the tillable land on the island has had the tendency to drive these lizards into the rocky corners and uncultivated places, where they exist in such great numbers as to cause one to wonder how so many of them manage to live on so small an island. As they are but little disturbed and have no natural enemies here, they are not very timid. Walking over the open, rocky places where there is no vegetation one may see the lizards withdrawing down the sides of the rock fragments apparently with much reluctance, at a distance of from three to six feet ahead of him. If he turn and look behind he will find them rapidly closing up the space yielded him for a passage. While seated upon the bare rocks I have often observed these little animals watching me, apparently with as much curiosity as I watched them, turning their heads from side to side as if in an effort to be wise. If I kept quiet for a few minutes they would creep up to me and finally up on me; if I moved, they ran down the faces of the rocks, and turning, stuck their heads above the edges to watch me. I caught a great many of them by keeping quiet until they came within easy reach and then snatched them. They bite freely but their teeth are too short and weak to inflict a severe wound. Upon one occasion when climbing with my photographic apparatus up a steep bluff, where great care and attention had to be given to every step and motion, my movements were not sufficiently rapid and decided to keep the lizards off my person, and as neither of my hands was free, they became offensively familiar. Several of them crawled leisurely over me examining my clothing and my person, and one even got up the leg of my trousers and for nearly an hour crept around and around my waist just below the band of my trousers. I was told by the inhabitants that there was another kind of a lizard on the island which had two tails. I found, however, that the so-called forked-tailed lizard was the same as the above mentioned one. The tail of this species is long and slender, and is so easily broken that it was quite difficult to catch one without breaking off a portion of its tail. If the piece broken does not fall off entirely the break may heal over sufficiently to hold it securely, while the growing out of the new tail gives the lizard a forked or double one. I have seen it stated, I believe in the Challenger reports that this species has never been found elsewhere in the world than upon Fernando de Noronha, and that the species to which it is most nearly related occurs in Demerara. I saw no snakes upon the island, and the old residents say there are none, save what is known in Brazil as the cobra cega (blind snake) or cobra de duas cabeças (double-headed snake). I found one specimen of this. It is a species of Amphisbaena”.

According to Branner (1888)BRANNER JC. 1888. Notes on the fauna of the islands of Fernando de Noronha. Am Nat 22(262): 861-871., all of the specimens collected in Fernando de Noronha were deposited in the MNRJ. Surprisingly, no geckos were noted by the author. Ridley (1888)RIDLEY HN. 1888. A visit to Fernando do Noronha. Zoologist 12: 41-49. also visited the island in August of 1887 and provided some additional data on the occurring reptiles. According to the author:

“… there are three species of terrestrial reptiles – a Skink, Mabuia punctata; a new species of Amphisbaena; and the Common House Gecko. The Skink is very common, and occurs on all the islands; it is about six inches in length, and of an iridescent-brown colour; it is very tame, and if the observer remains montionless will approach very close: it is apparently omnivorous. On one occasion when I had blown some doves’ eggs, a Skink ran forward and drank up the yelk; another time, on throwing away the skins of some bananas we had been eating, the lizards ran up and carried them off, or ate them on the spot. The Amphisbaena lives under stones and in the soil, as is the general habit of these animals; a number we found in digging sweet potatoes on Rat Island. The House Gecko was very common in the houses, where it did good service against the mosquitos, and it also lived during the day between the petioles of the bananas. We found its eggs on one or two occasions, either lying loosely on the ground in the garden or in a hole in the stem of a papaw-tree: they were perfectly globular and white, about the size of a pea, and rather large for the size of the animal”.

Interestingly, Ridley (1888)RIDLEY HN. 1888. A visit to Fernando do Noronha. Zoologist 12: 41-49. already raises concerns about the impacts of introduced rats and cats. According to the author “The Black Rat, which has been introduced, is exceedingly abundant and destructive, climbing the cocoa-nut palms and papaw-trees and devouring the fruit, and haunting the melon patches, where it does much mischief” while “The domestic cat has run wild in some of the islands. There was one on Rat Island which had escaped from an Italian vessel wrecked there, and was living on the mice and doves”. In a subsequent report, Ridley (1890)RIDLEY HN. 1890. Notes on the zoology of Fernando Noronha. Zool J Linn Soc-Lond 20: 473-570. refers again the introduction of alien species to the islands:

“… a considerable number of animals have been introduced by man into the islands intentionally and by accident: such, for instance, as the Gecko (Hemidactylus mabouia), the American cockroach (Blatta americana), and its curious parasite Evania, a spider, centipede, scorpion, rats and mice, and Sitoplidus oryzae. These, though usually plentiful on the main island around the houses, are markedly absent from the smaller islets.”.

The reptile specimens collected by Ridley were examined and published by Boulenger in Ridley (1890)RIDLEY HN. 1890. Notes on the zoology of Fernando Noronha. Zool J Linn Soc-Lond 20: 473-570.: “Only three species were found, viz. a Gecko (Hemidactylus mabouia, Mor.), a Skink (Mabuia punctata, Gray) [= Trachylepis atlantica], and an Amphisbaena, described below [= Amphisbaena ridleyi Boulenger, 1890]. The Gecko is of a widely-distributed species, ranging over the greater part of Tropical America and Africa”. Similarly to his contemporary authors and explorers of Fernando de Noronha, no reference was ever made to the presence of a species of the genus Lygodactylus.

The subsequent reports on the herpetofauna of Fernando de Noronha were only published almost a century later by Olson (1981)OLSON DC. 1981. Natural history of vertebrates of the Brazilian islands of the mid south Atlantic. Natl Geogr Res 13: 481-492. and Oren (1984)OREN DC. 1984. Resultados de uma nova expedição zoológica a Fernando de Noronha. Bol Mus Para Emílio Goeldi Zool 1(1): 19-44.. According to Olson (1981)OLSON DC. 1981. Natural history of vertebrates of the Brazilian islands of the mid south Atlantic. Natl Geogr Res 13: 481-492.:

“The endemic lizard Mabuya maculata was extremely common, and in the late afternoon more than 40 individuals catching the last rays of the evening sun could be seen on each utility pole along certain sections of road. Since Ridley’s report in 1890, a toad (Bufo paracnemis [=Rhinella diptycha]), the tegu lizard (Tupinambis teguixin [=Salvator merianae]), and a caviomorph rodent (Kerodon rupestris) have been successfully introduced to the island.”

While Oren (1984)OREN DC. 1984. Resultados de uma nova expedição zoológica a Fernando de Noronha. Bol Mus Para Emílio Goeldi Zool 1(1): 19-44. notes:

“The endemic lizard Mabuya maculata [=Trachylepis atlantica] is abundant in habitat with a good bush and arboreal cover, but it almost completely substituted by the Teju, Tupinambis teguixin [=Salvator merianae] in areas dominated by sheep and goats. According to the islanders, we were informed that a single couple of T. teguixin was introduced in 1960. In 1982 the species was dominant in certain parts of the Ilha Grande, although it was known to be used as a food item by the inhabitants. The juveniles were very common in the ground in fields dominated by sheeps and goats, running rapidly when a human approached. Contranstingly, the Mabuya maculata preferred tree and vertical surfaces, and showed a very gentle behavior, allowing humans to approach closely, even crawling in people who were seated. The gecko Hemidactylus mabouia was occasionally seen in houses at night. Its presence in the archipelago dates back at least from the nineteenth century, as Boulenger (1890) reported specimens collected by Ridley in 1887. Olson (1981)OLSON DC. 1981. Natural history of vertebrates of the Brazilian islands of the mid south Atlantic. Natl Geogr Res 13: 481-492. indicated that the endemic Amphisbaena ridleyana, the “two headed lizard”, was common during his visit in 1973. However, we looked for the species in several places and we only found it once, hiding under the rocks in the front yard of the Governor. It is possible that A. ridleyana population is declining in the archipelago. The two amphibian species introduced, Bufo paracnemis [=Rhinella diptycha] and Hyla ruber [=Scinax x-signatus]are nocturnal. The number of Bufo individuals was impressive at night, when they crawled out of the sewers and other hiding places near the houses. Some of them reach impressive sizes, with more than 20 cm. The frog (H. ruber) was present in anthropogenic habitats, preferring bathrooms and other humid environments inside houses. These two species of amphibians are not present in the previous reports on the zoology of the archipelago, and most likely were introduced during this century.”

