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Paracapillaria (Ophidiocapillaria) siamensis sp. nov. (Nematoda: Trichuroidea): a new nematode in Naja kaouthia from Thailand

Published online by Cambridge University Press:  04 April 2024

Vachirapong Charoennitiwat
Affiliation:
Department of Helminthology, Faculty of Tropical Medicine, Mahidol University, Bangkok, Thailand
Kittipong Chaisiri
Affiliation:
Department of Helminthology, Faculty of Tropical Medicine, Mahidol University, Bangkok, Thailand
Tapanee Kanjanapruthipong
Affiliation:
Department of Tropical Pathology, Faculty of Tropical Medicine, Mahidol University, Bangkok, Thailand
Sumate Ampawong
Affiliation:
Department of Tropical Pathology, Faculty of Tropical Medicine, Mahidol University, Bangkok, Thailand
Lawan Chanhome
Affiliation:
Snake Farm, Queen Saovabha Memorial Institute, The Thai Red Cross Society, Bangkok, Thailand
Taksa Vasaruchapong
Affiliation:
Snake Farm, Queen Saovabha Memorial Institute, The Thai Red Cross Society, Bangkok, Thailand
Urusa Thaenkham*
Affiliation:
Department of Helminthology, Faculty of Tropical Medicine, Mahidol University, Bangkok, Thailand
Napat Ratnarathorn*
Affiliation:
Animal Systematics & Molecular Ecology Laboratory and Applied Animal Science Laboratory, Department of Biology, Faculty of Science, Mahidol University, Bangkok, Thailand
*
Corresponding author: Urusa Thaenkham; Email: [email protected]; Napat Ratnarathorn; Email: [email protected]
Corresponding author: Urusa Thaenkham; Email: [email protected]; Napat Ratnarathorn; Email: [email protected]

Abstract

A comprehensive investigation, incorporating both morphological and molecular analyses, has unveiled the existence of a hitherto unknown nematode species, Paracapillaria (Ophidiocapillaria) siamensis sp. nov., residing in the intestine of the monocled cobra, Naja kaouthia, in the central region of Thailand. This study integrates morphological characteristics, morphometric examination, scanning electron microscopy and molecular phylogenetic analysis (COI, 18S rRNA and ITS1 genes). The findings place the newly described species within the subgenus Ophidiocapillaria, elucidating its distinctive characteristics, including a frame-like proximal spicule shape, approximate lengths of 19 000 and 22 500 μm with approximate widths of 90 and 130 μm for males and females, 39‒45 stichocytes, elevated lips without protrusion, a dorsal bacillary band stripe with an irregular pattern of bacillary cells and evidence of intestinal infection. These features serve to differentiate it from other species within the same subgenus, notably Paracapillaria (Ophidiocapillaria) najae De, 1998, a species coexisting P. siamensis sp. nov. in the monocled cobra from the same locality. This study addresses the co-infection of the novel species and P. najae within the same snake host, marking the second documented instance of a paracapillariid species in the monocled cobra within the family Elapidae. The genetic characterization supports the formal recognition of P. siamensis sp. nov. as a distinct species, thereby underscoring its taxonomic differentiation within the Capillariidae family. This research identifies and characterizes the new nematode species, contributing valuable insights into the taxonomy of this nematode.

Type
Research Article
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Copyright
Copyright © Mahidol University, 2024. Published by Cambridge University Press

Introduction

The nematode genus Paracapillaria Mendonça, 1963, which belongs to the family Capillariidae Railliet, 1915, has been classified into 3 distinct subgenera: Paracapillaria Mendonça 1963, found in fishes and amphibians; Ophidiocapillaria Moravec, Reference Moravec2001, which inhabits reptiles and Crossicapillaria Moravec, Reference Moravec2001, known to infect avian and mammalian hosts (Moravec, Reference Moravec1986; Moravec and Justine, Reference Moravec and Justine2020). One particular species within Crossicapillaria, Paracapillaria (Crossicapillaria) philippinensis (Chitwood, Velázquez y Salazar, Reference Chitwood, Valesquez and Salazar1968), has garnered the attention of the Centers for Disease Control and Prevention (CDC) due to its potential for zoonotic transmission, signifying its capacity to induce intestinal capillariasis in humans (Chitwood et al., Reference Chitwood, Valesquez and Salazar1968; El-Karaksy et al., Reference El-Karaksy, El-Shabrawi, Mohsen, Kotb, El-Koofy and El-Deeb2004; Saichua et al., Reference Saichua, Nithikathkul and Kaewpitoon2008). While substantial research has been conducted on the medically important worms, the subgenus Ophidiocapillaria, particularly within snakes, remains relatively underexplored from all angles, including its basic information like classification (Moravec, Reference Moravec1986; Moravec and Justine, Reference Moravec and Justine2020).

Until recently, researchers have identified 15 distinct species within Ophidiocapillaria inhabiting various snake host species. These encompass Paracapillaria mimgazzinii, described in the grass snake, Natrix natrix (Skryabin et al., Reference Skryabin, Shikhobalova and Orlov1957); Paracapillaria xochimilcensis, described in the narrow-headed garter snake, Thamnophis rufipunctatus (Skryabin et al., Reference Skryabin, Shikhobalova and Orlov1957); Paracapillaria sonsinoi, described in the green whip snake, Hierophis viridiflavus (Skryabin et al., Reference Skryabin, Shikhobalova and Orlov1957), alongside the viperine water snake, Natrix maura, and the diamondback water snake, Nerodia rhombifera (Moravec, Reference Moravec1986); Paracapillaria heterodontis, described in the eastern hog-nosed snake, Heterodon platirhinos (Pence, Reference Pence1970); Paracapillaria colubra, described in the eastern racer, Coluber constrictor (Pence, Reference Pence1970); Paracapillaria viperae, described in the nose-horned viper, Vipera ammodytes (Biserkov et al., Reference Biserkov, Georgiev and Genov1985); Paracapillaria ptyasi, described in the oriental rat snake, Ptyas mucosa (Wang, Reference Wang1982); and Paracapillaria najae, described in the Indian cobra, Naja naja (De, Reference De1998) and the monocled cobra, Naja koauthia (Charoennitiwat et al., Reference Charoennitiwat, Chaisiri, Ampawong, Laoungbua, Chanhome, Vasaruchapong, Tawan, Thaenkham and Ratnarathorn2023). Throughout most of these investigations, the primary emphasis was on morphological criteria for species identification, with microscopic structure and molecular data receiving comparatively limited attention.

Between 2000 and 2023, authors of this research conducted parasitological surveys in wildlife (Unpublished data), leading to the discovery of 2 distinct paracapillariid species residing within various digestive organs of the monocled cobras, Naja kaouthia, in central regions of Thailand. Additionally, other studies have reported finding eggs from these worms within the aforementioned snake host and location. However, precise identification has posed a considerable challenge, resulting in a taxonomic classification limited to the genus level, denoted as Capillaria sp. (Chaiyabutr and Chanhome, Reference Chaiyabutr and Chanhome2002; Vasaruchapong et al., Reference Vasaruchapong, Laoungbua, Tawan and Chanhome2017). The morphological similarity between these 2 paracapillariid species, without genetic investigation, caused confusion and led to the erroneous assumption in the survey that they were the same species. One of these species, P. najae, located in the cobra's oesophagus, was initially described by De in 1998 and subsequently redescribed by Charoennitiwat et al. (Reference Charoennitiwat, Chaisiri, Ampawong, Laoungbua, Chanhome, Vasaruchapong, Tawan, Thaenkham and Ratnarathorn2023). Conversely, the other species, infesting the cobra's intestine, exhibited discernible variations in both morphology and genetic sequences when compared to the data documented for P. najae, as delineated by Charoennitiwat et al. (Reference Charoennitiwat, Chaisiri, Ampawong, Laoungbua, Chanhome, Vasaruchapong, Tawan, Thaenkham and Ratnarathorn2023). This comprehensive examination ultimately resulted in the formal recognition of these as distinct new species and the revelation of the co-infection of this novel species alongside P. najae in the same snake host species.

