Morphological and molecular evidence for a new rhabdochonid species, Rhabdochona (Nematoda: Rhabdochonidae), parasitizing Eugerres mexicanus (Perciformes: Gerreidae), from the Lacantún River in the Biosphere Reserve of Montes Azules, Chiapas, Mexico

Caspeta-Mandujano, Juan Manuel; Salinas-Ocampo, Julio Cesar; Suárez-Rodríguez, Ramón; Martínez-Ramírez, Carlos; Matamoros, Wilfredo A.; Caspeta-Mandujano, Juan Manuel; Salinas-Ocampo, Julio Cesar; Suárez-Rodríguez, Ramón; Martínez-Ramírez, Carlos; Matamoros, Wilfredo A.

doi:10.22201/ib.20078706e.2021.92.3266

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Revista mexicana de biodiversidad

versión On-line ISSN 2007-8706versión impresa ISSN 1870-3453

Rev. Mex. Biodiv. vol.92 México 2021 Epub 25-Oct-2021

https://doi.org/10.22201/ib.20078706e.2021.92.3266

Taxonomy and systematics

Morphological and molecular evidence for a new rhabdochonid species, Rhabdochona (Nematoda: Rhabdochonidae), parasitizing Eugerres mexicanus (Perciformes: Gerreidae), from the Lacantún River in the Biosphere Reserve of Montes Azules, Chiapas, Mexico

Evidencias morfológicas y moleculares de una nueva especie de rabdocónido, Rhabdochona (Nematoda: Rhabdochonidae), parásito de Eugerres mexicanus (Perciformes: Gerreidae), del río Lacantún en la Reserva de la Biosfera Montes Azules, Chiapas, México

Juan Manuel Caspeta-Mandujano^a^*

Julio Cesar Salinas-Ocampo^a^b

Ramón Suárez-Rodríguez^c

Carlos Martínez-Ramírez^d

Wilfredo A. Matamoros^e

^{^a}Laboratorio de Parasitología de Animales Silvestres, Facultad de Ciencias Biológicas y Centro de Investigaciones Biológicas, Universidad Autónoma del Estado de Morelos, Av. Universidad Núm. 1001, Col. Chamilpa, 62209 Cuernavaca, Morelos, Mexico

^{^b}Maestría en Biología Integrativa de la Biodiversidad y la Conservación, Centro de Investigación en Biodiversidad y Conservación, Universidad Autónoma del Estado de Morelos, Av. Universidad Núm. 1001, Col. Chamilpa, 62209 Cuernavaca, Morelos, Mexico

^{^c} Laboratorio de Fisiología Molecular de Plantas, Centro de Investigación en Biotecnología, Universidad Autónoma del Estado de Morelos, Av. Universidad Núm. 1001, Col. Chamilpa, 62209 Cuernavaca, Morelos, Mexico

^{^d}Facultad de Medicina Veterinaria y Zootecnia, Universidad Autónoma de Nuevo León, Av. Francisco Villa Núm. 20, Hacienda El Canadá, 66050 Monterrey, Nuevo León, Mexico

^{^e}Posgrado en Ciencias en Biodiversidad y Conservación de Ecosistemas Tropicales, Instituto de Ciencias Biológicas, Universidad de Ciencias y Artes de Chiapas, Libramiento Norte Poniente 1150, Col. Lajas Maciel, 29039 Tuxtla Gutiérrez, Chiapas, Mexico

Abstract

A new nematode species, Rhabdochona juliacarabiasae sp. n. is described from specimens recovered from the intestine of the freshwater Mexican mojarra, Eugerres mexicanus (Steindachner) (Gerreidae) captured in the Lacantún River, Chiapas, Mexico. Rhabdochona juliacarabiasae sp. n. is characterized by possessing a prostome armed with 12 anterior teeth (excepcionally 11), small bifurcated deirids with a markedly long base, an unusual tetrafurcate tip of the larger (left) spicule, a smaller (right) spicule without dorsal barb on its distal tip, and eggs with 1 short filament on each pole. In addition, in order to assess the phylogenetic relationships of the new species, and further demonstrate its distinctiveness against closely related congeners, specimens of R. juliacarabiasae sp. n, R. xiphophori, R. salgadoi, R. kidderi, R. canadensis, R. guerreroensis, and R. mexicana were sequenced for the cox1 gene, and the sequences were aligned with other nematode sequences available in GenBank (R. adentata, R. ahuhuellensis, R. ictaluri, and R. osorioi). Maximum likelihood and Bayesian inference analyses indicated that this new nested in a well-supported clade with high posterior probability. The molecular analyses support the validity of the new species. R. juliacarabiasae sp. n. was recovered as sister to the clade formed by R. kidderi and R. ictaluri, and shows genetic divergence that range between 11.18 and 14.89% (P- distances) compared with other congeners.

