On-line version ISSN 0717-7712
Parasitol. latinoam. vol.60 no.1-2 Santiago June 2005
Parasitol Latinoam 60: 48 - 53, 2005 FLAP
Scanning electron microscopy of Neoechinorhynchus sp. (Acanthocephala: Neoechinorhynchidae), a possible new species of intestinal parasite of the Tallfin croaker Micropogonias altipinnis (Günther, 1864)
JUAN JOSÉ ALAVA* and WINDSOR E. AGUIRRE**
* Departments of Parasitology and Electron Microscopy, National Institute of Hygiene and Tropical Medicine "Leopoldo Izquieta Pérez". P.O. Box 09-01-3961. Guayaquil, Ecuador.
We describe an unidentified species of the genus Neoechinorhynchus occurring in the intestine of the marine fish Micropogonias altipinnis using scanning electron microscopy (SEM). The genus Neoechinorhynchus occurs mostly in freshwater fishes; this may be the first report of its occurrence in the marine fish genus Micropogonias and the New World Sciaenidae. The specimens collected have characteristics typical of the genus. The mean length of the trunk is 9.5 mm. The proboscis is short and subcylindrical measuring 70 mm in length and 50 mm in diameter near the base. The proboscis has three rings of curved spines each with six spines. The anterior spines are long measuring a mean of 55 mm in length, 9 mm in width, and 7 mm in depth, and are supported by simple unmodified roots. The spines of the middle ring are smaller and equivalent to 70% of the roots of the anterior spines. The spines of the posterior ring are much smaller than those of the anterior ring. The body surface lacks spines and consists of a series of folds. The estuarine habits of M. altipinnis and its ability to tolerate fresh waters may have facilitated its infection with a species of the primarily freshwater genus Neoechinorhynchus, as well as the possibility that this parasite can infect human beings from the consumption of this kind of croaker.
Key words: Acanthocephala, Neoechinorhynchus, Micropogonias altipinnis, SEM.
Se describe una especie de acantocéfalo no identificada del género Neoechinorhynchus presente en el intestino del pez marino Micropogonias altipinnis, conocido localmente como "corvinón" o "torno", usando microscopia electrónica de escaneo. Este género ocurre mayormente en peces de agua dulce y probablemente este es el primer informe de su presencia en el pez marino del género Micropogonias y peces de la familia Sciaenidae del Nuevo Mundo. La longitud media del tronco es 9,5 mm. La proboscis es corta y subcilíndrica, la cual mide 70 mm en longitud y 50 mm en diámetro, cerca de su base. La proboscis tiene tres anillos de espinas recurvadas, con cada anillo teniendo seis espinas. Las espinas anteriores son largas y tienen una longitud media de 55 mm, un ancho de 9 mm y una profundidad de 7 mm, mantenidas por raíces no modificadas en sus bases. Las espinas del anillo medio son pequeñas y equivalen al 70% de las raíces de las espinas anteriores. La superficie del cuerpo presenta escasas espinas y consiste de una serie de pliegues. El comportamiento estuarino de M. altippinnis y su habilidad para tolerar agua dulce puede haber facilitado la infección parasitaria con esta especie de acantocéfalo del género Neoechinorhynchus, el cual es primariamente dulceacuícola, así como la posibilidad de que este parásito infecte al hombre a partir del consumo de este tipo de corvina.
The phylum Acanthocephala includes approximately 1,150 species of relatively small vermiform endoparasites, the adults of which feed on the intestinal walls of vertebrates, especially in freshwater and marine fishes1. There are relatively few studies of the acanthocephalans of the marine fishes of Latin America2-9. The acanthocephalans of the marine fishes of Ecuador are particularly poorly known. We have found little published in this regard beyond Van Cleave's10 description of species from marine fishes of the Galapagos Islands.
