Introduction

Mexico has the second-richest reptile biodiversity of any country in the world, surpassed only by Australia [1–3]. There are over 950 recognized Mexican reptile species, of which over 50% are considered endemic to the country [2,4]. Each year this number increases due to novel discoveries. From 2022 to 2024, ten new reptile species were described from Mexico [e.g., 5–13].

The remarkable diversity of reptiles in Mexico is attributable to multiple factors, but the main drivers of this diversification are generally considered to be the country’s climatic heterogeneity and complex geological history [14–17]. The combination of these abiotic factors has promoted extraordinary radiations in many animal groups, one of which being the snake family Colubridae. The species of this family occupy almost all available habitats in Mexico and display substantial morphological variability.

Small, elusive snakes in tropical regions present special challenges for researchers due to a combination of factors that include enigmatic behavior, small geographic ranges, and low population sizes [18]. Fossorial snakes spend most of their lives underground and hence are especially difficult to observe [19,20]. Within the Colubridae, 34 genera have been reported from Mexico [3], of which four (12%) are country endemics and have some degree of fossoriality or semi-fossoriality. These four endemic genera — Conopsis, Geagras, Pseudoficimia, and Sympholis — are considered part of an assemblage of burrowing snakes termed the “tribe Sonorini” [19,21–31].

As defined by Dowling [19], the snake tribe Sonorini includes the genera Chilomeniscus, Chionactis, Conopsis, Ficimia, Gyalopion, Sonora, and Stenorrhina. Some authors have proposed the inclusion of other genera such as Tantilla, Tantillita, Scolecophis, and Geagras based on osteological data [23,24]. Furthermore, Hardy [32] considered Pseudoficimia to be related to Conopsis and Ficimia due to shared morphological characters. Recent large-scale molecular phylogenies have recovered the tribe Sonorini as a monophyletic group and as one of the few resolved clades of Neotropical colubrids [26,29,31,33–35]. However, higher-level relationships of the tribe remain unclear. The tribe Sonorini is sometimes considered related to “racer snakes” like Mastigodryas and Drymoluber [26], or to a plethora of other genera such as Coluber, Drymobius, Drymarchon, Masticophis, and Salvadora [31]. Additionally, the composition of the tribe remains controversial since some formerly recognized genera have been synonymized, and few works have tried to elucidate the phylogenetic relationships among these taxa [25,30].

The first comprehensive phylogenetic hypotheses for the tribe Sonorini was presented by Holm’s dissertation [25], based on external morphology, molecular data, and osteology. In this work, he established that the tribe is composed of a “Ficimia clade” that includes Conopsis, Ficimia, Gyalopion, Pseudoficimia, Stenorrhina, and Sympholis, and which is sister to a “Sonora clade” that includes Sonora, Chilomeniscus, and Chionactis; in turn, he resolved these two clades as sister to a third clade composed of Scolecophis and Tantilla. Notably, Holm [25] considered Geagras and Tantillita to be synonyms of Tantilla. Most of the information available on the tribe focuses on works that deal with only one genus, such as Conopsis [28,36], Ficimia [20,32,37], Pseudoficimia [38], Tantilla [39–42], and the “Tantilla clade” including Geagras, Scolecophis, Tantilla, and Tantillita [43]. Recent phylogenetic revisions of Sonora, Chionactis, Chilomeniscus, and Procinura also resulted in the synonymization of the latter three genera within Sonora [30,44]. We do not accept Holm’s (2008) hypothesis that synonymizes Geagras and Tantillita with Tantilla, because the proposal was based on limited morphological characters (absence of loreal and apical pits on dorsal scales), reduced sampling per genus (Geagras N = 13 and Tantillita N = 8), and no genetic information. We consider both genera as independent until new evidence confirms or detracts their distinctiveness; additionally, we follow Cox et al. [30] in considering Chilomeniscus, Chionactis, and Procinura as synonyms of Sonora. Hence, we consider the tribe Sonorini to be composed of the genera Conopsis, Ficimia, Geagras, Gyalopion, Pseudoficimia, Scolecophis, Sonora, Stenorrhina, Sympholis, Tantilla, and Tantillita.

While exploring the dry forests of the Balsas Basin in the southwestern part of the Mexican state of Puebla, we encountered two specimens of Sonorini snakes that were unassignable to any known genus of the tribe or any other snake taxon based on their distinctive morphological characters. This pair of puzzling specimens and their phylogenetic placement are the focus of this contribution.

Materials and methods

External morphology

The two novel specimens of Sonorini were found dead, collected and tissue was taken under the permission of the law that regulates the scientific collection issued by SEMARNAT/DGVS with number FAUT015, given to O.F.V. For comparisons we adhered to standard scale count protocols primarily following Myers [45], with ventral scales counted according to Dowling [46], and scale terminology in the loreal region following Savage [47]. Six qualitative and six meristic morphological characters were examined (Table 1). Snout–vent length (SVL) and tail length were measured with a metal ruler and rounded to the nearest millimeter (mm) for comparisons (see Description section). Catalog numbers and the number of individuals per genus examined for external morphology are provided in S1 Appendix. All measurements were taken using digital calipers (Mitutoyo 500-196-30 AOS) under a stereomicroscope (Zeiss 475002) and rounded to the nearest 0.1 mm.

[Figure omitted. See PDF.]

Internal morphology

We identified sex through a small incision at the base of the tail. The retracted hemipenis of the holotype was prepared following the procedures of Myers and Cadle [18], and we cut the retractor muscle close to the attachment with the hemipenial lobes as suggested by Smith and Ferrari-Castro [48]. Terminology used in the hemipenial description and the diagnosis follows Dowling and Savage [49], and Myers and Campbell [50]. We applied the same methods for other comparative material revised. We prepared and/or revised 17 hemipenes representing 13 Sonorini taxa, including our novel specimens. We removed the left maxilla of the holotype to describe the maxillary arch and count teeth.

Additionally, we CT-scanned the head of the holotype and paratype specimens at the UTA Shimadzu Center for Environmental Forensics and Material using the Shimadzu inspeXio SMX-100CT scanner at a resolution of 12 μm with x-ray operating at 65 kV and 40 mA. The segmentation and the 3D models of the CT-scan were made in the software 3DSlicer 5.0.2 [51]. We revised 35 CT-scans available from Morphosource and other published sources and scanned six additional specimens, including our Sonorini specimens, for this work (S3 Table S1). The image stack of this CT-scan is available at www.morphosource.org The osteological terminology follows Cundall & Irish [52].

Examined comparative material can be consulted at Appendix 1. All museum acronyms follow Sabaj [53,54] with the addition of UAGRO for Laboratorio Integral de Fauna Silvestre, Universidad Autónoma de Guerrero.

Additional data on external morphology, hemipenial characters, and osteology were obtained from the following sources: Cox et al. [30,44], Goyenechea [28], Goyenechea and Flores-Villela [27,36], Hardy [20,32,38,55,56], Humphrey and Shannon [57], Mahrdt et al. [58], McCranie [59], Wilson [60,61], and Wilson and Mata-Silva [43] (Table 1).

Molecular methods

DNA extraction and PCR protocol. We extracted genomic DNA of the two novel specimens of Sonorini using the DNeasy Blood & Tissue Kit protocol from Qiagen (Qiagen Valencia, CA) following the manufacturer protocol. We sequenced three mitochondrial loci including the small (12S) and large (16S) ribosomal units, and cytochrome b (cytb), together with the nuclear locus oocyte maturation factor MOS (c-mos), using the primers and PCR protocols described in Jadin et al. [62]. The sanger sequencing process was conducted in the Laboratorio de Secuenciación Genómica de la Biodiversidad (IB-UNAM).

Phylogenetics methods. We assembled forward and reverse reads of the resulting electropherograms in Geneious Prime 2021.0.3 (https://www.geneious.com). To assess the phylogenetic position of the two new Sonorini specimens, we downloaded available NCBI GenBank sequences from all the genera that are currently recognized within the tribe Sonorini including (N = number of taxa included): Conopsis (N = 3), Ficimia (N = 2), Gyalopion (N = 2), Pseudoficimia (N = 1), Scolecophis (N = 1), Sonora (N = 6), Stenorrhina (N = 2), Sympholis (N = 1), and Tantilla (N = 17), as well as representatives of 26 other Neotropical Colubrid genera to explore the phylogenetic affinities of the tribe Sonorini (S2 Table). We included as outgroup sequences the following snake families (number of terminals in parentheses): Acrochordidae (1), Aniliidae (1), Atractaspidae (1), Boidae (2), Calamariidae (1), Dipsadidae (4), Elapidae (1), Homalopsidae (1), Natricidae (1), Pareatidae (1), Psammophiidae (1), Pseudoxenodontidae (1), Tropidophiidae (1), Viperidae (2), and Xenodermidae (2). Whenever possible, we avoided mixing sequences of different individuals in our concatenated multi-locus dataset and abstained from using this kind of out available in repositories (S2 Table). The final dataset consisted of 94 terminals from 93 species, of which 37 are sonorines. We aligned most sequences using Muscle [63] and manually edited them by eye using PhyDE v.0.9971 [64], searching for conserved sites and adding gaps across the sequences when the alignment algorithm failed. The 12S and 16S sequences were aligned using MAFFT v.7 under the E-INS-i strategy [65].

