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Gill parasites of fish from two estuaries in northeastern Brazil: new hosts and geographical records

ABSTRACT

Parasites are important components of communities and constitute great part of the biological diversity found in ecosystems, providing valuable information about their hosts and the environment in which they live. However, despite its importance, parasitic diversity is still not well known in some regions of Brazil, especially with respect to fish parasites in the Northeast Region. The present study aims to perform the survey of gill parasites of fish from two tropical estuaries located in northeastern Brazil: Paraíba and Mamanguape rivers. Two collections were made in each estuary, one during the dry period (November / 2013) and the other during the rainy season (July / 2014). The fish were caught using a beach seine net, dragged along the main channel margin. After the identification, biometry and necropsy of the fish, their parasites were collected, stored and identified. For each species of parasite, the values ​​of prevalence, mean intensity and mean abundance were calculated. Of the 882 examined fish, belonging to four species, 145 were parasitized by at least one species of parasite. In total, 18 taxa of parasites of the groups Monogenea, Digenea, Nematoda, Copepoda and Isopoda were recorded, being the copepod Acusicola brasiliensis the most abundant species of parasite.

Key words:
fish parasites; parasite diversity; ectoparasites; tropical estuaries

INTRODUCTION

Considering the importance of parasites in terms of biomass (Kuris et al. 2008KURIS A ET AL. 2008. Ecosystem energetic implications of parasite and free-living biomass in three estuaries. Nature 454: 515-518. ) and also as determinants of the structure of the animal communities (Minchella and Scott 1991), the identification of these organisms can serve as the basis for a series of investigations, such as parasite-induced pathology (Pavanelli et al. 2002PAVANELLI GC, EIRAS JC AND TAKEMOTO RM. 2002. Doenças de Peixes: Profilaxia, diagonóstico e tratamento. Maringá, Brasil: Eduem, 305 p.), the use of parasites as bioindicators of water quality (Lafferty 1997LAFFERTY KD. 1997. Environmental parasitology: what can parasites tell us about human impact on the environment? Parasitol Today 13: 251-255.), ecological and economic impacts caused by invasive species and their parasites (Torchin et al. 2003), and studies on food webs (Lafferty et al. 2008) among others. Thus, it is necessary to study the parasites of hosts and areas that were not investigated previously.

In estuarine environments, marine water is diluted by freshwater from continental drainage, and these systems may have a free connection to the open ocean (Cameron and Pritchard 1963). The estuarine fish community is represented by resident and migrant, marine and freshwater species, many of which present feeding and / or economic value to fishermen living near the estuary. Fishes use these environments during some stage of the life cycle, such as feeding and breeding areas of larvae and young (Blaber 2000BLABER SJM. 2000. Tropical estuarine fishes: ecology, exploitation and conservation. Queensland, Blackwell Science, 384 p. ) or even during the whole life cycle, in the case of resident species.