This led to the inception of the present study. A substantial number of Paracapillaria samples retrieved from the monocled cobra's intestine underwent detailed molecular phylogenetic analysis and thorough morphological examination. The scrutiny of external morphological characteristics aimed to distinguish the new nematode species within its taxonomic context, aligning with insights derived from genetic data. The exploration of phylogenetic relationships involved the reconstruction utilizing genes, including cytochrome c oxidase subunit 1 (COI), internal transcribed spacer1 (ITS1) and small subunit nuclear ribosomal RNA (18S rRNA). Our findings conclusively validate the presence of the newly described Paracapillaria (Ophidiocapillaria) siamensis sp. nov., reinforcing previous reports of co-infection incidents involving P. najae in the same hosts organisms.

Materials and methods

Specimen preparation

Five carcasses of wild monocled cobras were provided by the Snake Farm at Queen Saovabha Memorial Institute, Thai Red Cross Society in Bangkok, Thailand. These cobras underwent dissection to investigate the presence of parasites in their intestine, following the protocols outlined by Toland and Dehne (Reference Toland and Dehne1960) as well as Terrell and Stacy (Reference Terrell and Stacy2007). Following the dissection, the organs were placed in Petri dishes filled with 0.85% normal saline and were subsequently examined under stereo-microscopes (Olympus, SZ30 and SZ51, Japan). Micro-dissecting needles were employed to observe and isolate the parasites, focusing on the paracapillariid nematodes. These isolated parasites were counted and preserved in 70% ethanol at −20 °C until required. Additionally, 4 specimens were separated and preserved in glutaraldehyde for scanning electron microscopic imaging.

Morphological study

For the morphological studies, 21 male and 21 female intact worm specimens were selected from the preserved 70% ethanol stock and subjected to comprehensive examination. This examination was conducted using an inverted microscope (Zeiss, Primovert, Germany) equipped with a Zeiss Axiocam and ZEN2 blue edition software. The measurements in micrometers (μm) of these morphological characters strictly adhered to the methodologies outlined by Biserkov et al. (Reference Biserkov, Mészáros and Chipev1994), De (Reference De1998) and Charoennitiwat et al. (Reference Charoennitiwat, Chaisiri, Ampawong, Laoungbua, Chanhome, Vasaruchapong, Tawan, Thaenkham and Ratnarathorn2023). Illustrations depicting selected morphological traits of both male and female worms were crafted under a light microscope with a camera lucida (Leitz, Wetzlar, Germany). Out of the total number of specimens, after the morphological investigations, 26 specimens (13 males and 13 females) were initially mounted in glycerine jelly and subsequently double mounted again with permount to establish permanent slides of type specimens. The remainder of the specimens (8 specimens for each sex) were designated for genetic analysis.

Scanning electron microscopy study

For a scanning electron microscope (SEM) analysis, 2 intact male and 2 intact female specimens were carefully selected. Initially, these specimens were immersed in a solution containing 2.5% glutaraldehyde in a 0.1 M sucrose phosphate buffer (SPB) for primary fixation. Subsequently, a secondary fixation step was performed using a 1% osmium tetroxide solution in the same 0.1 M SPB. The specimens were then dehydrated with ethanol and subsequently dried using a critical point drying device (CPD300 auto, Leica, Wetzlar, Germany). A fine coating of material was applied using a coat-sputter (Q150R PLUS, Quorum, East Sussex, England). Finally, these prepared specimens were examined under the SEM (JSM-6610LV, JEOL, Tokyo, Japan). This SEM analysis was conducted at the Department of Tropical Pathology, Faculty of Tropical Medicine, Mahidol University.

The taxonomic classification of the specimen was conducted based on the morphology outlined by Moravec and Justine (Reference Moravec and Justine2020). Morphological comparisons among paracapillariid species in the subgenus Ophidiocapillaria were made using information from various sources, including Teixeira de Freitas and Lent (Reference Teixeira de Freitas and Lent1934), Skryabin et al. (Reference Skryabin, Shikhobalova and Orlov1957), Pence (Reference Pence1970), Wang (Reference Wang1982), Biserkov et al. (Reference Biserkov, Georgiev and Genov1985), Moravec and Gibson (Reference Moravec and Gibson1986), Moravec (Reference Moravec1986), De (Reference De1998) and Charoennitiwat et al. (Reference Charoennitiwat, Chaisiri, Ampawong, Laoungbua, Chanhome, Vasaruchapong, Tawan, Thaenkham and Ratnarathorn2023), with reference examined specimens listed in Table S1.

Molecular study

For DNA extraction, 8 male and 8 female specimens were homogenized and processed using the DNeasy Blood & Tissue Kit (Qiagen, Germany) following the manufacturer's instructions. The extracted genomic DNA was eluted with 30 μL of nuclease-free water and quantified using spectrophotometry.

A partial mitochondrial (mtDNA) COI gene sequence was amplified from the selected samples. This gene locus has been previously demonstrated to be valuable for elucidating genetic diversity within nematode species (Chan et al., Reference Chan, Chaisiri, Morand, Saralamba and Thaenkham2020). Additionally, nuclear genes, 18S rRNA and ITS1, were amplified to support the results of the mtDNA analysis (Tokiwa et al., Reference Tokiwa, Harunari, Tanikawa, Komatsu, Koizumi, Tung, Suzuki, Kadosaka, Takada, Kumagi, Akao and Ohta2012; Eamsobhana et al., Reference Eamsobhana, Lim and Yong2015; Chan et al., Reference Chan, Chaisiri, Morand, Saralamba and Thaenkham2020). The following primers were used: COI_Paracap_F 5′-AGTRTTTGGTCCTTTRGG-3′ and COI_Paracap_R 5′-GAWGCATTAG AAAGAGA-3′ for the COI gene, 1096F 5′-GGTAATTCTGGAGCTAA TAC-3′ and 1916R 5′-TTTACGGTCAGAACTA GGG-3′ for the 18S rRNA gene and ITS1_Paracap_F 5′-TGCA GTGCCACCGTCACATC-3′ and ITS1_Paracap_R 5′-GTCAACCGACACGGATTAGC-3′ for the ITS1 gene. The resulting COI, 18S rRNA and ITS1 amplicon lengths were 288 bp, 800 bp and 521 bp, respectively.

The PCR reactions were conducted using a T100 thermocycler (Bio-Rad, California, the United States of America). The PCR reaction mixture contained a final volume of 30 μL, including 15 μL of 2X i-Taq master mix (Biotechnology, Gyeonggi, South Korea), 10 μM of each primer and 1 ng/μL of DNA. For the COI primers, the thermocycling profile was as follows: an initial denaturation step at 95 °C for 5 min, followed by 30 cycles of 95 °C for 30 s, 52 °C for 1 min and 72 °C for 45 s. The reaction concluded with a final extension step at 72°C for 5 min, as described by Charoennitiwat et al. (Reference Charoennitiwat, Chaisiri, Ampawong, Laoungbua, Chanhome, Vasaruchapong, Tawan, Thaenkham and Ratnarathorn2023). For the ITS1 primers, the thermocycling profile was as follows: an initial denaturation step at 95 °C for 5 min, followed by 30 cycles of 94 °C for 40 s, 60 °C for 1 min and 72 °C for 2 min. The reaction concluded with a final extension step at 72 °C for 5 min. Regarding the 18S rRNA primers, the thermocycling profile consisted of an initial denaturation at 94 °C for 5 min, followed by 5 cycles of 94 °C for 30 s, 45 °C for 30 s and 72 °C for 70 s, and 35 cycles of 94 °C for 30 s, 54 °C for 30 s and 72 °C for 70 s, as described by Holterman et al. (Reference Holterman, van der Wurff, van den Elsen, van Megen, Bongers, Holovachov, Bakker and Helder2006).