Keywords: Parasitic nematode; Freshwater fish; Eugerres mexicanus; Lacantún River; Mexico

Resumen

Una especie nueva de nemátodo, Rhabdochona juliacarabiasae sp. n., se describe a partir de ejemplares obtenidos del intestino de la mojarra mexicana de agua dulce Eugerres mexicanus (Steindachner) (Gerreidae), capturada en el río Lacantún, Chiapas, México. Rhabdochona juliacarabiasae sp. n. se caracteriza por poseer un prostoma armado con 12 dientes anteriores (excepcionalmente 11), pequeños deiridios bifurcados con una base marcadamente larga, una inusual terminación tetrafurcada de la espícula más grande (izquierda), la espícula derecha más pequeña y sin barba dorsal en su punta distal, y huevos con un filamento corto en los polos. Además, con el fin de evaluar las relaciones filogenéticas de la nueva especie y enfatizar más su carácter distintivo, con respecto a congéneres relacionados cercanamente, se comparó el gen cox1 de ejemplares de R. juliacarabiasae sp. n. con los de R. xiphophori, R. salgadoi, R. kidderi, R. canadensis, R. guerreroensis y R. mexicana; las secuencias se alinearon con otras secuencias de nemátodos disponibles en GenBank (R. adentata, R. ahuhuellensis, R. ictaluri y R. osorioi). Los análisis de máxima probabilidad e inferencia bayesiana indicaron que esta nueva especie forma un clado independiente y bien soportado con alta probabilidad posterior. Los análisis moleculares apoyan la validez de la especie nueva basada en observaciones morfológicas. R. juliacarabiasae sp. n. se agrupa como clado hermano del formado por R. kidderi y R. ictaluri, y muestra una divergencia genética que oscila entre 11.18 y 14.89% (distancias P) comparada con otros congéneres.

Palabras clave: Nemátodo parásito; Peces de agua dulce; Eugerres mexicanus; Río Lacantún; México

Introduction

The commonly named “mojarras” of the family Gerreidae comprise a group of fishes distributed along the subtropical and tropical coastal areas of the world. In America, the family is represented by 22 valid species, belonging to 4 genera (^{Nelson et al., 2004}): Gerres Quoy et Gaimard; Diapterus Ranzani; Eucinostomus Baird et Girard; and Eugerres Jordan et Evermann. Most species inhabit coastal lagoons and estuaries with sandy or muddy bottoms bordered by mangroves; however, they occasionally enter river mouths. It has been thought that Eugerres mexicanus (Steindachner) is the only gerreid species confined to freshwater habitats in southeastern Mexico and northern Guatemala (^{Castro-Aguirre et al., 1999}; ^{Deckert & Greenfield 1987}; ^{Miller et al., 2006}). Herein, as part of a biological inventory of the Biosphere Reserve Montes Azules (BRMA), fish from the main canal of the Lacantún River were sampled for helminth parasites and a new nematode species of Rhabdochona Railliet, 1916 was found in the intestine of E. mexicanus, which is described below.

Materials and methods

In January 2013, 7 individuals of E. mexicanus were caught with the use of a gillnet in the main canal of the Lacantún River, Chiapas, next to the Chajul Station (16°06’38.4’’ N, 90°56’23.6’’ W). The Lacantún River is the main body of water of the Biosphere Reserve Montes Azules and drains to the Usumacinta River basin near the Mexico and Guatemala borders. Fish were transported alive to the Estación de Biología Tropical Chajul and examined immediately. The recovered nematodes (n = 28) were fixed in hot 4% formalin and some individuals in 100% ethanol for molecular analysis; subsequently, they were cleared with glycerine for light microscopy study. Drawings were made with the aid of a Nikon drawing attachment. After examination, the nematode specimens were stored in vials with 70% ethanol. Six specimens were dried by critical point method to further study with a scanning electron microscope Hitachi S-2460N. All measurements are given in micrometres unless otherwise stated. Type and paratypes specimens of the new species are deposited in the Colección Nacional de Helmintos, Instituto de Biología, Universidad Nacional Autónoma de México (CNHE), Mexico City.

Total DNA was purified from vouchered nematodes using the Quick-DNA™ Universal Kit from Zymo Research according to the tissue samples protocol. A partial fragment of cytochrome c oxidase subunit I (cox1) gene was amplified with the forward primer COIintF (5´-TGATTGGTGGTTTTGGTAA-3´) and the reverse primer COIintR (5´-ATAAGTACGAGTATCAATATC-3´) (^{Casiraghi et al., 2001}), with the following conditions: initial denaturation at 94 °C for 3 min and 40 cycles of 94 °C for 45 sec, 57 °C for 45 sec, 72 °C for 90 sec, and a final extension for 5 min at 72 °C. PCR reactions (50 μl) consisted of 20 pmol of each primer, 5 μl of buffer (10X), 3 μl of MgCl2 (25mM), 4 μl of dNTPs mixture (2mM), 2 U of Taq DNA polymerase and 5 μl of DNA. The PCR products were verified on 1% agarose gels stained with ethidium bromide (Sigma-Aldrich, Toluca, Mexico) and purified with the QIAEX II Gel Extraction Kit (QIAGEN). The PCR products were sequenced at the Instituto de Biotecnología, Universidad Nacional Autónoma de México, Mexico City.