Modern revisions of the fauna of the archipelago have not cited any species of the genus Lygodactylus in Ferrnando de Noronha (Micheletti et al. 2020MICHELETTI T ET AL. 2020. Terrestrial invasive species on Fernando de Noronha archipelago: what we know and the way forward. In: LONDE V (Ed), Invasive Species. Nova Science Publishers, 52-94 p., Toledo et al. 2023TOLEDO LF, ZANOTTI AP, BEZERRA LMLS, ABRAHÃO C & LISBOA CS. 2023. Occasional herpetofaunal introductions into and from the archipelago of Fernando de Noronha, Brazil. Spixiana 45: 271-275.).

Systematics

(Reptilia: Squamata: Gekkonidae)

Lygodactylus neglectus sp. nov.

(Table I, Figs. 1-8)

Figure 1
General view of the dorsal and ventral side of the holotype of Lygodactylus neglectus sp. nov. (MNRJ 27809). Photo by LMPC.

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Table I
Measurements and scale counts of the type series of Lygodactylus neglectus sp. nov. Abbreviations as indicated in the Materials and Methods section. All specimens from the MNRJ collection.

ZooBank Life Science Identifier (LSID) - lsid:zoobank.org:act:0A151DAD-C06B-48B9-B3E3-54EC4CA90F41

Holotype. An adult male (MNRJ 27809, Figs. 1–8) collected at Fernando de Noronha Island, State of Pernambuco, northeastern Brazil [-3.8690º N, -32.4249 ºE], collected by John Casper Branner in 1876.

Paratypes. Fifty-one specimens, of which 18 are female (MNRJ 27812, 27814, 17818, 27819, 27823, 27824, 27825, 27828, 27832. 27834, 27838, 27840, 27841, 27842, 27849, 27851, 27853, 27857) and 33 are males (MNRJ 27806, 27807, 27808, 27810, 27811, 27813, 27815, 27817, 27820, 27821, 27822, 27826. 27827, 27829, 27830, 27830, 27831, 27833, 27835, 27836, 27837, 27839, 27843, 27844, 27845, 27846, 27847, 27848, 27850, 27852, 27854, 27855, 27856). All paratypes have the same collecting data as the holotype.

Diagnosis. A small sized Lygodactylus species, identified to genus by the following combination of characters: fully limbed, short and cylindrical body, short and rounded snout, small and granular dorsal scales, rudimentary inner toe, and precloacal pores present (Loveridge 1947LOVERIDGE A. 1947. Revision of the African lizards of the family Gekkonidae. Bull Mus Comp Zool 98: 1-469., Pasteur 1965PASTEUR G. 1965 [1964]. Recherches sur l’evolution des lygodactyles, lézards Afro-Malgaches actuels. Trav I Scient Chérifien Zool 9: 1-132, pls, 1-12. [1964]). Lygodactylus neglectus sp. nov. is immediately distinguishable from the South American congener, L. klugei by a higher number of precloacal pores (7–8 in L. neglectus sp. nov. versus 3–5 in L. klugei). These pores are in an inverted V-shape row in L. neglectus sp. nov. while in L. klugei they are disposed of in an almost linear row (Fig. 2). L. klugei occurs in the Caatinga biomes in Bahia, Ceará, Piauí and Rio Grande do Norte states, while L. neglectus sp. nov. is only known from Fernando de Noronha archipelago. The new species can also be distinguished from L. wetzeli by the scalation on the top of the head. While in L. neglectus sp. nov. these scales are somewhat larger, in L. wetzeli the scales are about twice as small. This is particularly well visible on the internasals, in which in L. neglectus sp. nov. there are three internasals, while in L. wetzeli there are usually four to six (Fig. 3). The chin and gular regions of the males of L. neglectus sp. nov. are marked with a considerable number of irregular dark spots, while in L. wetzeli this coloration is not common. L. wetzeli is endemic to southwestern Brazil (Mato Grosso do Sul state), northern Paraguay and eastern Bolivia, while L. neglectus sp. nov. is only known from Fernando de Noronha archipelago.

Figure 2
Comparison between the precloacal pores of the holotype Lygodactylus neglectus sp. nov. (MNRJ 27809; a) and those of the holotype of L. klugei (MZSP 22531; b).

Figure 3
Comparison between the dorsal scales on the snout of the holotype Lygodactylus neglectus sp. nov. (MNRJ 27809; a) and those of the holotype of L. wetzeli (MZSP 7722; b).

Description of holotype. SVL 26.5 mm; TrunkL: 11.6 mm; CrusL 4.1 mm; TL: 26.6 mm; TW: 3.4 mm; HL: 8.1 mm; HW: 5.2 mm; HH: 3.3 mm; EarL: 0.5 mm; ED: 1.8 mm; NE: 2.5 mm; SE: 3.2 mm; EE: 2.2 mm; IN: 1.3 mm; IO: 2.3 mm. Head broad and slightly distinct from neck (Fig. 4); snout longer than broad, the distance from its edge to the anterior border of the eye greater than the interorbital distance anteriorly, and than the distance between the eye and ear opening (Fig. 5); ear opening small and roundish (Fig. 5); snout covered with enlarged flattened granular scales, larger anteriorly on snout, medium-sized on head of crown, becoming smaller laterally above the eye (Fig. 4); scales on the snout larger than those on the occiput (Fig. 4); canthus rostralis not prominent (Fig. 5); rostral pentagonal-shape, about as high as wide; two scales (one supranasal and 1^st supralabial) entering the nostril (Fig. 5); nostrils pierced in the suture between supranasal and first supralabial (Fig. 5); nostril not in contact with rostral (Fig. 5); supranasals separated by a three internasal granular scales (Fig. 4); mental followed by enlarged scales, decreasing in size towards base of the throat and increasing on chest and belly (Fig. 6); supralabials 8/8; infralabials 6/6 (Fig. 5); smooth gulars, enlarged and forming transverse rows posteriorly, 25 between posterior extent of the infralabials/jaws; 21 midbody row of ventral scales (Fig. 6); 55 rows across dorsal midbody; limbs short but well developed, pentadactyl extremities; 1^stdigit of both manus and pes extremely reduced and lacking claw, distal portions of remaining digits expanded, bearing claw; 5 pairs of lamellae under 4^thdigit manus (Fig. 7) and 5 pairs of lamellae beneath 4^th digit pes; dorsum with small, homogeneous, granular and smooth scales with a similar size to those on trunk, the scales on limbs are slightly larger; venter with homogeneous smooth scales; scales on ventral surface of the forelimbs smaller, granular and imbricate, hindlimbs scales are similar to those on venter, although the surface scales of thighs are smaller and imbricate, similar to those on the arm; precloacal pores 7 arranged in a chevron shape; 38 to 40 generation glands – enlarged, glandular scales present along the ventral surface of each thigh (Fig. 8); tail cylindrical to slightly hexagonal; caudal scales dorsally enlarged, flattened and homogeneous; median subcaudal scales the same size as the remaining caudal scales, flattened and smooth. Coloration (in ethanol) is brown to above, with a narrowing continuous cinnamon brown band on the flanks from the neck to the base of the tail. Both band and dorsum irregularly marked by a series dark brown. The head same color as body and limbs, with two faint and thin darker brown bands extending from the anterior central part of the eye towards the upper nasal. The venter is cream to white with no markings or speckling. The chin and gular regions white to cream with a considerable number of irregular dark marking (Fig. 6). Dorsal part of the tail light brown, ventrally cream.