For the visualization of the PCR amplicons, a 1% agarose gel stained with SYBR safe (Thermo Fisher Scientific, Waltham, the United States of America) was employed. Following this, the PCR products from the 3 most exemplary sample sequences underwent Barcode Taq sequencing, a method that does not necessitate primer walking (Celemics, Seoul, South Korea). The nucleotide sequences derived from the parasite specimens in this study have been submitted to the NCBI database and allocated the respective accession numbers: OR839870–72 for the COI, OR840538–40 for the 18S rRNA and OR840543–45 for the ITS1.

The partial sequences of the 3 target genes were verified through manual inspection of electropherograms. The complementary strands were compared and adjusted using BioEdit version 7.2.5 (Hall, Reference Hall1999). For the analysis of phylogenetic relationships, a phylogenetic tree was constructed using the obtained sequences and additional sequences from parasites of Capillariidae, Trichuridae and/or Trichinellidae retrieved as outgroups from GenBank. The alignment of the data matrix was performed using ClustalX 2.1 (Hall, Reference Hall1999; Thompson et al., Reference Thompson, Gibson and Higgins2002), and the aligned sequences were visually analysed using BioEdit. The aligned sequences were verified before conducting the phylogenetic analysis using maximum likelihood (ML) in MEGA-X (Chan et al., Reference Chan, Chaisiri, Morand, Saralamba and Thaenkham2020). The best-fit nucleotide substitution model was determined by the Bayesian Information Criterion (BIC), and the analysis was performed with 1000 bootstrap replicates (Tamura et al., Reference Tamura, Stecher, Peterson, Filipski and Kumar2013). A bootstrap value exceeding 70% generally provides strong support (Hillis and Bull, Reference Hillis and Bull1993). The phylogenetic trees were constructed using the ML method, employing the Hasegawa-Kishino-Yano (HKY) model for the ITS1, Kimura 2-parameter (K2) with a gamma distribution for the 18S rRNA and the General Time Reversible (GTR) model with a gamma distribution for the COI.

Results

Taxonomy

Phylum: Nematoda Diesing, 1861
Class: Enoplea Inglis, 1983
Order: Trichocephalida Hall, 1916
Family: Capillariidae Railliet, 1915
Genus: Paracapillaria Mendonça, 1963
Subgenus: Ophidiocapillaria Moravec, Reference Moravec2001
Species: Paracapillaria (Ophidiocapillaria) siamensis sp. nov. Charoennitiwat et al., Reference Charoennitiwat, Chaisiri, Ampawong, Laoungbua, Chanhome, Vasaruchapong, Tawan, Thaenkham and Ratnarathorn2023 (Table 1, Figs 1 and 2)
Type-host: Naja kaouthia Lesson, 1831.
Type-locality: Bangkok's suburbs (e.g. Don Mueang district, Prawet district, etc.) in Thailand. Coordinates were not recorded.
Collection date: November 10, 2020, to July 18, 2023.
Site of infection: Small intestine
Parasite intensity: 16–82 (on average 47) nematodes in the five-host examined
ZooBank LSID: 7072F98E-09EC-4D3C-BC10-B86D654A7C60
Etymology: The specific epithet ‘siamensis’ indicates that the nematode species is found in Thailand or belongs to Thailand. ‘Siam’ is an original and informal name for ‘Thailand,’ and the suffix ‘-ensis’ in Latin is commonly used to create adjectives that signify ‘of’ or ‘belonging to’ specific places or localities.

General description

Small-to-medium sized, thin and filiform nematodes. Elevated oral opening surrounded by distinct papillae (Figs 2AB). Head narrow and rounded (Figs 1A, 2AB). Body long and slender with smooth transversely striated cuticles (Figs 2CE). Males shorter and thinner than gravid females. A bacillary band with irregular arrangement of button-like bacillary cells present dorsally, extending between 1/10 of body length and cloaca (Figs 2DE). Oesophagus with sinuous muscular part followed by stichosome; stichosome consisting of single row of 39‒45 stichocytes; anterior stichocytes short; middle and posterior stichocytes long and subannulated with large nuclei (Figs 1A, 1D). Stichocytes contain prominent nucleolus with distinct corpuscles (Fig. 1D). Nerve ring encircling muscular oesophagus 2/10 of its length. Two large cells present at oesophago-intestinal junction (Fig. 1E).

Figure 1. Paracapillaria (Ophidiocapillaria) siamensis sp. nov.: (A) anterior end of male, lateral view; (B) posterior end of female, lateral view; (C) fully developed egg; (D) stichosome region of male; (E) oesophago-intestinal junction of female, lateral view; (F) posterior end of male, enlarged latero-ventral view; (G) posterior end of male, latero-ventral view; (H) posterior end of male, lateral view; (I) proximal part of spicule; (J) spicular sheath; and (K) distal part of spicule. (IN, intestine; MO, muscular oesophagus; NR, nerve ring; RE, rectum; SP, spicule; SS, spicular sheath; ST, stichosome; VU, vulva)

Figure 2. Scanning electron micrograph of Paracapillaria (Ophidiocapillaria) siamensis sp. nov.: (A) lateral view and (B) apical view of head region of male, elevated oral lip (white arrow) surrounded by papillae (black arrows); (C) lateral view of middle body with transverse striations; (D) dorsal view of middle body with a bacillary band and (E) button-like bacillary cells (black arrow); (F) lateral view of posterior end of male with two post-cloacal papillae (white arrows); (G) spicular sheath without spines.

Table 1. The comparison between Paracapillaria (Ophidiocapillaria) siamensis sp. nov. and Paracapillaria (Ophidiocapillaria) najae

The micrometre (μm) is a unit of measurement.

Male (holotype, 12 paratypes and 8 type specimens): Body length 7150–18 098; maximum width 53–86. Whole oesophagus, 3805–9452 long; muscular oesophagus and stichosome, 160–395 and 3570–9081, respectively. Anterior: posterior body ratio (the distance from the head to the beginning of intestine: the distance from the beginning of intestine to the tip of the tail), 1:0.30–1:2.04. Tail 12–23 long. Spicule 749–1815 long (5–16% of body length) and slender (Figs 1FH, 1K); proximal end of spicule frame-like form (Fig. 1I). Spicular sheath non-spinous (Figs 1J, 2G). Posterior end of body broad and with 2 membranous lateral rays (Figs 1F, 2F). Two post-cloacal papillae present (Fig. 1F).

Gravid female (allotype, 12 paratypes and 8 type specimens): body length 11 816–25 160; maximum width 54–112. Whole oesophagus 5914–10 241 long; muscular oesophagus and stichosome 171–357 and 5689–10 070, respectively. Anterior: posterior body ratio, 1:0.82–1:1.64. Tail, 13–23 long (Fig. 1B). Vulva with no elevated lips (Figs 1E) situated at 31–93 from oesophagus end; vagina directed posteriorly from vulva and uterus containing 27–199 eggs. Eggs elongate with slightly protruding polar plugs (Figs 1C, 1E) and uncleaved content, 57–70 long and 25–34 wide; egg wall thick with 2 layers: an inner hyaline layer and a thicker outer layer with fine longitudinal sculpture (Fig. 1C).

Type materials

Holotype: mature male was deposited at the Mahidol University Museum of Natural History (Voucher no.: MUMNH-NEM0001; specimen code: SN62PMI05) was collected by Vachirapong Charoennitiwat and his team, on July 18, 2023, in the small intestine of a monocled cobra, Naja kaouthia (IDs: SN062 for this project; AAS089 [EL-Nk-025] for the Applied Animal Science laboratory's catalogue), at the Department of Helminthology, Faculty of Tropical Medicine, Mahidol University.

Description of holotype: body length 13 069; maximum width 66. Whole oesophagus, 7318 long; muscular oesophagus and stichosome, 305 and 7013, respectively. Stichosome with a single row of 40 stichocytes. Anterior: posterior body ratio, 1: 0.79. Tail 14 long. Spicule 1402 long (9.32% of body length) and slender; proximal end of spicule frame-like shape. Spicular sheath non-spinous. Posterior end of body broad and with two membranous lateral rays. Two post-cloacal papillae present.

