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Taxonomy and systematics of 2 new species of myxozoans (Cnidaria: Myxobolidae) parasitizing the gills of Iheringichthys labrosus (Teleostei: Pimelodidae) from southeastern Brazil

Published online by Cambridge University Press:  22 July 2025

Diego Henrique Mirandola Dias Vieira ,
Maria João Santos Open the ORCID record for Maria João Santos [Opens in a new window] ,
Sónia Rocha Open the ORCID record for Sónia Rocha [Opens in a new window] ,
Luis Filipe Rangel ,
Rodrigo Bravin Narciso  and
Reinaldo José da Silva
Diego Henrique Mirandola Dias Vieira
Affiliation:
Division of Parasitology, São Paulo State University (UNESP), Institute of Biosciences, Botucatu, SP, Brazil
Maria João Santos*
Affiliation:
Department of Biology, Faculty of Sciences, CIIMAR, University of Porto, Porto, Portugal CIIMAR/CIMAR LA, Interdisciplinary Centre of Marine and Environmental Research, Laboratory of Animal Parasitology and Pathology, University of Porto, Matosinhos, Portugal
Sónia Rocha
Affiliation:
Instituto de Investigação e Inovação em Saúde (i3S), University of Porto, Porto, Portugal School of Medicine and Biomedical Sciences (ICBAS), University of Porto, Porto, Portugal
Luis Filipe Rangel
Affiliation:
CIIMAR/CIMAR LA, Interdisciplinary Centre of Marine and Environmental Research, Laboratory of Animal Parasitology and Pathology, University of Porto, Matosinhos, Portugal
Rodrigo Bravin Narciso
Affiliation:
Division of Parasitology, São Paulo State University (UNESP), Institute of Biosciences, Botucatu, SP, Brazil
Reinaldo José da Silva
Affiliation:
Division of Parasitology, São Paulo State University (UNESP), Institute of Biosciences, Botucatu, SP, Brazil
*
Corresponding author: Maria João Santos; Email: mjsantos@fc.up.pt
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Abstract

During a survey of myxozoan infections in fishes from the Pardo River, Paranapanema River basin, São Paulo State, Brazil, 2 new species – Henneguya avareensis n. sp. and Myxobolus iheringichthys n. sp. – were discovered parasitizing the gills of Iheringichthys labrosus, a commercially important pimelodid fish in South America. Species descriptions were based on the morphology of myxospores and partial sequences of the small subunit ribosomal DNA. Phylogenetic analysis revealed host-related clustering, with the new species clustering together with other myxobolids that parasitize Pimelodidae (Siluriformes). Myxobolus iheringichthys n. sp. clustered specifically with Myxobolus cordeiroi, together forming yet another lineage of myxobolids infecting Pimelodidae fishes. Our analysis underscores the importance of monitoring the presence of these parasites in stocks of I. labrosus to assess potential pathologies they may cause. This is the first report of myxozoans parasitizing the gills of this Neotropical catfish.

Keywords

gill infectionmyxozoaPardo Riverphylogenyultrastructure

Information

Type
Research Article
Information
Parasitology , Volume 152 , Issue 10 , September 2025 , pp. 987 - 996
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This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2025. Published by Cambridge University Press.

Introduction

Myxozoans are highly diverse microscopic parasites that belong to the phylum Cnidaria. They are ubiquitous in aquatic environments, and can infect a wide variety of hosts, including vertebrates (usually fishes) and invertebrates (annelids and bryozoans) (Rangel et al., Reference Rangel, Rocha, Castro, Severino, Casal, Azevedo, Cavaleiro and Santos2015). During their complex life cycles, these parasites develop morphologically different stages that range from waterborne-infective spores to highly specialized forms living in host tissues or organ cavities (Adlard et al., Reference Adlard, Miller and Smit2015). The taxonomy of myxozoans is a challenging discipline due to the morphological complexity and diversity of these microscopic parasites. The traditional classification of myxozoans is primarily based on the morphological characteristics of spores, such as presence/absence of valvular processes and organization of polar capsules. However, advances in molecular biology have allowed for a more integrative approach to myxozoan taxonomy, revealing insights into their phylogeny and genetic diversity (Fiala, Reference Fiala2006).

Myxobolus Bütschli, 1882 and Henneguya Thélohan, 1892 are myxozoan genera belonging to the subclass Myxosporea Bütschli, 1881 (Lom and Dyková, Reference Lom and Dyková2006). Currently, approximately 980 Myxobolus spp. and 260 Henneguya spp. are known (Eiras et al., Reference Eiras, Cruz, Saraiva and Adriano2021; Rangel et al., Reference Rangel, Santos and Rocha2023). Both genera are known to cause diseases in fish, negatively impacting aquaculture industry and the health of aquatic ecosystems (Banu and Rathinam, Reference Banu and Rathinam2023). Studies have investigated the genetic diversity, ecology and transmission strategies of these myxosporeans, aiming to develop more effective control and prevention methods (Palenzuela et al., Reference Palenzuela, Redondo and Alvarez-Pellitero2002). The information obtained is crucial for the sustainable management of aquatic resources and for mitigating the impacts of diseases caused by these parasites. Phylogenetic studies support the paraphyletic nature of the Myxobolus clade, which contains not only Myxobolus spp. but also numerous Henneguya spp., as well as species of the genera Thelohanellus, Cardimyxobolus, Hennegoides, Dicauda, Unicauda and Triangula (Liu et al., Reference Liu, Gu and Luo2010, Reference Liu, Lövy, Gu and Fiala2019).

Iheringichthys labrosus (Lütken, 1874) is a freshwater fish species belonging to the family Pimelodidae (order Siluriformes), commonly known as ‘mandi-beiçudo’ or ‘mandi-bicudo’. It is found in rivers of South America, such as the Paraná and Paraguay River basins (Lundberg and Littmann, Reference Lundberg, Littmann, Reis, Kullander and Ferraris2003). It is an important fish for both sport and commercial fishing, being used for human consumption in some riverside communities (Abes et al., Reference Abes, Agostinho, Okada and Gomes2001; Kohn and Fernandes, Reference Kohn and Fernandes2011). Few parasitological studies of I. labrosus have been performed (França et al., Reference França, Isaac, Pavanelli and Takemoto2003; Moreira et al., Reference Moreira, Ito, Takemoto and Pavanelli2005; Kohn and Fernandes, Reference Kohn and Fernandes2011), none of which are related to myxozoan parasites.