The partial sequence of the cox1 gene was aligned with default parameters implemented in MAFFT with sequences of nematodes of Rhabdochona available in the GenBank database (Table 1): R. ahuehuellensis (MK353475, MK353476, MK353477); R. lichtenfelsi (DQ990982, DQ990984, DQ990987 ); R. xiphophori (MK353483); R. salgadoi (MK341632,); R. ictaluri (MK353479, MK353480, MK353482); R. acuminata (MK341634, MK341635, MK341636); R. osorioi (MK341623, MK341625, 341626), and R. mexicana (MK341611, MK353470). The sequences of R. juliacarabiasae sp. n. obtained in the present study were deposited in the GenBank with accession number MF405199. On the other hand, other Rhabdochona species deposited there were used in this study to compare with the new one, R. canadensis (MH778489), R. kidderi (MH778490), R. mexicana (MH778491), R. salgadoi (MH778492), R. xiphophori (MH778493, MN592670), and R. guerreroensis (MN592669). Spinitectus osorioi (MN592671) and Spinitectus humbertoi (MH778494) were used as outgroup. The best-fitting nucleotide substitution models (GTR+I+G) were estimated with the Akaike Information Criterion (AIC) implemented in jmodeltest2 (^{Posada, 2008}). Maximum likelihood (ML) and Bayesian Inference (BI) were used to estimate the phylogenies for the data set. Maximum likelihood analysis (^{Felsenstein, 1973}) was carried out in the RAxML (^{Stamatakis, 2006}) program version 0.9.0 (^{Koslov et al., 2019}). A GTRGAMMAI substitution model was used, and 10,000 bootstrap replicates were run to assess nodal support. Bayesian analysis was conducted using MrBayes version 3.2.6 (^{Altekar et al., 2004}; ^{Ronquist & Huelsenbeck, 2003}). The analysis was run with 4 million generations and sampling tree topologies every 1,000 generations and a Burning of 25%. Posterior probabilities of clades were obtained from 50% majority rule consensus of sample trees after excluding the initial 25% as “burn-in”. The generated trees were visualized in FigTree vl.4.3. To assess the level of genetic distances among isolates, the uncorrected genetic distance was calculated in MEGA v7 for the cox1 datasets (^{Kumar et al., 2016}; Table 2).

Table 1 Nematode species analyzed in this study, including host species, localities, and GenBank accession numbers to sequences generated in this work.

Parasite/host (Family)	Localities (geographical coordinates)	GenBank accession number	Reference
Rhabdochona acuminata Brycon guatemalensis (Characidae)	El Mangal, Tenosique, Tabasco (17°38’24” N, 91°22’48” W) Río Pichucalco, Chiapas (17°30’ N, 93°06’36” W)	MK341634 - 36	Santacruz et al., 2019
Rhabdochona adentata Profundulus oaxacae (Profundulidae)	Río Grande, Oaxaca (16°55’38.12” N, 96°19’42.58” W)	MN927199 - 201	Caspeta-Mandujano et al., 2020
Rhabdochona ahuehuellensis Ilyodon whitei (Goodeidae)	Huaquechula, Puebla (18°46’1” N, 98°32’09” W)	MK353475 - 77	Lagunas-Calvo et al., 2019
Rhabdochona canadensis Notropis boucardi (Cyprinidae)	Barranca la Cuera, Tlayecac, Morelos (18°45’28” N, 98°52’54” W)	MH778489	Present study
Rhabdochona guerreroensis Sicydium multipunctatum (Gobiidae)	Villa Purificación, Jalisco (19°42’02” N, 104°35’53” W)	MN592669	Present study
Rhabdochona ictaluri Ictalurus pricei (Ictaluridae)	Nombre de Dios, Durango (23°47’22” N, 104°18’09” W)	MK353479 MK353480 MK353482	Lagunas-Calvo et al., 2019
Rhabdochona juliacarabiasae Eugerres mexicanus (Gerreidae)	Río Lacantún, Chiapas (16°06’38.4” N, 90°56’23.6” W)	MF405199	Present study
Rhabdochona kidderi Cichlasoma istlanum (Cichlidae)	Barranca la Cuera, Tlayecac, Morelos (18°45’28” N, 98°52’54” W)	MH778490	Present study
Rhabdochona lichtenfelsi Goodea atripinis (Goodeidae)	Pátzcuaro, Michoacán (19°36’05” N, 101°39’13” W) La Minzita, Michoacán (19°38’4” N, 101°16’28”)	DQ990982 DQ990984 DQ990987	Mejía-Madrid et al., 2007a
Rhabdochona mexicana Astyanax mexicanus (Characidae)	Barranca la Cuera, Tlayecac, Morelos (18°45’28” N, 98°52’54” W) Río Jalpan, Querétaro (21°12’14.76” N, 99°28’28.2” W) Río Amacuzac, El Chisco, Morelos (18.4°80’73” N, 99.19°04’02” W)	MH778491 MK353470 MK341611	Present study Santacruz et al., 2019
Rhabdochona osorioi Astyanax mexicanus (Characidae)	Río Paso de Ovejas, Pueblo el Crucero, Veracruz (19°18’36” N, 96°31’48” W)	MK341623 MK341625 MK341626	Santacruz et al., 2019
Rhabdochona salgadoi Profundulus labialis (Profundulidae)	Pluma Hidalgo, Oaxaca (15°50’25” N, 96°21’26” W) Nacimiento del Río Tehuantepec, Oaxaca (16° 53’ 24” N, 99° 09’ 36” W)	MH778492 MK341632	Present study Santacruz et al., 2019
Rhabdochona xiphophori Xiphophorus hellerii (Poeciliidae) Poeciliopsis gracilis (Poeciliidae)	Pluma Hidalgo, Oaxaca (15°50’25” N, 96°21’26” W) Camino a Hierve el Agua, Oaxaca (16°54’23” N, 96°19’55” W)	MH778493 MN592670 MK353483	Present study Lagunas-Calvo et al., 2019
Spinitectus osorioi Atherinella osorioi (Atherinopsidae)	Arroyo San José, Chiapas (16°06‘50” N, 90°56‘03.3” W)	MN592671	Present study
Spinitectus humbertoi Profundulus labialis (Profundulidae)	Río Papagayo, Guerrero (16°47’01” N, 99°36’10” W)	MH778494	Present study

Table 2 Genetic distance among Rhabdochona spp. calculated with the cox1 matrix.