Allotype: gravid female was deposited at the Mahidol University Museum of Natural History (Voucher no.: MUMNH-NEM0002; specimen code: SN62PFI07) was collected by Vachirapong Charoennitiwat and his team, on July 18, 2023, in the small intestine of a monocled cobra, Naja kaouthia (IDs: SN062 for this project; AAS089 [EL-Nk-025] for the Applied Animal Science laboratory's catalogue), at the Department of Helminthology, Faculty of Tropical Medicine, Mahidol University.

Description of allotype: body length 19 720; maximum width 102. Whole oesophagus 7986 long; muscular oesophagus and stichosome 327 and 7630, respectively. Stichosome with a single row of 41 stichocytes. Anterior: posterior body ratio, 1:1.47. Tail 23 long. Vulva with no elevated lips situated at 71 from oesophagus end; vagina directed posteriorly from vulva and uterus containing 135 eggs. Eggs elongate with slightly protruding polar plugs and uncleaved content, 60 long and 30 wide; egg wall thick with 2 layers: an inner hyaline layer and a thicker outer layer with fine longitudinal sculpture.

Paratypes (1–24): a total of 12 males were deposited at the Mahidol University Museum of Natural History (Voucher no.: MUMNH-NEM0003‒NEM0014; specimen code: SN18PMI01‒PMI03; SN59PMI01‒PMI03; SN62PMI01, PMI03, PMI04, PMI06, PMI07 and PMI09, respectively). A total of 12 gravid females, at the Mahidol University Museum of Natural History (Voucher no.: MUMNH-NEM0015‒0026; specimen code: S18PFI01‒PFI03; SN59PFI01‒PFI03; SN62PFI02, PFI03, PFI05, PFI06, PFI08 and PFI09, respectively).

These paratype specimens were relatively collected from the small intestine of monocled cobras (Snake IDs: SN018, SN059 and SN062 for this project; or AAS022 [EL-Nk-016], AAS089 [EL-Nk-025] and AAS069 [EL-Nk-022] for the Applied Animal Science laboratory's catalogue) by Vachirapong Charoennitiwat and his team, on September 30, 2021; November 10, 2022; and July 18, 2023, respectively. All cobra hosts were obtained in Bangkok, Thailand, but the precise collecting coordinates were not recorded. The general description includes comprehensive morphological descriptions of these paratypes.

Diagnosis

As specified (see Table S1), Paracapillaria (Ophidiocapillaria) siamensis sp. nov. can be distinguished from other Paracapillaria species by diagnostic characteristics: body length 7150‒18 098 in males and 11 816‒25 160 in females. Maximum width 53‒86 in males and 54‒112 in females. Stichosome with a single row of 39‒45 stichocytes. Specifically, this nematode species was found in the snake intestine, frequently in the small intestine. Anterior: posterior body ratio in males, usually 1:<1 with average 1:0.9. The number of eggs in uterus is usually <199 with average 99. The eggs arrange in 1‒2 rows in uterus. Proximal end of spicule of male frame-like shape (Fig. 1I); spicule length 749‒1815. The cephalic region displayed elevated lips without protrusion (Figs 2AB). The body's midsection featured transverse striations on the ventral side (Fig. 2C). A dorsal stripe of bacillary band extending from the nearly beginning of the body to the cloaca (Figs 2DE). This bacillary band consists of irregular pattern of bacillary cells (Fig. 2D). P. siamensis sp. nov. primarily infected the small intestine of the snake host.

Specific diagnosis

Among these Ophidiocapillaria, the newly described Thai species, Paracapillaria siamensis sp. nov. can be distinctly differentiated from Italian Paracapillaria mingazzinii (Rizzo, 1902), American Paracapillaria colubra (Pence, Reference Pence1970), Paracapillaria heterodontis (Harwood, 1932), Bulgarian Paracapillaria viperae Biserkov et al., Reference Biserkov, Georgiev and Genov1985, Mexican Paracapillaria xochimilcensis (Caballero & Cercero, 1943), Brazilian Paracapillaria murinae (Travassos, 1914) and Portuguese Paracapillaria cesarpintoi (Freitas & Lent, 1934) due to differences in vulva lip characteristics. P. siamensis sp. nov. is characterized by the absence of elevated vulva lips, distinguishing it from the mentioned species. Furthermore, P. siamensis sp. nov. differs from these species in several measured characteristics, including longer spicule length (in P. colubra, P. heterodontis, and P. viperae), shorter spicule length (in P. cesarpintoi), a larger distance between the vulva opening and the end of the oesophagus (in P. colubra and P. heterodontis), and a shorter distance between the vulva opening and the end of the oesophagus (in P. cesarpintoi). Importantly, P. siamensis sp. nov. was recorded in Thailand, Asia, while all the other species were discovered on different continents.

In addition, P. colubra, P. heterodontis and P. murinae were found in the oviduct, rectum and stomach of snakes, unlike P. siamensis sp. nov., which specifically inhabits the small intestine. Based on Moravec (Reference Moravec1986), P. siamensis sp. nov. does not exhibit the same levels of characteristic variation as Paracapillaria sonsinoi (Parona, 1897), which includes body length of both genders, spicule length, the ratio of the anterior and posterior ends, egg length and importantly, its recorded locality in Europe and America.

Among Oriental Ophidiocapillaria, Taiwanese Paracapillaria kuntzi (Moravec and Gibson, Reference Moravec and Gibson1986) displays smaller maximum width in both males and females (♂ 53‒86 vs 95‒150 and ♀ 54‒112 vs 122‒204) and a shorter distance between the nerve-ring and the tip of the head (♂ 23‒69 vs 75‒105 and ♀ 40‒69 vs 78‒96), compared to P. siamensis sp. nov. In contrast, Indian Paracapillaria longispicula (Sonsino, 1889) shows significantly larger body length (♂ 40 000 vs 7150‒18 098 and ♀ 50 000‒60 000 vs 11 816‒25 160), longer spicule length: (2000‒3820 vs 749‒1815), and a greater distance between the vulva opening and the end of the oesophagus (140 vs 31‒93), compared to P. siamensis sp. nov.

The Chinese Paracapillaria ptyasi (Wang, Reference Wang1982) has different key characteristic compared to P. siamensis sp. nov: anterior spicule shape (round vs frame-like), the number of stichocytes (32‒34 vs 39‒45), the position of nerve-ring from the anterior end (40‒69 vs 80‒90), a shorter range of female body length (10 200‒11 900 vs 11 816‒25 160) and anterior part length (5000‒5200 vs 5914‒10 241). Within the same locality (centre Thailand) and snake host species (the monocled cobra, Naja kaouthia) – co-infection, Paracapillaria najae De, Reference De1998, differs from P. siamensis sp. nov. in several aspects: anterior spicule shape (spatula-like vs frame-like), infected organ (oesophagus vs small intestine), the ratio of posterior and anterior ends in both males and females (♂ 1.2–2.5 ave. 1.8 vs 0.3–2.0 ave. 0.9 and ♀ 1.4–3.0 ave. 2.1 vs 0.8–1.6 ave. 1.33), spicule length (1437–2715 ave. 2032 vs 749–1815 ave. 1381), a bacillary band covered dorsolaterally vs dorsally and other minor characters, with the measurements of P. najae typically being larger than those of P. siamensis sp. nov. (see Table 1).

Variation

The number of P. siamensis sp. nov. individuals, ranging from ~16 to 82 worms, displays significant morphological variation among the cobra specimens (see Table S2). Key characters that vary among the cobras include relative-to-body size and oesophagus characteristics of both male and female worms, encompassing body length and width, oesophagus lengths and other distance characters. Notably, cobra ID: SN013 exhibited relatively small parasites (average 7946.35, n = 4), whereas other cobra samples displayed nearly double the size in body length (14 171.67–15 788.92, n = 3–7). The spicule length stands out as another example of character with high variation; the worms in cobra ID: SN059 had an average spicule length of 2480.26 (n = 3), surpassing those in cobra IDs: SN018 and SN013, which measured 1265.00 (n = 3) and 969.60 (n = 4), respectively. This trend is also observable in other morphological characteristics. Despite the pronounced morphological diversity among P. siamensis sp. nov. individuals, specimens subjected to genetic analysis revealed minimal sequence differences (Fig. 2).