During a survey targeting the biodiversity of myxozoans infecting fishes from the Pardo River in São Paulo State (Brazil), 2 new species of these cnidarian parasites were found parasitizing the gills of I. labrosus. In this study, a thorough taxonomic description of the new species is performed including morphological, molecular and phylogenetic data, thus contributing to a better understanding of the biodiversity of myxozoans in South America. It is noteworthy that these 2 species constitute the first records of myxozoans parasitizing this Neotropical catfish.

Materials and methods

Host collection

Specimens of I. labrosus (n = 10, sex undetermined, ranging from 14.1 to 22.4 cm in length, and 210 to 289 g in weight) were captured from the Pardo River (22°57ʹ48.35″ S; 48°47ʹ26.07″ W), in the municipality of Avaré, São Paulo State, Brazil, between 2021 and 2022. Authorization for capture was provided by the Instituto Chico Mendes de Conservação da Biodiversidade (SISBIO #60640-1). Fish were captured using casting nets, euthanized with sodium thiopental (Thiopentax®), measured and weighed, and dissected for the macro- and microscopic examination of internal organs. All procedures adhered to the guidelines set forth by the Ethical Commission for Animal Experimentation at São Paulo State University (UNESP), Institute of Biosciences, Botucatu, Brazil (CEUA/IBB/UNESP no 9415260520).

Myxozoan collection and morphological analysis

Macro- and microscopic examination of fresh host organs focused on the gills, stomach, intestine, heart, liver, kidney, swim bladder and gallbladder, to detect the presence of myxozoans. This assessment was conducted utilizing a Leica S6 D stereomicroscope (Leica Microsystems, Germany) with a 16× ocular lens. Gills infected by myxozoan plasmodia were selectively sampled for both morphological and molecular analyses. Prevalence of infection was determined following the methodology outlined by Bush et al. (Reference Bush, Lafferty, Lotz and Shostak1997).

Fresh gill smears containing myxozoan plasmodia were individually examined under a light microscope (Leica DM1000) for performing morphological analyses. Measurements of fresh myxospores were determined following the guidelines established by Lom and Arthur (Reference Lom and Arthur1989). Thirty myxospores from each myxozoan species were measured using a Leica DMLB 5000 microscope equipped with differential interference contrast optics (Leica Microsystems, Wetzlar, Germany), at a magnification of 1000×. In both cases, morphometric data were collected from the myxospores of a single plasmodium, which followed for molecular analysis. Myxospore measurements are expressed in micrometres, and include average, standard deviation (s.d.) and range within parentheses. Digital images were captured using the Leica LAS V3.8 software applications (Leica Microsystems, Germany).

The procedures used for transmission electron microscopy mainly followed the protocol described by Casal et al. (Reference Casal, Silva, Soares, Oliveira, Santos and Rocha2023). Briefly, small portions of gills containing plasmodia were fixed in 3% glutaraldehyde buffered in 0.2 M sodium cacodylate (pH 7.4) for 20–24 h, and post-fixed in 2% osmium tetroxide in the same buffer for 3–4 h, while being kept at 4 °C. Samples were then dehydrated in a graded series of ethanol, and embedded using ascending mixtures of epoxy resin in oxide propylene, ending in epoxy resin. Semithin sections were stained with methylene blue-Azure II. Ultrathin sections were double contrasted using uranyl acetate and lead citrate, prior to being observed and photographed using a JEOL 100 CXII TEM (JEOL Optical, Tokyo, Japan), operated at 60 kV.

Molecular analysis

Isolated plasmodia were carefully removed from the gills and immediately fixed in absolute ethanol. Authorization for genetic data access was obtained from the Brazilian Ministry of Environment (Sisgen AAE660A). DNA extraction followed the DNeasy® Blood and Tissue kit (animal tissue protocol) (QIAGEN Inc., California, USA) instructions, and the final DNA concentration was quantified using a NanoDrop 2000 spectrophotometer (Thermo Fisher Scientific, Massachusetts, USA) at 260 nm.

For amplifying partial sequences of the small subunit ribosomal DNA (ssrDNA), the primer pairs ERIB1 (5′‐ACCTGGTTGATCCTGCCAG‐3′) (Barta et al., Reference Barta, Martin, Liberator, Dashkevicz, Anderson, Feighner, Elbrecht, Perkins-Barrow, Jenkins, Danforth, Ruff and Profous-Juchelka1997)–ACT1r (5′‐AATTTCACCTCTCGCTGCCA‐3′) (Kent et al., Reference Kent, Khattra, Hedrick and Devlin2000), and Myxgen4F (5′‐GTGCCTTGAATAAATCAGAG‐3′) (Hallett and Diamant, Reference Hallett and Diamant2001)–ERIB10 (5′‐CTTCCGCAGGTTCACCTACGG‐3′) (Barta et al., Reference Barta, Martin, Liberator, Dashkevicz, Anderson, Feighner, Elbrecht, Perkins-Barrow, Jenkins, Danforth, Ruff and Profous-Juchelka1997) were used. Polymerase chain reactions (PCRs) were performed with a final volume of 25 μL, by adding 20–40 ng of DNA, 1 μL of each primer at 10 pmol and 20 µL of ultrapure water to PCR Ready-to-Go beads (Pure TaqTMReady-to-GoTM beads, GE Healthcare, Chicago, USA). When a bead is reconstituted to a final volume of 25 μL, the concentration of each dNTP is 200 μM in 10 mM Tris-HCl (pH 9.0 at room temperature), 50 mM KCl and 1.5 mM MgCl2. Amplifications were conducted on a Bio-Rad MJ Mini Gradient Thermal Cycler (Bio-Rad Laboratories, PA, USA), with cycling parameters comprising an initial denaturation at 95 °C for 3 min, followed by 35 cycles of denaturation at 95 °C for 1 min, annealing at 55 °C for 45 s, extension at 72 °C for 2 min and a final extension at 72 °C for 7 min. PCR products were visualized on a 1% agarose gel stained with GelRed, and compared with a 1 kb Plus DNA Ladder (Invitrogen, Thermo Fisher Scientific, Massachusetts, USA). Positive PCR products were purified with magnetic beads from the Ampure XP kit (Beckman Coulter) following the manufacturer’s protocol and sequenced using the same set of PCR amplification primers. Sequencing reactions were conducted using the BigDye® Terminator v3.1 Cycle Sequencing Kit (Applied Biosystems) and analysed by capillary electrophoresis on the ABI3730xl Genetic Analyzer (Applied Biosystems, Foster City, CA, USA).