We created a partition file specifying the partitions by codon and gene, as well as the best substitution model selected using Partition Finder v.2.1.11 [66] under the “greedy” algorithm and the Bayesian Information Criterion [67]. A Maximum Likelihood (ML) analysis was conducted with IQTree software [68], and node support was assessed using 5,000 UltraFast Bootstrap (UFB) replicates [69]. We visualized and edited the resulting trees in FIGTREE v.1.4.4 [70] and calculated uncorrected pairwise genetic distances (p-distances) for the aligned mitochondrial gene fragments of the sampled sonorines with MEGA X software [71].

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:C639D697-067A-4007-B891-BFC8F402FBBD. 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, Totlok.mx and bidi.unam.mx.

Results

Phylogenetic relationships

Our final genetic matrix consisted of 2794 base pairs (bp) and 282 sequences, including 530 bp for 12S (57 sequences), 564 bp for 16S (64), 1117 bp for cytb (82), and 583 bp for c-mos (79). Seven new sequences were generated for our new Sonorini specimens (S2 Table). We obtained and implemented the following partition scheme and substitution models for the ML analysis: i) 12S, 16S, cytb 1^st and 2^nd positions, and the three positions of cmos (GTR + I + G), and ii) cytb 3^rd position (K81UF+I + G). The resulting ML tree had a value of -lnL = –44862.998 (Fig 1; S1 Fig). The tribe Sonorini was recovered as monophyletic, though with low support (UFB 73%). No unambiguous sister clade to the tribe Sonorini was identified, although a weak relation (UFB 52%) was recovered to a poorly supported clade (UFB 52%) that includes Chironius, Ptyas, Dendrophidion, Drymobius, Rhinobotrium, Leptodrymus, Palusophis, Drymoluber, Simophis, and Mastogodryas. Within the tribe Sonorini, three main monophyletic clades were recovered that match the Ficimia, Tantilla, and Sonora clades proposed by Holm [25], with UFB support values of 99%, 78%, and 85%, respectively. The Sonora clade consisted solely of the genus Sonora and was divergent from a moderately supported clade (UFB 81%) that included the Ficimia and Tantilla clades. The Ficimia clade included Conopsis, Ficimia, Gyalopion, Pseudoficimia, Stenorrhina, Sympholis, and our two unknown Sonorini samples. All genera were retrieved as monophyletic and strongly supported (UFB 99–100%), but the relationships between them were poorly supported (>60%), except for two subclades: i) Ficimia + Gyalopion (99%), and ii) a clade including Sympholis, Pseudoficimia, and the unknown Sonorini samples (98%). Our new specimens formed a monophyletic clade (UFB 100%) sister to Pseudoficimia frontalis (UFB 99%), which together are sister to the monotypic Sympholis lippiens with strong support (UFB 98%). This clade, in turn, was related to Gyalopion and Ficimia, albeit with low support (UFB 60%). The Tantilla clade groups Scolecophis and Tantilla with low support (UFB 78%), and recovers the genus Tantilla as monophyletic (UFB 100%).

[Figure omitted. See PDF.]

Numbers at the nodes represent ultrafast bootstrap values. Heads at the tips are intended to be illustrative and are not at the same scale.

Uncorrected pairwise distances of the three sequenced mitochondrial gene fragments were calculated (S4–S6 Table), although not all terminals were included for all loci due to incomplete sampling. For the 12S gene (S4 Table), the genetic distances of the Sonorini species inquirenda holotype (MZFC 37100) ranged from 10.61% against its sister taxon Pseudoficimia frontalis to 17.42% against Tantilla vermiformis. For the 16S gene (S5 Table), genetic distances of our Sonorini species inquirenda samples ranged from 5.53% against Gyalopion quadrangulare to 11.06% against Sonora occipitalis, and a distance of 6.28% from their sister group, Pseudoficimia frontalis. For the cytb gene (S6 Table), genetic distances of our Sonorini species inquirenda samples ranged from 12.04–12.25% against Gyalopion canum to 18.27–18.43% against Tantilla wilcoxi; genetic distances with their sister groups ranged from 13.5–13.85% against Sympholis lippiens to 15.46–16.06% against Pseudoficimia frontalis.

Systematic account

Our morphological comparisons (see below, Table 1) support the phylogenetic analyses, and we consider that the snake specimens from the Balsas Basin of Puebla represent a new taxon member of the tribe Sonorini. Hence, a new genus and species are named herein:

Yakacoatl gen. nov.

urn:lsid:zoobank.org:act:A1969E43-DBA2–4398-93B1-8416BBC0A505

Type species. Yakacoatl tlalli, new species (described below).

Diagnosis.—This genus differs from all the other Western Hemisphere colubrids by the following set of characters: 1) smooth dorsal scales arranged in 17-17-17 rows, 2) an upturned rostral scale in contact with the internasals, 3) 154–156 ventral scales in known males; 4) 35–36 paired subcaudals scales; 5) short, thick supranasal bones; 6) absence of a supraoccipital keel; 7) 12 maxillary teeth, with rear teeth enlarged and faintly grooved; 8) hemipenis subcylindrical with slightly protruding lobes, a single sulcus spermaticus, body covered with spines and spinules, and lacking calyces.

This is considered a polythetic group and not a single character is identified as an autapomorphy. However, the combination of short, thick supranasal bones, absence of a supraoccipital keel, and lack of calyces on the hemipenis represent a unique condition within the Sonorini tribe.

Comparison with known genera of Sonorini.—Yakacoatl gen. nov. differs from Geagras, Scolecophis, Sonora, Tantilla, and Tantillita by having more dorsal scale rows, 17 (in comparison with 13–15), and from Sympholis by having fewer dorsal scales, 17 (19). It has more ventral scales than Conopsis and Gyalopion, 154–156 (in comparison with 120–145) but fewer than Sympholis and Scolecophis (181–232). It differs from Ficimia, Gyalopion, Pseudoficimia, Stenorrhina and Tantilla by the absence of calyces in the hemipenis (presence) (Table 1). Additional differences between Yakacoatl and the remaining Sonorini genera follows, character states of the new genus are in parentheses.

The monotypic genus Pseudoficimia is distinguished by having an elongated premaxillae that enters well between the paired elongated nasals (premaxillae not inserting that far and short, thick), 13–17 maxillary teeth (12), a conspicuous parietal ridge (absent), and a moderate median keel and straight anterior border of the supraoccipital (median keel poor, concave border). Additionally, the dorsal pattern in Pseudoficimia consists of conspicuous blotches (patternless or nearly so), it presents 7 infralabials (6), and the hemipenis has apical calyces and an asymmetrical apex (calyces absent, apical region with paired symmetrical projections; Fig 4).

[Figure omitted. See PDF.]

Note the difference in size between the dorsal scales of the body and those from the tail. The scale bar represents centimeters.

[Figure omitted. See PDF.]

Rural construction where the holotype (MZFC-HE 37100) was found (B); typical vegetation at the type locality (C). Photographs of the type locality were taken by OOL, shape files used to construct the map were obtained from INEGI (Instituto Nacional de Estadística y Geografía, Mexico).

Sympholis is a Mexican endemic and monotypic genus that represents one of the largest Sonorini, attaining an SVL of up to 540 mm (381 mm in only known adult male), and also has a banded dorsal pattern (patternless or nearly so) and a rounded snout (pointed snout). Furthermore, in Sympholis the premaxilla has a pointed rostrum (round) and two large lateral processes (small), the elongated nasals are curved downward at their lateral margin (short nasals with lateral margin directed laterally), there is an evident dorsolateral ridge on the parietal (absent), the postorbital is absent or small (present), there is a moderate median keel on the supraoccipital (poorly developed), the ectopterygoid is simple (bifurcated), it has a single anal plate (divided), 14–24 subcaudals (35–36), and the hemipenis is calyculated and simple (spinulate, slightly bilobed).

Ficimia species usually present a banded dorsal pattern, although F. olivacea has no dark markings on the dorsum (no conspicuous dorsal pattern). Ficimia is further differentiated from Yakacoatl by the contact of the rostral scale with the frontal (rostral contacting internasals). Additionally, the revision of available CT-scans of F. publia, F. streckeri, and F. olivacea (Supplementary material, S1 Table) reveals osteological differences such as articulation of the nasals with the frontals (separated), long and wide postorbital bones almost reaching the lower margin of the orbit (relatively short and thin postorbital bones), an ample supraoccipital bone (narrow), and a narrow anterior process of the cephalic condyle of the quadrate shaped like a narrow scythe (wide scythe or wide triangle). The hemipenial morphology of F. publia, F. olivacea, and F. variegata shows the presence of papillated calyces on a simple organ (calyces absent and slightly bilobed).