In Brazil, the first study on parasitic fish fauna was conducted by the researcher Lauro Travassos at the Oswaldo Cruz Institute, in 1913; since then, the number of studies involving parasite taxonomy and distribution has increased in Brazil (Karling et al. 2014KARLING LC, UEDA BH, TAKEMOTO RM AND PAVANELLI GC. 2014. Scientometric study on the parasitology of freshwater fish in Brazil. Neotrop Helminthol 8: 131-140.). Although several studies have already been carried out on the biota of the estuaries of Mamanguape and Paraíba rivers, Northeast Region of Brazil (Leonel et al. 2002LEONEL R, VEIGA M, GODOY S, LOPES BC AND AVERSARI M. 2002. Distribution of wood-boring bivalves in the Mamanguape River estuary, Paraíba, Brazil. J Mar Biol Assoc UK 82: 1039-1040. , Xavier et al. 2012XAVIER JHA, CORDEIRO CAMM, TENÓRIO GD, DINIZ F, JÚNIOR ENP, ROSA RS AND ROSA IL. 2012. Fish assemblage of the Mamanguape Environmental Protection Area, NE Brazil: abundance, composition and microhabitat availability along the mangrove-reef gradient. Neotrop Ichthyol 10: 109-122., Alves et al. 2016ALVES VEN, PATRÍCIO J, DOLBETH M, PESSANHA A, PALMA ART, DANTAS E AND VENDEL AL. 2016. Do different degrees of human impact affect the diet of Atherinella brasiliensis (Brazilian silverside) in two Brazilian estuaries? J Fish Biol 89: 1239-1257., Nóbrega-Silva et al. 2016, Medeiros et al. 2016MEDEIROS CR, HEPP LH, PATRICIO J AND MOLOZZI J. 2016. Tropical estuarine macrobenthic communities are structured by turnover rather than nestedness. PLoS ONE 11: e0161082. , Dolbeth et al. 2016DOLBETH M, VENDEL AL, PESSANHA A AND PATRICIO J. 2016. Functional diversity of fish communities in two tropical estuaries subject to anthropogenic disturbance. Mar Pollut Bull 112: 244-254), none of them have considered a ubiquitous component of these communities: fish parasites.

The objective of this work was to identify the gill parasites of fish from the estuaries of the Mamanguape and Paraíba do Norte rivers, making new records of localities and hosts for the parasite species.

MATERIALS AND METHODS

STUDY AREAS

Two estuaries were considered in the present study: Paraíba do Norte (PN) (6°54’14” - 7°07’36”S; 34°58’16” - 34°49’31”W) and Mamanguape (MM) (6°43’02” - 6°51’54”S; 35°67’46” - 34°54’04”W) (Figure 1). The regional climate is hot and humid, with air temperature ranging from 25 to 30°C. The rainy season occurs from February to July and the dry season from October to December. Annual rainfall varies between 1750 and 2000 mm annually and the average water temperature ranges from 24 to 26°C (AESA 2010).

Figure 1
Estuaries of the river Paraíba do Norte (PN) (a) and Mamanguape (MM) (b), State of Paraíba, Brazil. Collection points and land use cover.

The distance between the two estuaries is approximately 22 km. The MM is inserted within an Environmental Protection Area. On the other hand, the PN is located near the city of Cabedelo, where there the Cabedelo Port is responsible for a large flow of vessels, and is also close to the city of João Pessoa, capital of the state of Paraíba, whose metropolitan region aggregates five cities and approximately 1,100,000 inhabitants. In this way, the PN suffers more anthropogenic pressures of urban origin, with possible consequences for the aquatic biota.

SAMPLING

In both estuaries, the collections were carried out in November of 2013 (dry season) and in July 2014 (rainy season), locallities indicated in Figure 1. Sampling sites were defined along the estuaries (15 in the PN, 12 in the MM), aiming to capture fish species with different tolerance to salinity, migrants and residents. Fish were collected using three manual trawls (ICMBio License 31000-1) and transported to the laboratory immersed in ice inside thermal boxes. The weight and total length of the fish were recorded and then the individuals were fixed in 10% formalin. Posteriorly, fish were necropsied and their gills were removed and observed under stereomicroscope. The collected parasites were conserved in 70% ethanol. For identification of monegeneans, specimens were stained with Gomori´s trichrome and mounted in slides with Canada balsam, or directly mounted in Hoyer`s medium. Digeneans were stained in acetic carmine and nematodes were clarified in Amman`s Lactophenol, and mounted in permanent slides with Canada balsam. Copepods were mounted in slides with Hoyer’s medium and isopods were observed immersed in 70% ethanol in Petri dishes under the stereomicroscope. Permanent slides were mounted in Canada balsam. Identification was performed according to Travassos et al. (1967TRAVASSOS L, FREITAS JFT AND KOHN A. 1967. Trematódeos do Brasil. Mem I Oswaldo Cruz 67: 1-886.), Amado and Rocha (1996), Moravec (1998MORAVEC F. 1998. Nematodes of Freshwater Fishes of the Neotropical Region. Praga, Academia Praha, 454 p.), Gibson et al. (2002) and Thatcher (2006THATCHER VE. 2006. Amazon fish parasites. Sofia, Pensoft, 508 p.). The values ​​of prevalence, mean intensity and mean abundance were expressed according to Bush et al. (1997BUSH AO, LAFFERTY KD, LOTZ JM AND SHOSTAK AW. 1997. Parasitology meets ecology on its own terms: Margolis et al. Revisited. J Parasitol 83: 575-583. ). Differences on prevalence, mean intensities and mean abundances of parasites between estuaries and seasons were calculated by the Fisher`s exact test (for prevalence) and the Bootstrap test with 1000 replications (for intensity and abundance), using the Quantitative Parasitology web 1.0 software (Rózsa et al. 2000RÓZSA L, REICZIGEL J AND MAJOROS G. 2000. Quantifying parasites in samples of hosts. J Parasitol 86: 228-232.), considering α=0.05. The parasites identified to species level were deposited in the Paulo Young Invertebrate Collection (CIPY), Federal University of Paraíba.