Figure 4
Drawing of the dorsal view of the head of the holotype Lygodactylus neglectus sp. nov. (MNRJ 27809).

Figure 5
Drawing of the lateral view of the head of the holotype Lygodactylus neglectus sp. nov. (MNRJ 27809).

Figure 6
Drawing of the ventral view of the head of the holotype Lygodactylus neglectus sp. nov. (MNRJ 27809).

Figure 7
Drawing of the dorsal view of the manus of the holotype Lygodactylus neglectus sp. nov. (MNRJ 27809).

Figure 8
Drawing of the cloacal view area of the holotype Lygodactylus neglectus sp. nov. (MNRJ 27809).

Variation. Variation in scalation and body measurements of the type series is reported in Table I. All the paratypes present are morphologically very similar to the holotype, without any relevant difference. Females don’t present the precloacal pores and lack the irregular dark markings in the chin and gular regions, otherwise, they agree entirely with the holotype and male paratypes.

Hemipenial morphology. Based on the partially everted hemipenis (MNRJ 27837; distal portion of each lobe remain inverted and tissue unfortunately is fragile to allow fully eversion procedure). Organ semi-everted and almost maximally expanded renders a slightly bilobed and subcylindrical hemipenis; hemipenial body nude without ornamentation, except for basal region of organ covered with pointed irregular papillae; papillae arranged into three longitudinal series to middle of organ; lobular region twice as wide as hemipenial body; lobes with serrated ridges (sensu Puente et al. 2009PUENTE M, GLAW F, VIEITES DR & VENCES M. 2009. Review of the systematics, morphology and distribution of Malagasy dwarf geckos, genera Lygodactylus and Microscalabotes (Squamata: Gekkonidae). Zootaxa 2103(1): 1-76.), most conspicuous on the asulcate face of lobes; sulcus spermaticus bifurcates on distal part of organ with each branch centrifugally oriented, running to tip of lobes; sulcus spermaticus margins smooth and deep, with no ornamentation along its length.

Distribution and natural history. The new species is known only from Fernando de Noronha Island. The nine ellipsoid eggs (6.0–7.0; mean = 6.55; SD = 0.34) contained embryos. Most of these eggs present one of the ends symmetrically severed, probably due to the union with another egg from the same clutch, while two eggs remain connected to each other. Considering the relatively large size of each egg and high number of the offspring, it is possible that there was communal posture in Lygodactylus neglectus sp. nov..

Etymology. The specific epithet “neglectus”, used here as a nominative adjective, refers to the almost 150 years in which the type series of this species has been overlooked in the collections of the MNRJ. We suggest the English common name of Fernando de Noronha Dwarf Gecko, and the Portuguese common name of Briba de Fernando de Noronha.

DISCUSSION

The surprising discovery of a new endemic and putatively extinct species of gecko of the genus Lygodactylus from Fernando de Noronha island based on specimens collected more than 150 years ago is an important reminder of the importance of natural history collections as repository of the past and present biodiversity of our planet. These collections work as time-capsules, unrepeatable glimpses about the biota of a given place and time. The Branner specimens, housed in the collections of the MNRJ and forgotten for decades, serve not only as the type series of a newly described species and, therefore, an important addition to our knowledge of Fernando de Noronha biodiversity, but also act as an important reminder of the impacts that humans have on the planet.

These impacts are especially felt in oceanic islands. Oceanic islands are unique reservoirs for biological diversity but have routinely been heavily negatively impacted following their discovery (Norder et al. 2020NORDER SJ ET AL. 2020. Global change in microcosms: environmental and societal predictors of land cover change on the Atlantic Ocean Islands. Anthropocene 30: 1-9.). The introduction of many alien species has led to a wave of extinctions following each major human colonization event, with the loss of endemic species (Doherty et al. 2016DOHERTY TS, GLEN AS, NIMMO DG, RITCHIE EG & DICKMAN CR. 2016. Invasive predators and global biodiversity loss. Proc Natl Acad Sci USA 113: 11261-11265., Russel et al. 2017RUSSEL JC, MEYER J-Y, HOLMES ND & PAGAD S. 2017. Invasive alien species on island: impacts, distribution, interactions and management. Environ Conserv 44(4): 359-370., 2018). Human commensal rodents have been the most unintentional introduced species (Jones et al. 2013JONES EP, EAGER HM, GABRIEL SI, JÓHANNESDÓTTIR F & SEARLE JB. 2013. Genetic tracking of mice and other bioproxies to infer human history. Trends Genet 29: 298308.). The rodent’s introduction is usually followed by the arrival of domestic cats, which are used to control the rodents, causing further negative impacts on native endemic species (Nogales et al. 2013NOGALES M, VIDAL E, MEDINA FM, BONNAUD E, TERSHY BR, CAMPBELL KJ & ZAVALETA ES. 2013. Feral cats and biodiversity conservation: the urgent prioritization of island management. BioScience 63: 804-810.).

Several species are known to have been extirpated from Fernando de Noronha, such as the case of the extinct endemic sigmodontine rodent Noronhomys vespuccii Carleton & Olson, 1999. This species was described in the late 1990s by Carleton & Olson (1999)CARLETON MD & OLSON SL. 1999. Amerigo Vespucci and the Rat of Fernando de Noronha: a new genus and species of Rodentia (Muridae: Sigmodontinae) from a volcanic island off Brazil’s continental shelf. Am Mus Novit 3256: 1-59. based on several crania, many mandibles with intact or partial tooth rows, and numerous postcranial elements collected in 1973 at beach dunes of the main island. According to the authors, Amerigo Vespucci itself has reported sightings of this species in the early 1500s, and argue that the introduction of other rodents, such as Rattus rattus, may have caused the species extinction. Olson (1981)OLSON DC. 1981. Natural history of vertebrates of the Brazilian islands of the mid south Atlantic. Natl Geogr Res 13: 481-492. also reported on the bones of a putative extinct endemic bird of the family Rallidae. The combination of deforestation, habitat loss and the introduction of other gecko species that compete with its habitat (Hemidactylus mabouia), and the invasive predators such as rats and domestic cats most likely explains the extinction of Lygodactylus neglectus sp. nov. This situation is very similar to that of the ecologically similar Reunion island endemic geckos Phelsuma inexpectata Mertens, 1966, which has almost been pushed to extinction due to the similar reasons (Sanchez & Probst 2011SANCHEZ M & PROBST J-M. 2011. Distribution and conservation status of the Manapany day gecko, Phelsuma inexpectata Mertens, 1966, an endemic threatened reptile from Reunion Island (Squamata: Gekkonidae). Cah Scient Ocean Ind Occid 2: 13-28., 2014SANCHEZ M & PROBST J-M. 2014. Distribution and habitat of the invasive giant day gecko Phelsuma grandis Gray 1870 (Sauria: Gekkonidae) in Reunion Island, and conservation implication. Phelsuma 22: 13-28., Sanchez 2021SANCHEZ M. 2021. Phelsuma inexpectata. The IUCN Red List of Threatened Species 2021: e.T17450049A17450059. https://dx.doi.org/10.2305/IUCN.UK.2021-2.RLTS.T17450049A17450059.en. Accessed on 13 February 2023.
https://doi.org/10.2305/IUCN.UK.2021-2.R... ).