The acanthocephalan genus Neoechino-rhynchus is a relatively large genus with approximately 70 - 75 species11,12. It occurs throughout the world including Latin America and is typically found in freshwater fishes13-16, although it occurs in other taxa as well. In this paper, we carried out a description and scanning electron microscopy study of the fine structure of an unidentified species of Neoechinorhynchus found in the intestine of the Tallfin croaker, Micropogonias altipinnis (Teleostei: Sciaenidae). This fish is locally named as "corvinon" or "torno" in Ecuadorian fish markets. The biodiversity on acanthocephalan species is poorly known in Ecuador. This study contributes to the knowledge of the genus Neoechinorhynchus in marine fishes, as well as to the knowledge of the acanthocephalans of the marine fishes of Ecuador.
MATERIALS AND METHODS
The parasites were collected from the intestine of specimens of M. altipinnis purchased from a fish market in Guayaquil, Ecuador. This species is a demersal fish common in coastal waters. Two sampling efforts were carried out, the first consisted of a sample of four fish and the second consisted of three fish. Fish were dissected in the laboratory and a total of 19 acanthocephalans were collected. Specimens were identified to genus using the Meyer-Van Cleave System for identification of classes, orders, families and subfamilies of acanthocephalans17, and the key to species of the genus Neoechinorhynchus for freshwater fishes of North America12. Two voucher specimens (codes: 001 and 002) were deposited in the collection of the Parasitology Department of the National Institute of Hygiene and Tropical Medicine "Leopoldo Izquieta Pérez", Guayaquil, Ecuador. Specimens from the first sampling effort were placed in saline solution prior to being processed whereas specimens from the second sampling effort were placed in cold distilled water to allow relaxation. A few specimens were dissected with an Olympus stereoscope for general description of the parasites. The proboscis of two specimens were isolated, cleared with glycerin, and mounted on a slide using Canadian's balsam. Eggs, male reproductive systems, and lemnisci were also mounted for future studies. The slides were observed under a light microscope (Olympus CX31). For the scanning electron microscopy study, two specimens were fixed with 3% glutaraldehide, washed in phosphate buffer (pH 7.4), treated with 1% osmium tetraoxide (OsO4) and then with distilled water, and dehydrated through consecutive washes of alcohol of increasing concentrations (50-100% washes). They were then treated with isoamilacetate and 100% alcohol in ratios of 3:1, 2:2, and 1:3, and pure isoamilacetate. Afterwards, samples were dried to critical point and covered in gold-platinum. Finally, the samples were observed and photographed with a Hitachi S-430 Scanning Electron Microscope (SEM), with an acceleration voltage of 15 KV.
SEM-description: This species of Neo-echinorhynchus is small to moderate in size; the mean length of the specimens collected was 9.5 mm. The trunk varies in shape but is typically cylindrical to oblong or fusiform (Figure 1). The body surface consists of a series of folds and lacks spines (Figure 2). The proboscis is short and subcylindrical, almost globular, measuring approximately 70 mm in length and 50 mm in diameter at the base (Figures 3-4). It possesses three rings of curved hooks each with six hooks (Figure 5). The anterior ring has long hooks all of similar size, with a mean length of 55 mm (maximum 62 mm) by 9 mm in width and 7 mm in depth (Figure 4), that are supported by simple unmodified roots (Figure 5). The hooks of the middle ring are smaller than those of the anterior ring, measuring approximately 70% of the length the roots of the anterior spines (Figure 5). The posterior ring of hooks is the smallest. The hooks of the middle and posterior rings lack roots (Figure 5). The eggs are ovoid (Figure 6).
Taxonomic comparison: We compared the unidentified species described in this paper with published accounts of several species of the genus known from South America13,15. The trunk is longer than that of N. paraguayensis, N. prochilodorum, and N. pterodoridis (the trunk of these species measures 1.6-2.0 mm, 4.5-8.0 mm, and 1.74-3.30 mm in length respectively, whereas the mean trunk length of our species is 9.5 mm). The proboscis is typically shorter and narrower than that of N. prochilodorum and N. pterodoridis (the proboscis length and width in N. prochilodorum is 83 mm and 93 mm respectively and in N. pterodoridis it is approximately 127 mm and 119 mm respectively, whereas in our species it is 70 mm and 50 mm). The anterior hooks of the proboscis are smaller than those of N. australis, N. paraguayensis, and N. pterodoridis (they are 75 mm, 87 mm and approximately 141 mm long respectively in these species, whereas they are 55 mm long in our species). In addition, N. australis, N. paragua-yensis, N. prochilodorum, and N. pterodoridis are all known from freshwater fishes.
