Four new species of Pristimantis Jiménez de la Espada, 1870 (Anura: Craugastoridae) in the eastern Amazon

Elciomar Araújo de Oliveira; Leandro Alves da Silva; Elvis Almeida Pereira Silva; Karen Larissa Auzier Guimarães; Marcos Penhacek; José Gregório Martínez; Luís Reginaldo Ribeiro Rodrigues; Diego José Santana; Emil José Hernández-Ruz

doi:10.1371/journal.pone.0229971

Abstract

The Pristimantis genus (Anura: Craugastoridae) is the most diverse among all vertebrates with 531 described species. The highest diversity occurs in Ecuador (215 species), followed by Colombia (202), Peru (139), Venezuela (60), Brazil (30), Bolivia (17), Guyana (6) Suriname and French Guiana (5). The genus is divided into 11 species groups. Of these, the P. conspicillatus group (containing 34 species), distributed in extreme southeastern Costa Rica, Isla Taboga (Panama), northern South America (from Colombia to eastern Guyana), south Bolivia, and is the best represented in Brazil (16 species). The main characteristics of this group are the tympanic membrane and tympanic annulus distinct (except in P. johannesdei); dorsum smooth or shagreen; dorsal lateral fold present or absent; usually smooth belly, but may be weakly granular in some species; toe V slightly larger than the toe III. Most of the taxonomic inconsistencies in species of Pristimantis could be due to its much conserved morphology and the lack of comprehensive taxonomic evaluations. Thus, an ongoing challenge for taxonomists dealing with the Pristimantis genus is the ubiquitous abundance of cryptic species. In this context, accurate species delimitation should integrate evidences of morphological, molecular, bioacoustics and ecological data, among others. Based on an integrative taxonomy perspective, we utilize morphological, molecular (mtDNA) and bioacoustic evidence to describe four new species of the Pristimantis conspicillatus group from the eastern Amazon basin. Pristimantis giorgii sp. nov. is known from the Xingu/Tocantins interfluve and can be distinguished from the other Pristimantis species of the region by presenting discoidal fold, dorsolateral fold absent, vocalization composed of three to four notes and genetic distance of 7.7% (16S) and 14.8% (COI) from P. latro, the sister and sympatric species with respect P. giorgii sp. nov.. Pristimantis pictus sp. nov. is known to the northern Mato Grosso state, Brazil, and can be distinguished from the other species of Pristimantis by presenting the posterior surface of the thigh with light yellow patches on a brown background, also extending to the inguinal region, vocalization consisting of four to five notes and a genetic distance of 11.6% (16S) and 19.7% (COI) from P. pluvian sp. nov., which occurs in sympatry. Pristimantis pluvian sp. nov. is known to the northern Mato Grosso state, Brazil, and may be distinguished from the other Pristimantis species by having a posterior surface of the thigh reddish and vocalization composed of two notes. Pristimantis moa sp. nov. is known to the northern Tocantins state and southwestern Maranhão state. This species can be distinguished from the other Pristimantis species by possessing slightly perceptible canthal stripe, external thigh surface with dark yellow spots on brown background, vocalization consisting of three to five notes and genetic distance of 2.3–11.7 (16S) and 10.5–23.1 (COI) for the new Pristimantis species of this study.

Citation: de Oliveira EA, da Silva LA, Silva EAP, Guimarães KLA, Penhacek M, Martínez JG, et al. (2020) Four new species of Pristimantis Jiménez de la Espada, 1870 (Anura: Craugastoridae) in the eastern Amazon. PLoS ONE 15(3): e0229971. https://doi.org/10.1371/journal.pone.0229971

Editor: Riccardo Castiglia, Universita degli Studi di Roma La Sapienza, ITALY

Received: June 12, 2019; Accepted: February 16, 2020; Published: March 18, 2020

Copyright: © 2020 Oliveira et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: All relevant data are within the manuscript and its Supporting Information files.