The lack of historical reports regarding this species should be interpreted with caution. On one hand, it can simply mean that the species was overlooked and neglected by Amerigo Vespucci and most of the nineteenth century explorers who visited the island. After all, the species is considerably small, and if it shares the same behavior and habitat selection as its South American congeners, it can easily be unnoticed by someone that is not actively looking for it. The first records of the continental species, L. klugei and L. wetzeli, have only been reported in the late 1960s (Vanzolini 1968aVANZOLINI PE. 1968a. Lagartos Brasileiros da família Gekkonidae (Sauria). Arq Zool 17(1): 1-84., b), which clearly show how animals of these species can go unnoticed by both scientists and the local population. Other hypothesis for the lack of reports could be the fact that the species was already rare or on the brink of extinction in the late nineteenth century. A much more intriguing issue is the fact that Branner (1888)BRANNER JC. 1888. Notes on the fauna of the islands of Fernando de Noronha. Am Nat 22(262): 861-871. himself has not referred to the species in his long and detailed account on the fauna of Fernando de Noronha. It is beyond reasonable doubt that the specimens were collected by Branner. Both the catalog information, the type of original tags, and the general appearance of the specimen point to the fact that these are indeed specimens collected by him during the Comissão Geológica do Império and appear to rule out the possibility that this is a case of specimen mislabeling. Given this, the explanation for lack of reference about these animals in Branner’s accounts must lie in the fact that he was a geologist and either considered the Lygodactylus specimens as juveniles of T. atlantica, or simply was unsure about its identity and preferred to omit them for his accounts.

Guedes et al. (2020)GUEDES JM, FEIO RN, MEIRI S & MOURA MR. 2020. Identifying factors that boost species discoveries of global reptiles. Zool J Linn Soc-Lond 190: 1274-1284. modeled the time to description using biological and sociological variables in a time-to-event analysis. They found that the time lag was shorter when the collector of the type-series was an author of the species description, and that the species collected by non-taxonomists were “shelved” in scientific collection and remained to be properly identified for a much longer time. We believe Travassos (1946)TRAVASSOS H. 1946. Estudo da variação de Mabuya punctata(Gray, 1839) (Ordem Squamata Oppel, 1881 – Fam. Scincidae Gray, 1825). Bol Mus Nac Zool 60: 1-56., an ichthyologist, confounded (or simply neglected) the presence of Lygodactylus specimen in Branner collections’ and identified all of the lizards of Fernando de Noronha as Trachylepis atlantica (see Travassos 1946TRAVASSOS H. 1946. Estudo da variação de Mabuya punctata(Gray, 1839) (Ordem Squamata Oppel, 1881 – Fam. Scincidae Gray, 1825). Bol Mus Nac Zool 60: 1-56.). This case reinforces the importance of preserving, reviewing and updating databases of historical collections in order to reduce the Linnean shortfall on Earth’s biota.

While the newly described species can be readily distinguished from L. klugei based on its precloacal pores, it is however morphologically similar to L. wetzeli. We assume that this may be due to a possible close relationship between L. neglectus sp. nov. and L. wetzeli, maybe even belonging to the species complex found by the work of Lanna et al. (2018)LANNA FM, WERNECK FP, GEHARA M, FONSECA EM, COLLI GR, SITES JR JW, RODRIGUES MT & GARDA AA. 2018. The evolutionary history of Lygodactylus lizards in the South American open diagonal. Mol Phylogenet Evol 127: 638-645.. The genus is known to harbor considerable cryptic diversity (Lanna et al. 2018LANNA FM, WERNECK FP, GEHARA M, FONSECA EM, COLLI GR, SITES JR JW, RODRIGUES MT & GARDA AA. 2018. The evolutionary history of Lygodactylus lizards in the South American open diagonal. Mol Phylogenet Evol 127: 638-645., Gippner et al. 2021GIPPNER S ET AL. 2021. A comprehensive phylogeny of dwarf geckos of the genus Lygodactylus, with insights into their systematic and morphological variation. Mol Phylogenet Evol 165: 107311.) and members of the same species complexes usually are morphologically very conservative (Gippner et al. 2021GIPPNER S ET AL. 2021. A comprehensive phylogeny of dwarf geckos of the genus Lygodactylus, with insights into their systematic and morphological variation. Mol Phylogenet Evol 165: 107311.). Nonetheless, its presence in Fernando de Noronha archipelago make biogeographically sense, as the islands also harbor another member of a mostly African genus, Trachylepis atlantica. Fernando de Noronha could have acted as a first steppingstone for the Lygodactylus’ colonization of South America directly from Africa.

Attempts to sequence DNA from the type series of Lygodactylus neglectus sp. nov. and CT-Scans techniques are currently underway in order to provide the systematic placement of the newly described species, as well as better glimpses to its ecology and natural history. Additional fieldwork is required to confirm the extinction of the species in Fernando de Noronha archipelago.

ACKNOWLEDGMENTS

The authors want to thank the staff of the herpetology collections of the vertebrate department of the Museu Nacional – UFRJ(MNRJ) for the support provided during this investigation. Miguel Trefaut Rodrigues is also thanked for facilitating the visit of LMPC to the collections of MZSP, and all the staff of the herpetology department of the MZSP are also thanked for their hospitality and support during the visit to the collections under their care. Mariana P. Marques prepared the photographic plates. The collection managers of the AMNH, CM and UCM are thanked for providing access and photos of the specimens in their collections. LMPC was funded by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) of the Ministério da Educação do Brasil, under the Programa Institucional de Internacionalização (#PRINT, 88887.695166/2022-00). PP was supported by the Conselho Nacional de Desenvolvimento Científico e Tecnológico (#405596/2021-9) and the Fundação Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de Janeiro (#E-26/202.737/2018 and #E-26/010.002164/2019).

APPENDIX

List of examined specimens (excluding the type series of Lygodactylus neglectus sp. nov.)

Lygodactylus wetzeli: MZSP 7722 (holotype), Urucum, Mato Grosso [Brazil]; CM 94180-94181, Filadelfia, Bóqueron [Paraguay]; UCM 514242, 55598, Filadelfia, Bóqueron [Paraguay]; AMNH 141616-141627, Santa Cruz [Bolívia].

Lygodactylus klugei: MZSP 22531 (holotype), Carnaubeira, Pernambuco [Brazil]; CM 65043, Carnaubeira, Pernambuco [Brazil]; MNRJ 26682, Morro do Chapéu, Baía [Brazil]; MNRJ 19638, Central, Belo Horizonte [Brazil]; MNRJ 17874-17880, Arreiroz (próximo de Vaqueijada), Ceará [Brazil]; MNRJ 18600-18609, unknown locality.