The unidentified species described in this paper also differs from the published description of the Asian species N. argentatus collected from the sciaenid Pennahia argentata18. This is the only published account of a species of Neoechinorhynchus collected from a sciaenid we could find. Our species differs in having a smaller trunk (19.2 mm in length in N. argentatus), a shorter, narrower proboscis (123 mm in length and 99 mm in width in N. argentatus), and shorter anterior spines on the proboscis (96 mm in length in N. argentatus).
This study documents the occurrence of the genus Neoechinorhynchus in marine waters of Ecuador, specifically as an intestinal parasite of the marine sciaenid M. altipinnis. The characteristics described of the specimens studied, such as the shape and size of the proboscis, the low number and position of the spines on the proboscis, and the form of the body, clearly place this species within the genus Neoechinorhynchus. As far as we can tell, this is the first report of the genus Neoechinorhynchus from marine fishes of Ecuador and from the genus Micropogonias. In addition, we have not found published accounts of the genus Neoechinorhynchus occurring in other New World sciaenids. Other acanthocephalan genera have been reported from the genus Micropogonias and other New World sciaenids4-,6,9,19-21, and there is at least one report of the genus Neoe-chinorhynchus from an Asian sciaenid18. The specimens studied differ morphologically in several respects from species infecting freshwater fishes of South America as discussed above. However, we have not been able to compare our specimens with species of Neoechinorhynchus infecting other South American marine fishes because of the scarcity of information available on the latter. The estuarine habits of M. altipinnis and its ability to tolerate fresh waters may have facilitated its infection with a species of the primarily freshwater genus Neoechinorhynchus.
Presently, there is little known about the life history of this species of Neoechinorhynchus. In this study, the number of acanthocephalans per fish seemed to increase as the size of the fish increased. This finding has been reported previously; for example, Amin22 noted the progressive increase in the number of acanthocephalans of the genus Echinorhynchus in older brown trout and whitefish of North America. Acanthocephalans of the class Eoacanthocephala, to which the genus Neoechinorhynchus belongs, typically use crustaceans as intermediate hosts1. Therefore, we suggest that the intermediate host for this species is also an estuarine-marine crustacean. We found remains of amphipods of the suborder Gammaridea and caridean shrimp of the family Ogyrididae in the digestive tract of one of the fishes dissected; either of these could be the intermediate host for the infective cystacanth stage.
Given that M. altipinnis is common in coastal waters and occasionally consumed as a traditional semi-raw seafood called "cebiche" in Ecuador, there is the possibility that human beings may become infected with this species of Neo-echinorhynchus. Acanthocephalans have been known to infect or potentially infect human beings in other areas23,24, and the genus Neoechinorhynchus has been reported to infect mammals occasionally25.
In the future, larger collections for studies of this species should be made to elucidate if this is a new specie, and to document its abundance and spatio-temporal dynamics in Micropogonias. In addition, surveys of other estuarine sciaenids are warranted as these may also serve as hosts for the same or closely related species of Neoechinorhynchus.
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Acknowledgements: The authors thank Drs. Lorena Manzo and Gustavo Rubio and lab technician Bolivar García for their technical assistance and support during the processing and analysis of sample with SEM. We are in gratitude with Drs. Luigi Martini and Teresa Flor for their lab support to accomplish this research. We wish to express our gratitude to Dr. Gladys de Gonzalez of the shrimp pathology lab AQUALAB for the identification of crustaceans from the digestive tube of M. altipinnis. We also warmly thank Dr. Francisco Hernandez-Chavarría for his valuable insights and suggestions to this manuscript.
Correspondent Address: School of the Environment, University of South Carolina. 901 Sumter Street 702G Byrnes Building, Columbia, SC 29208. USA. E-mail: firstname.lastname@example.org