Species	1	2	3	4	5	6	7	8	9	10	11	12	13	14	15
1 R. acuminata	0.00
2 R. adentata	10.40	0.00
3 R. ahuehuellensis	8.61	8.30	0.00
4 R. canadensis	9.84	8.67	8.97	0.00
5 R. guerreroensis	10.28	8.19	5.02	9.43	0.00
6 R. ictaluri	11.44	11.00	11.90	11.61	13.03	0.00
7 R. juliacarabiasae	12.95	11.75	13.00	12.11	14.09	13.00	0.00
8 R. kidderi	9.67	9.06	8.61	9.75	10.24	9.59	12.31	0.00
9 R. lichtenfelsi	8.33	7.45	7.00	9.00	9.35	10.53	12.94	8.77	0.00
10 R. mexicana	12.95	11.75	11.00	13.21	13.21	14.15	14.89	12.01	11.40	0.00
11 R. osorioi	8.52	11.95	10.26	11.70	11.39	10.86	12.22	9.97	10.96	11.74	0.00
12 R. salgadoi	7.38	8.86	7.69	7.39	9.43	11.06	11.63	8.66	8.55	11.40	9.97	0.00
13 R. xiphophori	8.20	7.71	6.90	7.98	8.63	9.71	11.18	7.45	7.24	11.40	9.62	7.10	0.00
14 S. osorioi	13.00	12.14	13.19	13.29	13.41	14.71	15.40	13.29	13.82	14.26	13.45	10.86	12.16	0.00
15 S. humbertoi	13.44	12.33	12.82	12.11	14.01	12.75	15.89	12.16	11.84	15.20	14.00	11.04	11.04	10.86	0.00

Description

Family Rhabdochonidae Travassos, Artigas and Pereira, 1928

Rhabdochona juliacarabiasae sp. n. Figs. 1-19 http://zoobank.org/urn:lsid:zoobank.org:act:72BF6143-6156-4C29-A819-2F1AAD3AB068

Figures 1-9 Rhabdochona juliacarabiasae sp. n. 1) Anterior end of male, ventral view; 2, 3) anterior end of female, lateral views; 4) anterior end of male, ventral view, larger magnification; 5) posterior end of female, lateral view; 6) posterior end of male, lateral view; 7) mature egg; 8) spicules; 9) cephalic end of female, apical view. Scale bar in mm.

Figures 10-19 Rhabdochona juliacarabiasae sp. n., scanning electron micrographs. 10) Anterior end of male, ventral view; 11, 12) cephalic end of female and male, apical views (arrows indicate sublabia); 13) posterior end of female, subterminal view; 14) posterior end of male, lateral view; 15) deirid; 16) distal tip of larger spicule; 17) tail tip of male; 18) eggs; 19) tail tip of female. am = amphid, pa = papilla.

General. Medium sized nematodes with a transversely striated cuticle. Oral aperture oval, dorso-ventrally elongated, surrounded by 4 small submedian plates (sublabia), 4 submedian cephalic papillae and pair of lateral amphids (Figs. 11, 12). Prostom funnel-shaped, wide, with basal teeth; anterior margin of prostom armed internally with 12 teeth (exceptionally 11) (2 dorsal, 2 ventral and 4 lateral on each side forming pairs) (Figs. 9, 11, 12). Vestibule relatively long (Figs. 1-4). Deirids small, bifurcated (Fig. 15), somewhat asymmetrical, located short distance posterior to prostom. Tail of both sexes conical, with sharply pointed tip (Figs. 5, 6, 13, 14, 17, 19).

Male (10 specimens; measurements of holotype in parentheses). Length of body 3.53-4.72 (4.17) mm, maximum width 75-133 (75). Prostom 10-12 (12) long and 7-8 (7) wide. Length of vestibule including prostom 75-87 (83), muscular esophagus 112-143 (125) long, glandular esophagus 937-1.35 mm (1.10 mm) long. Nerve ring, excretory pore and deirids 106-131 (118), 181-231 (206) and 56-62 (60), respectively, from anterior end. Precloacal papillae: 9-10 pairs of subventrals and 1 lateral pair, situated between second and third subventral pairs (counting from cloacal opening) (Figs. 6, 14). Postcloacal papillae: 6 pairs; second pair lateral, remaining pairs subventral (Figs. 6, 14). Ventral precloacal cuticular ridges (area rugosa) absent. Larger (left) spicule 287-324 (312) long, length of shaft 137-162 (162) (representing 48-52% of spicule length); distal tip tetrafurcated (Figs. 8, 16). Smaller (right) spicule 72-75 (75) long, without dorsal barb (Fig. 8). Length ratio of spicules 1:3.8-4.5 (4.2). Tail conical, 187-275 (225) long (Figs. 14, 17).