REFERENCES

BRANNER JC. 1888. Notes on the fauna of the islands of Fernando de Noronha. Am Nat 22(262): 861-871.
BONS J & PASTEUR G. 1977. Solution histologique a un probleme de taxinomie herpetologique interessant les rapports paleobiologiques de l’Amerique du Sud et de l’Afrique. C R Acad Sci Paris 248: 2547-2750.
CARLETON MD & OLSON SL. 1999. Amerigo Vespucci and the Rat of Fernando de Noronha: a new genus and species of Rodentia (Muridae: Sigmodontinae) from a volcanic island off Brazil’s continental shelf. Am Mus Novit 3256: 1-59.
CERÍACO LMP. 2015. Lost in the middle of the sea, found in the back of the shelf: a new giant species of Trachylepis (Squamata: Scincidae) from Tinhosa Grande islet, Gulf of Guinea. Zootaxa 3973(3): 511-527.
CERÍACO LMP, SANTOS BS, MARQUES MP, BAUER AM & TIUTENKO A. 2021. Citizen Science meets specimens in old formalin filled jars: a new species of Banded Rubber Frog, genus Phrynomantis (Anura, Phrynomeridae) from Angola. Alytes 38: 18-48.
DIAS RA ET AL. 2017. Prospects for domestic and feral cat management on an inhabited tropical island. Biol. Invasions 10: 2339-2353.
DOHERTY TS, GLEN AS, NIMMO DG, RITCHIE EG & DICKMAN CR. 2016. Invasive predators and global biodiversity loss. Proc Natl Acad Sci USA 113: 11261-11265.
FONTAINE B, PERRARD A & BOUCHET P. 2012. 21 years of shelf life between discovery and description of new species. Curr Biol 22: 943-944.
GAMBLE T, BAUER AM, COLLI GR, GREENBAUM E, JACKMAN TR, VITT LJ & SSIMONS AM. 2011. Coming to America: multiple origins of New World geckos. J Evolution Biol 24: 231-244.
GIPPNER S ET AL. 2021. A comprehensive phylogeny of dwarf geckos of the genus Lygodactylus, with insights into their systematic and morphological variation. Mol Phylogenet Evol 165: 107311.
GIPPOLITI S & AMORI G. 2011. A new species of mole-rat (Rodentia, Bathyergidae) from the Horn of Africa. Zootaxa 2918: 39-46.
GRAY JE. 1845. Catalogue of the specimens of lizards in the collection of the British Museum. Trustees of the British Museum/Edward Newman, London, 289 p.
GUEDES JM, FEIO RN, MEIRI S & MOURA MR. 2020. Identifying factors that boost species discoveries of global reptiles. Zool J Linn Soc-Lond 190: 1274-1284.
HELGEN KM, PINTO M, KAYS R, HELGEN L, TSUCHIYA M, QUINN A, WILSON D & MALDONADO J. 2013. Taxonomic revision of the olingos (Bassaricyon), with description of a new species, the Olinguito. ZooKeys 324: 1-83.
HILTON EJ, WATKINS-COLWELL G & HUBBER SK. 2021. The expanding roles of natural history collections. Ichthyol Herpetol 109: 379-391.
JONES EP, EAGER HM, GABRIEL SI, JÓHANNESDÓTTIR F & SEARLE JB. 2013. Genetic tracking of mice and other bioproxies to infer human history. Trends Genet 29: 298308.
KOCH C, MARTINS A & SCHWEIGER S. 2019. A century of waiting: description of new Epictia Gra, 1845 (Serpentes: Leptotyphlopidae) based on specimens housed more than 100 years in the collection of Natural History Museum Vienna (NMW). PeerJ 7: e7411.
LANNA FM, GEHARA M, WERNECK FP, FONSECA EM, COLLI GR, SITES JR J, RODRIGUES MT & GARDA AA. 2020. Dwarf geckos and giant rivers: the role of the São Francisco River in the evolution of Lygodactylus klugei (Squamata: Gekkonidae) in the semi-arid Caatinga of north-eastern Brazil. Biol J Linn Soc 129: 88-98.
LANNA FM, WERNECK FP, GEHARA M, FONSECA EM, COLLI GR, SITES JR JW, RODRIGUES MT & GARDA AA. 2018. The evolutionary history of Lygodactylus lizards in the South American open diagonal. Mol Phylogenet Evol 127: 638-645.
LOVERIDGE A. 1947. Revision of the African lizards of the family Gekkonidae. Bull Mus Comp Zool 98: 1-469.
MARQUES MP, CERÍACO LMP, BUEHLER MD, BANDEIRA SA, JANOTA JM & BAUER AM. 2020. A revision of the Dwarf Geckos, genus Lygodactylus (Squamata: Gekkonidae) from Angola, with the description of three new species. Zootaxa 4853: 201-352.
MAYR E & ASHLOCK PD. 1991. Principles of Systematic Zoology, Second Edition. McGraw Hill, 475 p.
MICHELETTI T ET AL. 2020. Terrestrial invasive species on Fernando de Noronha archipelago: what we know and the way forward. In: LONDE V (Ed), Invasive Species. Nova Science Publishers, 52-94 p.
NOGALES M, VIDAL E, MEDINA FM, BONNAUD E, TERSHY BR, CAMPBELL KJ & ZAVALETA ES. 2013. Feral cats and biodiversity conservation: the urgent prioritization of island management. BioScience 63: 804-810.
NORDER SJ ET AL. 2020. Global change in microcosms: environmental and societal predictors of land cover change on the Atlantic Ocean Islands. Anthropocene 30: 1-9.
OLSON DC. 1981. Natural history of vertebrates of the Brazilian islands of the mid south Atlantic. Natl Geogr Res 13: 481-492.
OREN DC. 1984. Resultados de uma nova expedição zoológica a Fernando de Noronha. Bol Mus Para Emílio Goeldi Zool 1(1): 19-44.
PASTEUR G. 1965 [1964]. Recherches sur l’evolution des lygodactyles, lézards Afro-Malgaches actuels. Trav I Scient Chérifien Zool 9: 1-132, pls, 1-12.
PUENTE M, GLAW F, VIEITES DR & VENCES M. 2009. Review of the systematics, morphology and distribution of Malagasy dwarf geckos, genera Lygodactylus and Microscalabotes (Squamata: Gekkonidae). Zootaxa 2103(1): 1-76.
RIDLEY HN. 1888. A visit to Fernando do Noronha. Zoologist 12: 41-49.
RIDLEY HN. 1890. Notes on the zoology of Fernando Noronha. Zool J Linn Soc-Lond 20: 473-570.
RUSSEL JC, ABRAHÃO CR, SILVA JCR & DIAS RA. 2018. Management of cats and rodents on inhabited islands: an overview and case study of Fernando de Noronha, Brazil. Perspect Ecol Conserv 16: 193-200.
RUSSEL JC, MEYER J-Y, HOLMES ND & PAGAD S. 2017. Invasive alien species on island: impacts, distribution, interactions and management. Environ Conserv 44(4): 359-370.
SABAJ MH. 2020. Codes for Natural History collections in ichthyology and herpetology. Copeia 108(3): 593-669.
SANCHEZ M. 2021. Phelsuma inexpectata. The IUCN Red List of Threatened Species 2021: e.T17450049A17450059. https://dx.doi.org/10.2305/IUCN.UK.2021-2.RLTS.T17450049A17450059.en. Accessed on 13 February 2023.
» https://doi.org/10.2305/IUCN.UK.2021-2.RLTS.T17450049A17450059.en
SANCHEZ M & PROBST J-M. 2011. Distribution and conservation status of the Manapany day gecko, Phelsuma inexpectata Mertens, 1966, an endemic threatened reptile from Reunion Island (Squamata: Gekkonidae). Cah Scient Ocean Ind Occid 2: 13-28.
SANCHEZ M & PROBST J-M. 2014. Distribution and habitat of the invasive giant day gecko Phelsuma grandis Gray 1870 (Sauria: Gekkonidae) in Reunion Island, and conservation implication. Phelsuma 22: 13-28.
SMITH HM, MARTIN RL & SWAIN TA. 1977. A new genus and two new species of South American geckos (Repilia: Lacertilia). Pap Avulsos de Zool 30: 195-213.
SUAREZ AV & TSUTSUI ND. 2004. The value of museum collections for research and society. BioScience 54: 66-74.
THOMSON CW & MURRAY J. 1885. Report on the scientific results of the voyage of H.M.S. Challenger during the years 1873-76. Narrative – Vol. I. London: Longmans & Co., 509 p.
TOLEDO LF, ZANOTTI AP, BEZERRA LMLS, ABRAHÃO C & LISBOA CS. 2023. Occasional herpetofaunal introductions into and from the archipelago of Fernando de Noronha, Brazil. Spixiana 45: 271-275.
TRAVASSOS H. 1946. Estudo da variação de Mabuya punctata(Gray, 1839) (Ordem Squamata Oppel, 1881 – Fam. Scincidae Gray, 1825). Bol Mus Nac Zool 60: 1-56.
UETZ P, FREED P & HOSEK J (Eds). 2023. The Reptile Database. Available in: http://reptile-database.org
» http://reptile-database.org
VANZOLINI PE. 1968a. Lagartos Brasileiros da família Gekkonidae (Sauria). Arq Zool 17(1): 1-84.
VANZOLINI PE. 1968b. Geography of the South American Gekkonidae (Sauria). Arq Zool 17(2): 85-112.
VANZOLINI PE. 1974. Ecological and geographical distribution of lizards in Pernambuco, northeastern Brasil (Sauria). Pap Avulsos Zool 28: 61-90.
VANZOLINI PE, RAMOS-COSTA AMM & VITT LJ. 1980. Répteis das caatingas. Academia Brasileira de Ciências, 161 p.
VELAZCO P & PATTERSON B. 2014. Two new species of yellow-shouldered bats, genus Sturnira Gray, 1842 (Chiroptera, Phyllostomidae) from Costa Rica, Panama and western Ecuador. ZooKeys 402: 43-66.
WATANABE ME. 2019. The evolution of natural history collections. BioScience 69: 163- 169.
WEBSTER WHB. 1834a. Narrative of a voyage to the Southern Atlantic ocean in the years 1828, 29, 30, performed in H. M. Sloop Chanticleer, under the command of the late Captain Henry Foster, F.R.S. &c. Vol. I, London: Richard Bentley, 398 p.
WEBSTER WHB. 1834b. Narrative of a voyage to the Southern Atlantic ocean in the years 1828, 29, 30, performed in H. M. Sloop Chanticleer, under the command of the late Captain Henry Foster, F.R.S. &c. Vol. II, London: Richard Bentley, 398 p.

