Nematodes as indicators of environmental changes in a river with different levels of anthropogenic impact

LEHUN, ATSLER LUANA; DUARTE, GISELE S.C.; TAKEMOTO, RICARDO M.

doi:10.1590/0001-3765202320200307

Abstract

Considering that changes in the biodiversity of parasite communities can be used as indicators of ecosystem health, the aim of this study was to investigate the potential use of Geophagus brasiliensis parasites as bioindicators of environmental changes. We established three sample points in the Iguaçu River, each presenting different degrees of environmental impact. Out of the 69 G. brasiliensis specimens analyzed, 32 (46.3%) were parasitized by at least one parasite. We collected a total of 56 specimens of endoparasites belonging to the phylum Nematoda. Fishes collected in point 3 presented a significantly higher abundance of nematode species (moderately degraded) (Kruskal-Wallis₂;₆₉ = 8.62; p = 0.01) and species compositions between points were significantly different (F = 6.95, p = 0.002). No significant difference in relative condition factor (Kn) among the points (F₂;₆₆ = 2.54; p = 0.08) or correlation in Kn and abundance of nematodes (rs = 0.1; p = 0.4) were indicated. The results presented in this study indicate that the parasitic community of G. brasiliensis is characterized by low diversity in polluted locations, which explains the absence of certain parasite species and the occurrence of nematode species with varied responses to the pollution gradient.

Key words
ecotoxicology; freshwater; parasites; fish

INTRODUCTION

In the context of the serious, growing problem of pollution of aquatic ecosystems (Dalzochio et al. 2016DALZOCHIO T, RODRIGUES GZP, PETRY IE, GEHLEN G & DA SILVA LB. 2016. The use of biomarkers to assess the health of aquatic ecosystems in Brazil: a review. Int Aqua Res 8: 283-298.), urbanization, industrialization, disordered use of fertilizers, pesticides and the transport of allochthonous substances to rivers are anthropic actions that contribute to higher pollution and degradation of water quality in aquatic ecosystems (Silva-Souza et al. 2006SILVA-SOUZA AT, SHIBATTA OA, MATSUMURA-TUNDISI T, TUNDISI JG & DUPAS FA. 2006. Parasitas de peixes como indicadores de estresse ambiental e eutrofização. In: Tundisi JG, Matsumura-Tundisi T & Sidagis Galli C (Eds), Eutrofização na América do Sul: causas, tecnologias de gerenciamento e controle. São Carlos: IIE, p. 373-386., Silva et al. 2022SILVA JVF, LANSAC-TÔHA FM, SEGOVIA BT, AMADEO FE, BRAGHIN LDSM, VELHO LFM, SARMENTO H & BONECKER CC. 2022. Experimental evaluation of microplastic consumption by using a size-fractionation approach in the planktonic communities. Sci Total Environ 821: 153045.). In natural systems affected by such disturbance, the intensity of the impacts is directly proportional to the degree of diversity of the environment and the vulnerability of the species involved (Bastos & Abilhoa 2004BASTOS LP & ABILHOA V. 2004. A utilização do índice de integridade biótica para avaliação da qualidade de água: um estudo de caso para riachos urbanos da bacia hidrográfica do rio Belém, Curitiba, Paraná. Rev Est Biol 26: 33-44., Alimba & Bakare 2016ALIMBA CG & BAKARE AA. 2016. In vivo micronucleus test in the assessment of cytogenotoxicity of landfill leachates in three animal models from various ecological habitats. Ecotoxicol 25: 310-319.).