Geagras redimitus (monotypic) is a very distinctive snake that differs from Yakacoatl by having a very conical head (normal, anterior section of parietal relatively wide); premaxilla with a conical rostrum (short and wide) without lateral processes (with rounded lateral processes); a very ample articulation between nasals and frontals (not articulating); septomaxilla with long conchal processes (short) that are taller posteriorly (medially) and articulate with prefrontal and frontal; very short prefrontals (relatively high); ectopterygoid with very short anterior processes (moderately long) and a terminally truncated anterolateral process (slender and terminally pointed); supratemporal Y-shaped with one longer arm directed anterodorsally (bar-like); and quadrate short (tall). Additionally, Geagras can be differentiated from Yakacoatl by having 5 supralabials (7), 15 dorsal scale rows (17), 113–124 ventrals (154–156), 26–33 subcaudals (35–36), by lacking an upturned rostral scale (present), and by having hemipenes that are simple (slightly bilobed), capitated (uncapitated), and with calyces (absent).

Gyalopion is differentiated by its unique premaxilla, with a rostrum having an extensive flat anterior projection that is even laterally expanded, before the round lateral processes (premaxillary rostrum with only moderate projection and not laterally expanded). It also has a long and somewhat robust postorbital (relatively short and thin), a median keel on the supraoccipital (poorly developed), a very short and narrow scythe-like anterior process of the cephalic condyle of the quadrate (wide scythe or wide triangle of moderate length), 122–140 ventral scales (154–156), and a simple and slightly bulbous hemipenis with apical calyces (slightly bilobed organ without calyces).

Both species of Stenorrhina have the ectopterygoid with a short, expanded and terminally truncated anterolateral process (slender, long and terminally rounded), a very short triangular anterior process of the cephalic condyle of the quadrate (wide scythe or wide triangle of moderate length), two mental foramina on the dentary (one), and three foramina below prefrontal on the anterior portion of the maxillae (one anterior to the prefrontal). Stenorrhina further presents a characteristic fusion of the internasal scales with the nasal (separated), 7–8 infralabials (6), and the hemipenes being simple, bulbous, and covered with flounces at the apical region (simple, slightly bilobed, covered with spines and spinules).

Available CT-scans of Conopsis (C. biserialis, C. nasus, C. sp.; Supplementary material, S1 Table) show the premaxilla presenting a narrow rounded rostrum (wide), dorsally expanded postorbital bones (thin), and the presence of a well-developed median keel on the supraoccipital (poorly developed). Additionally, Conopsis spp. have 120–145 ventral scales (154–156), and lack an upturned rostral scale (present).

Representatives of Sonora (based on CT-scans of S. cinctus, S. occipitalis, S. semiannulata, and S. straminea; Supplementary material, S1 Table) present a well-developed premaxilla (not conspicuously enlarged), postorbital bone contacting frontal, and compound bone with prearticular crest noticeably higher than surangular crest (subequal). Sonora can also be distinguished from Yakacoatl by having 13–15 dorsal scale rows at midbody (17).

Scolecophis is a slender snake (stout), with an elongated head (short), frontal bones (rectangular), and braincase (short); premaxilla without anterior rostral projection (present); premaxillary ascending process thin throughout (wide at base), vertical (slanted backwards), and not separating nasals (separating); postorbital bone in broad contact with frontal (not in contact); and ectopterygoid with a short, expanded and terminally truncated anterolateral process (slender, long and terminally rounded). Additionally, Scolecophis has a tricolored dorsal body pattern resembling that of coral snakes (patternless or nearly so), 15 dorsal scale rows (17), 181–198 ventrals (154–156), and 45–54 subcaudals (35–36). Tantilla presents a vast amount of variation in many morphological characters, and to date, a comprehensive phylogenetic hypothesis of this genus is lacking as well as an exhaustive review of the characters exhibited by the 69 described species [3]. The premaxillary ascending process of Tantilla is variable, from thin to wide, from vertical to directed backwards and sometimes fitting between the nasals anteriorly but, even with this last condition, direct dorsal articulation between the ascending process and the nasals is not observed in our samples (in broad contact). Additionally, all Tantilla can be differentiated from Yakacoatl by having 15 dorsal scale rows (17), by lacking an upturned rostral scale (present), and having calyces present in the hemipenes (absent).

Tantillita (CT-scan of Tantillita lintoni available) differs from Yakacoatl by having the ascending process of the premaxilla not contacting or being situated between the nasals (in broad contact), postorbital bone in broad contact with frontal (not in contact), and ectopterygoid with an expanded and terminally truncated anterolateral process (slender, long and terminally rounded). Additionally, Tantillita can be differentiated from Yakacoatl by having 15 dorsal scale rows (17), by lacking an upturned rostral scale (present), and having calyces present in the hemipenes (absent).

Etymology.—From the Nahuatl words yacatl meaning nose, and coatl meaning snake, in reference to the pronounced rostral scale that resembles a pointed nose in the species. Of feminine gender.

Yakacoatl tlalli sp. nov.

Holotype.—MZFC-HE 37100 (Fig 2), adult male from San Jerónimo Xayacatlán, Santo Domingo Tonahuixtla Municipality, Puebla, Mexico, 1335 m elevation (18.20517ºN, 97.89025ºW), collected 7 November 2014 by Oscar Olivares Loyola in a crop field (Fig 3B).

Paratype.—UTA R-66192, juvenile male from San Jerónimo Xayacatlán, Municipio Santo Domingo Tonahuixtla, Puebla, Mexico 1341 m elevation (18.20617ºN, 97.88856ºW), collected 19 May 2015 by Oscar Olivares Loyola in a crop field.

Description of the holotype.—Adult male, judged by the presence of mineralized spines on hemipenis (Fig 4); specimen in fair condition, except for some small wounds on the ventral surface. SVL length 319 mm, tail length 62 mm; head not distinct from body, 10.1 mm long, 6.3 mm wide (Fig 2); eye diameter 1.4 mm; snout length 3.4 mm; dorsal arrangement of head plates in classic colubroid fashion (Fig 5); upturned rostral, 1.4 mm long, 2.6 mm wide; two paired internasals, 1.1 mm tall, 1.7 mm wide, 0.4 mm contact; two paired prefrontals, 1.3 mm tall, 2.2 mm wide; frontal longer than wide (3.6 x 2.7 mm), bordered by two supraoculars, and paired parietals, 4.4 mm long, 3.1 mm wide, 2.8 mm contact, longer and shorter than frontal; rostral contacting nasal, internasals, and first supralabials; nasal divided below, in contact with prefrontal and first and second supralabials; no loreal; one preocular; two postoculars; temporals 1 + 2 on right side, apparent malformation on “upper” secondary temporal, 1 + 1 on left side; seven supralabials, the first noticeably shorter than the others, 3–4 contacting orbit; six infralabials, first pair in ample contact, 1–3 contacting first pair of chinshields; two pairs of chinshields, first pair 2.9 mm tall and 1.6 mm wide, second pair 1.8 mm long and 1.4 mm wide; five rows of gulars; dorsals in 17-17-17 rows, smooth, lacking apical pits except for some fine marks in some scales; anal ridges absent; six scale rows at middle of tail; scales with uniform size throughout body, but becoming noticeably enlarged towards the rear and at level of cloaca; ventral scales 154; anal plate divided; subcaudal scales paired, 35 + cornified terminal spine; the dorsal coloration is smoke-grey, with enlarged scales at the level of the cloaca, surrounded by black outlines; the ventral part is creamy white.

Hemipenes— In situ right organ covered by transparent sheath with few melanized reticules; organ reaches end of subcaudal 10, bifurcates dextrally at middle of subcaudal 9 and medially at anterior of subcaudal 10; retractor muscle inserts at level of subcaudals 28 and 29. Ex situ organ (Fig 4A) is simple and subcylindrical in shape, except for two paired projections at apex; sulcus spermaticus undivided, bordered by definite lips, ending next to right projection of apex; sulcate ornamentation from base to apex: pedicel essentially naked, followed by two large basal spines decreasing in size towards apex, region between apical projections wide and naked; ornamentation on asulcate side as in sulcate.