The ssrDNA partial sequences obtained for each myxozoan species analysed were assembled using Sequencher v. 5.2.4 (Gene Codes, Ann Arbor, MI, USA), prior to being aligned with their most similar sequences available in the GenBank database, according to the Basic Local Alignment Search Tool (BLAST). The dataset used for performing the phylogenetic analysis included the ssrDNA sequences of species exceeding 80% of genetic similarity to the myxozoans in study. The ssrDNA sequence of Chloromyxum trilineatum (LC417364) and Ortholinea lauquen (MN128729) served as outgroup. Sequences were aligned using the ClustalW algorithm (Larkin et al., Reference Larkin, Blackshields, Brown, Chenna, McGettigan, McWilliam, Valentin, Wallace, Wilm, Lopez, Thompson, Gibson and Higgins2007) with the default settings selected in Geneious 7.1.3 software. The similarity between was compared by similarity matrix in Geneious 7.1.3 software. The Bayesian inference method was performed in MrBayes 3.1.2 (Ronquist and Huelsenbeck, Reference Ronquist and Huelsenbeck2003), with the Markov Chain Monte Carlo tree searches conducted in parallel runs for 5 million generations each. The ‘burn-in’ was set at 25%. PhyML 3.1 (Guindon et al., Reference Guindon, Dufayard, Lefort, Anisimova, Hordijk and Gascuel2010) software was used to perform Maximum Likelihood analysis, with bootstrap confidence calculated with 1000 replications and the GTR + I + G evolutionary model, which was chosen by jModeltest (Posada, Reference Posada2008) as the best model for the analysis. The resulting trees were visualized using Figtree 1.4.2. (Rambaut, Reference Rambaut2012).

Results

Two species belonging to the Myxobolidae family were observed in the gill arch and filaments of I. labrosus, having been morphologically differentiated as belonging to the genera Myxobolus and Henneguya. Comparisons of biological, morphological and molecular data support their description as new species. There was no coinfection. Only one plasmodium containing myxospores of the genus Myxobolus was found, which is the reason why no other morphological analyses of this species were carried out.

Description of Myxobolus iheringichthys n. sp.

Phylum Cnidaria Hatschek, 1888

Subphylum Endocnidozoa Zrzavý and Hypša, 2003

Class Myxozoa Grassé, 1970

Subclass Myxosporea Bütschli, 1881

Order Bivalvulida Shulman, 1959

Family Myxobolidae Thélohan, 1892

Genus Myxobolus Bütschli, 1882

Myxobolus iheringichthys n. sp.

A single plasmodium was observed in the gill arch (Figure 1), whitish, round and measuring about 0.1 mm. Myxospores oval, formed by 2 smooth and symmetric valves united along a prominent suture line. Myxospores measuring 8.9 ± 0.3 (8.2–9.5) μm in length, 5.8 ± 0.3 (5.5–6.4) μm in width and 4.4 ± 0.2 (4.1–4.8) μm in thickness. Two polar capsules located at the anterior end, slightly convergent at the apex, equal in size, pyriform and measuring 4.3 ± 0.3 (3.7–4.6) μm in length and 2.0 ± 0.2 (1.6–2.4) μm in width. Polar tubules with 6–7 turns. Binucleate sporoplasm (Figures 2; 3A).

Figure 1. Plasmodium (P) of Myxobolus iheringichthys n. sp. found parasitizing the gill arch of Iheringichthys labrosus collected from the Pardo River, municipality of Avaré, State of São Paulo, Brazil.

Figure 2. Light micrograph of fresh myxospores of Myxobolus iheringichthys n. sp. found parasitizing the gill arch of Iheringichthys labrosus collected from the Pardo River, municipality of Avaré, State of São Paulo, Brazil.

Figure 3. A-B. Schematic drawing of the myxospores of Myxobolus iheringichthys n. sp. In frontal (A) and side (B) view. (C and D). Schematic drawing of the myxospores of Henneguya avareensis n. sp. In frontal (C) and side (D) view.

Taxonomic summary

Type-host: Iheringichthys labrosus (Lütken, 1874) (Siluriformes, Pimelodidae).

Type-locality: Pardo River (22°57ʹ48.35″ S 48°47ʹ26.07″ W), Paranapanema River basin, municipality of Avaré, São Paulo State, Brazil.

Site of infection: histozoic, gill arch.

Prevalence of infection: 10% (1 infected out of 10 fish examined).

Type-material: A glass slide with myxospores (hapantotype) was deposited in the collection of the Instituto Nacional de Pesquisa da Amazônia (INPA), Brazil (No. INPA-CND 000113). The ssrDNA partial sequence was deposited in GenBank with accession number PV779188.

Etymology: The specific epithet name is derived from the host genus.

Zoobank ID: urn:lsid:zoobank.org:pub:812FDDC2-9BBB-4 FFB-8C19-E778CC7ABF16

Description of Henneguya avareensis n. sp.

Phylum Cnidaria Hatschek, 1888

Subphylum Endocnidozoa Zrzavý and Hypša, 2003

Class Myxozoa Grassé, 1970

Subclass Myxosporea Bütschli, 1881

Order Bivalvulida Shulman, 1959

Family Myxobolidae Thélohan, 1892

Genus Henneguya Thélohan, 1892

Henneguya avareensis n. sp.

Plasmodia located in the gill filaments, whitish, rounded and measuring about 0.1 mm (Figure 4). Myxospore body elongated and convex-shaped, formed by 2 smooth and symmetric valves, each with a caudal appendage extending posteriorly. Myxospores measuring 34.8 ± 1.5 (32.3–36.3) μm in total length, 11.9 ± 0.4 (11.2–12.4) μm in body length, 5.4 ± 0.5 (4.7–6.0) μm in body width and 4.1 ± 0.1 (3.9–4.2) μm in body thickness. Caudal appendages measuring 23.0 ± 1.7 (20.0–25.0) μm in length. Two polar capsules located at the anterior end, equal in size, pyriform and measuring 6.4 ± 0.3 (6.0–6.6) μm in length and 2.1 ± 0.1 (2.0–2.2) μm in width. Polar tubules with 10–12 turns. Binucleate sporoplasm (Figures 3B; 5).

Figure 4. Plasmodia (P) of Henneguya avareensis n. sp. found parasitizing the gill filaments of Iheringichthys labrosus collected in the Pardo River, municipality of Avaré, State of São Paulo, Brazil.