Publication Dates

Publication in this collection
20 Oct 2023
Date of issue
2023

History

Received
3 Mar 2023
Accepted
28 May 2023

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

[1] BRANNER JC. 1888. Notes on the fauna of the islands of Fernando de Noronha. Am Nat 22(262): 861-871.

[2] BONS J & PASTEUR G. 1977. Solution histologique a un probleme de taxinomie herpetologique interessant les rapports paleobiologiques de l’Amerique du Sud et de l’Afrique. C R Acad Sci Paris 248: 2547-2750.

[3] CARLETON MD & OLSON SL. 1999. Amerigo Vespucci and the Rat of Fernando de Noronha: a new genus and species of Rodentia (Muridae: Sigmodontinae) from a volcanic island off Brazil’s continental shelf. Am Mus Novit 3256: 1-59.

[4] CERÍACO LMP. 2015. Lost in the middle of the sea, found in the back of the shelf: a new giant species of Trachylepis (Squamata: Scincidae) from Tinhosa Grande islet, Gulf of Guinea. Zootaxa 3973(3): 511-527.

[5] CERÍACO LMP, SANTOS BS, MARQUES MP, BAUER AM & TIUTENKO A. 2021. Citizen Science meets specimens in old formalin filled jars: a new species of Banded Rubber Frog, genus Phrynomantis (Anura, Phrynomeridae) from Angola. Alytes 38: 18-48.

[6] DIAS RA ET AL. 2017. Prospects for domestic and feral cat management on an inhabited tropical island. Biol. Invasions 10: 2339-2353.

[7] DOHERTY TS, GLEN AS, NIMMO DG, RITCHIE EG & DICKMAN CR. 2016. Invasive predators and global biodiversity loss. Proc Natl Acad Sci USA 113: 11261-11265.

[8] FONTAINE B, PERRARD A & BOUCHET P. 2012. 21 years of shelf life between discovery and description of new species. Curr Biol 22: 943-944.

[9] GAMBLE T, BAUER AM, COLLI GR, GREENBAUM E, JACKMAN TR, VITT LJ & SSIMONS AM. 2011. Coming to America: multiple origins of New World geckos. J Evolution Biol 24: 231-244.

[10] GIPPNER S ET AL. 2021. A comprehensive phylogeny of dwarf geckos of the genus Lygodactylus, with insights into their systematic and morphological variation. Mol Phylogenet Evol 165: 107311.

[11] GIPPOLITI S & AMORI G. 2011. A new species of mole-rat (Rodentia, Bathyergidae) from the Horn of Africa. Zootaxa 2918: 39-46.

[12] GRAY JE. 1845. Catalogue of the specimens of lizards in the collection of the British Museum. Trustees of the British Museum/Edward Newman, London, 289 p.

[13] GUEDES JM, FEIO RN, MEIRI S & MOURA MR. 2020. Identifying factors that boost species discoveries of global reptiles. Zool J Linn Soc-Lond 190: 1274-1284.

[14] HELGEN KM, PINTO M, KAYS R, HELGEN L, TSUCHIYA M, QUINN A, WILSON D & MALDONADO J. 2013. Taxonomic revision of the olingos (Bassaricyon), with description of a new species, the Olinguito. ZooKeys 324: 1-83.

[15] HILTON EJ, WATKINS-COLWELL G & HUBBER SK. 2021. The expanding roles of natural history collections. Ichthyol Herpetol 109: 379-391.

[16] JONES EP, EAGER HM, GABRIEL SI, JÓHANNESDÓTTIR F & SEARLE JB. 2013. Genetic tracking of mice and other bioproxies to infer human history. Trends Genet 29: 298308.

[17] KOCH C, MARTINS A & SCHWEIGER S. 2019. A century of waiting: description of new Epictia Gra, 1845 (Serpentes: Leptotyphlopidae) based on specimens housed more than 100 years in the collection of Natural History Museum Vienna (NMW). PeerJ 7: e7411.

[18] LANNA FM, GEHARA M, WERNECK FP, FONSECA EM, COLLI GR, SITES JR J, RODRIGUES MT & GARDA AA. 2020. Dwarf geckos and giant rivers: the role of the São Francisco River in the evolution of Lygodactylus klugei (Squamata: Gekkonidae) in the semi-arid Caatinga of north-eastern Brazil. Biol J Linn Soc 129: 88-98.

[19] LANNA FM, WERNECK FP, GEHARA M, FONSECA EM, COLLI GR, SITES JR JW, RODRIGUES MT & GARDA AA. 2018. The evolutionary history of Lygodactylus lizards in the South American open diagonal. Mol Phylogenet Evol 127: 638-645.

[20] LOVERIDGE A. 1947. Revision of the African lizards of the family Gekkonidae. Bull Mus Comp Zool 98: 1-469.

[21] MARQUES MP, CERÍACO LMP, BUEHLER MD, BANDEIRA SA, JANOTA JM & BAUER AM. 2020. A revision of the Dwarf Geckos, genus Lygodactylus (Squamata: Gekkonidae) from Angola, with the description of three new species. Zootaxa 4853: 201-352.

[22] MAYR E & ASHLOCK PD. 1991. Principles of Systematic Zoology, Second Edition. McGraw Hill, 475 p.

[23] MICHELETTI T ET AL. 2020. Terrestrial invasive species on Fernando de Noronha archipelago: what we know and the way forward. In: LONDE V (Ed), Invasive Species. Nova Science Publishers, 52-94 p.

[24] NOGALES M, VIDAL E, MEDINA FM, BONNAUD E, TERSHY BR, CAMPBELL KJ & ZAVALETA ES. 2013. Feral cats and biodiversity conservation: the urgent prioritization of island management. BioScience 63: 804-810.

[25] NORDER SJ ET AL. 2020. Global change in microcosms: environmental and societal predictors of land cover change on the Atlantic Ocean Islands. Anthropocene 30: 1-9.