Osteology —Skull of holotype (Fig 6) presents some fractures on frontals, parietals, supraoccipitals, and compound bones, but overall condition allows detailed osteological observation; teeth counts given as left/right; ascending process of premaxilla with a broad base, projects posterodorsally separating nasals anteriorly; premaxilla presenting a short and wide rounded rostrum with rounded lateral processes, short transverse processes, a prominent vomerine process with parallel margins and bilobated end; nasals acute anteriorly and posteriorly, wider medially, separated from frontal; frontal paired, squarish, anterior border with soft slit, lateral border medially curved, interolfactory pillar present, three foramina laterally, supraorbital ridge present; parietal truncated anteriorly, contacting frontal, midpart globous, posterior border rounded, bending anteroventrally to basisphenoid; postorbital contacting parietal near frontoparietal suture, projecting ventrally to level of mid-orbit, compressed anteroposteriorly; supratemporal laminar, bar-like, contacting prootic anteriorly and quadrate posteriorly; septomaxilla narrow anteriorly, wider posteriorly, conchal process short and with broad rounded end directed dorsally at midlength and not articulating with prefrontal or frontal; vomer dorsally concave, posterior border with laterally compressed palatine process; prefrontal formed by facial sheet anteriorly, orbitonasal flange posteriorly, vertical prominent anteorbital ridge; orbitonasal flange pierced by a rounded and wide lacrimal foramen; quadrate compressed laterally, cephalic condyle expanded and shaped like a wide scythe directed anteriorly, mandibular condyle narrow, stylohyal process present as oval disc on medial surface of quadrate; supraocciptal roughly heart-shaped, lacking transverse crests and having a poorly developed median keel; prootic with three ventrolateral foramina, maxillary branch of trigeminal nerve with two anterior exits, dorsal bigger than ventral, mandibular branch of trigeminal opening posterolaterally; exoccipital divided, oval foramen opens posteriorly, recessus scalae tympani located ventrally to oval foramen; basisphenoid lacking parabasisphenoid keel; stapes with prominent footplate inside the inner ear cavity and not visible externally, shaft robust and projecting posteriorly to reach middle of cephalic condyle of quadrate.

Palatomaxillary arch with three dentigerous bones, maxilla, palatine, and pterygoid; maxilla starts at level of second supralabial, ends at level slightly behind eye, with soft dorsolateral curvature, one anterior facial foramen; maxillary teeth 12/12, heterodont, gradually enlarging towards rear, last three slightly grooved laterally; ectopterygoid Y-shaped, expanded anteriorly to embrace posterior end of maxilla, anteromedial process slender and pointed, anterolateral process slender and rounded at tip, contacting pterygoid posteriorly; palatine with anterior maxillary process expanded dorsolaterally, harboring large fenestra parallel to main axis, choanal process expanding dorsomedially, from mid-palatine and tip curving ventrally, teeth 7/8, nearly homodont; pterygoid partially sutured along length between dentary surface and lateral projection embracing ectopterygoid, expanded posteriorly, teeth 13/13, nearly homodont throughout; dentary bowed anteromedially, single mental foramen at middle of lateral face, teeth 13/13; splenial bar-like, pointed anteriorly, expanded posteriorly, fits into slit at medial surface of dentary; angular contacting splenial anteroventrally, coronoid process of dentary dorsally; compound bone overlapping and fitting into dentary anterodorsally, adductor fossa extending from midlength to articular facet for quadrate, prearticular crest subequal in height to surangular crest, concavity laterally below adductor fossa, retroarticular process laterally compressed and posteriorly projected.

Variation in the juvenile male paratype (measurements in mm).—SVL 131, tail length 28, head length 6.35, head width 3.3, eye diameter 1.1, snout length 1.75; dorsal scale rows 17-17-17; ventrals 156; anal plate divided; subcaudals 36; supralabials 7/7; infralabials 7/7; preoculars 1/1; postoculars 2/2; scutellation characters as in adult holotype except for fourth infralabial on the right side barely reaching first pair of chinshields; coloration differs by presence of black mark below orbit, and faint striped pattern encompassing dorsal scale rows 3–4, 5–6, 11–12, 14–15.

Skull of paratype (Fig 7) similar to that of the holotype, except for having slightly shorter nasals; a small azygous spherical bone between the anterior tip of the frontals; frontals with two foramina laterally; postorbital slightly longer and more slender, projecting ventrally to level of ¼ of orbit diameter below mid-orbit; supratemporal more acute anteriorly; quadrate slightly shorter and more robust, with anterior cephalic condyle triangular anteriorly; supraoccipital shorter, band-shaped; maxillary teeth 12/12, as holotype; palatine teeth 8/7, as in holotype; pterygoid teeth 15/14, slightly higher than holotype; dentary teeth 13/14, one count higher than in holotype.

[Figure omitted. See PDF.]

Sulcate and asulcate views are presented as left and right, respectively. Scale bar represents millimeters.

[Figure omitted. See PDF.]

Scale bar represents millimeters.

[Figure omitted. See PDF.]

Lateral (A), dorsal (B), ventral (D), anterior (F), and posterior (G) view of the skull; lateral view of the left (C) and right (E) lower mandible. Scale bar represents millimeters.

[Figure omitted. See PDF.]

Scale bar represents millimeters.

Distribution and natural history. — Both known specimens of Yakacoatl tlalli were obtained dead near the surroundings of San Jerónimo Xayacatlán, Puebla, Mexico, in the Balsas Basin. The snakes were obtained in a rural home, the holotype being preyed by a domestic chicken (Gallus gallus), and the paratype was found dehydrated at the same house (Fig 2B). Original vegetation at the type locality consisted of tropical deciduous forest but is currently heavily fragmented by agricultural activities. Upon dissection of the adult holotype, we obtained in its stomach the tail of a scorpion of the genus Diplocentrus (Alacranidae) (Fig 8).

[Figure omitted. See PDF.]

(B) Food item consisting of a scorpion tail of the genus Diplocentrus (Alacranidae) found in the stomach of the snake. Scale bars represent centimeters.

Etymology.—The specific epithet tlalli, comes from the Nahuatl word for land or earth. This naming choice alludes to the presumed fossorial habits of Yakacoatl tlalli, inferred from its morphology and the known behavior of other Sonorini genera.

Specimen identification using available keys.—Dichotomous keys for identifying the snake genera of Mexico and Central America are available in González-Hernández et al. [72], Heimes [73], Köhler [74], and Peters and Orejas-Miranda [75]. Running the known specimens of Yakacoatl through these keys would lead to the following couplets:

In Heimes [73], one would be led to couplet 58 with a choice between Geagras, Tantilla, and Tantillita, while in González-Hernández et al. [72], one would reach couplet 107 with a choice between Tantilla and Tantillita. See above for differences between known specimens of Yakacoatl and those genera. In Köhler [74], examination would lead to couplet 3, where one can choose between Ficimia and the dipsadid genus Phimophis; Ficimia is easily distinguishable by the contact of the rostral scale with the frontal (absent in Yakacoatl, see above for further comparisons), while Phimophis may be differentiated by the presence of a loreal scale (absent), 21-19-17 dorsal scale rows (17 throughout), and >190 ventral scales (154–156 [76–78]). In Peters and Orejas-Miranda [75], examination would lead to couplet 43, reaching the dipsadid genus Enulius; this genus and the related Enuliophis are differentiated by having extremely thin and long tails with >80 subcaudals (35–36), and an elongated loreal (absent) [59].

Discussion

The semi-arid Balsas Basin is recognized as a region possessing high levels of regional and local endemism in a wide array of taxa [79–84], but also as a vulnerable ecoregion [79,81,82]. Due to the Basin’s biotic composition, two biogeographical units (termed districts by [85]) have been proposed, the Lower and the Upper Balsas Basin [85,86], with the latter being the origin of the type series of Y. tlalli. Previous authors have recognized the relevance of the Balsas Basin using herpetofauna as a model [14,87,88], and studies involving other taxonomic groups have highlighted its importance as a refuge during dramatic climatic events such as the Last Glacial Maximum (e.g., [83,85]). Although several endemic species have been reported from the Basin, it remains largely unexplored. According to recent checklists and our own data, there are at least 77 snake species distributed within the Balsas Basin in the states of Estado de México, Guerrero, Jalisco, Michoacán, Morelos, Oaxaca, and Puebla [89–93 and E. A. Reyes-Velázquez, unpublished]. However, the number of snakes reported from the Balsas Basin within each state ranges from 16 to 44, which is low considering that the number of reported snake species in these states can be as high as 166 in Oaxaca [91]. Additionally, there are very few species of snakes considered endemic to the Balsas Basin, namely Coniophanes melanocephalus, Micrurus laticollaris, Thamnophis postremus, and Tropidodipsas zweifeli. We now add Yakacoatl tlalli to the short list. Whether this low number of endemic snake species represents a sampling bias or the result of historical events remains an open question.