Female (10 specimens, measurements of the allotype in parentheses). Length of body of gravid specimens 9.48-10.66 (10.66) mm, maximum width 100-200 (170). Prostom 13-18 (16) long and 12-13 (13) wide. Length of vestibule including prostom 100-110 (100), muscular esophagus 131-200 (181) long, glandular esophagus 1.301.78 (1.38) mm long. Nerve ring, excretory pore and deirids 137-168 (168), 212-250 (250), and 93-100 (100), respectively, from anterior end. Vulva preequatorial, 3.124.56 (4.55) mm from anterior extremity. Muscular vagina directed anteriorly. Uterus below level of posterior end of esophagus. Size of mature (embryonated) eggs 30-32 x 18-20; surface of eggs with 1 thick polar filament on each pole (Figs. 7, 18). Tail conical, 125-143 (138) long (Figs. 5, 13).

Taxonomic sumary

Type host: Eugerres mexicanus (Steindachner) (Gerreidae).

Site of infection: intestine.

Type locality: Chajul Station (16°06’38.4” N, 90°56’23.6” W), Lacantún River, Chiapas, Mexico (collected January 2013).

Prevalence and intensity of infection: 7 fish infected/7 examined; 3-40 nematodes per fish.

Type material: holotype, CNHE-8052, allotype CNHE-8053, and paratypes CNHE-8054 at Instituto de Biología, UNAM, Mexico City.

Etymology: this species has been named in honor of Prof. Julia Carabias Lillo from the Universidad Nacional Autónoma de Mexico (UNAM), acknowledging her contributions to environmental restoration and management of natural resources in the Biosphere Reserve of Montes Azules in the state of Chiapas.

Sequences: sequences obtained from 1 specimen of the new species and other specimens: R. canadensis (MH778489), R. kidderi kidderi (MH778490), R. mexicana (MH778491), R. salgadoi (MH778492), R. xiphophori (MH778493, MN592670), R. guerreroensis (MN592669), and sequences from S. osorioi (MN592671) and S. humbertoi (MH778494), were deposited in GenBank.

Remarks

The number of prostomal teeth, the shape of deirids, the presence or absence of superficial formations on eggs, the shape of the distal tip of the larger spicule and the number of postcloacal papillae in males, have been shown to be the most important interspecific characteristics that help in the discrimination of species of Rhabdochona (^{Caspeta-Mandujano & Moravec, 2000}; ^{Caspeta-Mandujano et al., 2000}, ²⁰⁰¹, ²⁰⁰²; ^{Moravec, 1968}, ¹⁹⁷², ¹⁹⁷⁵, ¹⁹⁷⁸, ²⁰¹⁰; ^{Moravec et al., 2008}, ²⁰⁰⁹, ²⁰¹³; ^{Moravec, Bilal et al., 2012}).

Rhabdochona includes more than 100 valid species parasitizing freshwater fish in all zoogeographical regions (^{Caspeta-Mandujano et al., 2020}; ^{Moravec et al., 2013}; ^{Santacruz et al., 2019}). Currently, 23 valid species and 2 subspecies of Rhabdochona have been reported in America (^{Caspeta-Mandujano, 2010}; ^{Caspeta-Mandujano et al., 2020}; ^{Moravec et al., 2011}; ^{Moravec, Salgado-Maldonado et al., 2012}; ^{Santacruz et al., 2019}), 12 of which are registered as parasites of freshwater fishes in Mexico: R. acuminata Molin, 1860; R. adentata^{Caspeta-Mandujano, Salinas-Ocampo, Calixto-Rojas, Rubio-Godoy et Pinacho-Pinacho, 2020}; R. ahuhuellensis Mejía-Madrid et Pérez-Ponce de León, 2003; R. canadensis Moravec et Arai, 1971; R. cascadilla Wingdor, 1918; R. guerreroensis Caspeta-Mandujano, Aguilar-Aguilar et Salgado-Maldonado, 2000; R. ictaluri Aguilar-Aguilar, Rosas-Valdez and Pérez-Ponce de León, 2010; R. kidderi Pearse, 1930; R. lichtenfelsi Sánchez-Álvarez, García-Prieto et Pérez-Ponce de León, 1998; R. mexicana Caspeta-Mandujano, Moravec et Salgado-Maldonado, 2000; R. ovifilamenta Weller, 1938; R. salgadoi CaspetaMandujano et Moravec, 2000; R. xiphophori CaspetaMandujano, Moravec et Salgado-Maldonado, 2001 (^{Moravec, Salgado-Maldonado et al., 2012}).