Aquatic organisms are often exposed to a variety of natural and artificial environmental stressors, such as variations and/or changes in physical and chemical parameters, alterations in diet and habitat availability (Adams & Greeley 2000ADAMS SM & GREELEY MS. 2000. Ecotoxicological indicators of water quality: using multi-response indicators to assess the health of aquatic ecosystems. Water Air Soil Pollut 123: 103-115., Reid et al. 20REID AJ ET AL. 2019. Emerging threats and persistent conservation challenges for freshwater biodiversity. Biol Rev 94: 849-873.). Therefore, pollution, as well as the stress suffered by the aquatic environment, reflects directly in organisms, populations, communities, and food chain structure (Tundisi & Tundisi 2008TUNDISI JG & TUNDISI MT. 2008. Limnologia, São Paulo: Oficina de Textos, 631 p.). In this sense, the use of fish parasites as indicators of environmental changes or disturbances allows to assess the effect of stressors on hosts and aquatic ecosystems (Marcogliese 2005MARCOGLIESE DJ. 2005. Parasites of the superorganism: are they indicators of ecosystem health? Int J Parasitol 35: 705-716., Madi & Ueta 2009MADI RR & UETA MT. 2009. O papel de Ancyrocephalinae (Monogenea: Dactylogyridae), parasita de Geophagus brasiliensis (Pisces: Cichlidae), como indicador ambiental. Rev Bras Parasitol V 18: 38-41., Timi & Poulin 2020TIMI JT & POULIN R. 2020. Why ignoring parasites in fish ecology is a mistake. Int J Parasitol 50: 755-761.).

Studies have demonstrated the close relationship between parasitism and ecological conditions in a given environment for reflecting environmental impacts through their responses to changes in populational structure, such as changes in prevalence and intensity. In addition, their occurrence or abundance can describe the situation of the environment (Vidal-Martínez et al. 2010VIDAL-MARTÍNEZ VM, PECH D, SURES B, PURUCKER T & POULIN R. 2010. Can parasites really reveal environmental impact? Trends Parasitol 26: 44-51., Madi & Ueta 2012MADI RR & UETA MT. 2012. Parasitas de peixes como indicadores ambientais. In: Silva-Souza AT, Lizama MAP & Takemoto RM (Eds), Patologia e Sanidade de Organismos Aquáticos, Maringá: Massoni, p. 33-58., Vidal-Martínez & Wunderlich 2017VIDAL-MARTÍNEZ VM & WUNDERLICH AC. 2017. Parasites as bioindicators of environmental degradation in Latin America: a meta-analysis. J Helminthol 91: 165-173., Negreiros et al. 2018NEGREIROS LP, PEREIRA FB, TAVARES-DIAS M & TAVARES LE. 2018. Community structure of metazoan parasites from Pimelodus blochii in two rivers of the Western Brazilian Amazon: same seasonal traits, but different anthropogenic impacts. Parasitol Res 117: 3791-3798.). Some groups of parasites are more sensitive to environmental disturbances than host species, which makes them efficient indicators for various contaminants and anthropic changes (Marcogliese 2005MARCOGLIESE DJ. 2005. Parasites of the superorganism: are they indicators of ecosystem health? Int J Parasitol 35: 705-716., Duarte et al. 2020DUARTE GSC, LEHUN AL, LEITE LAR, CONSOLIN-FILHO N, BELLAY S & TAKEMOTO RM. 2020. Acanthocephalans parasites of two Characiformes fishes as bioindicators of cadmium contamination in two neotropical rivers in Brazil. Sci Total Environ 738: 140339.).

Responses from hosts and parasitic communities vary according to the type and intensity of the stressor, parasite life cycle, and time of exposure, however, in general, pollution and stress are often associated with lower parasite species richness (Marcogliese 2004MARCOGLIESE DJ. 2004. Parasites: small players with crucial roles in the ecological theater. EcoHealth 1: 151-164., Falkenberg et al. 2019FALKENBERG JM, GOLZIO JES, PESSANHA A, PATRÍCIO J, VENDEL AL & LACERDA AC. 2019. Gill parasites of fish and their relation to host and environmental factors in two estuaries in northeastern Brazil. Aquat Ecol 53: 109-118.). Parasite life cycle can include a definitive host and several intermediate hosts, and for the parasite to survive, all hosts must co-occur in a stable community structure (Marcogliese & Cone 1997MARCOGLIESE DJ & CONE DK. 1997. Parasite communities as indicators of ecosystem stress. Parassitologia 39: 227-232.). Changes in environmental conditions affect hosts, either directly or indirectly, and have a significant effect on the prevalence and intensity of infection and diversity of parasites present in fish (Marcogliese & Cone 1997MARCOGLIESE DJ & CONE DK. 1997. Parasite communities as indicators of ecosystem stress. Parassitologia 39: 227-232., MacKenzie 1999MACKENZIE K. 1999. Parasites as pollution indicators in marine ecosystems: a proposed early warning system. Mar Pollut Bull 38: 955-959.). Therefore, such diversity of endoparasites can decrease since the stages of free living can be directly affected or certain intermediate hosts can be reduced, hampering the transmission of the parasite (MacKenzie 1999MACKENZIE K. 1999. Parasites as pollution indicators in marine ecosystems: a proposed early warning system. Mar Pollut Bull 38: 955-959.).