Sexual dimorphism, reflected in traits such as larger size in females (average 19 630.29 vs 13 672.54 in males), distinct vulva lips in females (Fig. 1E) and specific features of the spicular sheath in males (Figs 1G–H and J), is observed in this novel species (Table S2).

Genetic characterization and phylogenetic position

The molecular characterization of the newly identified species, P. siamensis sp. nov., involved the amplification and sequencing of the nuclear 18S rDNA and ITS1 genes, as well as the mitochondrial COI gene. The outcomes of the phylogenetic analysis clearly indicated that P. siamensis sp. nov. is a distinct species within the taxonomic classification of Capillariidae. The species available for comparison included Baruscapillaria sp., Pseudacapillaria sp., Pearsonema sp., Aonchotheca sp., Capillaria spp., Eucoleus spp., Paratrichosoma sp. and other Paracapillaria sp. Specifically, the COI strongly suggested that P. siamensis sp. nov. forms a sister clade with P. najae (Fig. 3A), even though the 2 species infect the same snake host species. This illustrates the co-infection between both paracapillariid species. Both nuclear 18S rRNA and ITS1 also supported the differentiation of P. siamensis sp. Nov. from P. najae and other capillariid sequences available in GenBank, similar to the mtDNA result (Figs 3B–C). The genetic variation between P. siamensis sp. Nov. and other capillariids ranged from 14 to 25% for the COI, 2–14% for the 18S and 41–63% for the ITS1. The closest genetic distances were observed between P. siamensis sp. nov. and members of P. najae, with 14% for the COI, 2% for the 18S rRNA and 41% for the ITS1.

Figure 3. Phylogenetic analysis of capillariids based on different genetic markers: (A) COI gene, (B) 18S rRNA and (C) ITS1. The analyses were conducted using MEGAX with the maximum likelihood method. Branch length scale bars indicate the number of substitutions per site. Coloured lines/fonts represent genetic data from various capillariid genera sourced from GenBank, with the red line/font specifically highlighting the genus Paracapillaria. The blue box indicates the specimens of Paracapillaria siamensis sp. nov. used in the present study. Synonym remarks include Capillaria hepatica = Calodium hepaticum, Capillaria gastrica = Eucoleus gastricus, Capillaria putorii = Aonchotheca putorii, Capillaria plica = Pearsonema plica, and Capillaria suis = Aonchotheca suis.

Natural history

Paracapillaria siamensis sp. nov., appears to be a prevalent parasite in the monocled cobra, given its discovery in all 5 snake samples examined. This species, exclusively found in the small intestine of the cobras, has been documented to co-occur with P. najae, which predominantly resides in the oesophagus. This co-occurrence was observed consistently across all snake samples examined in the study. As a common behaviour, the worms tend to aggregate through ball-coiling within the intestinal mucus, extending throughout the entire intestinal tract and occasionally reaching into the proximal large intestine area. Importantly, visual inspection revealed no discernible lesions on the target organ.

Although the precise geographic coordinates of the sample collection sites were not recorded, the cobras were captured in suburban areas surrounding Bangkok, directly linked to their prey choices. Within the gut contents, a conspicuous presence of small conical structures resembling the teeth of lizards or rodent claws was observed under the stereomicroscope. This observation raises the possibility of intermediate hosts for the new paracapillariid species within the ecosystem.

Discussion

Paracapillaria siamensis sp. nov., as per Moravec and Justine (Reference Moravec and Justine2020), belongs to the subgenus Ophidiocapillaria, as it resides in the snake species, the monocled cobra, Naja kaouthia, found in Thailand. The key diagnostic morphology of this new species aligns with that of other Paracapillaria spp., including the presence of a bursa supported by lateral lobes and a non-spiny spicular sheath at the male caudal end (e.g. Moravec, Reference Moravec1986; Moravec et al., Reference Moravec, Solís and Vázquez1995; Moravec and Justine, Reference Moravec and Justine2020). Furthermore, the phylogenetic results from both mitochondrial and nuclear genes in this study strongly support the morphological findings, indicating that this new paracapillariid species falls within the capillariid lineage.

The newly discovered Ophidiocapillaria species exhibits distinct morphological differences from other species within the same subgenus, characterized by variations in morphological measurements and proportions. Key features used for classifying this new paracapillariid species include body length, body width, oesophagus length, distance from the nerve ring to the anterior end, stichosome and spicule length, among others (e.g. Moravec, Reference Moravec1986; Moravec and Gibson, Reference Moravec and Gibson1986; Moravec et al., Reference Moravec, Solís and Vázquez1995; De, Reference De1998; Moravec and Justine, Reference Moravec and Justine2020; Sakaguchi et al., Reference Sakaguchi, Yunus, Sugi and Sato2020; Charoennitiwat et al., Reference Charoennitiwat, Chaisiri, Ampawong, Laoungbua, Chanhome, Vasaruchapong, Tawan, Thaenkham and Ratnarathorn2023). Several characteristics, such as the target organ of infection, type of vulva lips, shape of the proximal spicule and locality, can serve as alternatives for species identification (e.g. Moravec, Reference Moravec2001; Timi et al., Reference Timi, Rossin, Lanfranchi and Etchegoin2007; Moravec and Justine, Reference Moravec and Justine2010 and, Reference Moravec and Justine2020; Melnychuk et al., Reference Melnychuk, Yevstafieva, Borodai and Lozhkina2020; Sakaguchi et al., Reference Sakaguchi, Yunus, Sugi and Sato2020; Carvalho et al., Reference Carvalho, Santana, Sindeaux Neto, Silva and Giese2023). Despite the distinctiveness of many species based on those characteristics, a few original papers on Paracapillaria lacked morphological details, resulting in difficulties in the identification of species, particularly Paracapillaria ptyasi found in the southern part of China. This species exhibited minimal morphological differences from P. siamensis sp. nov., except for a few measurements i.e. nerve-ring position, stichocytes numbers, anterior part length, female body length and importantly, the spicule shape, a key factor in Paracapillaria's identification (sensu Moravec and Justine, Reference Moravec and Justine2020; Carvalho et al., Reference Carvalho, Santana, Sindeaux Neto, Silva and Giese2023). The spicule shape was markedly different between these 2 species – round for P. ptyasi and frame-like for P. siamensis sp. nov.

Additional evidence for the differentiation of these 2 worm species lies in the isolation of their hosts and the host distribution (the monocled cobra, Naja kaouthia, vs the Oriental rat snake, Ptyas mucosa). Moreover, there are reports of geographical distribution separation in the rat snake (genus Ptyas) between China and Thailand (Gernot and Sjon, Reference Gernot and Sjon2013). This separation is attributed to the high elevation of the Himalayan Mountain ranges, suggesting that parasites restricted to their hosts might not cross the border. Similar isolation of reptiles is observed in other Colubrid species (Bain and Hurley, Reference Bain and Hurley2011), such as the keelback snake, Rhabdophis subminiatus (Liu et al., Reference Liu, Xie, Wu, Shu, Guo, Guo and Cui2021) and Dendrelaphis sp. (Biakzuala et al., Reference Biakzuala, Lalremsanga, Tariang, Vabeiryureilai, Muansanga, Hrima, Kumar, Kundu, Purkayastha and Vogel2022).