Figure 5. (A and B) light micrographs of fresh myxospores of Henneguya avareensis n. sp. found parasitizing the gill filaments of Iheringichthys labrosus collected in the Pardo River, municipality of Avaré, State of São Paulo, Brazil.

Ultrastructure

Plasmodia mostly comprising mature myxospores and bearing few cytoplasmic organelles. Plasmodial wall smooth (Figure 6A). Wall of the polar capsules formed by 2 layers – an inner electron-lucent layer surrounded by an outer electron-dense layer. Mature myxospores evidencing the 2 smooth valves united along a straight suture line (Figure 6B). Each polar capsule with an isofilar polar tubule located in its matrix, forming 10–12 coils around the inner wall (Figure 6C). Transverse sections of the caudal appendages showing the absence of discernible coating (Figure 6D). Sporoplasm displaying heterogeneous content surrounding a posterior vacuole and 2 nuclei (Figure 6B, D).

Figure 6. (A–D) TEM micrographs of the plasmodia and myxospores of Henneguya avareensis n. sp. Found in the gill filaments of Iheringichthys labrosus. (A) Plasmodial wall (WP) smooth. (B) Transverse section of a myxospore showing the sutures (S) with its thickened valves. (C) Longitudinal cut of a polar capsule. Notice the outer electron-dense layer (OL) and inner electron-lucent layer (IL) forming the wall, and the polar tubules (PT) coiled within. (D) Transverse section of a myxospore showing the posterior vacuole (PV) containing 1 of the nuclei (N). Note the heterogeneous content in the sporoplasm (SP) and sutures (S).

Taxonomic summary

Type-host: Iheringichthys labrosus (Lütken, 1874) (Siluriformes, Pimelodidae).

Type-locality: Rio Pardo (22°57ʹ48.35″ S 48°47ʹ26.07″ W), Paranapanema River basin, municipality of Avaré, São Paulo State, Brazil.

Site of infection: histozoic, gill filaments, intrafilamental type.

Prevalence of infection: 60% (6 infected out of 10 fish examined).

Type-material: A glass slide with myxospores (hapantotype) was deposited in the collection of the Instituto Nacional de Pesquisa da Amazônia (INPA), Brazil (No. INPA-CND 000112). The ssrDNA partial sequence was deposited in GenBank with accession number PV779187.

Etymology: The specific epithet refers to the name of the city where the host was collected (Avaré).

Zoobank ID: urn:lsid:zoobank.org:pub:812FDDC2-9BBB-4FFB-8C19-E778CC7ABF16

Molecular and phylogenetic analysis

One partial ssrDNA sequences of M. iheringichthys n. sp. (2001 bp), and 1 partial ssrDNA sequences of H. avareensis n. sp. (1933 bp) were obtained. The sequences were obtained from the same plasmodia used for the morphometric analysis. When aligned with each other, the partial sequences of M. iheringichthys n. sp. and H. avareensis n. sp. showed only 73.3% similarity and differed in 529 nucleotides.

The species genetically most similar to M. iheringichthys n. sp. was Myxobolus cordeiroi (Adriano et al., Reference Adriano, Arana, Alves, Silva, Ceccarelli, Henrique-Silva and Maia2009), with 95.6% similarity. In turn, the species genetically most similar to H. avareensis n. sp. was Henneguya maculosus (Carriero et al., Reference Carriero, Adriano, Silva, Ceccarelli and Maia2013), with 93.0% similarity.

Our phylogenetic analysis retrieved the new myxozoan species in study and their genetically most similar relatives – represented by Myxobolus and Henneguya spp. – divided into several subclades (Figure 7). Myxobolus iheringichthys n. sp. clusters together with M. cordeiroi – another myxobolid that infects a Pimelodidae host – together forming a subclade sister to Myxobolus spp. that parasitize freshwater Cypriniformes. In turn, H. avareensis n. sp. clusters with H. maculosus and Henneguya pseudoplatystoma (Naldoni et al., Reference Naldoni, Arana, Maia, Ceccarelli, Tavares, Borges, Pozo and Adriano2009) within a subclade of Henneguya spp. that also parasitize the gills of freshwater fish belonging to the family Pimelodidae.

Figure 7. Bayesian inference phylogenetic tree showing the placement of Henneguya avareensis n. sp. and Myxobolus iheringichthys n. sp. In relation to the genetically most similar species of Henneguya/Myxobolus obtained from GenBank. The scale bar is given below the tree. The numbers on the branches indicate posterior probability/bootstrap values. Values below 0.9/70 were suppressed with -.

Remarks

When morphologically compared to M. cordeiroi, M. iheringichthys n. sp. showed differences in almost all analysed characteristics, mainly in the width of the myxospore body (7.1–7.5 μm vs 5.5–6.4 μm) and in the length of the polar capsule (5.2–5.4 μm vs 3.7–4.6 μm). Highest morphological similarity was found with Myxobolus figueirae (Naldoni et al., Reference Naldoni, Maia, Correa, da Silva and Adriano2018) and Myxobolus sciades Azevedo, Casal, Mendonça, Carvalho, Mato and Matos, 2010 (Table 1). However, the myxospores of M. sciades are narrower (4.3 ± 0.2 μm vs 5.8 ± 0.3 μm) and less thick (2.6 ± 0.3 μm vs 4.4 ± 0.2 μm) than those of M. iheringichthys n. sp., while the myxospores of M. figueirae differ in shape, being ovoid instead of round. Additionally, these species differ in host species, with M. figueirae further displaying tropism towards the skin.

Table 1. Morphometric comparison between Myxobolus iheringichthys n. sp. and other Myxobolus spp. described from South American siluriformes

BL: body length; BW: body width; T: thickness; LP: length of polar capsules; WP: width of polar capsules; PTc: number of coils of polar tubules. Measurements are given in μm.

a Largest capsule.

b Smaller capsule.

When morphologically compared to H. maculosus, H. avareensis n. sp. showed differences mainly in the length of the caudal appendages (17.5 ± 1.0 μm vs 23.0 ± 1.7 μm) and in the length of the myxospore body (13.7 ± 0.6 μm vs 11.9 ± 0.4 μm). Two other species, H. pseudoplatystoma and Henneguya quelen (Abrunhosa et al., Reference Abrunhosa, Sindeaux-Neto, Hamoy and Matos2018), presented highest morphological similarity to H. avareensis n. sp. (Table 2). However, the myxospore body of H. quelen is longer (15.6 ± 0.8 μm vs 11.9 ± 0.4 μm) than that of H. avareensis n. sp., while the myxospores of H. pseudoplatystoma are narrower (3.4 ± 0.4 μm vs 5.4 ± 0.5 μm) and display shorter polar capsules (3.3 ± 0.4 μm vs 6.4 ± 0.3 μm).