The endoparasitic fauna of Geophagus brasiliensis (Quoy & Gaimard 1824) includes digeneans, nematodes, and acanthocephalans (Fernandes & Kohn 2001FERNANDES BMM & KOHN A. 2001. On some trematodes parasites of fishes from Paraná river. Braz J Biol 61: 461-466., Azevedo et al. 2006, Bellay et al. 2008BELLAY S, TAKEMOTO RM, YAMADA FH & PAVANELLI GC. 2008. A new species of Sciadicleithrum (Monogenea: Ancyrocephalinae), gill parasite of Geophagus brasiliensis (Quoy and Gaimard) (Teleostei: Cichlidae) from reservoirs in the State of Paraná, Brazil. Zootaxa 1700: 63-68., 2012BELLAY S, UEDA BH, TAKEMOTO RM, LIZAMA MDLAP & PAVANELLI GC. 2012. Fauna parasitária de Geophagus brasiliensis (Perciformes: Cichlidae) em reservatórios do estado do Paraná, Brasil. Rev Bras Biocienc 10: 74-78., Carvalho et al. 2010CARVALHO AR, TAVARES LER & LUQUE JL. 2010. Variação sazonal dos metazoários parasitos de Geophagus brasiliensis (Perciformes: Cichlidae) no rio Guandu, Estado do Rio de Janeiro, Brasil. Acta Sci Biol Sci 32: 159-167.). Since parasites indicate environmental contaminants, their presence is an indication of environmental quality (Chubb 1980, 1982, Overstreet 1997OVERSTREET RM. 1997. Parasitological data as monitors of environmental health. Parasitologia 39: 169-175.). Good indicators can be exceptionally sensitive to pollution, and significant changes in the number of individuals in the populations can be considered an alert of changes in environmental conditions (Mackenzie et al. 1995MACKENZIE K, WILLIAMS HH, WILLIAMS B, MCVICAR AH & SIDDALL R. 1995. Parasites as indicators of water quality and the potential use of helminth transmission in marine pollution studies. Adv Parasit 35: 85-144., Sures & Streit 2001SURES B & STREIT B. 2001. Eel parasite diversity and intermediate host abundance in the River Rhine, Germany. Parasitol 123: 185-191.).

Considering the increasing urbanization and the presence or absence of these parasites, this study aimed at investigating the potential use of parasites of G. brasiliensis as indicators of environmental changes in a pollution gradient for the Iguaçu River.

MATERIALS AND METHODS

Sampling area

Iguaçu River basin is located mostly in the southern portion of the state of Paraná, Brazil, and presents geomorphological characteristics related to its hydrography. Thus, rivers and waterfalls influence its geographic distribution of species, and Iguazu falls act as an important geographical barrier generating a high endemism degree for ichthyofauna (Zawadzki et al. 1999ZAWADZKI CH, RENESTO E & BINI LM. 1999. Genetic and morphometric analysis of three species of the genus Hypostomus Lacépède, 1803 (Osteichthyes: Loricariidae) from the Iguaçu basin (Brazil). Rev Suisse Zool 106: 91-105., Baumgartner et al. 2012BAUMGARTNER G, PAVANELLI CS, BAUMGARTNER D, BIFI AG, DEBONA & FRANA VA. 2012. Peixes do baixo rio Iguaçu, Maringá: Eduem, 225 p.). However, due to the influence of several anthropic factors, such as the construction of hydroelectric plants, pollution, and species introduction, the risk of extinction of these fish species has increased significantly (Daga & Gubiani 2012DAGA VS & GUBIANI ÉA. 2012. Variations in the endemic fish assemblage of a global freshwater ecoregion: associations with introduced species in cascading reservoirs. Acta Oecol 41: 95-105.). Currently, Iguaçu River is considered the second most polluted river in Brazil because of massive load of pollutants released at the source of the river, resulting from the anthropic activity in the Metropolitan Region of Curitiba (IBGE 2010IBGE. 2010. IBGE, Censo 2010. Available in: http://www.censo2010.ibge.gov.br/.
http://www.censo2010.ibge.gov.br/... ).