Funding: Thanks to Capes, according Edital 143/2019, item 11.1, b) “This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES) - Finance Code 001”. EAO was supported by the “Programa de Apoio à Produção Qualificada” - PAPQ/UFPA (Proc.N. 23073.026959/2016-92) and received PhD scholarship from Conselho Nacional de Desenvolvimento Científico and Tecnológico (CNPq/Brazil-www.cnpq.br http://brazil-www.cnpq.br) (Proc.N. 141718/2016-1). LAS thanks to CNPq by the scholarship (140408/2018-5). KLAG received Mastership from Coordenação de Aperfeiíoamento de Pessoal de Nível Superior (CAPES/Brazil-www.capes.gov.br http://brazil-www.capes.gov.br/>). DJS thanks CNPq for his research fellowship (311492/2017-7). LRRR received grants from CAPES/ProAmazônia (AUXPE 3318/2013). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

The genus Pristimantis Jiménez de la Espada 1870, is the most diverse among vertebrates [1], currently comprised of 531 valid species, 155 of which have only been described in the last decade [2]. Most species of this genus occur in the western part of the Amazon [3]. The topographic heterogeneity of the Andes, accompanied by the life history of Pristimantis (direct development, high endemism and the ability to colonize a wide variety of habitat types, including highlands) could be partially responsible for this great diversity [4]. In the eastern Amazon, few studies have focused on taxonomic aspects of Pristimantis populations, and most of the information about this genus comes from faunal inventories [5–8], of which many do not present specific identification of existing lineages [9].

The genus is currently divided into 11 morphologically defined groups of species [10]. The P. conspicillatus group contains 34 species distributed mainly in northern South America (from Costa Rica to eastern Guyana and Taboga Islands), south Bolivia and Atlantic forest, Brazil [11]. The main characteristics of this group are the tympanic membrane and tympanic annulus distinct (except in P. johannesdei Rivero & Serna 1988); dorsum smooth or shagreen; lateral dorsal fold present or absent; usually smooth belly, but may be weakly granular in some species; toe V slightly larger than the toe III (for more details see Hedges and colleagues [11]. In Brazil, 16 species of the aforementioned group are known: Pristimantis buccinator (Rodriguez, 1994), P. chiastonotus (Lynch & Hoogmoed, 1977), P. conspicillatus (Gunther, 1858), P. dundeei (Heyer & Muñoz, 1999), P. fenestratus (Steindachner, 1864), P. gutturalis (Hoogmoed, Lynch & Lescure, 1977), P. latro de Oliveira, Rodrigues, Kaefer, Pinto, and Hernández-Ruz 2017, P. malkini (Lynch, 1980), P. paulodutrai (Bokermann, 1975), P. peruvianus (Melin, 1941), P. ramagii (Boulenger, 1888), P. skydmainos (Flores & Rodriguez, 1997), P. ventrigranulosus (Maciel, Vaz-Silva, Oliveira & Padial, 2012), P. vilarsi (Melin, 1941), P. vinhai (Bokermann, 1975) and P. zeuctotylus (Lynch & Hoogmoed, 1977).

The species of the P. conspicillatus group mentioned above, only P. gutturalis, P. chiastonotus, P. zeuctotylus, P. latro and P. dundeei occur in the eastern Amazon rainforest. Adding P. inguinalis, P. marmoratus (Boulenger, 1900), and P. zimmermanae (Heyer & Hardy, 1991) are recorded eight species of Pristimantis to the east of the Brazilian Amazon. This region has been suffering from strong deforestation pressures in recent years, causing habitat loss, which is one of the main threats to biodiversity [12], [13].

Most of the taxonomic inconsistencies within Pristimantis can be attributed to its conserved morphology and its high diversity [1], [9], [14]. The conserved morphology of the species is seen in the high cryptic diversity within the genus, where distinct lineages are usually associated with the same nominal species [15], [16]. Given this context, correctly delimiting a species often requires an integrative approach, associating morphological, molecular, and bioacoustic data [14], [17], [18]. After several expeditions in different regions of the eastern Amazon and north Cerrado, we recorded Pristimantis lineages that we could not associate with any nominal species. Based on an integrative taxonomy framework, herein we describe four new Pristimantis species belonging to the P. conspicillatus group.

Materials and methods

Ethics statement

The permits for field samples collections were provided by the Brazilian Government (SISBIO licence N 30034–1, 32401, 54493–5, and 54493–11). Although euthanized methods were not evaluated by an institutional animal care and use committee or similar regional ethics committee, voucher collections strictly complied with the ethical conditions as dictated by the Sistema of Autorização and Informação in Biodiversidade–SISBIO, environmental authorities of Brazil (see scientific license numbers above). The collected frogs were euthanized by topical application of a 2% liquid solution of lidocaine hydrochloride, fixed in 10% formalin and transferred to permanent collections in alcohol 70%. We collected tissue samples (muscle and liver) before individuals were fixated and stored.