However, species infected within the same snake host, like P. siamensis sp. nov. and P. najae are distinguished by the described morphological measurements and ratios in Table 1, as well as descriptive characteristics such as proximal spicule shape (frame-like for P. siamensis sp. nov. vs spatula-like for P. najae, sensu Charoennitiwat et al., Reference Charoennitiwat, Chaisiri, Ampawong, Laoungbua, Chanhome, Vasaruchapong, Tawan, Thaenkham and Ratnarathorn2023) and the organ of infection (the intestine for P. siamensis sp. nov. vs the oesophagus for P. najae). Nevertheless, these characteristics, which closely resemble each other between the 2 species, pose challenges in species identification when the parasites are isolated from the host body and in low numbers. Therefore, microscopic structure and molecular genetic studies play a crucial role in species identification for paracapillariid worms, given their high morphological variation (Charoennitiwat et al., Reference Charoennitiwat, Chaisiri, Ampawong, Laoungbua, Chanhome, Vasaruchapong, Tawan, Thaenkham and Ratnarathorn2023), potentially leading to species misidentification. The microscopic surface images clearly display variation in the position of the bacillary band between the 2 species. The genetic information derived from the mt COI, as well as the nuclear 18S rDNA and ITS1 (slowly evolving nuclear genes, Mallatt et al., Reference Mallatt, Garey and Shultz2004) markers, provides valuable insights into the identification, confirming the genetic distinctiveness of P. siamensis sp. nov. from P. najae. This emphasizes the importance of genetic data for the species identification of Paracapillaria, although the available data in GenBank on Paracapillaria species is still limited.

Despite the considerable morphological variation observed in P. siamensis sp. nov., the genetic sequence exhibited minimal differences. This suggests that the observed morphological differentiation may arise from other factors, such as environmental influences (e.g. Thompson and Lymbery, Reference Thompson and Lymbery1990; Benesh and Kalbe, Reference Benesh and Kalbe2016). Therefore, considering alternative sources of information, in addition to morphological characteristics, for species identification may be advisable.

The co-infection involving 2 paracapillariid species: P. siamensis sp. nov. and P. najae, within the same snake host, the monocled cobra, is documented for the first time in this study. However, such occurrences are not unique, as evidenced in other parasitic helminth groups (Behnke et al., Reference Behnke, Bajer, Sinski and Wakelin2001), such as Angiostrongylus (Watthanakulpanich et al., Reference Watthanakulpanich, Jakkul, Chanapromma, Ketboonlue, Dekumyoy, Lv, Chan, Thaenkham and Chaisiri2021), Trichinella (Marucci et al., Reference Marucci, Tonanzi, Interisano, Vatta, Galati and La Rosa2022), Taenia (Anantaphruti et al., Reference Anantaphruti, Yamasaki, Nakao, Waikagul, Watthanakulpanich, Nuamtanong, Maipanich, Pubampen, Sanguankiat, Muennoo, Nakaya, Sato, Sako, Okamoto and Ito2007; Devleesschauwer et al., Reference Devleesschauwer, Aryal, Joshi, Rijal, Sherchand, Praet, Speybroeck, Duchateau, Vercruysse and Dorny2012; Shin et al., Reference Shin, Won, Jung, Park, Nam, Kim and Shin2019) and Trichuris (Areekul et al., Reference Areekul, Putaporntip, Pattanawong, Sitthicharoenchai and Jongwutiwes2010). P. siamensis sp. nov. and P. najae exhibit parasitism in different organs of the same host, potentially mitigating competition between the 2 species (Stancampiano et al., Reference Stancampiano, Mughini-Gras and Poglayen2010; Venter et al., Reference Venter, Matthews and Silvester2022; Presswell et al., Reference Presswell, Bennett, Chai and Poulin2023). This phenomenon departs from the norm observed in other parasitic helminth groups, where co-infections occur regularly.

P. siamensis sp. nov., appearing in the adult stage, infects the monocled cobra, a generalist species predominantly found in the central lowland region of Thailand (Cox et al., Reference Cox, Hoover, Chanhome and Thirakhupt2012; Ratnarathorn et al., Reference Ratnarathorn, Harnyuttanakorn, Chanhome, Evans and Day2019 and, Reference Ratnarathorn, Nadolski, Sumontha, Hauser, Suntrarachun, Khunsap, Laoungbua, Radcliffe, Vasaruchapong, Tawan and Chanhome2023). It is plausible that transmission of the parasite species occurs through various prey items consumed by the cobra, such as rodents, chicks, amphibians or other reptiles (Cox et al., Reference Cox, Hoover, Chanhome and Thirakhupt2012; Kalki et al., Reference Kalki, Cherukuri and Adhikari2022). Given the capability of paracapillariid species to infect multiple hosts (Charoennitiwat et al., Reference Charoennitiwat, Chaisiri, Ampawong, Laoungbua, Chanhome, Vasaruchapong, Tawan, Thaenkham and Ratnarathorn2023), a further investigation involving their prey and other generalist snake species, such as rat snakes (Ptyas spp.) and the Siamese spitting cobra (Naja siamensis), which share similar prey preferences with the monocled cobra (Cox et al., Reference Cox, Hoover, Chanhome and Thirakhupt2012), may contribute to a more comprehensive understanding of the natural history aspects, including the life cycle of this newly described species.

In conclusion, both morphological and molecular characterizations provide robust evidence supporting the identification of a new species within the subgenus Ophidiocapillaria. This discovery prompts formally naming of the species Paracapillaria (Ophidiocapillaria) siamensis sp. nov. The distinct characteristics observed in this species set it apart from closely related species within the Ophidiocapillaria subgenus. Additionally, the study unveils a noteworthy aspect of co-infection involving P. siamensis sp. nov. and P. najae in the monocled cobra, Naja kaouthia, collected from the same locality. This marks the first documented evidence of potential host sharing within the Paracapillaria group.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0031182024000404.

Data availability statement

The data that support the findings of this study are available from the first and corresponding authors upon reasonable request.

Acknowledgements

Thank all supporting staffs from the Snake Farm, Queen Saovabha Memorial Institute, the Department of Helminthology, Faculty of Tropical Medicine, the Department of Tropical Pathology, Faculty of Tropical Medicine, and the Department of Biology, Faculty of Science, Mahidol University for facilitating working spaces and convivences.

Author contributions

VC as a principal investigator performed data investigation, formal analyses, data curation and contributed to methodology and visualization and writing the article (original draft). NR and UT contributed to research conceptualization, methodology, data analyses and validation, visualization, writing and editing the article (original draft), and recommendations. KC contributed to methodology, visualization, data analyses and validation. TK and SA contributed to visualization and methodology. LC and TV contributed to specimen preparation and processing, and resources.

Financial support

This project is funded by National Research Council of Thailand (NRCT) and Mahidol University (Contact ID: N42A660912).

Competing interests

None.

Ethical standards

All procedures performed by researchers, snake handlers and veterinarians in handling snakes were approved by the Safety Committee of Queen Saovabha Memorial Institute (Document No. SN001). The authors confirm that the field studies did not involve endangered or protected species. The study was also approved by the Ethics Committee of Queen Saovabha Memorial Institute (Approval Protocol Number: QSMI-ACUC-11-2021).