RESULTS AND DISCUSSION

In total, 882 hosts were analyzed from both estuaries, belonging to three species: Anchoa januaria (Steindachner, 1879) (Clupeiformes: Engraulidae) (total=260, PN=111, MM=149), Atherinella brasiliensis (Quoy & Gaimard, 1825) (Atheriniformes: Atherinopsidae) (total=408, PN=224, MM=184) and Mugil curema Valenciennes, 1836 (Mugiliformes: Mugilidae) (total=214, PN=124, MM=90). Total length of examined fish (mean±standard deviation, minimum-maximum): Anchoa januaria (54.6±27.9, 62-88), Atherinella brasiliensis (52.8±28.9, 9-129) and Mugil curema (56.6±32.6, 17-292)

Gill parasites belonging to 18 species of the groups Monogenea, Digenea, Nematoda, Copepoda and Isopoda (Table I) were collected, a total of 1,738 adult specimens. Of the 882 examined fish, belonging to three species, 145 were parasitized by at least one parasite taxa; most of them were Copepoda (N = 1,523), highlighting Acusicola brasiliensis Amado & Rocha, 1996 (N = 929) found in the hosts Atherinella brasiliensis and Anchoa januaria. New geographical records consider the first time the parasite taxa were recorded in northeastern Brazil.

TABLE I
Taxa and catalog numbers of voucher specimens of gill parasites of fish from the estuaries (E) of the rivers Paraíba do Norte (PN) and Mamanguape (MM), in the rainy and dry seasons (S) and respective values of prevalence (P%), mean abundance (MA) and mean intensity (MI) of infection. Letters and symbols indicate new host-parasite record ( nh ),new geographical record ( ng ), and significant differences between estuaries or seasons(*).

It is important to emphasize that most of the analyzed hosts were in the juvenile phase; thus, it is possible that the parasite community has been underestimated, since studies point to the positive correlation between the standard host length and the parasite richness, either due to the increase in the time of exposure of the host to infecting stages, or due to the greater availability of space in larger hosts to be colonized by parasites (Poulin and Morand 2004).