Based on the number of prostomal teeth, species of Rhabdochona can be arranged into 7 groups: those possessing 6 teeth or those with 8, 10, 12, 14, 16 and 20-22. The American species of Rhabdochona have been reported to possess 6 (R. cubensis, R. longleyi, R. xiphophori), 10 (R. ahuhuellensis, R. kisutchi, R. lichtenfelsi, R. mexicana), 12 (R. guerreroensis), 14 (R. acuminata, R. canadensis, R. cascadilla, R. cotti, R. decaturensis, R. ictaluri, R. kidderi, R. osorioi, R. rotundicaudatum, R. uruyeni, R. zacconis), and 16 (R. fabianae, R. ovifilamenta, R. salgadoi). In addition, R. adentata has an unusual prostom lacking anterior teeth. The newly described species belongs to the group of species possessing 12 teeth. In the New World, only R. guerreroensis belongs to this group. Although both species are rather similar, they can be differentiated by: 1) the distribution of prostomal teeth (4 dorsal, 4 ventral and 2 lateral on each side vs. 2 dorsal , 2 ventral and 4 lateral on each side, respectively) (Figs. 20, 21); 2) shape of deirids (22, 23); 3) the distal tip of the larger (left) spicule (trifurcated vs. tetrafurcate in R. juliacarabiasae) (Figs. 24, 25); 4) the length of the small spicule (right) (92-140 vs. 72-75, being smaller in the new species; 5) the absence of dorsal barb in the small spicule, which is present in R. guerreroensis (Figs. 26, 27); 6) the absence of area rugosa which is present in R. guerreroensis (Figs. 28-29), and 7) the number of pre and postanal papillae (12-12, 13-13 and 5-8, 7-8, 7-9 vs. 9-9, 10-10 and 6-6, respectively; Figs. 30, 31). In addition, both species differ in the host species (Sycidium multipunctatum [Gobidae] vs. Eugerres mexicanus [Gerreidae]) and the drainage system (Balsas vs. Usumacinta rivers, respectively).

Figures 20-31 Rhabdochona guerreroensis vs. R. juliacarabiasae n. sp. 20) Anterior end of R. guerreroensis, apical view; 21) anterior end of R. juliacarabiasae, apical view; 22) deirid of R. guerreroensis; 23) deirid of R. juliacarabiasae; 24) distal tip of larger spicule of R. guerreroensis; 25) distal tip of larger spicule of R. juliacarabiasae; 26) distal tip of smaller spicule showing dorsal barb of R. guerreroensis; 27) distal tip of smaller spicule showing dorsal barb of R. juliacarabiasae; 28) area rugosa of R. guerreroensis; 29) area rugosa of R. juliacarabiasae; 30) postcloacal papillae of R. guerreroensis; 31) postcloacalpapillae of R. juliacarabiasae.

^{Moravec, Salgado-Maldonado et al. (2012)} reported another species of Rhabdochona, R. kidderi, parasitizing several species of fishes from the Lacantún River, as well as the presence of the fourth-stage larva of R. kidderi in E. mexicanus. However, all fourth-stage larvae of Rhabdochona spp. are rather similar morphologically, which preclude determining the specific identity. Nevertheless, it is possible to assume that the specimens of ^{Moravec, Salgado-Maldonado et al. (2012)}, which share host species and locality with our material, belong to the new species.

Furthermore, R. juliacarabiasae was recovered as sister of the clade form by R. ictaluri and R. kidder (Fig. 32). The genetic divergence between R. juliacarabiasae and it congeners ranged between 11.18-14.89%. These genetic distances with the cox1 gene are equal and sometimes higher than distances recovered from already described and valid species, indicating that R. juliacarabiasae is in fact a new taxon.

Figure 32 Phylogenetic tree inferred using maximum likelihood and Bayesian inference based on cox1 sequences. Above each node bootstrap values/posterior probability values are shown.

Discussion

^{Moravec (1975)} based on a complex of morphological features, mainly number of teeth in the prostom and presence or absence of cervical alae, divided Rhabdochona into 4 subgenera: Rhabdochona, Globochona, Globochonoides, and Sinonema. In this respect, the general morphology of R. juliacarabiasae is typical of the subgenus Rhabdochona (12 prostomal teeth, eggs provided with polar filaments and absence of lateral alae). However, it is important to note that all species recorded in the New World, belong to the nominotypical subgenus Rhabdochona (see ^{Moravec, 1975}, ²⁰¹⁰).

With the exception of R. acuminata, R. canadensis, R. cascadilla, R. kidder, and R. ovifilamenta, all remaining species from Mexico (7 including R. juliacarabiasae) appear to be endemic. This places Mexico as the country with the highest number of endemic species of Rhabdochona in the world.

Mitochondrial molecular markers are currently being used more frequently in helminth parasite research. Mitochondrial genes show higher substitution rates and have been shown that the use of these genes is more informative in molecular phylogenies (^{Blouin, 2002}). In this work, the partial sequence of the subunit 1 gene of cytochrome c oxidase (cox1) was obtained from an organism of R. juliacarabiasae sp. n. Phylogenetic analyzes of the data set included sequences retrieved from GenBank and from organisms collected in this study. The ML and BI analyzes for the partial sequences of the cox1 gene show that R. juliacarabiase sp. n. is part of an independent clade with high nodal support. The fragment size of the cox1 of the new species was 662 bp, and has shown a high level of genetic divergence (11.18 - 14.89%). This result is consistent with those of ^{Santacruz et al. (2019)}, which found high values of genetic divergence comparing Rhabdochona species reported in Mexico (10 - 12%).

Acknowledgments

To Berenit Mendoza Garfias from the Universidad Nacional Autónoma de México and Alejandro de Jesús Medrano Silva, Rosa Cerros Tlatilpa and José Augusto Ramírez Trujillo from the Universidad Autónoma del Estado de Morelos, for the technical assistance with the SEM, photographs and the use of maximum likelihood, and Bayesian programs and molecular biology techniques. This study is a partial result of the project “Evaluación del estado de conservación de los ecosistemas naturales y especies indicadoras de las áreas naturales protegidas de la Selva Lacandona, Chiapas y zonas de influencia”, from Natura y Ecosistemas Mexicanos, A.C., with financing Alianza WWF-Fundación Carlos Slim.