Given the morphology of Yakacoatl, we initially hypothesized a close relationship with Conopsis or Pseudoficimia. The grooved rear fangs and the lack of hemipenial calyces in Yakacoatl are similar to Conopsis, while its body size and high ventral scales count resemble Pseudoficimia (Table 1). However, our phylogenetic analysis suggests a close relationship between Yakacoatl, Pseudoficimia, and Sympholis (Fig 1). According to Holm [25], who used morphological characters and a fragment of the cytb gene, the sister taxa of Sympholis and Pseudoficimia were Gyalopion and Stenorrhina, respectively. These relationships were not supported in later molecular phylogenies, which instead suggested for the first time that Sympholis and Pseudoficimia were sister taxa [26,31]. Based on our work, Yakacoatl now joins Pseudoficimia and Sympholis as a third endemic, monotypic Sonorini genus distributed in seasonally dry forests along the Pacific drainages of Mexico.

We lack firsthand knowledge of the natural history of Yakacoatl, as both specimens were found dead. Nonetheless, characteristics of its cranium such as a modified premaxilla, short supratemporals, compact and short braincase, and a short occipital condyle suggest fossorial habits. The enlarged rear fangs and stomach content indicate a diet specialized in arthropods as in many Sonorini [23]. According to Jackson et al. [94], a diet including centipedes, spiders, and scorpions has been reported in Sympholis. Holm [25] has reported beetle larvae for this species and suggested a burrowing lifestyle and a probable interaction with Atta mexicana nests, including secretion of an oily substance that may protect the snake from bites. In the case of Pseudoficimia, minimal data on its natural history have been published. We have collected specimens from the Balsas Basin under vegetal debris, and a diet consisting of Lepidoptera larvae and tarantulas of the genus Aphonopelma have been reported for specimens collected in Sonora [95]. It is important to mention that we do not consider Yakacoatl to have any degree of anthropophilia. Despite having been found in areas of high disturbance, we believe that Y. talli individuals are burrowers and do not usually inhabit anthropogenic areas (as suggested by its only recent discovery). After the two specimens (holotype and paratype) were encountered, further field trips to the area in search of additional individuals were unsuccessful. Therefore, while there are genera that are highly tolerant to disturbances and have relatively high abundances (e.g., Conopsis), we believe that this is not the case for Y. tlalli. Based on the morphological evidence and the encounter locality, we believe that this species usually inhabits xerophilous zones of the area, buried under rocks or logs.

Although the tribe Sonorini has been repeatedly recovered as a monophyletic group, the distinctiveness of genera such as Geagras and Tantillita remains to be tested [25,43]. Although they have been proposed as invalid genera [25], we believe that there is insufficient evidence for that proposal, given the limited number of organisms from each genus analyzed and the plasticity of the characters that support synonymy. Their inclusion in phylogenetic analyses with genetic data should be a focus of future research. On the other hand, the validity of Scolecophis and Tantilla as another clade within the tribe, and the relationships of the former with other Colubridae, remain challenging (see [35] for a summary of these conflicting higher-level relationships). The taxonomy of the speciose genus Tantilla represents another challenge, and until very recently few efforts have been made to resolve the relationships within the genus [39–41]. Although this genus has received scant attention, it is considered one of the most diverse snake genera in the world [42,43,89], which counters the argument that the Neotropical fossorial snakes are an “evolutionary dead-end” [96].

To our knowledge, since the year 2000, at least 58 Mexican snake taxa have been resurrected, described, or elevated from subspecific to specific status (Supplementary material, S3 Table). Of these, 24 (~42%) represent fossorial/semifossorial species of the genera Cenaspis, Chersodromus, Epictia, Geophis, Rena, Rhadinaea, Rhadinella, Tantilla, and now Yakacoatl. Furthermore, most of these taxa were described based on the discovery of new populations previously unknown to science, which is a comparatively infrequent occurrence among Mexican squamate descriptions [97]. With the recognition of Yakacoatl, there are now 16 snake genera endemic to Mexico, and they represent 18% of the currently known snake diversity in the country.

Supporting information

S1 Appendix. Specimens examined, exclusive of CT-scanned material.

See Materials and Methods for information on acronyms used. RPA refers to uncatalogued specimens to be deposited at the herpetological collection of the MZFC.

https://doi.org/10.1371/journal.pone.0337187.s001

(DOCX)

S1 Fig. Unedited tree resulting from the ML analysis of the Sonorini tribe.

https://doi.org/10.1371/journal.pone.0337187.s002

S1 Table. Taxa and respective CT-scans examined for osteological comparison.

Morphosource ID number provided. * Denotes specimens scanned for this study.

https://doi.org/10.1371/journal.pone.0337187.s003

(DOCX)

S2 Table. Species, specimen vouchers, and GenBank accession numbers used in our phylogenetic analysis.

Taxa in bold represent members of the tribe Sonorini.

https://doi.org/10.1371/journal.pone.0337187.s004

(DOCX)

S3 Table. Mexican snake species listed with at least one taxonomic status modification since the year 2000 to date.

https://doi.org/10.1371/journal.pone.0337187.s005

(DOCX)

S4 Table. Genetic uncorrected pairwise distances calculated from the 12S gene using MEGA X software.

https://doi.org/10.1371/journal.pone.0337187.s006

(DOCX)

S5 Table. Genetic uncorrected pairwise distances calculated from the 16S gene using MEGA X software.

https://doi.org/10.1371/journal.pone.0337187.s007

(DOCX)

S6 Table. Genetic uncorrected pairwise distances calculated from the cytb gene using MEGA X software.

https://doi.org/10.1371/journal.pone.0337187.s008

(DOCX)

Acknowledgments

This paper is part of the requirements for A.Y.C.B to obtain a Doctoral degree in systematics in the Posgrado en Ciencias Biológicas, UNAM. Sequencing was conducted at the Laboratorio Nacional de Biodiversidad (LANABIO), Instituto de Biología (IB), UNAM by Nelly López and Laura Margarita Marquez Valdelamar. Additionally, we thank Brett O. Butler and Daniela T. Candia Ramírez, for their help with software and phylogenetic analyses, as well as valuable comments on our preliminary results. We are also grateful to Uri Omar García-Vázquez for funding the fieldwork of this project, to Erika Adriana Reyes Velázquez for sharing with us her unpublished database of amphibians and reptiles from Estado de Mexico for preparing our discussion, to Fernando Hidalgo-Licona, Claudia Koch, Gonzalo Medina-Rangel, Oscar Pérez, and Paulino Ponce Campos for kindly sharing images to include in our plates, and to Edmundo López (Colección Nacional de Arácnidos, UNAM) for helping us identify the scorpion found in the stomach content of the holotype. Rodolfo Rodríguez Reyes took the photographs illustrating several aspects of the holotype of Y. tlalli. We thank Gregory G. Pandelis from the UTA ARDRC for arranging permits for importing and exporting specimens of Y. tlalli between Mexico and the USA, and for scanning the paratype at the UTA Shimadzu Center for Environmental Forensics and Material. For permission to use the CT-scanner at the Shimadzu Center, we thank J. F. Campbell.

References

1. 1. Flores-Villela O, Canseco-Márquez L. Nuevas especies y cambios taxonómicos para la herpetofauna de México. AZM. 2020;20(2):115–44.

* View Article

* Google Scholar

2. 2. Flores Villela OA, García-Vázquez UO. Biodiversidad de reptiles en México. RevMexBiodiv. 2013;85.

* View Article

* Google Scholar

3. 3. Uetz P, Freed P, Aguilar R, Reyes F, Kudera J, Hošek J. The Reptile Database. http://www.reptile-database.org. 2023. Accessed 2023 April 1.

4. 4. Suazo-Ortuño I, Ramírez-Bautista A, Alvarado-Díaz J. Amphibians and reptiles of Mexico: diversity and conservation. In: Jones RW, Ornelas-García CP, Pineda-López R, Álvarez F, editors. Mexican fauna in the Anthropocene. Switzerland: Springer Nature. 2023.

5. 5. Clause AG, Luna-Reyes R, Mendoza-Velázquez OM, Nieto-Montes de Oca A, Solano-Zavaleta I. Bridging the gap: A new species of arboreal Abronia (Squamata: Anguidae) from the Northern Highlands of Chiapas, Mexico. PLoS One. 2024;19(1):e0295230. pmid:38170723

* View Article

* PubMed/NCBI

* Google Scholar

6. 6. Grünwald CI, Reyes-Velasco J, Ahumada-Carrillo IT, Montaño-Ruvalcaba C, Franz-Chávez H, La Forest BT, et al. A new species of saxicolous Lepidophyma (Squamata, Xantusiidae) from Tamaulipas, Mexico. Herpetozoa. 2023;36:9–21.

* View Article

* Google Scholar

7. 7. Campillo-García G, Flores-Villela OA, Butler BO, Benabib M, Castiglia R. More cryptic diversity among spiny lizards of the Sceloporus torquatus complex discovered through a multilocus approach. Amphib-Reptilia. 2023;45(1):21–35.