Monogeneans are ectoparasites that often present high host specificity (Goater et al. 2014GOATER TM, GOATER CP AND ESCH GW. 2014. Parasitism: The diversity and ecology of animal parasites. Cambridge, Cambridge University Press, 497 p.). In the present study, these parasites were observed only in the host Mugil curema. Ligophorus mugilinus (= Pseudohaliotrema mugilinus) (Hargis, 1955) is a parasite restricted to hosts of the family Mugilidae and, according to Sarabeev et al. (2005SARABEEV VL, BALBUENA JA AND EUZET L. 2005. Estatuto taxonómico de Ligophorus mugilinus (Hargis, 1955) (Monogenea: Ancyrocephalidae), com uma descrição de uma nova espécie de Ligophorus de Mugil cephalus (Teleostei: Mugilidae) no Mediterrâneo bacia. J Parasitol 91: 1444-1451.), is the only species of Ligophorus that is distributed in European and American waters. There are records of this parasite for M. liza in Brazil (Abdallah et al. 2009ABDALLAH VD, AZEVEDO RK AND LUQUE JL. 2009. Four new species of Ligophorus (Monogenea: Dactylogyridae) parasitic on Mugil liza (Actinopterygii: Mugilidae) from Guandu River, Southeastern Brazil. J Parasitol 95: 855-864.), M. cephalus in Ukraine (Sarabeev et al. 2005) and M. curema in Venezuela (Fuentes and Nasir 1990) and in Caribbean seas-Puerto Rico (Garcia and Williams 1985). This is the first record of L. mugilinus parasitizing M. curema in Brazil.

The adult digenean Parahemiurus merus (Linton 1910) (Hemiuridae) was found on the gills of the host Anchoa januaria. According to Fernandes et al. (2009FERNANDES BMM, ARCI ADN AND COHEN SC. 2009. New data on some species of Monogenea and Digenea parasites of marine fish from the coast of the State of Rio de Janeiro, Brazil. Rev Bras Parasitol Vet 18: 13-18.), this is cosmopolitan parasite species that was recorded parasitizing the digestive tract of 28 species of host (only in South America), including the hosts Anchoa tricolor and Genypterus brasiliensis from Rio de Janeiro, Southeastern Brazil. Another Digenea observed in the present study was Rhipidocotyle sp., parasitizing Atherinella brasiliensis. Parasites of the genus Rhipidocotyle Diesing, 1858 (Bucephalidae) have been recorded in Brazil, in the digestive tract of the hosts Scomber colias Gmelin, 1789, Euthynnus alletteratus (Rafinesque, 1810), Acestrorhynchus lacustris (Lütken, 1875), Scomberomorus maculatus (Mitchill, 1825), Galeocharax humeralis (Valenciennes, 1824), Salminus brasiliensis (Cuvier, 1816), Salminus hilarii Valenciennes, 1850, Auxis thazard (Lacepède, 1800) and Katsuwonus pelamis (Linnaeus, 1758) (Kohn et al. 2007KOHN A, FERNANDES BMM AND COHEN SC. 2007. South American Trematodes Parasites of Fishes. Rio de Janeiro, FIOCRUZ, 318 p.).

The two morphotypes of nematodes parasitizing Atherinella brasiliensis were identified as members of family Pharyngodonidae, by having oral aperture surrounded by four large cephalic papillae and oesophagical bulb. Nematodes of this family parasitizes the posterior gut of mainly lower vertebrates, with few species in mammals (Anderson 2000ANDERSON RC. 2000. Nematode parasites of vertebrates: their development and transmission. 2nd ed., London, CABI, 650 p.). Both morphotypes showed very low infestation values, and for this reason, a more precise identification was not possible due to the lack of available specimens. The low number of adult digeneans and nematodes can be explained by the fact that most of them are not ectoparasites, they were recovered from the gills circumstantially, probably as a consequence of the manipulation of the hosts during fish catching.

Copepods are the most important parasitic crustaceans of fish in the world (Eiras et al. 2016EIRAS JC, VELLOSO AL AND PEREIRA-JR J. 2016. Parasitos de Peixes Marinhos da América do Sul. Rio Grande, Editora da FURG, 441 p.). The copepod Acusicola brasiliensis Amado & Rocha, 1996 (Ergasilidae) has been recorded parasitizing the fish Atherinella brasiliensis, Lile piquitinga and Opisthonema oglinum in the following Brazilian states: Bahia, Espírito Santo, Pará, Paraná and Sergipe (Eiras et al. 2016). Bomolochus xenomelanirisi Carvalho, 1955 (Bomolochidae) was described parasitizing Atherinella brasiliensis in the State of São Paulo. Ergasilus atafonensis Amado & Rocha, 1997 (Ergasilidae) has been described as parasitizing species of the genus Mugil in several Brazilian States (Eiras et al. 2016). The copepods Acusicola brasiliensis and Bomolochus xenomelanirisi parasites of Atherinella brasiliensis and Ergasilus atafonensis, E. bahiensis and E. caragatubensis parasite of M. curema, present previous records from the northeast of Brazil (El-Rashidy and Boxshall 2001, Luque and Tavares 2007, Eiras et al. 2016). Bomolochus nitidus, observed in Mugil curema, had already been recorded in M. cephalus in Arica and Lima, and in M. planatus in Rio de Janeiro (Eiras et al. 2016).