[26] OLSON DC. 1981. Natural history of vertebrates of the Brazilian islands of the mid south Atlantic. Natl Geogr Res 13: 481-492.

[27] OREN DC. 1984. Resultados de uma nova expedição zoológica a Fernando de Noronha. Bol Mus Para Emílio Goeldi Zool 1(1): 19-44.

[28] PASTEUR G. 1965 [1964]. Recherches sur l’evolution des lygodactyles, lézards Afro-Malgaches actuels. Trav I Scient Chérifien Zool 9: 1-132, pls, 1-12.

[29] PUENTE M, GLAW F, VIEITES DR & VENCES M. 2009. Review of the systematics, morphology and distribution of Malagasy dwarf geckos, genera Lygodactylus and Microscalabotes (Squamata: Gekkonidae). Zootaxa 2103(1): 1-76.

[30] RIDLEY HN. 1888. A visit to Fernando do Noronha. Zoologist 12: 41-49.

[31] RIDLEY HN. 1890. Notes on the zoology of Fernando Noronha. Zool J Linn Soc-Lond 20: 473-570.

[32] RUSSEL JC, ABRAHÃO CR, SILVA JCR & DIAS RA. 2018. Management of cats and rodents on inhabited islands: an overview and case study of Fernando de Noronha, Brazil. Perspect Ecol Conserv 16: 193-200.

[33] RUSSEL JC, MEYER J-Y, HOLMES ND & PAGAD S. 2017. Invasive alien species on island: impacts, distribution, interactions and management. Environ Conserv 44(4): 359-370.

[34] SABAJ MH. 2020. Codes for Natural History collections in ichthyology and herpetology. Copeia 108(3): 593-669.

[35] SANCHEZ M. 2021. Phelsuma inexpectata. The IUCN Red List of Threatened Species 2021: e.T17450049A17450059. https://dx.doi.org/10.2305/IUCN.UK.2021-2.RLTS.T17450049A17450059.en. Accessed on 13 February 2023.
» https://doi.org/10.2305/IUCN.UK.2021-2.RLTS.T17450049A17450059.en

[36] SANCHEZ M & PROBST J-M. 2011. Distribution and conservation status of the Manapany day gecko, Phelsuma inexpectata Mertens, 1966, an endemic threatened reptile from Reunion Island (Squamata: Gekkonidae). Cah Scient Ocean Ind Occid 2: 13-28.

[37] SANCHEZ M & PROBST J-M. 2014. Distribution and habitat of the invasive giant day gecko Phelsuma grandis Gray 1870 (Sauria: Gekkonidae) in Reunion Island, and conservation implication. Phelsuma 22: 13-28.

[38] SMITH HM, MARTIN RL & SWAIN TA. 1977. A new genus and two new species of South American geckos (Repilia: Lacertilia). Pap Avulsos de Zool 30: 195-213.

[39] SUAREZ AV & TSUTSUI ND. 2004. The value of museum collections for research and society. BioScience 54: 66-74.

[40] THOMSON CW & MURRAY J. 1885. Report on the scientific results of the voyage of H.M.S. Challenger during the years 1873-76. Narrative – Vol. I. London: Longmans & Co., 509 p.

[41] TOLEDO LF, ZANOTTI AP, BEZERRA LMLS, ABRAHÃO C & LISBOA CS. 2023. Occasional herpetofaunal introductions into and from the archipelago of Fernando de Noronha, Brazil. Spixiana 45: 271-275.

[42] TRAVASSOS H. 1946. Estudo da variação de Mabuya punctata(Gray, 1839) (Ordem Squamata Oppel, 1881 – Fam. Scincidae Gray, 1825). Bol Mus Nac Zool 60: 1-56.

[43] UETZ P, FREED P & HOSEK J (Eds). 2023. The Reptile Database. Available in: http://reptile-database.org
» http://reptile-database.org

[44] VANZOLINI PE. 1968a. Lagartos Brasileiros da família Gekkonidae (Sauria). Arq Zool 17(1): 1-84.

[45] VANZOLINI PE. 1968b. Geography of the South American Gekkonidae (Sauria). Arq Zool 17(2): 85-112.

[46] VANZOLINI PE. 1974. Ecological and geographical distribution of lizards in Pernambuco, northeastern Brasil (Sauria). Pap Avulsos Zool 28: 61-90.

[47] VANZOLINI PE, RAMOS-COSTA AMM & VITT LJ. 1980. Répteis das caatingas. Academia Brasileira de Ciências, 161 p.

[48] VELAZCO P & PATTERSON B. 2014. Two new species of yellow-shouldered bats, genus Sturnira Gray, 1842 (Chiroptera, Phyllostomidae) from Costa Rica, Panama and western Ecuador. ZooKeys 402: 43-66.

[49] WATANABE ME. 2019. The evolution of natural history collections. BioScience 69: 163- 169.

[50] WEBSTER WHB. 1834a. Narrative of a voyage to the Southern Atlantic ocean in the years 1828, 29, 30, performed in H. M. Sloop Chanticleer, under the command of the late Captain Henry Foster, F.R.S. &c. Vol. I, London: Richard Bentley, 398 p.

[51] WEBSTER WHB. 1834b. Narrative of a voyage to the Southern Atlantic ocean in the years 1828, 29, 30, performed in H. M. Sloop Chanticleer, under the command of the late Captain Henry Foster, F.R.S. &c. Vol. II, London: Richard Bentley, 398 p.