References

Anantaphruti, MT, Yamasaki, H, Nakao, M, Waikagul, J, Watthanakulpanich, D, Nuamtanong, S, Maipanich, W, Pubampen, S, Sanguankiat, S, Muennoo, C, Nakaya, K, Sato, MO, Sako, Y, Okamoto, M and Ito, A (2007) Sympatric occurrence of Taenia solium, T. saginata, and T. asiatica, Thailand. Emerging Infectious Diseases 13, 14131416.CrossRefGoogle Scholar
Areekul, P, Putaporntip, C, Pattanawong, U, Sitthicharoenchai, P and Jongwutiwes, S (2010) Trichuris vulpis and T. trichiura infections among schoolchildren of a rural community in northwestern Thailand: the possible role of dogs in disease transmission. Asian Biomedicine 4, 4960.CrossRefGoogle Scholar
Bain, R and Hurley, M (2011) A biogeographic synthesis of the amphibians and reptiles of Indochina. Bulletin of the American Museum of Natural History 360, 1138.CrossRefGoogle Scholar
Behnke, JM, Bajer, A, Sinski, E and Wakelin, D (2001) Interactions involving intestinal nematodes of rodents: experimental and field studies. Parasitology 122, S39S49.CrossRefGoogle ScholarPubMed
Benesh, DP and Kalbe, M (2016) Experimental parasite community ecology: intraspecific variation in a large tapeworm affects community assembly. Journal of Animal Ecology 85, 10041013.CrossRefGoogle Scholar
Biakzuala, L, Lalremsanga, HT, Tariang, A, Vabeiryureilai, M, Muansanga, L, Hrima, V, Kumar, V, Kundu, S, Purkayastha, J and Vogel, G (2022). Contributions to the taxonomic status and molecular phylogeny of Asian Bronzeback snakes (Colubridae, Ahaetuliinae, Dendrelaphis Boulenger, 1890), from Mizoram State, Northeast India. Zoosystema 44, 177196.CrossRefGoogle Scholar
Biserkov, VY, Georgiev, BB and Genov, T (1985) Paracapillaria viperae sp. n. (Nematoda, Capillariidae) a parasite of Vipera ammodytes L. in Bulgaria. Comptes Rendus de l'Academie Bulgare des Sciences 38, 251254.Google Scholar
Biserkov, VY, Mészáros, F and Chipev, N (1994) On the validity of the species considered synonyms of Paracapillaria sonsinoi (Parona, 1897) (Nematoda: Capillariidae). Parasitologia Hungarica 27, 5356.Google Scholar
Carvalho, E., Santana, RLS, Sindeaux Neto, JL, Silva, MVOD and Giese, EG (2023) A new nematode of the family Capillariidae identified in Cairina moschata (Linnaeus) on Marajó Island in the Brazilian Amazon. Revista Brasileira de Parasitologia Veterinaria 32, e007523.CrossRefGoogle ScholarPubMed
Chaiyabutr, N and Chanhome, L (2002) Parasites in snakes of Thailand. Bulletin of the Maryland Herpetological Society 38, 3950.Google Scholar
Chan, AHE, Chaisiri, K, Morand, S, Saralamba, N and Thaenkham, U (2020) Evaluation and utility of mitochondrial ribosomal genes for molecular systematics of parasitic nematodes. Parasites and Vectors 13, 113.CrossRefGoogle ScholarPubMed
Charoennitiwat, V, Chaisiri, K, Ampawong, S, Laoungbua, P, Chanhome, L, Vasaruchapong, T, Tawan, T, Thaenkham, U and Ratnarathorn, N (2023) Redescription and new record of Paracapillaria (Ophidiocapillaria) najae (Nematoda: Trichuroidea) in the monocled cobra Naja kaouthia from central Thailand: morphological and molecular insights. Parasitology 150, 901910.CrossRefGoogle ScholarPubMed
Chitwood, MB, Valesquez, C and Salazar, NG (1968) Capillaria philippinensis sp. n. (Nematoda: Trichinellida), from the intestine of man in the Philippines. The Journal of Parasitology 52, 368371.CrossRefGoogle Scholar
Cox, MJ, Hoover, M, Chanhome, L and Thirakhupt, K (2012) The Snakes of Thailand. Bangkok: Chulalongkorn University Museum of Natural History.Google Scholar
De, NC (1998) A new capillariid, Paracapillaria (Ophidiocapillaria) najae n. sp. (Nematoda: Trichuroidea), from an elapid snake in West Bengal, India. Systematic Parasitology 39, 153157.CrossRefGoogle Scholar
Devleesschauwer, B, Aryal, A, Joshi, DD, Rijal, S, Sherchand, JB, Praet, N, Speybroeck, N, Duchateau, L, Vercruysse, J and Dorny, P (2012) Epidemiology of Taenia solium in Nepal: is it influenced by the social characteristics of the population and the presence of Taenia asiatica?. Tropical Medicine and International Health 17, 10191022.CrossRefGoogle ScholarPubMed
Eamsobhana, P, Lim, PE and Yong, HS (2015) Phylogenetics and systematics of Angiostrongylus lungworms and related taxa (Nematoda: Metastrongyloidea) inferred from the nuclear small subunit (SSU) ribosomal DNA sequences. Journal of Helminthology 89, 317325.CrossRefGoogle ScholarPubMed
El-Karaksy, H, El-Shabrawi, M, Mohsen, N, Kotb, M, El-Koofy, N and El-Deeb, N (2004) Capillaria philippinensis: a cause of fatal diarrhea in one of two infected Egyptian sisters. Journal of Tropical Pediatrics 50, 5760.CrossRefGoogle ScholarPubMed
Gernot, V and Sjon, H (2013) Addition of Ptyas nigromarginata (Blyth, 1854) (Squamata: Colubridae) to the snake fauna of Thailand with preliminary remarks on its distribution. Asian Herpetological Research 4, 166181.CrossRefGoogle Scholar
Hall, TA (1999) BioEdit: a user-friendly biological sequence alignment editor and analysis program for Window 98/98/NT. Nucleic Acids Symposium Series 41, 9598.Google Scholar
Hillis, DM and Bull, JJ (1993) An empirical test of bootstrapping as a method for assessing confidence in phylogenetic analysis. Systematic Biology 42, 182192.CrossRefGoogle Scholar
Holterman, M, van der Wurff, A, van den Elsen, S, van Megen, H, Bongers, T, Holovachov, O, Bakker, J and Helder, J (2006) Phylum-wide analysis of SSU rDNA reveals deep phylogenetic relationships among nematodes and accelerated evolution toward crown clades. Molecular Biology and Evolution 23, 17921800.CrossRefGoogle ScholarPubMed
Kalki, Y, Cherukuri, S and Adhikari, S (2022) Novel prey species in the diet of the Spectacled Cobra (Naja naja). Reptiles and Amphibians 29, 197198.CrossRefGoogle Scholar
Liu, Q, Xie, X, Wu, Y, Shu, G, Guo, K, Guo, P and Cui, L (2021) High genetic divergence but low morphological differences in a keelback snake Rhabdophis subminiatus (Reptilia, Colubridae). Journal of Zoological Systematics and Evolutionary Research 59, 13711381.CrossRefGoogle Scholar
Mallatt, JM, Garey, JR and Shultz, JW (2004) Ecdysozoan phylogeny and Bayesian inference: first use of nearly complete 28S and 18S rRNA gene sequences to classify the arthropods and their kin. Molecular Phylogenetics and Evolution 31, 178191.CrossRefGoogle ScholarPubMed
Marucci, G, Tonanzi, D, Interisano, M, Vatta, P, Galati, F and La Rosa, G (2022) The International Trichinella Reference Centre database. Report on thirty-three years of activity and future perspectives. Food and Waterborne Parasitology 27, e00156.CrossRefGoogle ScholarPubMed
Melnychuk, BB, Yevstafieva, VO, Borodai, YO and Lozhkina, OV (2020) Peculiarities of identifying capillariides parasatizing in poultry. Bulletin of Poltava State Agrarian Academy 2, 156163.Google Scholar
Moravec, F (1986) Review of capillariid nematodes (Capillariinae) parasitic in amphibians and reptiles. Part 3. Genus Paracapillaria. Věstník Československé Společnosti Zoologické 50, 273289.Google Scholar
Moravec, F (2001) Trichinelloid Nematodes Parasitic in Cold-Blooded Vertebrates. Praha, Czech Republic: Academia.Google Scholar
Moravec, F and Gibson, DI (1986) A new capillariid, Paracapillaria kuntzi sp. n. (Nematoda: Trichuridae), from colubrid snakes in Taiwan. Folia Parasitologica 33, 151155.Google Scholar
Moravec, F and Justine, J-L (2010) Some trichinelloid nematodes from marine fishes off New Caledonia, including description of Pseudocapillaria novaecaledoniensis sp. nov. (Capillariidae). Acta Parasitologica 55, 7180.CrossRefGoogle Scholar
Moravec, F and Justine, J-L (2020) Paracapillaria (Paracapillaria) gastrica n. sp. (Nematoda: Capillariidae) from the marine fish Synodus variegatus Lacépède (Synodontidae, Aulopiformes) off New Caledonia. Systematic Parasitology 97, 157163.CrossRefGoogle Scholar
Moravec, F, Solís, DG and Vázquez, JV (1995) Paracapillaria rhamdiae sp. n. (Nematoda: Capillariidae) from Rhamdia guatemalensis (Pisces) in Yucatan, Mexico. Parasite 2, 235238.CrossRefGoogle Scholar
Pence, DB (1970) Capillaria colubra sp. n. from the oviduct of Coluber constrictor priapus. The Journal of Parasitology 56, 261264.CrossRefGoogle Scholar
Presswell, B, Bennett, J, Chai, X and Poulin, R (2023) Physical evidence of direct antagonistic interactions between trematodes in the host gut: the kiss of death?. Parasitology Research 122, 19531957.CrossRefGoogle Scholar
Ratnarathorn, N, Harnyuttanakorn, P, Chanhome, L, Evans, SE and Day, JJ (2019) Geographical differentiation and cryptic diversity in the monocled cobra, Naja kaouthia (Elapidae), from Thailand. Zoologica Scripta 48, 711726.CrossRefGoogle Scholar
Ratnarathorn, N, Nadolski, B, Sumontha, M, Hauser, S, Suntrarachun, S, Khunsap, S, Laoungbua, P, Radcliffe, C, Vasaruchapong, T, Tawan, T, Chanhome, L (2023) An expanded description, natural history, and genetic variation of the recently described cobra species Naja fuxi Shi, et al., 2022. Vertebrate Zoology 73, 257276.CrossRefGoogle Scholar
Saichua, P, Nithikathkul, C and Kaewpitoon, N (2008) Human intestinal capillariasis in Thailand. World Journal of Gastroenterology 14, 506510.CrossRefGoogle ScholarPubMed
Sakaguchi, S, Yunus, M, Sugi, S and Sato, H (2020) Integrated taxonomic approaches to seven species of capillariid nematodes (Nematoda: Trichocephalida: Trichinelloidea) in poultry from Japan and Indonesia, with special reference to their 18S rDNA phylogenetic relationships. Parasitology Research 119, 957972.CrossRefGoogle ScholarPubMed
Shin, JH, Won, EJ, Jung, JS, Park, K-H, Nam, KI, Kim, SH and Shin, JH (2019) A co-infection case report of Taenia saginata in a patient with subclinical clonorchiasis confirmed by the combination of diagnostic tools. BMC Infectious Diseases 19, 115.CrossRefGoogle Scholar
Skryabin, KI, Shikhobalova, NP and Orlov, IV (1957) Principles of Nematology, Trichocephalidae and Capillariidae of Animals and man and the Diseases Caused by Them. Moscow: Akademii Nauk SSSR.Google Scholar
Stancampiano, L, Mughini-Gras, L and Poglayen, G (2010) Spatial niche competition among helminth parasites in horse's large intestine. Veterinary Parasitology 170, 8895.CrossRefGoogle ScholarPubMed
Tamura, K, Stecher, G, Peterson, D, Filipski, A and Kumar, S (2013) MEGA6: molecular evolutionary genetics analysis version 6.0. Molecular Biology and Evolution 30, 27252729.CrossRefGoogle ScholarPubMed
Teixeira de Freitas, JF and Lent, H (1934) Capillaria cesarpintoi n. sp., parasita de Leimadophis poecilogyrus (Wied.). Memórias do Instituto Oswaldo Cruz 28, 263265.CrossRefGoogle Scholar
Terrell, PS and Stacy, AB (2007) Infectious Diseases and Pathology of Reptiles. Boca Raton: CRC Press.Google Scholar
Thompson, RCA and Lymbery, AJ (1990) Intraspecific variation in parasites — what is a strain? Parasitology Today 6, 345348.CrossRefGoogle ScholarPubMed
Thompson, J, Gibson, T and Higgins, D (2002) Multiple sequence alignment using ClustalW and ClustalX. In Current Protocols in Bioinformatics https://doi.org/10.1002/0471250953CrossRefGoogle Scholar
Timi, JT, Rossin, MA, Lanfranchi, AL and Etchegoin, JA (2007) A new species of Paracapillaria (Nematoda: Capillariidae) parasitizing the Brazilian sandperch, Pinguipes brasilianus (Pisces: Pinguipedidae), from Argentina. The Journal of Parasitology 93, 922924.CrossRefGoogle Scholar
Tokiwa, T, Harunari, T, Tanikawa, T, Komatsu, N, Koizumi, N, Tung, KC, Suzuki, J, Kadosaka, T, Takada, N, Kumagi, T, Akao, N and Ohta, N (2012) Phylogenetic relationships of rat lungworm, Angiostrongylus cantonensis, isolated from different geographical regions revealed widespread multiple lineages. Parasitology International 61, 431436.CrossRefGoogle ScholarPubMed
Toland, GF and Dehne, GL (1960) Laboratory observations of the anatomy of the snake. The American Biology Teacher 22, 278285.CrossRefGoogle Scholar
Vasaruchapong, T, Laoungbua, P, Tawan, T and Chanhome, L (2017) The survey of internal parasites of consumed – siamese cobra (Naja kaouthia) in Thailand. Veterinary Parasitology: Regional Studies and Reports 9, 8892.Google ScholarPubMed
Venter, F, Matthews, KR and Silvester, E (2022) Parasite co-infection: an ecological, molecular and experimental perspective. Proceedings: Biological Sciences 289, 20212155.Google ScholarPubMed
Wang, PQ (1982) Studies on nematodes of the family Capillariidae from Fujian. Acta Zootaxonomica Sinica 7, 117126.Google Scholar
Watthanakulpanich, D, Jakkul, W, Chanapromma, C, Ketboonlue, T, Dekumyoy, P, Lv, Z, Chan, AHE, Thaenkham, U and Chaisiri, K (2021) Co-occurrence of Angiostrongylus malaysiensis and Angiostrongylus cantonensis DNA in cerebrospinal fluid: evidence from human eosinophilic meningitis after ingestion of raw snail dish in Thailand. Food and Waterborne Parasitology 24, e00128.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. Paracapillaria (Ophidiocapillaria) siamensis sp. nov.: (A) anterior end of male, lateral view; (B) posterior end of female, lateral view; (C) fully developed egg; (D) stichosome region of male; (E) oesophago-intestinal junction of female, lateral view; (F) posterior end of male, enlarged latero-ventral view; (G) posterior end of male, latero-ventral view; (H) posterior end of male, lateral view; (I) proximal part of spicule; (J) spicular sheath; and (K) distal part of spicule. (IN, intestine; MO, muscular oesophagus; NR, nerve ring; RE, rectum; SP, spicule; SS, spicular sheath; ST, stichosome; VU, vulva)