* View Article

* Google Scholar

8. 8. Barragán-Reséndiz LM, Pavón-Vázquez CJ, Cervantes-Burgos RI, Trujano-Ortega M, Canseco-Márquez L, García-Vázquez UO. A New Species of Snake of the Geophis sieboldi Group (Squamata: Dipsadidae) from Estado de México, Mexico. Herpetologica. 2022;78(4).

* View Article

* Google Scholar

9. 9. García-Vázquez UO, Clause AG, Gutiérrez-Rodríguez J, Cazares-Hernández E, de la Torre-Loranca MÁ. A New Species of Abronia (Squamata: Anguidae) from the Sierra de Zongolica of Veracruz, Mexico. Ichthyology & Herpetology. 2022;110(1):33–49.

* View Article

* Google Scholar

10. 10. Flores-Villela O, Smith EN, Campillo-Garca G, Martnez-Mndez N, Campbell JA. A new species of Sceloporus of the torquatus group (Reptilia: Phrynosomatidae) from West Mexico. Zootaxa. 2022;5134(2):286–96. pmid:36101064

* View Article

* PubMed/NCBI

* Google Scholar

11. 11. Flores-Villela OA, Smith EN, Canseco-Márquez L, Campbell JA. A new species of blindsnake from Jalisco, Mexico (Squamata: Leptotyphlopidae). RevMexBiodiv. 2022;93:e933933.

* View Article

* Google Scholar

12. 12. de Oca AN-M, Castresana-Villanueva N, Canseco-Márquez L, Campbell JA. A New Species of Xenosaurus (Squamata: Xenosauridae) from the Sierra de Juárez of Oaxaca, Mexico. Herpetologica. 2022;78(1).

* View Article

* Google Scholar

13. 13. Palacios-Aguilar R, Flores-Villela O. An updated checklist of the herpetofauna from Guerrero, Mexico. Zootaxa. 2018;4422(1):1–24. pmid:30313509

* View Article

* PubMed/NCBI

* Google Scholar

14. 14. Flores-Villela O. Herpetofauna of Mexico: distribution and endemism. In: Ramamoorthy TP, Bye R, Lot A, Fa J, editors. Biological diversity of Mexico: origins and distributions. New York: Oxford University Press. 1993.

15. 15. Bryson RW Jr, Linkem CW, Dorcas ME, Lathrop A, Jones JM, Alvarado-Díaz J, et al. Multilocus species delimitation in the Crotalus triseriatus species group (Serpentes: Viperidae: Crotalinae), with the description of two new species. Zootaxa. 2014;3826(3):475–96. pmid:24990060

* View Article

* PubMed/NCBI

* Google Scholar

16. 16. Mastretta‐Yanes A, Moreno‐Letelier A, Piñero D, Jorgensen TH, Emerson BC. Biodiversity in the Mexican highlands and the interaction of geology, geography and climate within the Trans‐Mexican Volcanic Belt. J Biogeography. 2015;42(9):1586–600.

* View Article

* Google Scholar

17. 17. Blair C, Bryson RW Jr, Linkem CW, Lazcano D, Klicka J, McCormack JE. Cryptic diversity in the Mexican highlands: Thousands of UCE loci help illuminate phylogenetic relationships, species limits and divergence times of montane rattlesnakes (Viperidae: Crotalus). Mol Ecol Resour. 2019;19(2):349–65. pmid:30565862

* View Article

* PubMed/NCBI

* Google Scholar

18. 18. Myers CW, Cadle JE. On the snakes hemipenis, with notes on Psomophis and techniques of eversion: a response to Dowling. Herpetological Review. 2003;34:295–302.

* View Article

* Google Scholar

19. 19. Dowling HG. Yearbook of herpetology 1974. New York: Herpetological Information Search System, American Museum of Natural History. 1975.

20. 20. Hardy LM. A Systematic Revision of the Colubrid Snake Genus Ficimia. Journal of Herpetology. 1975;9(2):133.

* View Article

* Google Scholar

21. 21. Stickel WH. The Mexican snakes of the genera Sonora and Chionactis with notes on the status of other colubrid genera. Proceedings of the Biological Society of Washington. 1943;56:109–28.

* View Article

* Google Scholar

22. 22. Dowling HG, Duellman WE. Systematic herpetology: A synopsis of families and higher categories. New York: Herpetological Information Search System. 1978.

23. 23. SAVITZKY AH. Coadapted Character Complexes Among Snakes: Fossoriality, Piscivory, and Durophagy. Am Zool. 1983;23(2):397–409.

* View Article

* Google Scholar

24. 24. Greene HW. Snakes: the evolution of mystery in nature. California: University of California Press. 1997.

25. 25. Holm P. Phylogenetic biology of the burrowing snake tribe Sonorini (Colubridae). Department of Ecology and Evolutionary Biology, University of Arizona. 2008. http://hdl.handle.net/10150/196086

26. 26. Pyron RA, Burbrink FT, Wiens JJ. A phylogeny and revised classification of Squamata, including 4161 species of lizards and snakes. BMC Evol Biol. 2013;13:93. pmid:23627680

* View Article

* PubMed/NCBI

* Google Scholar

27. 27. GOYENECHEA I, FLORES-VILLELA O. Taxonomic summary of Conopsis, Günther, 1858 (Serpentes: Colubridae). Zootaxa. 2006;1271(1).

* View Article

* Google Scholar

28. 28. Goyenechea I. Relaciones filogenéticas de las serpientes del género Conopsis con base en la morfología. RevMexBiodiv. 2009;80(003).

* View Article

* Google Scholar

29. 29. Figueroa A, McKelvy AD, Grismer LL, Bell CD, Lailvaux SP. A Species-Level Phylogeny of Extant Snakes with Description of a New Colubrid Subfamily and Genus. PLoS One. 2016;11(9):e0161070. pmid:27603205

* View Article

* PubMed/NCBI

* Google Scholar

30. 30. Cox CL, Davis Rabosky AR, Holmes IA, Reyes-Velasco J, Roelke CE, Smith EN, et al. Synopsis and taxonomic revision of three genera in the snake tribe Sonorini. J Natural History. 2018;52(13–16):945–88.

* View Article

* Google Scholar

31. 31. Zaher H, Murphy RW, Arredondo JC, Graboski R, Machado-Filho PR, Mahlow K, et al. Large-scale molecular phylogeny, morphology, divergence-time estimation, and the fossil record of advanced caenophidian snakes (Squamata: Serpentes). PLoS One. 2019;14(5):e0216148. pmid:31075128

* View Article

* PubMed/NCBI

* Google Scholar

32. 32. Hardy LM. Comparative Morphology and Evolutionary Relationships of the Colubrid Snake Genera Pseudoficimia, Ficimia, and Gyalopion. Journal of Herpetology. 1975;9(4):323.

* View Article

* Google Scholar

33. 33. Jadin RC, Burbrink FT, Rivas GA, Vitt LJ, Barrio-Amorós CL, Guralnick RP. Finding arboreal snakes in an evolutionary tree: phylogenetic placement and systematic revision of the Neotropical birdsnakes. J Zoolog Syst Evol Res. 2013;52(3):257–64.

* View Article

* Google Scholar

34. 34. Tonini JFR, Beard KH, Ferreira RB, Jetz W, Pyron RA. Fully-sampled phylogenies of squamates reveal evolutionary patterns in threat status. Biological Conservation. 2016;204:23–31.

* View Article

* Google Scholar

35. 35. Montingelli GG, Grazziotin FG, Battilana J, Murphy RW, Zhang Y, Zaher H. Higher‐level phylogenetic affinities of the Neotropical genusMastigodryasAmaral, 1934 (Serpentes: Colubridae), species‐group definition and description of a new genus forMastigodryas bifossatus. J Zool Syst Evol Res. 2019;57(2):205–39.

* View Article

* Google Scholar

36. 36. Goyenechea I, Flores-Villela O. Taxonomic Status of the Snake Genera Conopsis and Toluca (Colubridae). Journal of Herpetology. 2002;36(1):92–5.

* View Article

* Google Scholar

37. 37. Cisneros-Bernal AY. Análisis de las relaciones filogenéticas del género de serpientes Ficimia con base a su morfología. Facultad de Ciencias, Universidad Nacional Autónoma de México. 2015.

38. 38. Hardy LM. A Systematic Revision of the Genus Pseudoficimia (Serpentes: Colubridae). Journal of Herpetology. 1972;6(1):53.

* View Article

* Google Scholar

39. 39. Azevedo WD, Franco FL, Thomassen H, Marcial de Castro T, Abegg AD, Leite FSF. Reassessment of Tantilla boipiranga (Serpentes: Colubridae) and a preliminary approach to the phylogenetic affinities within Tantilla. Salamandra. 2021;57:400–12.

* View Article

* Google Scholar

40. 40. dos Santos Azevedo W, Franco FL, Menezes L, Kunz TS, Grazziotin FG. Integrated evidence sheds light on the taxonomy of the widespread Tantilla melanocephala species complex (Serpentes: Colubridae) and indicates the existence of a new species from southern South America. Org Divers Evol. 2024;24(1):119–47.

