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Memórias do Instituto Oswaldo Cruz

Print version ISSN 0074-0276

Mem. Inst. Oswaldo Cruz vol.108 no.2 Rio de Janeiro Apr. 2013

http://dx.doi.org/10.1590/0074-0276108022013004 

Articles

Ultrastructural description of Ceratomyxa microlepis sp. nov. (Phylum Myxozoa): a parasite infecting the gall bladder of Hemiodus microlepis, a freshwater teleost from the Amazon River

Carlos Azevedo1  2  + 

Sónia Rocha2 

Graça Casal2  3 

Sérgio Carmona São Clemente4 

Patrícia Matos5 

Saleh Al-Quraishy6 

Edilson Matos7 

IDepartmento de Biologia Celular, Instituto de Ciências Biomédicas, Universidade do Porto, Porto, Portugal

IILaboratório de Patologia, Centro Interdisciplinar de Investigação Marinha e Ambiental, Porto, Portugal

IIIDepartamento de Ciências, Instituto Superior de Ciências da Saúde-Norte, Gandra, Portugal

IVLaboratório de Inspeção e Tecnologia de Alimentos, Faculdade de Veterinária, Universidade Federal Fluminense, Niterói, RJ, Brasil

VLaboratório de Pesquisa Edilson Matos, Instituto de Ciências Biológicas, Universidade Federal do Pará, Belém, PA, Brasil

VIZoology Department, College of Science, King Saud University, Riyadh, Saudi Arabia

VIILaboratório de Pesquisa Carlos Azevedo, Universidade Federal Rural da Amazônia, Belém, AM, Brasil

ABSTRACT

A new ceratomyxid parasite was examined for taxonomic identification, upon being found infecting the gall bladder of Hemiodus microlepis (Teleostei: Hemiodontidae), a freshwater teleost collected from the Amazon River, Brazil. Light and transmission electron microscopy revealed elongated crescent-shaped spores constituted by two asymmetrical shell valves united along a straight sutural line, each possessing a lateral projection. The spores body measured 5.2 ± 0.4 µm (n = 25) in length and 35.5 ± 0.9 µm (n = 25) in total thickness. The lateral projections were asymmetric, one measuring 18.1 ± 0.5 µm (n = 25) in thickness and the other measuring 17.5 ± 0.5 µm (n = 25) in thickness. Two equal-sized subspherical polar capsules measuring 2.2 ± 0.3 µm in diameter were located at the same level, each possessing a polar filament with 5-6 coils. The sporoplasm was binucleate. Considering the morphometric data analyzed from the microscopic observations, as well as the host species and its geographical location, this paper describes a new myxosporean species, herein named Ceratomyxa microlepis sp. nov.; therefore representing the first description of a freshwater ceratomyxid from the South American region.

Key words: Ceratomyxa microlepis sp. nov.; gall bladder; Hemiodus microlepis ; freshwater teleost; Amazon River; ultrastructure

The genus Ceratomyxa Thélohan, 1892, constitutes one of the largest genera within the class Myxosporea of the phylum Myxozoa, comprising about 190 species, the great majority of which are coelozoic parasites infecting the gall bladder of marine teleosts (Eiras 2006, Lom & Dyková 2006). Ceratomyxa spp have elongated, crescent-shaped or arcuate spores with shell valves that are frequently conical, exceeding in length the axial diameter of the spore. Spores contain two subspherical capsules and a binucleate sporoplasm or, more rarely, two uninucleate sporoplasms (Lom & Dyková 1992).

Despite having a worldwide distribution, only three species of Ceratomyxa have been described from South American fish hosts: Ceratomyxa dissostichi from Dissostichus eleginoides from the Falklands islands, Ceratomyxa curvata from Odontaspis americanus and Ceratomyxa hippocampi from Hippocampus punctulatus , both from the Brazilian Atlantic coast (Cunha & Fonseca 1918, Brickle et al. 2001). These are all species infecting the gall bladder of marine fish hosts. In fact, only five species have been reported from freshwater teleosts worldwide: Ceratomyxa anguillae from the gall bladder of Anguilla anguilla from France, Ceratomyxa hilsae from the gall bladder of Hilsa ilisha from India, Ceratomyxa hongtzensis from the gall bladder of Pelteobagrus eupogon from China, Ceratomyxa hungarica from the gall bladder of Proterorhinus marmoratus from Hungary and Ceratomyxa shasta from the digestive tract of Oncorhynchus mykiss from the United States of America (Chakravarty 1939, Noble 1950, Tuzet & Ormières 1957, Hsieh & Chen 1984, Molnár 1992). Of the five mentioned freshwater species, only C. shasta is histozoic (Noble 1950).

The present paper uses light microscopy and transmission electronic microscopy to describe a new myxosporean species of the genus Ceratomyxa found infecting the gall bladder of Hemiodus microlepis . The host species is a teleost that inhabits the Amazon River, making this the first description of a freshwater ceratomyxid species from the South American region.