Figure 1

Figure 2. Scanning electron micrograph of Paracapillaria (Ophidiocapillaria) siamensis sp. nov.: (A) lateral view and (B) apical view of head region of male, elevated oral lip (white arrow) surrounded by papillae (black arrows); (C) lateral view of middle body with transverse striations; (D) dorsal view of middle body with a bacillary band and (E) button-like bacillary cells (black arrow); (F) lateral view of posterior end of male with two post-cloacal papillae (white arrows); (G) spicular sheath without spines.

Figure 2

Table 1. The comparison between Paracapillaria (Ophidiocapillaria) siamensis sp. nov. and Paracapillaria (Ophidiocapillaria) najae

Figure 3

Figure 3. Phylogenetic analysis of capillariids based on different genetic markers: (A) COI gene, (B) 18S rRNA and (C) ITS1. The analyses were conducted using MEGAX with the maximum likelihood method. Branch length scale bars indicate the number of substitutions per site. Coloured lines/fonts represent genetic data from various capillariid genera sourced from GenBank, with the red line/font specifically highlighting the genus Paracapillaria. The blue box indicates the specimens of Paracapillaria siamensis sp. nov. used in the present study. Synonym remarks include Capillaria hepatica = Calodium hepaticum, Capillaria gastrica = Eucoleus gastricus, Capillaria putorii = Aonchotheca putorii, Capillaria plica = Pearsonema plica, and Capillaria suis = Aonchotheca suis.

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