References

Altekar, G., Dwarkadas, S., Huelsenbeck, J. P., & Ronquist, F. (2004). Parallel Metropolis coupled Markov chain Monte Carlo for Bayesian phylogenetic inference. Bioinformatics, 20, 407-415. https://doi.org/10.1093/bioinformatics/btg427 [ Links ]

Blouin, M. S. (2002). Molecular prospecting for cryptic species of nematodes: mitochondrial DNA versus internal transcribed spacer. International Journal for Parasitology, 32, 527-531. https://doi.org/10.1016/s0020-7519(01)00357-5 [ Links ]

Casiraghi, M., Anderson, T. J. C., Bandi, C., Bazzocchi, C., & Genchi, C. (2001). A phylogenetic analysis of filarial nematodes: Comparison with the phylogeny of Wolbachia endosymbionts. Parasitology, 122, 93-103. https://doi.org/10.1017/s0031182000007149 [ Links ]

Caspeta-Mandujano, J. M. (2010). Nemátodos parásitos de peces de agua dulce de México: clave de identificación, descripción y distribución. Mexico City: AGT Editor, S.A. [ Links ]

Caspeta-Mandujano, J. M., Aguilar-Aguilar, R., & Salgado-Maldonado, G. (2002). Rhabdochona guerreroensis n. sp. (Nematoda: Rhabdochonidae) from the intestine of the gobiid Sicydium multipunctatum from freshwaters in Mexico. Journal of Parasitology, 88, 746-749. https://doi.org/10.1645/0022-3395(2002)088[0746:RGNSNR]2.0.CO;2 [ Links ]

Caspeta-Mandujano, J. M., & Moravec, F. (2000). Two new intestinal nematodes of Profundulus labialis (Pisces, Cyprinodontidae) from Mexican freshwater fish. Acta Parasitologica, 45, 285-292. [ Links ]

Caspeta-Mandujano, J. M., Moravec, F., & Salgado-Maldonado, G. (2000). Rhabdochona mexicana sp. n. (Nematoda: Rhabdochonidae) from the intestines of characid fish in Mexico. Folia Parasitologica, 47, 217-215. https://doi. org/10.14411/fp.2000.039 [ Links ]

Caspeta-Mandujano, J. M., Moravec, F., & Salgado-Maldonado, G. (2001). Two new species of rhabdochonids (Nematoda: Rhabdochonidae) from freshwater fish in Mexico, with the description of a new genus. Journal of Parasitology , 87, 139-143. https://doi.org/10.2307/3285190 [ Links ]

Caspeta-Mandujano, J. M., Salinas-Ocampo, J. C., CalixtoRojas, M., Rubio-Godoy, M. y Pinacho-Pinacho, C. D. (2020). Morphological and molecular evidences for a new rhabdochonid species (Nematoda: Rhabdochonidae) parasitizing Profundulus oaxacae (Profundulidae) in the state of Oaxaca, México. Journal of Parasitology , 106, 261-267. https://doi.org/10.1645/19-179 [ Links ]

Castro-Aguirre, J. L., Espinosa-Pérez, H. S., & Schmitter-Soto, J. J. (1999). Ictiofauna estuarinolagunar y vicaria de México. Mexico City: Limusa-Noriega. [ Links ]

Deckert, G. D., & Greenfield, D. W. (1987). A review of the western Atlantic species of the genera Diapterus and Eugerres (Pisces: Gerreidae). Copeia, 1987, 182-194. [ Links ]

Felsenstein, J. (1973). Maximum likelihood and minimum-steps methods for estimating evolutionary trees from data on discrete characters. Systematic Zoology, 22, 240-249. https://doi.org/10.1093/sysbio/22.3.240 [ Links ]

Kozlov, A. M., Darriba, D., Flouri, T., Morel, B., & Stamatakis, A. (2019). RAxML-NG: a fast, scalable, and user-friendly tool for maximum likelihood phylogenetic inference. Bioinformatics, 35, 4453-4455. https://doi.org/10.1093/bioinformatics/btz305 [ Links ]

Kumar, S., Stecher, G., & Tamura, K. (2016). MEGA7. Molecular evolutionary genetics analysis. Version 7.0 for bigger datasets. Molecular Biology Evolution, 33, 1870-1874. https://doi.org/10.1093/molbev/msw054 [ Links ]

Lagunas-Calvo, O., Santacruz, A., Hernández-Mena, D. I., Rivas, G., Pérez-Ponce de León, G., & Aguillar-Aguillar, R. (2019). Taxonomic status of Rhabdochona ictaluri (Nematoda: Rhabdochonidae) based on molecular and morphological evidence. Parasitology Research, 118, 441-452. https://doi.org/10.1007/s00436-018-6189-8 [ Links ]

Miller, R. R., Minckley, W. L., & Norris, S. M. (2006). Freshwater fishes of Mexico. Chicago: The University of Chicago Press. [ Links ]

Moravec, F. (1968). Species of the genus Rhabdochona Railliet 1916 (Nematoda: Rhabdochonidae) from fishes of Czechoslovakia. Folia Parasitologica , 15, 29-40. [ Links ]