The species diversity of crustaceans parasites of marine fish in South America is about 400 species and 26 families, distributed in a large number of hosts (Eiras et al. 2016EIRAS JC, VELLOSO AL AND PEREIRA-JR J. 2016. Parasitos de Peixes Marinhos da América do Sul. Rio Grande, Editora da FURG, 441 p.). The isopods are the second group of crustaceans with more species of fish parasites (Eiras et al. 2016). They are ectoparasites found on the gills and tegument, being easily visible macroscopically. In the present study, Mothocya nana (Schioedte & Meinert, 1884), M. omidaptria Bruce, 1986 and M. argenosa (Cymothoidae) were observed in Atherinella brasiliensis. Mothocya argenosa has no record of occurrence in Brazil. According to Luque et al. (2013LUQUE JL, VIEIRA FM, TAKEMOTO RM, PAVANELLI GC AND EIRAS JC. 2013. Checklist of Crustacea parasitizing fishes from Brazil. Check List 9: 1449-1470.), Mothocya nana was already observed in the state of Rio de Janeiro, in an unidentified host, and M. omidaptria was already observed in the same State, parasitizing the host Hyporhamphus unifasciatus. Thus, this is the first record of Mothocya nana and M. omidaptria parasitizing Atherinella brasiliensis, as well as the first record of Mothocya argenosa in Brazil. The isopod found parasitizing Anchoa januaria was identified as Artystone sp. by having the prehensile pereopods 1-6 and 7 ambulatory, and differentiated pleon and pleotelson. Specimens of Artystonehave been recorded in freshwater fishes in Brazil. Lironeca sp. was also recorded in the host A. januaria, but in the PN. Isopods of the genus have been recorded parasitizing several species of marine fishes in Brazil, including the northeast region (Luque et al. 2013).

The host species that presented the highest number of parasite taxa were Atherinella brasiliensis and Mugil curema, with seven parasite taxa each. Atherinella brasiliensis also presented the highest number of analyzed hosts. Atherinella brasiliensis is considered estuarine resident and habitually live at the mouth of the rivers (Pessanha et al. 2000PESSANHA ALM, ARAÚJO FG, AZEVEDO MCC AND GOMES ID. 2000. Variações temporais e espaciais na composição e estrutura da comunidade de peixes jovens da baía de Sepetiba, Rio de Janeiro. Rev Bras Zool 17: 251-261., Fávaro et al. 2003FÁVARO LF, LOPES SCG AND SPACH HL. 2003. Reprodução do peixe-rei, Atherinella brasiliensis (Quoy & Gaimard) (Atheriniformes, Atherinidae), em uma planície de maré adjacente à gamboa do Baguaçu, Baía de Paranaguá, Paraná, Brasil. Rev Bras Zool 3: 501-506. ). This characteristic, together with the great diversity of the estuarine ecosystem, possibly favors the acquisition of parasites by the hosts, which remain for longer in this environment rich in infecting stages. On the other hand, the species Mugil curema is distributed among estuaries and shallow coastal marine regions, being considered a catadrome species, as mature individuals migrate to spawn in the ocean (Ibáñez and Gutiérrez-Benítez 2004); In addition, this species exhibits schooling behavior (Carvalho et al. 2007CARVALHO CD, CORNETA CM AND UIEDA VS. 2007. Schooling behavior of Mugil curema (Perciformes: Mugilidae) in an estuary in southeastern Brazil. Neotrop Ichthyol 5: 81-83.). Considering all the parasites found in M. curema are monoxenic (they do not require intermediate hosts to complete their cycle), it is possible that the schooling behavior has favored the infestation of these hosts by the recorded parasites.