Catalogue number	Sex	SVL	TrunkL	TL	TW	HL	HW	HH	EARL	ED	NE	SE	EE	IN	PCL	MRDS	MRVS	FFingL	FToeL	SL	IL
27809 (holotype)	male	26,5	11,6	26,6	3,4	8,1	5,2	3,3	0,5	1,8	2,5	3,2	2,2	1,3	7	21	55	5	5	8/8	7/7
27806 (paratype)	male	28,3	12,7	26,8	3,5	7,4	5,2	3,8	0,5	1,8	3,1	3,6	2,8	1,4	8	22	57	5	5	9/9	8/8
27807 (paratype)	male	28	12,3	26,9	3,4	8	4,7	3,7	0,5	2	2,7	3,5	2,3	1,1	7	17	57	5	5	9/9	7/7
27808 (paratype)	male	29,1	13,6	27,8	3,7	8,2	5,1	3,3	0,5	1,8	3,1	3,4	2,5	1,3	8	22	58	5	5	8/8	7/7
27810 (paratype)	male	26,7	11,5	22,1	3	7,8	4,9	3,3	0,5	1,6	2,5	3,5	2,3	1,2	7	20	53	5	5	8/8	7/7
27811 (paratype)	male	27,5	12	22,8	3,5	7,9	5,2	3,5	0,5	1,6	2,5	3,5	2,3	1,4	7	22	56	5	5	7/7	7/7
27812 (paratype)	female	29,4	14,9	25,4	3,3	7,2	5,2	3,8	0,5	1,7	2,6	3,3	2,2	1,4	–	22	52	5	5	7/7	7/7
27813 (paratype)	male	28,7	12,8	27,1	3,4	8,2	5,3	3,6	0,5	1,8	2,9	3,4	2,6	1,2	6	25	49	5	5	8/8	7/6
27814 (paratype)	female	29,7	13,9	28,2	3,6	8,5	5,3	3,8	0,5	1,9	2,9	3,2	2,4	1,2	–	26	50	5	5	7/8	6/6
27815 (paratype)	male	29,1	14,2	26,1	3,5	8,3	5,7	3,9	0,5	2,1	2,6	3,4	2,5	1,1	7	25	51	5	5	7/8	7/7
27817 (paratype)	male	25,9	10,4	–	3,1	6,6	5,1	3,9	0,4	1,4	2,8	3,3	2,4	1,4	7	15	58	5	5	7/7	6/6
27818 (paratype)	female	28,2	14,3	–	3,3	7,4	5	3,5	0,5	1,5	2,8	3,5	2,4	1,3	–	21	57	5	5	7/7	6/6
27819 (paratype)	female	26,4	12,4	–	3,1	8,6	5,4	3,8	0,5	1,3	3,3	3,3	2,3	1,5	–	19	56	5	5	7/–	6/–
27820 (paratype)	male	27,1	12,6	–	3,4	8,1	5,1	3,9	0,5	1,6	2,9	3,7	2,4	1,2	7	20	58	5	5	8/8	7 /7
27821 (paratype)	male	27,8	12,6	–	3,3	6,9	4,9	3,7	0,6	1,4	2,7	3,5	2,4	1,5	7	19	56	5	5	8/8	6/6
27822 (paratype)	male	27,3	11,4	26,3	3,6	8	5,1	3,5	0,5	1,4	2,7	3,3	2,2	1,2	7	21	57	5	5	8/8	7/7
27823 (paratype)	female	29,1	12,8	–	3,6	8,3	5,2	3,7	0,5	1,6	2,9	3,6	2,7	1,3	–	18	55	5	5	7 /8	7/ 7
27824 (paratype)	female	27,4	11,5	–	2,9	7,3	5	3,6	0,4	1,6	2,7	3,5	2,4	1,4	–	20	61	5	5	8/7	6/6
27825 (paratype)	female	28,2	12,3	–	2,8	7,6	5,1	3,9	0,5	1,5	2,4	3,4	2,3	1,5	–	18	56	5	5	8/8	7/7
27826 (paratype)	male	28,8	12,3	–	3,3	7,2	5,3	3,9	0,5	1,5	2,8	3,7	2,6	1,4	7	17	54	5	5	7/8	7/7
27827 (paratype)	male	26,3	11,5	–	3,6	6,5	5,3	3,6	0,5	1,6	3,4	3,6	2,3	1,5	7	18	61	5	5	8/8	7/7
27828 (paratype)	female	27,8	12,8	–	3,1	6,5	5,5	3,9	0,5	1,6	3	3,5	2,3	1,5	–	19	57	5	5	8/8	6/6
27829 (paratype)	male	26,8	11	25,5	3,5	6,9	5,2	3,7	0,5	1,5	3,4	3,8	2,3	1,5	7	19	56	5	5	7/7	6/6
27830 (paratype)	male	27,5	12,1	11,1	3,2	7,1	4,8	3,8	0,5	1,5	2,6	3,5	2,2	1,4	7	20	57	5	5	7/7	7/7
27831 (paratype)	male	26,5	10,2	–	3	6,7	4,9	3,4	0,5	1,5	3,2	3,4	2,4	1,6	7	19	57	5	5	7/7	6/6
27832 (paratype)	female	29,1	13	–	3	8,7	5,4	4	0,5	1,7	3,3	3,8	2,4	1,2	–	18	50	5	5	7 /8	7 /6
27833 (paratype)	male	26,8	11,7	–	3,3	7,8	5	3,8	0,5	1,4	2,7	3,4	2,1	1,5	6	21	60	5	5	7/7	6/6
27834 (paratype)	female	26,2	11,2	19,6	2,8	7,4	4	3,2	0,5	1,3	2,5	3	2,3	1,4	–	17	58	5	5	6/7	6/5
27835 (paratype)	male	27,4	12	20	3,7	7,3	5,3	3,8	0,5	1,4	3,2	3,8	2,3	1,4	7	20	57	5	5	8/7	6/6
27836 (paratype)	male	26,6	12,2	–	3,1	7,2	5	4,1	0,7	1,5	3,1	3,6	2,2	1,6	–	17	58	5	5	7/–	6/–
27837 (paratype)	male	27,1	11,1	–	3,6	7	5	3,8	0,5	1,5	3,3	3,3	2,1	1,3	7	20	55	5	5	8/7	6/6
27838 (paratype)	female	29,4	12,8	18,7	2,5	7,4	4,6	3,8	0,5	1,5	3,3	3,6	2,4	1,5	–	19	58	5	5	7/7	6/7
27839 (paratype)	male	25,3	10,4	25,7	3,6	7,6	5,2	3,7	0,5	1,3	2,6	3,5	2,1	1,3	7	19	61	5	5	7/7	6/6
27840 (paratype)	female	25	12,3	22,3	3	6,7	4,9	3,9	0,5	1,6	3,2	3,5	2,4	1,5	–	19	58	5	5	8/8	7/7
27841 (paratype)	female	28,6	13,1	–	3,3	7,7	5	3,2	0,5	1,5	3	3,4	2,1	1,3	–	19	60	5	5	7/7	7/6
27842 (paratype)	female	27,2	12,7	–	3,1	7,4	5,1	3,9	0,5	1,5	2,8	3,5	2,3	1,3	–	15	62	5	5	7/7	7/7
27843 (paratype)	male	28,9	14,2	–	3,6	8,1	5	3,7	0,5	1,5	3,1	3,7	2,6	1,4	8	19	56	5	5	8/8	6/7
27844 (paratype)	male	24,7	11	–	2,6	7,2	4,4	3,3	0,5	1,4	2,7	3,1	2,2	1,3	8	20	58	5	5	7/7	6/6
27845 (paratype)	male	24,8	11,4	–	2,6	7,1	4,4	3,8	0,5	1,3	2,6	3	2	1,3	7	20	58	5	5	7/7	6/–
27846 (paratype)	male	25,7	11	–	3,1	7,1	4,7	3,7	0,5	1,5	2,5	3	2,2	1,6	7	19	53	5	5	8/7	7/6
27847 (paratype)	male	24,1	9,7	–	3,1	6,3	4,4	3,6	0,4	1,3	2,5	3,2	2,2	1,4	7	22	51	5	5	8/8	7/7
27848 (paratype)	male	26,7	11,3	20	3,2	6,7	–	–	0,4	1,4	2,6	3,4	2,3	1,4	7	17	56	5	5	8/8	7/–
27849 (paratype)	female	25	11	20	3,2	6	4,9	3,4	0,6	1,4	2,9	3,5	2,2	1,4	–	19	60	5	5	8/8	6/6
27850 (paratype)	male	22,8	9	–	3	6,2	4,7	3	0,5	1,5	2,6	3,2	–	1,4	7	19	58	5	5	7/7	6/–
27851 (paratype)	female	26,7	13,3	–	2,9	7	4,9	3,5	0,5	1,4	2,4	3,5	2,1	1,5	–	19	59	5	5	8/8	7/7
27852 (paratype)	male	25,3	11,3	25	3,6	–	–	–	–	–	3	–	–	–	7	17	58	5	5	7/–	6/–
27853 (paratype)	female	24,9	10,3	13,6	1,9	6	3,7	2,3	0,5	1,4	2,8	3,2	2,2	1,3	–	20	56	5	5	7/7	6/6
27854 (paratype)	male	23,5	8,6	–	1,6	5,9	3,4	2	0,5	1,3	2,8	3,2	2,1	1,4	7	22	58	5	5	7/7	6/6
27855 (paratype)	male	23,9	12	20,1	3,1	6	5,1	3,3	0,4	1,2	2,9	3,4	2,3	1,2	7	21	60	5	5	8/8	8/7
27856 (paratype)	male	24	9,4	–	3,2	6,6	4,7	3,6	0,5	1,5	3	3	2,2	1,2	7	17	56	5	5	7/7	6/6
27857 (paratype)	female	27,1	13	20,8	2,8	7,6	5,2	3,7	–	1,6	3,2	3,7	–	1,5	–	18	61	5	5	8/8	7/8

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