MATERIALS AND METHODS

Twenty five specimens (15 females and 10 males) of H. microlepis Kner, 1858 (Teleostei: Hemiodontidae), known by the Brazilian common name Orana and displaying an average body length of 14-22 cm, were collected from the Trombetas River, an affluent located at about 770 km from the mouth of the Amazon River (01º45'S 55º51'W), near the city of Oriximiná in the state of Pará (PA), Brazil. Upon necropsy, the gall bladder of each specimen was examined for parasitic infection. Small fragments of infected gall bladder tissue and bile were examined using Nomarski differential interference contrast microscopy, equipped with a micrometric ocular lens and image software. Fresh spore measurements were taken.

For transmission electron microscopy (TEM), the bile of the infected gall bladders was fixed in 5% glutaraldehyde in 0.2 M sodium cacodylate buffer (pH 7.4) for 24 h at 4ºC. The solution was then washed overnight in the same buffer at 4ºC and postfixed in 2% OsO4, buffered with the same solution for 4 h at the same temperature. After dehydration in a graded ethanol-series followed by propylene oxide, samples were embedded in Epon. Semi-thin sections were stained with methylene blue-Azur II. Ultrathin sections were cut with a diamond knife, double-stained with uranyl acetate and lead citrate and observed in a JEOL 100CXII TEM operated at 60 kV.

RESULTS

Light microscopy revealed mature spores of an undescribed Ceratomyxa species floating free in the bile (Figs 1-3), but no other sporogenic developmental stages were observed. The infection was detected in the gall bladder of 36% of the H. microlepis examined, but no obvious morphological and behavioural symptoms of infection were observed.

Figs 1-3 light and transmission electron micrographs of Ceratomyxa microlepis sp. nov. infecting the gall bladder of Hemiodus microlepis collected from the Amazon River. 1: several free unfixed spores observed by differential interference contrast microscopy; 2: spores sectioned at different levels and displaying different ultrastructural aspects, including the polar capsules (PC); 3: longitudinal section of a spore revealing its general organization, namely the two lateral projections (P) and the two PCs. 

Ceratomyxa microlepis sp. nov.

(Figs 1-9)

Figs 4-8 transmission electron micrographs of Ceratomyxa microlepis sp. nov. infecting the gall bladder of Hemiodus microlepis collected from the Amazon River. 4: ultrastructural detail of the two polar cap sules in longitudinal section, displaying the organization of its polar filaments (PF) and the extrusion pores (arrows) located at the spore anterior pole, near the sutural line (arrowheads). A nucleus (N) of the sporoplasm is observed close to these structures; 5: oblique section of a polar capsule (PC), allowing the recognition of its double-layer wall (arrowheads) and number of PF coils; 6: oblique section of the central region of a spore showing the PCs, one of the two Ns of the sporoplasm, some sporoplasmosomes (arrowheads) and a lipidic-like structure (arrow); 7: detailed aspect of the sutural line (arrowheads) uniting the two shell valves (V); 8: slightly oblique transverse section of a lateral projection containing numerous reserve bodies (arrows) and displaying the double-layer wall (arrowheads) organization of the spore shell Vs. 

Description - The spores displayed crescent-shape with a convex anterior pole and a slightly concave posterior pole (Figs 1-3), measuring 5.2 ± 0.4 µm (n = 25) in length and 35.5 ± 0.9 µm (n = 25) in total thickness (Figs 1, 3). Two asym-metric conical shell valves united along a straight sutural line (Figs 4, 7), each possessing an elongated lateral projection with slightly different thickness and shape (Figs 1, 3). In one shell valve, the lateral projection was 18.1 ± 0.5 µm (n = 25) thick and tapered into a blunt end, while in the other shell valve, the lateral projection was 17.5 ± 0.5 µm (n = 25) thick and displayed a rounded end (Figs 1, 3). The lateral projections were a continuation of the cytoplasmic material of the spore, as well as of the wall of the shell valves, which was comprised of a continuous external layer of dense material and a continuous internal layer of lighter material (Figs 4, 5, 6, 8). Two equal-sized subspherical polar capsules were located side by side and measured 2.2 ± 0.3 µm in diameter (n = 30) (Figs 3, 4, 6). The wall of these polar capsules was comprised of a continuous external dense layer and an internal hyaline layer (Fig. 5), which displayed extrusion pores located near the sutural line at the anterior pole of the spore. An electron dense stopper closed each extrusion pore, preventing extrusion of the polar filament (Fig. 4). Inside the polar capsules the isofilar polar filament coiled in five-six turns and appeared obliquely arranged, forming an angle of about 58º-60º to the longitudinal axis of these structures (Figs 4, 5). The sporoplasm was irregular in shape and displayed two nuclei randomly positioned in its matrix (Figs 4, 6). The cytoplasm of the shell valves contained several dense reserve bodies and vesicles (Fig. 8). A schematic drawing of a spore is shown in Fig. 9, allowing recognition of its overall ultrastructural aspects.