Nomenclatural acts

The electronic edition of this article conforms to the requirements of the amended International Code of Zoological Nomenclature, and hence the new names contained herein are available under that Code from the electronic edition of this article. This published work and the nomenclatural acts it contains have been registered in ZooBank, the online registration system for the ICZN. The ZooBank LSIDs (Life Science Identifiers) can be resolved and the associated information viewed through any standard web browser by appending the LSID to the prefix “http://zoobank.org/”. The LSID for this publication is: urn:lsid:zoobank.org:pub:A1A7A538-68C8-401B-B706-6C7C16D87296. The electronic edition of this work was published in a journal with an ISSN, and has been archived and is available from the following digital repositories: PubMed Central, LOCKSS.

Sampling

We conducted active searches in 27 localities, including areas typical to the Amazonian domain (Pará state and northern Mato Grosso state), transition areas between the Amazon and Cerrado (Araguaína, in Tocantins state and Balsas, in Maranhão state) and Cerrado areas (Riachão in Maranhão state and Palmas in Tocantins state) (Fig 1). Additionally, we analyzed 291 specimens from the following zoological collections: Coleção Zoológica de Referência da Universidade Federal do Mato Grosso do Sul (ZUFMS-AMP), Acervo Biológico da Amazônia Meridional (ABAM) da Universidade Federal do Mato Grosso (UFMT/Sinop), Coleção de Anfíbios e Répteis do Instituto Nacional de Pesquisas da Amazônia (INPA-H), Coleção do Museu Paraense Emílio Goeldi (MPEG), Coleção Zoológica da Universidade Federal do Oeste do Pará (UFOPA), Coleção Zoológica da Universidade Federal de Goiás (ZUFG) e Coleção do Laboratório de Zoologia Adriano Giorgi (LZAG) na Universidade Federal do Pará/Altamira (UFPA/Altamira).

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Fig 1. Map of the collection points and distribution of the new Pristimantis species in eastern Amazon.

Abbreviations: SB = Sub Basins; PA = State of Pará; AM = State of Amazonas; TO = State of Tocantins; MA = Maranhão State; MT = Mato Grosso state. 1–5) Altamira—PA; 6–7) Brasil Novo, PA; 8–9) Volta Grande, PA; 10) Senador José Porfírio, PA; 11) Anapu, PA; 12) Caxiuanã, PA; 13) Portel, PA; 14) Tucuruí, PA; 15) Carajás, PA; 16) Marabá, PA; 17) Terra do Meio, PA; 18) Medicilândia, PA; 19) Santarém, PA; 20) Juruti, PA; 21) Parintins, AM; 22) Jacareacanga, PA; 23) Cotriguaçu, MT; 24) Paranaíta, MT; 25) Novo Mundo, MT; 26) Tabaporã, MT; 27) Sinop, MT; 28) Novo Mundo, MT; 29) Cristalino, MT; 30) Palmas; 31) Palmeirante, TO; 32) Araguaína, TO; 33) Carolina, MA and 34) Riachão, MA. Author: Elciomar A. de Oliveira).

https://doi.org/10.1371/journal.pone.0229971.g001

Molecular analysis

We extracted the total genomic DNA using the 2% CTAB protocol [19]. We amplified a fragment of 16S mtDNA by polymerase chain reaction (PCR) using 16Saf primers and 16Sbr [20], and the Cytochrome Oxidase sub unit I (COI) with the primers dgLCO 1490 forward and dgHCO 2198 reverse [21]. The sequences were obtained through the di-desoxiterminal Sanger method using ABI PRISM^® Big Dye™ Terminator V.3 Cycle Sequencing kit (Applied Biosystems™), with 16Saf and COI (forward and reverse). PCR details and sequencing reaction are available in Supporting information (S1 File).