Regarding differences between the studied estuaries, ten taxa of parasites were recorded in both estuaries, five only in the PN and three only in the MM. Three out of the ten taxa recorded in both estuaries presented significant differences in parasitism indexes: P. merus showed higher values of prevalence, mean intensity and mean abundance in the MM; Ergasilus sp. and E. atafonensis showed higher values of prevalence in the PN. The digenean Parahemiurus merus is a typical gastrointestinal parasite, and its presence on the gills was considered accidental, as previously discussed; thus, its prevalence reported in the present study does not reflect its actual prevalence in the sample, since only the gills of the hosts were examined for parasites. The highest prevalence of Ergasilus sp. and Ergasilus atafonensis in the PN may be related to local features of the hosts and/or environmental factors; the PN is an estuary under strong anthropogenic pressure, while the MM is located inside a protected area. The increased prevalence of parasitic copepods on mugilid fishes from anthropogenically impacted coastal marine systems was reported by Dzikowski et al. (2003DZIKOWSKI R, PAPERNA I AND DIAMANT A. 2003. Use of fish parasite species richness indices in analyzing anthropogenically impacted coastal marine ecosystems. Helgol Mar Res 57: 220-227), and the authors stated that monoxenous parasites appear to be more adapted to survival in some polluted habitats, and the copepod populations may have been enhanced by possible immune suppression of the fish. All the species found in only one of the two studied estuaries presented low values of prevalence (≤4%) and mean abundance (<1); therefore, it is possible that they could be recorded in the other estuary using greater sampling effort.

Five parasite taxa were observed in the rainy and dry seasons, and three of them presented significant differences between seasons. Acusicola brasiliensis showed higher values of prevalence and mean abundance in the rainy season for the host Atherinella brasiliensis, and in the dry season for the host A. januaria. Parahemiurus merus also presented higher prevalence and abundance in the dry season. Six taxa were observed only in the dry season, and five only in the rainy season. Differences between seasons could be explained by fluctuations on the availability of suitable hosts during different seasons, considering that the abundance and the diversity of fishes are higher in the rainy season in the MM (Xavier et al. 2012XAVIER JHA, CORDEIRO CAMM, TENÓRIO GD, DINIZ F, JÚNIOR ENP, ROSA RS AND ROSA IL. 2012. Fish assemblage of the Mamanguape Environmental Protection Area, NE Brazil: abundance, composition and microhabitat availability along the mangrove-reef gradient. Neotrop Ichthyol 10: 109-122.).

In conclusion, the present study constitutes the first study on the parasites of fish in estuaries in the Paraíba State, showing new geographical records and hosts for these environments and the Northeast region. This is an important contribution to the knowledge of the local parasite diversity, serving as a basis for future studies that seek to correlate the parasites to the conditions of their hosts, as well as the environmental conditions in which they are inserted.

ACKNOWLEDGMENTS

The authors thank the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) for the financing of the PVE/CAPES project (Process 173/2012): “What lessons can be learned from ecological functioning in the estuarine systems of the state of Paraiba? An analysis of the effect of natural and anthropogenic disturbances” and the Science without Borders Program (Special Visiting Researcher). CAPES also funded J. Golzio through a master scholarship. The Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) funded J. Falkenberg and A. Coutinho through an undergraduate scholarship (Scientific Initiation). Thanks also to Saulo Vital for the map.

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Publication Dates

  • Publication in this collection
    20 July 2017
  • Date of issue
    2017

History

  • Received
    16 Dec 2016
  • Accepted
    08 Mar 2017
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