Table 2. Morphometric comparison between Henneguya avareensis n. sp. and other Henneguya spp. described from South American siluriformes

TL: total length; BL: body length; BW: body width; T: thickness; CA: length of caudal appendages; LP: length of polar capsules; WP: width of polar capsules; PTc: number of coils of polar tubules. Measurements are given in μm.

a Largest capsule.

b Smaller capsule.

None of the other myxobolid species used for comparison exhibited morphological or morphometric characteristics resembling the new species being described here. They differed in at least 1 morphometric aspect, such as the number of turns of the polar tubules (varying by at least 3 turns), or in their partial genetic sequences.

Discussion

For many years, the taxonomic classification of myxozoans was based solely on morphological and morphometric characteristics of the plasmodia and myxospores. Since the 1990s, molecular tools have been implemented, aiding the correct identification of myxozoans species, with a great number of species described since then (Negrelli et al., Reference Negrelli, Vieira, Tagliavini, Abdallah and de Azevedo2019; Úngari et al., Reference Úngari, Vieira, da Silva, Santos, de Azevedo and O’Dwyer2019; Vieira et al., Reference Vieira, Rangel, Tagliavini, Abdallah, Santos and de Azevedo2020). Increasing amounts of sequence data have confirmed the paraphyletic nature of the genus Myxobolus, with several Henneguya species clustering within the Myxobolus clade (Xiao and Desser, Reference Xiao and Desser2000; Fiala, Reference Fiala2006; Liu et al., Reference Liu, Gu and Luo2010; Vieira et al., Reference Vieira, Pelegrini, Abdallah and de Azevedo2019), as observed in this study. Eszterbauer (Reference Eszterbauer2004) found that a preference for a specific developmental site, rather than spore morphology, is a significant criterion for determining phylogenetic relationships between Myxobolus species. The phylogenetic analysis performed in this study agrees with previous cladograms, through supporting host (order or family level) and tissue tropism as robust phylogenetic signals for clustering Myxobolidae species (Carriero et al., Reference Carriero, Adriano, Silva, Ceccarelli and Maia2013; Capodifoglio et al., Reference Capodifoglio, Adriano, Milanin, Silva and Maia2016; Vieira et al., Reference Vieira, Pelegrini, Abdallah and de Azevedo2019, Reference Vieira, Rangel, Tagliavini, Abdallah, Santos and de Azevedo2021). Henneguya avareensis n. sp. clusters within a subclade that is exclusively composed by species that parasitize siluriforms of the family Pimelodidae, being an integral part of a large clade formed by myxozoan parasites of Siluriformes. In turn, M. iheringichthys n. sp. is included in a subclade formed by M. cordeiroi – a species that parasitizes multiple organs of Zungaro jahu (Ihering, 1898) (Siluriformes: Pimelodidae) – and myxobolids that parasitize Cypriniformes. Myxobolus cordeiroi was the first species of Myxobolus described in Brazil using molecular and phylogenetic analysis (Adriano et al., Reference Adriano, Arana, Alves, Silva, Ceccarelli, Henrique-Silva and Maia2009). The phylogenetic analysis of the species description already includes species that parasitize Cypriniformes, which shows a possible co-relationship between these orders of hosts and their myxozoan parasites (Adriano et al., Reference Adriano, Arana, Alves, Silva, Ceccarelli, Henrique-Silva and Maia2009). Myxobolus cordeiroi appears in an isolated subclade and may reflect the existence of a lineage of myxozoans parasites of fish from South America or a lineage of Myxobolus parasites of Pimelodidae. In this study, M. iheringichthys n. sp. appears as a sister species of M. cordeiroi.

The specific localization of plasmodia in the hosts tissues is a significant taxonomic trait for distinguishing among histozoic myxozoan species (Molnár, Reference Molnár2002). Regrettably, due to the limited number of infected hosts analysed in this study, molecular identifications took precedence over histological preparations. Subsequent research should focus on identifying the specific tissue within the gills serving as the site of infection for the new species.

In the current study, 2 new species of myxozoans were described based on morphometric characteristics, supported by molecular and phylogenetic analyses. The evidence collected conclusively confirmed the existence of 2 new species, identified as Henneguya avareensis n. sp. and Myxobolus iheringichthys n. sp., infecting the gills of I. labrosus. Thus, we advocate for ongoing surveillance of these parasites in farmed stocks of I. labrosus to assess potential pathogenic effects they might induce.

Author contribution

DHMDV conceived and designed the study, did molecular analysis and wrote the article. RBN collaborated in the collection of the material and made the schematic draw of the new species. MJS, SR and LFR did the ultrastructure analysis and reviewed the article. RJS supervised and obtained funding for the project.

Financial support

This research was supported by Fundação de Amparo à Pesquisa do Estado de São Paulo – FAPESP (D. H. M. D. V., R. B. N. and R. J. S, grant numbers 2019/19060-0, 2022/06703-2, 2020/05412-9 and 2019/26831-2), and by Portuguese national funds through FCT – Foundation for Science and Technology within the scope of UIDB/04423/2020 and UIDP/04423/2020.

Competing interests

The authors declare there are no conflicts of interest.

Ethical standards

The study followed all necessary ethical standards. Authorization for capture was provided by the Instituto Chico Mendes de Conservação da Biodiversidade (SISBIO #60640-1). All procedures adhered to the guidelines set forth by the Ethical Commission for Animal Experimentation at São Paulo State University (UNESP), Institute of Biosciences, Botucatu, Brazil (CEUA/IBB/UNESP No. 9415260520).