GenBank sequences (https://www.ncbi.nlm.nih.gov/genbank/) of other Pristimantis species and of the P. conspicillatus group were used in the database for phylogenetic analyses (access numbers are listed in S2 File). The sequences were aligned using the ClustalW Algorithm [22] implemented in the software Geneious v. 9.1.2. The alignment of the 16S mtDNA gene presented gaps, which were removed using GBLOCKS v.0.91b [23], [24], available online (http://molevol.cmima.csic.es/castresana/Gblocks_server.html). A gene tree was built using the MrBayes software [25], with the concatenated genes (16s + COI) using the evolutionary model HKY + G, estimated in the JModelTest software [26] under the Bayesian information criterion (BIC). We followed the standard values for two runs and four chains, running 50⁷ generations, with a tree sampled every 10.000 generations. The burn in value was selected by viewing the log likelihoods associated with the distribution of the tree after the software Tracer v 1.5 [27], discarding 20% of the trees with the TreeAnnotator software v1.8 [28]. We accessed convergence by examining the average standard deviation of the split frequency between runs (< 0.01). The number of independent samples was considered sufficient when the stationary was reached and the Effective Sample Sizes (ESS) were higher than 200. As additional evidence for species delimitation, the uncorrected pairwise distance (p-distances for the 16S rRNA and Kimura 2 Parameters–K2P for the COI) among the species of Pristimantis of this study and others in the P. conspicillatus group were calculated using MEGA 6.0 [29]. Hedges and colleagues [11] suggest Oreobates genus as sister group of Pristimantis, so we used it as the outgroup (O. quixensiss of Amazonas State) in our analysis. We built a network of haplotypes among Pristimantis species from the 16S mtRNA and COI mtDNA genes in the POPART software [30] using the median-joining network method in order to check for possible haplotype sharing.

Morphological analysis

The nomenclature of morphological characters has been described following the current literature [14], [31–33]: 1) belly skin texture (smooth, granular, granular posterolaterally); 2) dorsal tubercle (presence/absence of dorsal tubercles or short folds); 3) fringe on the fingers (prominent, weak, absent); 4) dorsalateral fold (prominent or weak); 5) fringe on toes (prominent, weak or absent); 6) basal webbing between toes (present or absent); 7) Inner tarsal fold (long, short or absent); 8) color pattern of the throat, chest and belly (heavily stained, weakly stained, immaculate); 9) pattern of the posterior surface of the thigh.

Measurements were made using a 0.01 mm digital caliper and rounded to 0.1 mm as in [31–34]. The measures obtained were: snout-vent length (from tip of snout to posterior margin of vent), SVL; head length (from posterior margin of lower jaw to tip of snout), HL; head width, (at level of angle of jaw ), HW; snout length (from anterior corner of eye to tip of snout), SL; distance from eye to nostril (from anterior corner of eye to posterior margin of naris), DEN; internarial distance (taken between the median margins of the nares), ID; eye length (measured horizontally), EL; interorbital distance (taken between the inner margins of the orbits), IoD; eyelid width (the largest transverse width of the upper eyelid.), EW; tympanum length (the largest length of the tympanum from the anterior margin to the posterior margin of the tympanum), TL; arm length (from the tip of the elbow to the proximal edge of the palmar tubercle), AL; hand length (from the proximal edge of the palmar tubercle to the tip of finger III), HaL; thigh length (from vent to knee), ThL; tibia length (from outer edge of flexed knee to heel), TiL; tarsus length (from the heel to the proximal edge of the inner metatarsal tubercle.), TaL; foot length (from proximal border of inner metatarsal tubercle to tip of fourth toe), FL; leg length (from the knee joint to the tip of toe IV), LL (all morphometric measurements are listed in S3 File). Sex was determined by direct visualization of secondary sexual characters in adult individuals, such as the presence or absence of vocal slits, vocal sac and nuptial callus in males. Comparisons of characters states were performed with specimens from the P. conspicillatus group available in specialized literature [31], [32], [34–37].

Bioacoustic analysis

We used two types of audio recorders to capture vocalizations: Sony Digital Recorder ICD-PX240 and Tascam DR-40 digital recorder. We obtained records of advertisement calls (vocalizations) from seven males between 18h – 20h, at Uberlândia Farm, Portel municipality, Pará state; four males from Jacareacanga municipality, Pará state; two males from Paranaíta municipality, Mato Grosso state; three males from Taquaruçu district, Palmas municipality, Tocantins state; and five males from Balsas municipality, Maranhão state. The species of the P. conspicillatus group selected for acoustic comparisons were P. fenestratus, P. zeuctotylus, P. chiastonotus, P. samaipatae [38], P. vilarsi, P. gutturalis and P. latro, as they present similar morphological and geographic distribution (east of the Amazon) as the species described in this study, except for P. vilarsi (western Amazon) and P. samaipatae (Bolivia).