* View Article

* Google Scholar

41. 41. Jowers MJ, Rivas GA, Jadin RC, Braswell AL, Auguste RJ, Borzeé A. Unearthing the species diversity of a cryptozoic snake, Tantilla melanocephala, in its northern distribution with emphasis on the colonization of the Lesser Antilles. Amphibian & Reptile Conservation. 2020;14:206–17.

* View Article

* Google Scholar

42. 42. Wilson LD, Mata-Silva V. Snakes of the genus Tantilla (Squamata: Colubridae) in Mexico: taxonomy, distribution, and conservation. Mesoamerican Herpetol. 2014;1:5–95.

* View Article

* Google Scholar

43. 43. Wilson LD, Mata-Silva V. A checklist and key to the snakes of the Tantilla clade (Squamata: Colubridae), with comments on taxonomy, distribution, and conservation. Mesoamerican Herpetol. 2015;2:418–98.

* View Article

* Google Scholar

44. 44. Cox CL, Davis Rabosky AR, Reyes-Velasco J, Ponce-Campos P, Smith EN, Flores-Villela O, et al. Molecular systematics of the genusSonora(Squamata: Colubridae) in central and western Mexico. Systematics and Biodiversity. 2012;10(1):93–108.

* View Article

* Google Scholar

45. 45. Myers CW. The systematics of Rhadinaea (Colubridae), a genus of New World snakes. Bulletin of the American Museum of Natural History. 1974;(153):1–262.

* View Article

* Google Scholar

46. 46. Dowling HG. A proposed standard system of counting ventrals in snakes. British J Herpetol. 1951;1:97–9.

* View Article

* Google Scholar

47. 47. Savage JM. A revised terminology for plates in the loreal region of snakes. British J Herpetol. 1973;(5):360–2.

* View Article

* Google Scholar

48. 48. SMITH EN, FERRARI-CASTRO JA. A new species of jumping pitviper of the genus Atropoides (Serpentes: Viperidae: Crotalinae) from the Sierra de Botaderos and the Sierra La Muralla, Honduras. Zootaxa. 2008;1948(1).

* View Article

* Google Scholar

49. 49. Dowling HG, Savage JM. A guide to the snake hemipenis: a survey of basic structure and systematic characteristics. Zoologica : scientific contributions of the New York Zoological Society. 1960;45(2):17–28.

* View Article

* Google Scholar

50. 50. Myers CW, Campbell JA. A new genus and species of colubrid snake from the Sierra Madre del Sur of Guerrero, Mexico. American Museum Novitates. 1981;(2708):1–20.

* View Article

* Google Scholar

51. 51. Fedorov A, Beichel R, Kalpathy-Cramer J, Finet J, Fillion-Robin J-C, Pujol S, et al. 3D Slicer as an image computing platform for the Quantitative Imaging Network. Magn Reson Imaging. 2012;30(9):1323–41. pmid:22770690

* View Article

* PubMed/NCBI

* Google Scholar

52. 52. Cundall D, Irish F. The snake skull. In: Grans C, Gaunt AS, Adler K, editors. Biology of Reptilia. USA: Society for the study of Anphibians and Reptiles. 2008. p. 349–692.

53. 53. Sabaj MH. Codes for Natural History Collections in Ichthyology and Herpetology. Copeia. 2020;108(3).

* View Article

* Google Scholar

54. 54. Sabaj MH. Codes for natural history collections in ichthyology and herpetology (online supplement). Washington, DC: American Society of Ichthyologists and Herpetologists. 2025. https://asih.org

55. 55. Hardy LM, Gyalopion G. Gyalopion, G. canum, G. quadrangularis. Catalogue of American Amphibians and Reptiles. 1976;(182):1–4.

* View Article

* Google Scholar

56. 56. Hardy LM. Ficimia. Catalogue of American Amphibians and Reptiles. 1990;(471):1–5.

* View Article

* Google Scholar

57. 57. Humphrey FL, Shannon FA. A state record and range extension for the snake Sympholis lippiens (Serpentes: Colubridae). Herpetologica. 1958;13:257–60.

* View Article

* Google Scholar

58. 58. Mahrdt CR, Beaman KR, Rosen PC, Holm PA. Catalogue of American Amphibians and Reptiles. 2001;730:1–6.

* View Article

* Google Scholar

59. 59. McCranie JR. The snakes of Honduras: systematics, distribution, and conservation. New York: Society for the Study of Amphibians and Reptiles. 2011.

60. 60. Wilson LD, Geagras G. Redimitus. 1987. https://doi.org/10.15781/T20Z71215

61. 61. Wilson LD, Tantillita T. Tantillita, T. brevissima, T. lintoni. 1988. https://doi.org/10.15781/T21R6N53S

62. 62. Jadin RC, Blair C, Orlofske SA, Jowers MJ, Rivas GA, Vitt LJ, et al. Not withering on the evolutionary vine: systematic revision of the Brown Vine Snake (Reptilia: Squamata: Oxybelis) from its northern distribution. Org Divers Evol. 2020;20(4):723–46.

* View Article

* Google Scholar

63. 63. Edgar RC. MUSCLE: multiple sequence alignment with high accuracy and high throughput. Nucleic Acids Res. 2004;32(5):1792–7. pmid:15034147

* View Article

* PubMed/NCBI

* Google Scholar

64. 64. Müller K, Müller J, Neinhuis C, Quandt D. PhyDE: Phylogenetic data editor. 2010.

65. 65. Katoh K, Standley DM. MAFFT multiple sequence alignment software version 7: improvements in performance and usability. Mol Biol Evol. 2013;30(4):772–80. pmid:23329690

* View Article

* PubMed/NCBI

* Google Scholar

66. 66. Lanfear R, Frandsen PB, Wright AM, Senfeld T, Calcott B. PartitionFinder 2: New Methods for Selecting Partitioned Models of Evolution for Molecular and Morphological Phylogenetic Analyses. Mol Biol Evol. 2017;34(3):772–3. pmid:28013191

* View Article

* PubMed/NCBI

* Google Scholar

67. 67. Lanfear R, Calcott B, Ho SYW, Guindon S. Partitionfinder: combined selection of partitioning schemes and substitution models for phylogenetic analyses. Mol Biol Evol. 2012;29(6):1695–701. pmid:22319168

* View Article

* PubMed/NCBI

* Google Scholar

68. 68. Nguyen L-T, Schmidt HA, von Haeseler A, Minh BQ. IQ-TREE: a fast and effective stochastic algorithm for estimating maximum-likelihood phylogenies. Mol Biol Evol. 2015;32(1):268–74. pmid:25371430

* View Article

* PubMed/NCBI

* Google Scholar

69. 69. Minh BQ, Nguyen MAT, von Haeseler A. Ultrafast approximation for phylogenetic bootstrap. Mol Biol Evol. 2013;30(5):1188–95. pmid:23418397

* View Article

* PubMed/NCBI

* Google Scholar

70. 70. Rambaut A. FigTree v.1.4.4. http://tree.bio.ed.ac.uk/software/figtree/. Accessed 2020 October 25.

71. 71. Kumar S, Stecher G, Li M, Knyaz C, Tamura K. MEGA X: Molecular Evolutionary Genetics Analysis across Computing Platforms. Mol Biol Evol. 2018;35(6):1547–9. pmid:29722887

* View Article

* PubMed/NCBI

* Google Scholar

72. 72. González-Hernández AJX, Garza-Castro JM, Balderas-Valdivia CJ. Manual de identificación de la herpetofauna de México. Mexico: Dirección General de Divulgación de la Ciencia/Facultad de Ciencias, Universidad Nacional Autónoma de México. 2021.

73. 73. Heimes P. Herpetofauna Mexicana Vol. 1: Snakes of Mexico. Frankfurt: Chimaira. 2016.

74. 74. Köhler G. Reptiles of Central America. 2nd ed. Offenbach, Germany: Herpeton Verlag. 2008.

75. 75. Peters JA, Orejas-Miranda B, Donoso-Barros R. Catalogue of the neotropical Squamata. Smithsonian Institution Press. 1970. https://doi.org/10.5962/bhl.title.46653

76. 76. Galdeano AP, Gómez-Alés R, Blanco GM, Acosta JC. Phimophis vittatus Boulenger, 1897 (Serpentes: Dipsadidae): nuevo registro para la provincia de San Juan Argentina. Cuadernos de Herpetología. 2018;32:67–9.

* View Article

* Google Scholar

77. 77. Filho GAP, Santana GG, Vieira WL da S, Alves RR da N, Montenegro PFGP, Freitas MA de. Phimophis guerini (Duméril, Bibron and Dumeril, 1854) (Serpentes: Dipsadidae): distribution extension in Paraiba, Brazil. cl. 2012;8(5):966.