Fig. 9 schematic drawing of Ceratomyxa microlepis sp. nov. infecting the gall bladder of Hemiodus microlepis collected from the Amazon River, displaying the spore overall morphology, with special emphasis on the two opposite and asymmetric lateral projections of the shell valves 

Type host - H. microlepis Kner, 1858 (Teleostei: Hemiodontidae).

Site of infection - Mature spores were found floating free in the bile. Spores were not observed attached to the epithelial tissue of the gall bladder.

Type locality - Trombetas River (01º45'S 55º51'W), an affluent of the Amazon River located 770 km upstream from its mouth, near the city of Oriximiná, PA.

Type data and depository (upon acceptance) - A glass slide containing a semi-thin section of mature spores of the hapantotype was deposited in the International Myxozoan Type Slide Collection at the National Institute of Amazonian Research, Manaus, state of Amazonas, Brazil, under acquisition (012/12).

Prevalence of infection - Nine out of 25 (36%) specimens were infected [5/15 (33.3%) for females and 4/10 (40%) for males].

Etymology - The specific epithet of this parasite derives from the specific epithet of the host species.

DISCUSSION

Despite the numerous descriptions relating to the genus Ceratomyxa, only C. anguillae , C. hilsae , C. hongtzensis , C. hungarica and C. shasta are known to infect freshwater teleosts, none of which are from the South American region (Eiras 2006, Lom & Dyková 2006). With the exception of C. shasta, which is histozoic (Noble 1950), all the other freshwater species of the genus Ceratomyxa are coelozoic (Chakravarty 1939, Tuzet & Ormières 1957, Hsieh & Chen 1984, Molnár 1992). The parasite here described was also coelozoic in the gall bladder of H. microlepis , but displayed ultrastructural characteristics very distinct from those reported for the other freshwater species within the genus, as shown in Table. The most prominent of which was the presence of two elongated lateral projections, which are missing in the remaining freshwater species of the genus.

TABLE Features of Ceratomyxa spp infecting freshwater fish hosts 

PC: polar capsule; PF: number of polar filaments coils; SL: spore (SP) length; ST: SP thickness

Although all other currently known species of Ceratomyxa infecting freshwater fish lack elongated lateral projections, there are about 70 marine species of Ceratomyxa in which such projections have been described (Ali et al. 2006, Eiras 2006, Abdel-Ghaffar et al. 2008, Gunter & Adlard 2008, 2009, Gunter et al. 2010). Morphological comparison to these marine species suggested that C. microlepis sp. nov. shared some superficial similarity with Ceratomyxa aglomerata from the gall bladder of Synodus foetans from the USA Atlantic Coast (Davis 1917), Ceratomyxa attenuata from the gall bladder of Scoliodon terranovae from the USA Atlantic Coast (Davis 1917) and Ceratomyxa koieae from the gall bladder of Sphyraena forsteri from Lizard Island in Australia (Gunter et al. 2010). On the other hand, comparative analysis of specific morphological characteristics of these species revealed some singular aspects that allow differentiation. C. aglomerata spores were less thick and the polar capsules slightly bigger, C. attenuata spores were of a similar shape, but much larger in length and thickness, as well as in the diameter of their polar capsules, and C. koieae spores displayed identical measurements, but had symmetrical shell valves (Davis 1917, Gunter et al. 2010). No specific similarity was observed to the spores of Ceratomyxa dissostichi , C. curvata and C. hippocampi , which were reported from the same geographical area, but from marine hosts (Cunha & Fonseca 1918, Brickle et al. 2001).

Also taken into account were numerous molecular based studies that have revealed that the class Myxosporea is divided into two main clades: freshwater and marine species. C. shasta constitutes one of the few exceptions to this division, due to the anadromous nature of its host (Kent et al. 2001, Fiala & Dyková 2004, Fiala 2006). Therefore, the parasite here described, which infects the gall bladder of a potamodromous fish, is more likely to be phylogenetically related to the other freshwater species within Ceratomyxa , rather than to the marine species with which it demonstrates an apparently higher level of morphological similarity.

The totality of comparative morphometric data analyzed, from both freshwater and marine species, combined with the specificity of the host geographical location, together suggest that this parasite is a new species, herein named C. microlepis sp. nov. Morphological comparisons were solely based on the mature spores' characteristics, since other developmental stages were not observed. The lack of vegetative and earlier sporogenic stages shows that during the hosts' collection period, the parasite had already incurred sporogenesis and full maturation. To conclude, the present paper constitutes the first description of a freshwater ceratomyxid from the South American region and the sixth report worldwide.

ACKNOWLEDGEMENTS

To Mr Karl Woodgett, for the English language proofreading of this paper.

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Financial support: Eng A Almeida Foundation (Portugal), CNPq, CAPES, Visiting Professor Program of College of Science, King Saud University, Riyadh (Saudi Arabia)

Received: May 03, 2012; Accepted: May 28, 2012

+ Corresponding author: azevedoc@icbas.up.pt