We analyzed vocalizations at a sampling rate of 44.1 kHz and 16-bit resolution using the Raven Pro v 1.5 software for Windows (Bioacoustics Research Program 2014). Information about frequency was obtained through Fast Fourier Transformations (FFT; width of 1024 points), Frame = 100, Overlap = 75 and flat top filter. Spectrograms and oscillograms were generated using the SeeWave package [39] in the R software (R Core Team, 2018) following the same parameters as the Raven software. The following variables were measured according to specialized literature [34], [40]: call length (ms), number of notes per call, length of the note (ms), presence of pulses, fundamental frequency (frequency band in which the first sound is visualized through a spectral slice output, in Hz) and dominant frequency (measured from a spectral slice taken from the highest amplitude portion of the note, in Hz). The vocalizations were deposited in the Fonoteca Mapinguari UFMS (MAP-V 306–312 Pristimantis giorgii sp. nov.; MAP-V 313–316 P. pictus sp. nov.; MAP-V 317–319 P. pluvian sp. nov.; and MAP-V 320–325 P. moa sp. nov.).

Species delimitation

To delimit the Candidate Species (CS), we followed the model proposed by Padial and colleagues (2010) [41]: where a given CS can be classified as an Unconfirmed Candidate Species (UCS), Confirmed Candidate Species (CCS) and Deeply Conspecific Lineages (DCL). UCS is considered any CS that presents genetic differences above the limit (> 3%) proposed for the 16S rRNA gene [18], [42], [43], but with no complementary characters verified, such as morphology, bioacoustics, ecology or distribution. A CCS is considered a CS that presents genetic differentiation in relation to other species and also has support of parallel evidence. Finally, a DCL is considered a CS that presents genetic divergence above the proposed limit (> 3%), but cannot be differentiated by parallel evidence (morphology and acoustics).

Results

Phylogenetic relationships and genetic distances

Our tree topology, based only on 16S and COI genes (82 sequences of two concatenated mitochondrial genes, 866bp), recovered posterior probabilities support values among three main divergent lineages.(Fig 2): 1) Andean, 2) Amazon Basin, and 3) Tocantins Basin. The Andean lineages were represented by P. peruvianus, P. achatinus, P. vilarsi and P. bipunctatus [44]. The Amazon Basin lineages consists in Pristimantis zeuctotylus, P. fenestratus complex (with three cryptic lineages, one for Manaus municipality and two for Borba municipality in Amazonas state), Pristimantis sp1 (Altamira municipality), Pristimantis sp2 (Juruti municipality), P. latro, and two undescribed lineages for Mato Grosso state. Two lineages were found for the Tocantins Basin, one of which occurs in the eastern Pará state and another in Tocantins and Maranhão states.

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Fig 2. A gene tree reconstructed by Bayesian analysis using the evolutionary model HKY + G with the 16S and COI genes concatenated (866 bp) between the new species of Pristimantis in the eastern Amazonia and others from the P. conspicillatus group closest genetically and geographically.

The values below the nodes correspond to the posterior probability. The bar below represents the number of substitutions per site. The red color in the left hand corner represents the Amazon Basin (BA in the right corner of the tree) and the green color represents the Tocantins Basin (BT in the right corner of the tree).

https://doi.org/10.1371/journal.pone.0229971.g002

The two undescribed Pristimantis lineages from the Amazon Basin occur in northern Mato Grosso (Cristalino, Novo Mundo, Paranaíta, Sinop, Tabaporã and Cotriguaçu municipalities), showing genetic distances (Table 1) between each other of 11.6% (gene 16S rRNA) and 25.9% (gene COI mtDNA) and distant phylogenetic positioning, even though being sympatric in some localities (e.g. Cotriguaçu and Novo Mundo). The lineage identified as Pristimantis sp1, with individuals from the left bank of the upper Xingu River, in Altamira municipality, represents the sister group of the clade formed by P. latro and three undescribed Pristimantis lineages from the Amazon Basin and Tocantins (HPD = 1), with genetic distances of 9.1–9.9% (16s rRNA gene) and 19.5–22% (COI mtDNA gene). Pristimantis sp2, represented by individuals from the municipality of Juruti, Pará state, were found as a sister group of P. fenestratus (lineage from Borba, Amazonas state, support HPD = 1), with genetic distances of 4% (16S rRNA gene) and 14.6% (COI mtDNA gene).