References

Abdallah, VD, de Azevedo, RK, Luque, JL and Do Bomfim, TC (2007) Two new species of Henneguya Thélohan, 1892 (Myxozoa, Myxobolidae), parasitic on the gills of Hoplosternum littorale (Callichthyidae) and Cyphocharax Gilbert (Curimatidae) from the Guandu River, State of Rio de Janeiro, Brazil. Parasitología Latinoamericana 62, 3541.CrossRefGoogle Scholar
Abes, SDS, Agostinho, AA, Okada, E and Gomes, LC (2001) Diet of Iheringichthys labrosus (Pimelodidae, Siluriformes) in the Itaipu Reservoir, Paraná River, Brazil-Paraguay. Brazilian Archives of Biology and Technology 44, 101105.CrossRefGoogle Scholar
Abrunhosa, J, Sindeaux-Neto, JL, Hamoy, I and Matos, ER (2018) A new species of Myxosporea, Henneguya quelen, from silver catfish Rhamdia quelen (Siluriforme: Pimelodidae) in the Amazonian region. Parasitology Research 117, 38093820.CrossRefGoogle ScholarPubMed
Abrunhosa, J, Sindeaux-Neto, JL, Santos, ÂKD, Hamoy, I and Matos, E (2017) Myxobolus marajoensis sp. n. (Myxosporea: Myxobolidae), parasite of the freshwater catfish Rhamdia quelen from the Brazilian Amazon region. Revista Brasileira de Parasitologia Veterinária 26, 465471.CrossRefGoogle Scholar
Adlard, RD, Miller, TL and Smit, NJ (2015) The butterfly effect: Parasite diversity, environment, and emerging disease in aquatic wildlife. Trends in Parasitology 31, 160166.CrossRefGoogle ScholarPubMed
Adriano, EA, Arana, S, Alves, AL, Silva, MRMD, Ceccarelli, PS, Henrique-Silva, F and Maia, AAM (2009) Myxobolus cordeiroi n. sp., a parasite of Zungaro jahu (Siluriformes: Pimelodiade) from Brazilian Pantanal: Morphology, phylogeny and histopathology. Veterinary Parasitology 162, 221229.CrossRefGoogle Scholar
Adriano, EA, Carriero, MM, Maia, AAM, Silva, MRMD, Naldoni, J, Ceccarelli, OS and Arana, S (2012) Phylogenetic and host–parasite relationship analysis of Henneguya multiplasmodialis n. sp. infecting Pseudoplatystoma spp. in Brazilian Pantanal wetland. Veterinary Parasitology 185, 110120.CrossRefGoogle Scholar
Azevedo, C, Casal, G, Mendonça, I, Carvalho, E, Matos, P and Matos, E (2010) Light and electron microscopy of Myxobolus sciades n. sp. (Myxozoa), a parasite of the gills of the Brazilian fish Sciades herzbergii (Block, 1794) (Teleostei: Ariidae). Memórias Do Instituto Oswaldo Cruz 105, 203207.CrossRefGoogle Scholar
Banu, H and Rathinam, RB (2023) Myxozoan fish diseases: Possible treatment and zoonoses. Journal of Parasitic Diseases 47, 215223.CrossRefGoogle ScholarPubMed
Barta, JR, Martin, DS, Liberator, PA, Dashkevicz, M, Anderson, JW, Feighner, SD, Elbrecht, A, Perkins-Barrow, A, Jenkins, MC, Danforth, HD, Ruff, MD and Profous-Juchelka, H (1997) Phylogenetic relationships among eight Eimeria species infecting domestic fowl inferred using complete small subunit ribosomal DNA sequences. The Journal of Parasitology 83, 262271.CrossRefGoogle ScholarPubMed
Bush, AO, Lafferty, KD, Lotz, JM and Shostak, AW (1997) Parasitology meets ecology on its own terms: Margolis et al. revisited. The Journal of Parasitology 83, 575583.CrossRefGoogle Scholar
Capodifoglio, KR, Adriano, EA, Milanin, T, Silva, MR and Maia, AA (2016) Morphological, ultrastructural and phylogenetic analyses of Myxobolus hilarii n. sp. (Myxozoa, Myxosporea), a renal parasite of farmed Brycon hilarii in Brazil. Parasitology International 65, 184190.CrossRefGoogle Scholar
Carriero, MM, Adriano, EA, Silva, MR, Ceccarelli, OS and Maia, AA (2013) Molecular phylogeny of the Myxobolus and Henneguya genera with several new South American species. PLoS One 8, e73713.CrossRefGoogle ScholarPubMed
Casal, G, Silva, TJ, Soares, EC, Oliveira, E, Santos, M and Rocha, S (2023) Morphological, histopathological, ultrastructural and phylogenetic analysis of Henneguya archosargus n. sp. (Cnidaria, Myxosporea) infecting the sparid fish Archosargus probatocephalus in Brazilian waters. Microbial Pathogenesis 184, 106366.CrossRefGoogle Scholar
Eiras, JC, Cruz, CF, Saraiva, A and Adriano, EA (2021) Synopsis of the species of Myxobolus (Cnidaria, Myxozoa, Myxosporea) described between 2014 and 2020. Folia Parasitologica 68, 012.CrossRefGoogle Scholar
Eiras, JC, Takemoto, RM and Pavanelli, GC (2009) Henneguya corruscans n. sp. (Myxozoa, Myxosporea, Myxobolidae), a parasite of Pseudoplatystoma corruscans (Osteichthyes, Pimelodidae) from the Paraná River, Brazil: A morphological and morphometric study. Veterinary Parasitology 159, 154158.CrossRefGoogle Scholar
Eszterbauer, E (2004) Genetic relationship among gill-infecting Myxobolus species (Myxosporea) of cyprinids: Molecular evidence of importance of tissue-specificity. Diseases of Aquatic Organisms 58, 3540.CrossRefGoogle ScholarPubMed
Fiala, I (2006) The phylogeny of Myxosporea (Myxozoa) based on small subunit ribosomal RNA gene analysis. International Journal for Parasitology 36, 15211534.CrossRefGoogle ScholarPubMed
França, JG, Isaac, A, Pavanelli, GC and Takemoto, RM (2003) Dactylogyridae (Monogenea) from the gills of Iheringichthys labrosus (Osteichthyes: Pimelodidae) from the upper Paraná River floodplain, Brazil, with the proposal of Pseudovancleaveus ng. Systematic Parasitology 54, 2531.CrossRefGoogle Scholar
Guindon, S, Dufayard, JF, Lefort, V, Anisimova, M, Hordijk, W and Gascuel, O (2010) New algorithms and methods to estimate maximum-likelihood phylogenies: Assessing the performance of PhyML 3.0. Systematic Biology 59, 307321.CrossRefGoogle ScholarPubMed
Hallett, SL and Diamant, A (2001) Ultrastructure and small-subunit ribosomal DNA sequence of Henneguya lesteri n. sp. (Myxosporea), a parasite of sand whiting Sillago analis (Sillaginidae) from the coast of Queensland, Australia. Diseases of Aquatic Organisms 46, 197212.CrossRefGoogle Scholar
Kent, ML, Khattra, J, Hedrick, RP and Devlin, RH (2000) Tetracapsula renicola n. sp. (Myxozoa: Saccosporidae); the PKX myxozoan—the cause of proliferative kidney disease of salmonid fishes. Journal of Parasitology 86, 103111.Google Scholar
Kohn, A and Fernandes, BM (2011) A new species of Parspina (Trematoda: Cryptogonimidae) from catfish (Iheringichthys labrosus) in the reservoir of the Itaipu Hydroelectric Power Station, Brazil. Comparative Parasitology 78, 275279.CrossRefGoogle Scholar
Larkin, MA, Blackshields, G, Brown, NP, Chenna, R, McGettigan, PA, McWilliam, H, Valentin, F, Wallace, IM, Wilm, A, Lopez, R, Thompson, JD, Gibson, TJ and Higgins, DG (2007) Clustal W and Clustal X version 2.0. Bioinformatics 23, 29472948.CrossRefGoogle Scholar
Liu, Y, Gu, ZM and Luo, YL (2010) Some additional data to the occurrence, morphology and validity of Myxobolus turpisrotundus Zhang, 2009 (Myxozoa: Myxosporea). Parasitology Research 107, 6773.CrossRefGoogle Scholar
Liu, Y, Lövy, A, Gu, Z and Fiala, I (2019) Phylogeny of Myxobolidae (Myxozoa) and the evolution of myxospore appendages in the Myxobolus clade. International Journal for Parasitology 49, 523530.CrossRefGoogle ScholarPubMed