* View Article

* Google Scholar

78. 78. Santos-Jr AP, Almeida-Santos DA, Ribeiro S, Carmargo ICM, da Costa Prudente AL. Distribution extension of Phimophis guerini (Serpentes: Dipsadidae: Xenodontinae) in the Brazilian Amazon. Zoologia. 2019;36:1–6.

* View Article

* Google Scholar

79. 79. Rzedowski J. Vegetación de México. 2nd Edition. Mexico: Editorial Limusa;1983.

80. 80. Ceballos G, García A. Conserving Neotropical Biodiversity: The Role of Dry Forests in Western Mexico. Conservation Biology. 1995;9(6):1349–56.

* View Article

* Google Scholar

81. 81. Ochoa-Ochoa LM, Flores Villela O. Áreas de diversidad y endemismo de la herpetofauna mexicana. Mexico: Las Prensas de Ciencias, Facultad de Ciencias, UNAM. 2006.

82. 82. Garcia A, Solano-Rodríguez H, Flores-Villela O. Patterns of alpha, beta and gamma diversity of the herpetofauna in Mexico’s Pacific lowlands and adjacent interior valleys. Anim Biodiv Conserv. 2007;30(2):169–77.

* View Article

* Google Scholar

83. 83. Gámez N, Escalante T, Espinosa D, Eguiarte LE, Morrone JuanJ. Temporal dynamics of areas of endemism under climate change: a case study of Mexican Bursera (Burseraceae). J Biogeography. 2013;41(5):871–81.

* View Article

* Google Scholar

84. 84. Estrada-Márquez AS, Morrone JJ, Villaseñor JL. Areas of endemism of two biogeographic provinces in central Mexico based on their endemic Asteraceae: a conservation proposal. RevMexBiodiv. 2021;92:e923470.

* View Article

* Google Scholar

85. 85. Morrone JJ. Biogeographical regionalisation of the Neotropical region. Zootaxa. 2014;3782:1–110. pmid:24871951

* View Article

* PubMed/NCBI

* Google Scholar

86. 86. Morrone JJ, Escalante T, RodrÍguez-Tapia G. Mexican biogeographic provinces: Map and shapefiles. Zootaxa. 2017;4277(2):277–9. pmid:30308652

* View Article

* PubMed/NCBI

* Google Scholar

87. 87. Smith HM. An analysis of the biotic provinces of Mexico, as indicated by the distribution of the lizards of the genus Sceloporus. Anales de la Escuela Nacional de Ciencias Biológicas. 1941;2:95–102.

* View Article

* Google Scholar

88. 88. Johnson JD, Wilson LD, Mata-Silva V, García-Padilla E, DeSantis DL. The endemic herpetofauna of Mexico: organisms of global significance in several peril. Mesoamerican Herpetology. 2017;4:544–620.

* View Article

* Google Scholar

89. 89. Palacios-Aguilar R, Fucsko LA, Jiménez-Arcos VH, Wilson LD, Mata-Silva V. Out of the past: A new species of Tantilla of the calamarina group (Squamata: Colubridae) from southeastern coastal Guerrero, Mexico, with comments on relationships among members of the group. Amphibian and Reptiles Conservation. 2022;16:120–32.

* View Article

* Google Scholar

90. 90. Alvarado-Díaz J, Suazo-Ortuña I, Wilson LD, Medina-Aguilar O. Patterns of physiographic distribution and conservation status of the herpetofauna of Michoacán, Mexico. Amphibian & Reptile Conservation. 2013;7:128–70.

* View Article

* Google Scholar

91. 91. Mata-Silva V, Garca-Padilla EL, Rocha A, Desantis DL, Johnson JD, Ramrez-Bautista A, et al. A Reexamination of the Herpetofauna of Oaxaca, Mexico: Composition Update, Physiographic Distribution, and Conservation Commentary. Zootaxa. 2021;4996(2):201–52. pmid:34810533

* View Article

* PubMed/NCBI

* Google Scholar

92. 92. Woolrich-Piña GA, García-Padilla E, DeSantis DL, Johnson J, Mata-Silva V, Wilson LD. The herpetofauna of Puebla, Mexico: composition, distribution, and conservation. Mesoamerican Herpetology. 2017;4:794–884.

* View Article

* Google Scholar

93. 93. Cruz-Sáenz D, Muñoz-Nolasco FJ, Mata-Silva V, Johnson J, García-Padilla E, Wilson LD. The herpetofauna of Jalisco, Mexico: composition, distribution, and conservation. Mesoamerican Herpetology. 2017;4:23–118.

* View Article

* Google Scholar

94. 94. Jackson TNW, Jouanne H, Vidal N. Snake Venom in Context: Neglected Clades and Concepts. Front Ecol Evol. 2019;7.

* View Article

* Google Scholar

95. 95. Bogert CM, Oliver JM. A preliminary analysis of the herpetofauna of Sonora. Bulletin of the American Museum of Natural History. 1945;(83):297–426.

* View Article

* Google Scholar

96. 96. Cyriac VP, Kodandaramaiah U. Digging their own macroevolutionary grave: fossoriality as an evolutionary dead end in snakes. J Evol Biol. 2018;31(4):587–98. pmid:29418035

* View Article

* PubMed/NCBI

* Google Scholar

97. 97. Clause AG, Luna-Reyes R, De Oca AN-M. A New Species of Abronia (Squamata: Anguidae) from a Protected Area in Chiapas, Mexico. Herpetologica. 2020;76(3):330.

* View Article

* Google Scholar

Citation: Cisneros-Bernal AY, Palacios-Aguilar R, Hernández-Jiménez C, Smith EN, Flores-Villela O, Hernández-Morales C, et al. (2025) Sticking our nose into the Sonorini tribe: A new genus and species of snake (Squamata: Colubridae: Sonorini) from the Balsas Basin of Mexico. PLoS One 20(12): e0337187. https://doi.org/10.1371/journal.pone.0337187

About the Authors:

Antonio Y. Cisneros-Bernal

Contributed equally to this work with: Antonio Y. Cisneros-Bernal, Ricardo Palacios-Aguilar

Roles: Conceptualization, Data curation, Formal analysis, Investigation, Methodology, Writing – original draft

E-mail: [email protected]

Affiliations: Posgrado en Ciencias Biológicas, Unidad de Posgrado, Circuito de Posgrados, Ciudad Universitaria, Coyoacán, Mexico, Departamento de Biología Evolutiva, Facultad de Ciencias, Universidad Nacional Autónoma de México, Circuito exterior s/n, Ciudad Universitaria, Coyoacán, México, Totlok A. C., Tlalpan, Mexico

ORICD: https://orcid.org/0000-0001-5739-8409

Ricardo Palacios-Aguilar

Contributed equally to this work with: Antonio Y. Cisneros-Bernal, Ricardo Palacios-Aguilar

Roles: Conceptualization, Data curation, Formal analysis, Investigation, Methodology, Writing – original draft

Affiliations: Departamento de Biología Evolutiva, Facultad de Ciencias, Universidad Nacional Autónoma de México, Circuito exterior s/n, Ciudad Universitaria, Coyoacán, México, Totlok A. C., Tlalpan, Mexico

ORICD: https://orcid.org/0000-0001-7131-5534

Carlos Hernández-Jiménez

Roles: Data curation, Resources, Writing – review & editing

¶‡ These authors also contributed equally to this work.

Affiliation: Facultad de Ciencias Biológicas, Benemérita Universidad Autónoma de Puebla, Puebla, Mexico

Eric N. Smith

Roles: Resources, Writing – review & editing

¶‡ These authors also contributed equally to this work.

Affiliation: Amphibian and Reptile Diversity Research Center, Department of Biology, The University of Texas at Arlington, Arlington, Texas, United States of America

Oscar Flores-Villela

Roles: Funding acquisition, Project administration, Supervision, Writing – review & editing

Affiliation: Departamento de Biología Evolutiva, Facultad de Ciencias, Universidad Nacional Autónoma de México, Circuito exterior s/n, Ciudad Universitaria, Coyoacán, México

Cristian Hernández-Morales

Roles: Methodology, Resources, Writing – review & editing

Affiliation: Argentine Dryland Research Institute of the National Scientific and Technical Research Council, Mendoza, Argentina

ORICD: https://orcid.org/0000-0001-9964-9173

Oscar Olivares Loyola

¶‡ These authors also contributed equally to this work.

Affiliation: Facultad de Ciencias Biológicas, Benemérita Universidad Autónoma de Puebla, Puebla, Mexico

Gustavo Campillo-García

Roles: Resources, Writing – review & editing

¶‡ These authors also contributed equally to this work.

Affiliation: Departamento de Biología Evolutiva, Facultad de Ciencias, Universidad Nacional Autónoma de México, Circuito exterior s/n, Ciudad Universitaria, Coyoacán, México