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Table 1. Uncorrected distance genetics (%) between the new species of Pristimantis and other species of the P. conspicillatus group of this study.

In below diagonal distance p (16S) and above diagonal Kimura 2 Parameters (COI). 1) Pristimantis moa sp. nov. (Tocantins and Maranhão); 2) P. giorgii sp. nov. (Pará state); 3) P. pictus sp. nov. (Mato Grosso and Pará state); 4) P. latro (Pará state); 5) P. fenestratus (Amazonas state); 6) P. fenestratus (Amazonas state); 7) Pristimantis sp1 (Pará state); 8) Pristimantis sp2 (Pará state); 9) P. pluvian sp. nov. (Mato Grosso state); 10) P. fenestratus (Amazonas state); 11) P. bipunctatus (Peru).

https://doi.org/10.1371/journal.pone.0229971.t001

In the Tocantins Basin, the two lineages found showed genetic distances of 2.3% (16S rRNA gene) and 10.5% (COI mtDNA gene) among themselves, with one found only in Pará state and the other in Tocantins and Maranhão states. Regarding phylogenetic positioning, the two lineages are sisters with high support (HPD = 1). Pristimantis latro (occurring in the Amazon Basin and Tocantins Basin), is sympatric with the Pará lineage, presenting genetic distances of 7.7% (16S rRNA gene) and 14.8% (COI mtDNA gene) and is sister to the lineages from northern Mato Grosso state (HPD = 0.95).

The haplotype networks for the 16S (422 bp) and COI (444 bp) genes showed seven distinct mitochondrial haplogroups, corroborating the lineages found in phylogenetic reconstruction, with no haplotype sharing among the new species of Pristimantis described in this study (Fig 3). Based on the large genetic distance found with the 16S and COI mitochondrial markers, phylogenetic positioning, and morphological and acoustic (Fig 4) divergences (mentioned in the "Diagnosis" and "Comparison with other species" sections), herein we describe four new species occurring throughout the east of Amazon and north Cerrado.

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Fig 3.

Median-joining haplotype network based on 16S (A) and COI (B). Each haplotype is represented by a circle, in which the area is proportional to its frequency. The traits indicate additional mutational steps of branches with more than one mutation. Black dots represent lost or unsampled haplotypes. Colours represent different species.

https://doi.org/10.1371/journal.pone.0229971.g003

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Fig 4.

A) Vocalization of Pristimantis giorgii sp. nov. State of Pará; B) Vocalization of P. pluvian sp. nov. State of Mato Grosso; C) Vocalization of P. pictus sp. nov. Mato Grosso and Pará states and D) vocalization of P. moa sp. nov. Tocantins and Maranhão states.

https://doi.org/10.1371/journal.pone.0229971.g004

Systematics

Allocation to species group.

The new taxon described in this article belong to the Pristimantis conspicillatus group based on (1) molecular phylogenetic relationship (Fig 2); and (2) morphological characteristics such as: tympanic membrane and tympanic annulus distinct (except in P. johannesdei); dorsum smooth or shagreen; lateral dorsal fold present or absent; usually smooth belly, but may be weakly granular in some species; toe V slightly larger than toe III (see Hedges and colleagues [11]).

Pristimantis giorgii sp. nov. (Fig 5A–5D) urn:lsid:zoobank.org:act:7CA1240B-0506-45F9-A9E1-0E38A18A0B65

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Fig 5.

Color in life of: Pristimantis giorgii sp. nov. Pará state (A—D); P. pictus sp. nov. Mato Grosso state (E–H); P. pluvian sp. nov. Mato Grosso state (I–L) and P. moa sp. nov. Tocantins state (L–P).

https://doi.org/10.1371/journal.pone.0229971.g005

Holotype.

(Fig 6A–6D), LZAG 1381, adult male collected on 06 February 2018 in Portel municipality, Pará state, Brazil (02°59'38.10" S; 50°4'48.57" W) by Elciomar Araújo de Oliveira, Emil José Hernández Ruz and Erick Fabrício Santos Moraes. Voucher is deposited in the collection of the Laboratório de Zoologia Adriano Giorgi at the Universidade Federal do Pará, Campus de Altamira, Brazil.

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Fig 6.