Lom, J and Arthur, JR (1989) A guideline for the preparation of species descriptions in Myxosporea. Journal of Fish Diseases 12, 151156.CrossRefGoogle Scholar
Lom, J and Dyková, I (2006) Myxozoan genera: Definition and notes on taxonomy, life-cycle terminology and pathogenic species. Folia Parasitologica 53, 136.CrossRefGoogle ScholarPubMed
Lundberg, JG and Littmann, MW (2003) Pimelodidae (Long-whiskered catfishes). In Reis, RE, Kullander, SO and Ferraris, CJ ((eds.)), Checklist of the Freshwater Fishes of South and Central America. Porto Alegre, Brasil: EDIPUCRS, 432446.Google Scholar
Mathews, PD, Maia, AA and Adriano, EA (2016) Morphological and ultrastructural aspects of Myxobolus Niger n. sp. (Myxozoa) gill parasite of Corydoras melini (Siluriformes: Callichthyidae) from Brazilian Amazon. Acta Tropica 158, 214219.CrossRefGoogle Scholar
Mathews, PD, Mertins, O, Milanin, T, Espinoza, LL, Flores-Gonzales, AP, Audebert, F and Morandini, AC (2020) Molecular phylogeny and taxonomy of a new Myxobolus species from the endangered ornamental fish, Otocinclus cocama endemic to Peru: A host-parasite coextinction approach. Acta Tropica 210, 105545.CrossRefGoogle Scholar
Matos, E, Tajdari, J and Azevedo, C (2005) Ultrastructural studies of Henneguya rhamdia n. sp. (Myxozoa) a parasite from the Amazon teleost fish, Rhamdia quelen (Pimelodidae). Journal of Eukaryotic Microbiology 52, 532537.CrossRefGoogle Scholar
Molnár, K (2002) Site preference of fish myxosporeans in the gill. Diseases of Aquatic Organisms 48, 197207.CrossRefGoogle ScholarPubMed
Moreira, ST, Ito, KF, Takemoto, RM and Pavanelli, GC (2005) Ecological aspects of the parasites of Iheringichthys labrosus (Lütken, 1874) (Siluriformes: Pimelodidae) in reservoirs of Paraná basin and upper Paraná floodplain, Brazil. Acta Scientiarum - Biological Sciences 27, 317322.CrossRefGoogle Scholar
Naldoni, J, Arana, S, Maia, AAM, Ceccarelli, PS, Tavares, LER, Borges, FDA, Pozo, CF and Adriano, EA (2009) Henneguya pseudoplatystoma n. sp. causing reduction in epithelial area of gills in the farmed pintado, a South American catfish: Histopathology and ultrastructure. Veterinary Parasitology 166, 5259.CrossRefGoogle Scholar
Naldoni, J, Arana, S, Maia, AAM, Silva, MRMD, Carriero, MM, Ceccarelli, PS, Tavares, LER and Adriano, EA (2011) Host–parasite–environment relationship, morphology and molecular analyses of Henneguya eirasi n. sp. parasite of two wild Pseudoplatystoma spp. in Pantanal wetland, Brazil. Veterinary Parasitology 177, 247255.CrossRefGoogle Scholar
Naldoni, J, Maia, AA, Correa, LL, da Silva, MR and Adriano, EA (2018) New myxosporeans parasitizing Phractocephalus hemioliopterus from Brazil: Morphology, ultrastructure and SSU-rDNA sequencing. Diseases of Aquatic Organisms 128, 3749.CrossRefGoogle ScholarPubMed
Negrelli, DC, Vieira, DHMD, Tagliavini, VP, Abdallah, VD and de Azevedo, RK (2019) Molecular and morphological analysis of Henneguya jundiai n. sp. (Cnidaria: Myxosporea), a new parasite of the gills of Rhamdia quelen in Brazil. Acta Tropica 197, 105053.CrossRefGoogle Scholar
Palenzuela, O, Redondo, MJ and Alvarez-Pellitero, P (2002) Description of Enteromyxum scophthalmi gen. nov., sp. nov. (Myxozoa), an intestinal parasite of turbot (Scophthalmus maximus L.) using morphological and ribosomal RNA sequence data. Parasitology 124, 369379.CrossRefGoogle Scholar
Posada, D (2008) jModelTest: Phylogenetic model averaging. Molecular Biology and Evolution 25, 12531256.CrossRefGoogle ScholarPubMed
Rambaut, A (2012) FigTree v1.4. Molecular evolution, phylogenetics and epidemiology website: http://tree.bio.ed.ac.uk (accessed 19 November 2024).Google Scholar
Rangel, LF, Rocha, S, Castro, R, Severino, R, Casal, G, Azevedo, C, Cavaleiro, F and Santos, MJ (2015) The life cycle of Ortholinea auratae (Myxozoa: Ortholineidae) involves an actinospore of the triactinomyxon morphotype infecting a marine oligochaete. Parasitology Research 114, 26712678.CrossRefGoogle ScholarPubMed
Rangel, LF, Santos, MJ and Rocha, S (2023) Synopsis of the species of Henneguya Thélohan, 1892 (Cnidaria: Myxosporea: Myxobolidae) described since 2012. Systematic Parasitology 100, 291305.CrossRefGoogle ScholarPubMed
Ronquist, F and Huelsenbeck, JP (2003) MrBayes 3: Bayesian phylogenetic inference under mixed models. Bioinformatics 19, 15721574.CrossRefGoogle Scholar
Úngari, LP, Vieira, DHMD, da Silva, RJ, Santos, ALQ, de Azevedo, RK and O’Dwyer, LH (2019) A new myxozoan species Henneguya unitaeniata sp. nov. (Cnidaria: Myxosporea) on gills of Hoplerythrinus unitaeniatus from Mato Grosso State, Brazil. Parasitology Research 118, 33273336.CrossRefGoogle ScholarPubMed
Vieira, DHMD, Narciso, RB and da Silva, RJ (2022a) Morphological and molecular characterization of the cryptic species Myxobolus cataractae n. sp. (Cnidaria: Myxozoa: Myxobolidae) parasitizing Imparfinis mirini (Siluriformes: Heptapteridae). Parasitology International 88, 102560.CrossRefGoogle Scholar
Vieira, DHMD, Narciso, RB and da Silva, RJ (2022b) Diversity of myxozoans parasitizing the catfish Rhamdia quelen (Siluriformes: Heptapteridae), in southeastern Brazil, based on morphological and molecular evidence. Scientific Reports 12, 17596.CrossRefGoogle Scholar
Vieira, DHMD, Pelegrini, LS, Abdallah, VD and de Azevedo, RK (2019) Supplementary studies on Henneguya guanduensis (Cnidaria: Myxosporea) infecting gills and intestine of Hoplosternum littorale in Brazil: Ultrastructural and molecular data. Parasitology International 70, 2732.CrossRefGoogle ScholarPubMed
Vieira, DHMD, Rangel, LF, Tagliavini, VP, Abdallah, VD, Santos, MJ and de Azevedo, RK (2020) A new species, Henneguya lacustris n. sp. (Cnidaria: Myxosporea), infecting the gills of Astyanax lacustris from Brazil. Parasitology Research 119, 42594265.CrossRefGoogle Scholar
Vieira, DHMD, Rangel, LF, Tagliavini, VP, Abdallah, VD, Santos, MJ and de Azevedo, RK (2021) Morphological and molecular analysis of Henneguya tietensis n. sp. (Cnidaria: Myxosporea), parasitizing the gill filaments of Prochilodus lineatus (Valenciennes, 1837) from Brazil. Parasitology Research 120, 2736.CrossRefGoogle Scholar
Vieira, DHMD, Tagliavini, VP, Abdallah, VD and de Azevedo, RK (2018) Myxobolus imparfinis n. sp. (Myxozoa: Myxosporea), a new gill parasite of Imparfinis mirini Haseman (Siluriformes: Heptapteridae) in Brazil. Systematic Parasitology 95, 309318.CrossRefGoogle Scholar
Xiao, C and Desser, SS (2000) Cladistic analysis of myxozoan species with known alternating life-cycles. Systematic Parasitology 46, 8191.CrossRefGoogle ScholarPubMed
Zatti, SA, Atkinson, SD, Maia, AA, Corrêa, LL, Bartholomew, JL and Adriano, EA (2018) Novel Myxobolus and Ellipsomyxa species (Cnidaria: Myxozoa) parasiting Brachyplatystoma rousseauxii (Siluriformes: Pimelodidae) in the Amazon basin, Brazil. Parasitology International 67, 612621.CrossRefGoogle Scholar
Figure 0