Moravec, F. (1972). General characterization of the nematode genus Rhabdochona, with a review of the South American species. Acta Societatis Zoologicae Bohemoslovacae, 36, 29-46. [ Links ]

Moravec, F. (1975). Reconstruction of the nematode genus Rhabdochona Railliet 1916 with a review of the species parasitic in fishes of Europe and Asia. Studie ČSAV No. 8. Prague: Academia. [ Links ]

Moravec, F. (1978). Species of the genus Rhabdochona Railliet, 1916 from fishes of Czechoslovakia. Folia Parasitologica , 15, 29-40. [ Links ]

Moravec, F. (2010). Some aspect of the taxonomy, biology, possible evolution and biogeography of nematodes of the spirurine genus Rhabdochona Railliet, 1916 (Rhabdochonidae, Thelazioidea). Acta Parasitologica , 55, 144-160. https://doi. org/10.2478/s11686-010-0017-3 [ Links ]

Moravec, F., Bilal, S. J., & Abdullah, S. M. (2012). Two species of Rhabdochona (Nematoda: Rhabdochonidae) from the cyprinid fish Luciobarbus kersin (Heckel) in northern Iraq, including R. (Globochona) kurdistanensis sp. n. Folia Parasitologica , 59, 139-147. https://doi.org/10.14411/fp.2012.019 [ Links ]

Moravec, F., Levron, C., & de Buron, I. (2011). Morphology and taxonomy status of two little known species parasitizing North American fishes. Journal of Parasitology , 97, 297-304. https://doi.org/10.1645/GE-2651.1 [ Links ]

Moravec, F., Pachanawam, A., & Kamchoo, K. (2013). Rhabdochona (Rhabdochona) hypsibarbi n. sp. (Nematoda: Rhabdochonidae) from the freshwater cyprinid fish Hypsibarbus wetmorei (Smith) in northern Thailand. Journal of Parasitology , 99, 397-302. https://doi.org/10.1645/12-32.1 [ Links ]

Moravec, F., Říha, M., & Kuchta, R. (2008). Two new nematode species, Paragendria papuanensis sp. n. (Seuratoidea) and Rhabdochona papuanensis sp. n. (Thelazioidea), from freshwater fishes in Papua New Guinea. Folia Parasitologica , 55, 127-135. https://doi.org/10.14411/fp.2008.017 [ Links ]

Moravec, F., Saraiva, A., Abdullah, S. M. A., Bilal, S. J., & Rahemo, Z. I. F. (2009). Two species of Rhabdochona Railliet, 1916 (Nematoda: Rhabdochonidae) parasitising cyprinid fishes in Iraq, with a redescription of R. tigridis Rahemo, 1978 (emend.). Systematic Parasitology, 74, 125-135. https://doi.org/10.1007/s11230-009-9196-4 [ Links ]

Moravec, F., Salgado-Maldonado, G., González-Solís, D., & Caspeta-Mandujano, J. M. (2012). Host-parasite relationships of Rhabdochona kidder Pearse, 1936 (Nematoda: Rhabdochonidae) in fishes of the Lacantún River in the Lacandon rain forest of Chiapas State, southern Mexico, with a key to Mexican species of Rhabdochona Railliet, 1916. Systematic Parasitology , 82, 1-12. https://doi.org/10.1007/s11230-012-9342-2 [ Links ]

Nelson, J. S., Crossman, E. J., Espinosa-Pérez, H., Finley, L. T., Gilbert, C. R., Lea, R. N. (2004). Common and scientific names of fishes from the United States, Canada, and Mexico. 6th Ed. Bethesda: American Fisheries Society, Special publication. [ Links ]

Posada, D. (2008). jModelTest: phylogenetic model averaging. Molecular Biology and Evolution, 25, 1253-1256. https:// doi.org/10.1093/molbev/msn083 [ Links ]

Ronquist, F., & Huelsenbeck, J. P. (2003). MrBayes 3: Bayesian phylogenetic inference under mixed models. Bioinformatics Oxford, England, 19, 1572-1574. https://doi.org/10.1093/bioinformatics/btg180 [ Links ]

Santacruz, A., Ornelas-García, C. P., & Pérez-Ponce de León, G. (2019). Diversity of Rhabdochona mexicana (Nematoda: Rhabdochonidae), a parasite of Astyanax spp. (Characidae) in Mexico and Guatemala, using mitochondrial and nuclear genes, with the description of a new species. Journal of Helminthology, 94, E34. https://doi.org/10.1017/S0022149X19000014 [ Links ]

Stamatakis, A. (2006). RAxML-VI-HPC. Maximum likelihoodbased phylogenetic analyses with thousands of taxa and mixed models. Bioinformatics, 22, 2688-2690. https://doi.org/10.1093/bioinformatics/btl446 [ Links ]

Yang Z., & Rannala, B. (1977). Bayesian phylogenetic inference using DNA sequences: a Markov chain Monte Carlo method. Molecular Biology and Evolution, 14, 717-724. https://doi.org/10.1093/oxfordjournals.molbev.a025811 [ Links ]

http://zoobank.org/urn:lsid:zoobank.org:pub:F34700AE-BC8E-4B0E-AEE1-3FE6C828772F

Received: October 25, 2019; Accepted: August 06, 2020

*Corresponding author: caspeta@uaem.mx (J.M. Caspeta-Mandujano)

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