Holotype of Pristimantis giorgii sp. nov. (Portel, State of Pará): A) dorsal view (SVL = 34.2 mm), B) ventral view; C) left hand (8.9 mm) and D) left foot (16 mm). Holotype of Pristimantis pictus sp. nov. (Novo Mundo, State of Mato Grosso): E) dorsal view (SVL = 30.6 mm), F) ventral view; G) left hand (8.2 mm) and H) left foot (15.8 mm). Holotype of Pristimantis pluvian sp. nov. (Cotriguaçu, State of Mato Grosso): I) dorsal view (SVL = 28.7 mm), J) ventral view; K) right hand (7.3 mm) and L) right foot (14 mm). Holotype of Pristimantis moa sp. nov. (Palmeirante, Tocantins State): M) dorsal view (SVL = 32.9 mm), N) ventral view; O) left hand (8.8 mm) and P) right foot (15.9 mm).

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Paratopotypes.

Six adult males: LZAG 1382, 1383, 1385, 1386, 1389, 1391 and two adult females: LZAG 1384 and LZAG 1388 collected along with the holotype. Material deposited in the collection of the Laboratório de Zoologia Adriano Giorgi at the Universidade Federal do Pará, Campus de Altamira, Brazil.

Paratypes.

Females LZAG 1188, 1190, 1191, 1197, BLM 1089 and a male LZAG 1387, collected by Suyanna Ferreira no Assurini, Travessão do Espelho (3°19'40.11"S; 52°10'13.82"O), Altamira municipality, Pará state. Material deposited in the collection of the Laboratório de Zoologia Adriano Giorgi at the Universidade Federal do Pará, Campus de Altamira, Brazil.

Diagnosis

Pristimantis giorgii sp. nov. distinguishes from other species in the P. conspicillatus group by the following combination of characters (summarized in Table 2): (1) shagreen dorsal skin, with dorsal tubercles in the scapular region, supra ocular and laterally; lateral dorsal fold absent; discoidal fold present; smooth and granular belly skin texture laterally; (2) males with slit and vocal sac; (3) thigh surface with dark yellow spots on brown background; (4) four supernumerary tubercles present on palms of the hands and almost the same size as the subarticular tubercles projected; (5) side fringe along the fingers; (6) supernumerary tubercles present in the base of the foot's IV, conical and small format; (7) basal webbing and lateral fringe present between toes; (8) vocalization with three to four notes pulsed in length 0.017–0.074 s (N = 7);

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Table 2.

Comparison of the diagnostic characters among some species of the Pristimantis conspicillatus group, including new species: (1) belly texture (smooth, granular, granular posterolaterally), (2) dorsal tubercles (presence/absence of dorsal tubercles or short folds); (3) fringe on finger (prominent, weak, absent); (4) dorsolateral fold (prominent or weak); (5) fringe on toe (prominent, weak, absent); (6) basal membrane on toe (present or absent); (7) Inner tarsal fold (long, short or absent); (8) throat color pattern (stained, immaculate or light); (9) thigh surface coloring (yellow spots, reddish, spotted, strongly spotted, brown, other); (10) number of notes/call (1, 2, 3, 4, 5, more).

https://doi.org/10.1371/journal.pone.0229971.t002

Comparison with other species

Pristimantis giorgii sp. nov. distinguishes from P. latro by the absence of lateral dorsal fold (present in P. latro) and vocalization composed of three to four notes (seven notes, see Table 3); from P. vilarsi by presenting smooth belly texture in the center and granular laterally (smooth throughout the belly), presence of basal webbing in the feet (absent), vocalization of three to four notes (eight notes) [45], [46]; from P. fenestratus by presenting smooth belly texture in the center and granular laterally (smooth throughout the belly in P. fenestratus), fringe on toes prominent (weak) [31], [34], [47]; from P. koehleri by having a lateral fringe on the fingers (absent in P. koehleri), presence of basal webbing in the feet (absent), vocalization composed of three to four notes (four to eight notes) [14]; from P. dundeei by presenting a flat belly in the center and granular laterally (areolated in P. dundeei), presence of fringes on fingers (absent) [14], [48]; from P. zeuctotylus by presenting a divided palmar tubercle (undivided in P. zeuctotylus), white belly coloring with scattered black dots (black belly) [37]; from P. chiastonotus by presenting basal webbing and fringe on toes (absent in P. chiastonotus), tarsal fold present (absent); rostrum subacuminated in dorsal view (acuminate), dorsal tubercles present (absent), vocalization composed of three to four notes (one note) [37].