Figure 1. Plasmodium (P) of Myxobolus iheringichthys n. sp. found parasitizing the gill arch of Iheringichthys labrosus collected from the Pardo River, municipality of Avaré, State of São Paulo, Brazil.

Figure 1

Figure 2. Light micrograph of fresh myxospores of Myxobolus iheringichthys n. sp. found parasitizing the gill arch of Iheringichthys labrosus collected from the Pardo River, municipality of Avaré, State of São Paulo, Brazil.

Figure 2

Figure 3. A-B. Schematic drawing of the myxospores of Myxobolus iheringichthys n. sp. In frontal (A) and side (B) view. (C and D). Schematic drawing of the myxospores of Henneguya avareensis n. sp. In frontal (C) and side (D) view.

Figure 3

Figure 4. Plasmodia (P) of Henneguya avareensis n. sp. found parasitizing the gill filaments of Iheringichthys labrosus collected in the Pardo River, municipality of Avaré, State of São Paulo, Brazil.

Figure 4

Figure 5. (A and B) light micrographs of fresh myxospores of Henneguya avareensis n. sp. found parasitizing the gill filaments of Iheringichthys labrosus collected in the Pardo River, municipality of Avaré, State of São Paulo, Brazil.

Figure 5

Figure 6. (A–D) TEM micrographs of the plasmodia and myxospores of Henneguya avareensis n. sp. Found in the gill filaments of Iheringichthys labrosus. (A) Plasmodial wall (WP) smooth. (B) Transverse section of a myxospore showing the sutures (S) with its thickened valves. (C) Longitudinal cut of a polar capsule. Notice the outer electron-dense layer (OL) and inner electron-lucent layer (IL) forming the wall, and the polar tubules (PT) coiled within. (D) Transverse section of a myxospore showing the posterior vacuole (PV) containing 1 of the nuclei (N). Note the heterogeneous content in the sporoplasm (SP) and sutures (S).

Figure 6

Figure 7. Bayesian inference phylogenetic tree showing the placement of Henneguya avareensis n. sp. and Myxobolus iheringichthys n. sp. In relation to the genetically most similar species of Henneguya/Myxobolus obtained from GenBank. The scale bar is given below the tree. The numbers on the branches indicate posterior probability/bootstrap values. Values below 0.9/70 were suppressed with -.

Figure 7

Table 1. Morphometric comparison between Myxobolus iheringichthys n. sp. and other Myxobolus spp. described from South American siluriformes

Figure 8

Table 2. Morphometric comparison between Henneguya avareensis n. sp. and other Henneguya spp. described from South American siluriformes