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Table 3. Diagnostic characters in vocalization among the species of Pristimantis used in this study.

Values are given as distribution in seconds (average ± SD). SD = Standard Deviation; Hz = Hertz; pop = population.

https://doi.org/10.1371/journal.pone.0229971.t003

Description of the holotype

Adult male 34.2 mm SVL. Dorsal skin shagreen, dorsal tubercles present, dorsolateral fold absent; smooth belly texture and granular laterally, granular posterior surface of thighs; head longer (39.5% of the SVL) than wide; snout subacuminated in dorsal view and curved anteroventrally in lateral view; canthus rostralis weakly concave in dorsal view and in cross section, flat loreal region; ovoid tongue, wider than long; dentigerous process of vomer oblique and posterior to choanae, eight visible teeth; eye 93% of distance from the eye to the nose; elliptical pupil; supraocular tubercles and inter-supraocular bar present; cranial crests absent; prominent supra tympanic fold, not contacting the eyelid; tympanic membrane 47.5% of EL, rounded and translucent, tympanic annulus prominent; relatively small hands, 26% of the SVL; relative length of fingers: II < IV < I < III; discs of fingers III and IV are wider than fingers I and II; prominent, semi divided, heart-shaped external metacarpal tubercle; large internal palmar tubercle; one subarticular tubercle prominent on fingers I, II, III and IV; one supernumerary tubercles present at the base of fingers I, II, III and IV; long legs, tibia 56.1% of the SVL; relative length of toes: I <V <II <III <IV; well developed and oval inner metatarsal tubercle; external metatarsal tubercle much smaller than the internal; one subarticular tubercle on toes I and II; two subarticular tubercles on toes III and V; and three subarticular tubercles on toe IV; basal webbing and lateral fringes (weak) present on toes; inner tarsal fold present; outer tarsal tubercles absent.

Measurements of holotype (in mm)

SVL: 34.2; HL: 13.5; HW: 12.7; SL: 6.7; DEN: 4.3; ID: 3.0; EL: 4.0; IoD: 2.8; EW: 3.5; TL: 1.9; AL: 7.6; HaL: 8.9; ThL: 15.5; TiL: 19.2; TaL: 9.7; FL: 16.0; LL: 24.6.

Color in life

The dorsum is predominantly light brown with scattered dark brown bars. Posterior and anterior limbs with dark brown bars. Black labial bars. Black canthal stripe. White belly with tiny scattered black dots. Iris presents a golden coloration at the top and bottom, while in the anterior and posterior region is predominantly red. White groin area with few yellow spots. Posterior thigh surface predominantly light brown.

Coloration in preservative

In alcohol, the coloration is predominantly brown in the dorsal region, both in males and females. The belly is white with tiny black dots scattered or black spots scattered all over the venter.

Variation

The texture of the venter is predominantly smooth in the center and granular laterally, but in some individuals it is completely smooth (BLM 1089, LZAG 1188, 1190, 1191, 1197, 1387, 1388). Dorsal tubercles absent in BLM 1089. All the individuals collected from the left bank of the lower Tocantins River present the dorsum and anterior and posterior limbs strongly barred, while those collected on the right bank of the middle Xingu River present a brown dorsum with few transversal bars. Females are larger than males (Average = 32.23, N = 25; Average = 32.09, N = 14)

Etymology

The specific epithet is a patronymic to the Professor José Adriano Giorgi† of the Universidade Federal do Pará, due to his great contributions to knowledge about entomofauna of the Xingu region and since he accompanied us during the first collection of the species.

Distribution, ecology and habitat

Pristimantis giorgii sp. nov. has been recorded in the interfluve Xingu/lower Tocantins in Pará state, Brazil throughout the municipalities of Altamira (Assurini, right bank of the middle Xingu river), Portel (left bank of the lower Tocantins River), Marabá and Melgaço (Flona de Caxiuanã) (Fig 1). This species can be found in preserved forest areas (Flona Caxiuanã and Portel) or in some disturbed environments, e.g. forest fragments surrounded by pastures (agrovila do Assurini, Altamira municipality, Pará state). During the rainy season, this species becomes reproductively active, and males move up in the vegetation to call at a height of two meters; during the dry season, they can be found in the leaf litter.

Pristimantis pictus sp. nov. (Fig 5E–5H) urn:lsid:zoobank.org:act:AEE3D30E-203C-4215-BFA8-5EBFBEFD78FC