We established three sampling points along the Iguaçu River (Figure 1). The first point is located in the upper Iguaçu (25°36’17.1”S 49°30’35.9”W), in the metropolitan region of Curitiba and Araucária and characterized by large population concentration, industrial, commercial and service activities, classified by the responsible environmental agency as critically degraded to polluted (Superintendência de Desenvolvimento e Recursos Hídricos e Saneamento Ambiental 1997SUPERINTENDÊNCIA DE DESENVOLVIMENTO DE RECURSOS HÍDRICOS E SANEAMENTO AMBIENTAL. 1997. Qualidade das águas interiores do Estado do Paraná. 1987-1995, Curitiba: SUDERHSA, 257 p., Carneiro et al. 2014CARNEIRO C, ANDREOLI CV, DA NOBREGA CUNHA CDL & GOBBI EF. 2014. Reservoir eutrophication: Preventive management, IWA Publishing, 480 p., IAP 2017IAP - INSTITUTO AMBIENTAL DO PARANÁ. 2017. Qualidade das Águas – Reservatórios do Estado do Paraná de 2017, 219 p. Ed. Fundamento, Brasil. (in Portuguese). Available in: http://www.iap.pr.gov.br/arquivos/File/Qualidade_das_aguas/RElatoriofinal.pdf.
http://www.iap.pr.gov.br/arquivos/File/Q... ). Despite the degraded condition reported by the Instituto Ambiental do Paraná (2017), its water supplies the population of the city of Curitiba and its metropolitan region.

Figure 1
Map of the location of the Iguaçu River and the three sampling points. (Jaime Luiz Lopes Pereira - Nupélia/UEM).

The second point is situated in the region of the middle Iguaçu (26°15’02.1”S 51°06’13.4”W), where agriculture predominates and the classification is moderately degraded (Superintendência de Desenvolvimento e Recursos Hídricos e Saneamento Ambiental 1997, IAP 2017IAP - INSTITUTO AMBIENTAL DO PARANÁ. 2017. Qualidade das Águas – Reservatórios do Estado do Paraná de 2017, 219 p. Ed. Fundamento, Brasil. (in Portuguese). Available in: http://www.iap.pr.gov.br/arquivos/File/Qualidade_das_aguas/RElatoriofinal.pdf.
http://www.iap.pr.gov.br/arquivos/File/Q... ). The third point is located in the region of the lower Iguaçu (26°02’51.9”S 51°36’04.1”W) and characterized by the beginning of the cascade of reservoirs in the river and use of water for public supply to cities. It is categorized as moderately degraded (Baumgartner et al. 2012BAUMGARTNER G, PAVANELLI CS, BAUMGARTNER D, BIFI AG, DEBONA & FRANA VA. 2012. Peixes do baixo rio Iguaçu, Maringá: Eduem, 225 p., IAP 2017IAP - INSTITUTO AMBIENTAL DO PARANÁ. 2017. Qualidade das Águas – Reservatórios do Estado do Paraná de 2017, 219 p. Ed. Fundamento, Brasil. (in Portuguese). Available in: http://www.iap.pr.gov.br/arquivos/File/Qualidade_das_aguas/RElatoriofinal.pdf.
http://www.iap.pr.gov.br/arquivos/File/Q... ).

We collected specimens of G. brasiliensis in January 2019 by measuring the following limnological variables of water: pH, conductivity, temperature, and dissolved oxygen. Water samples were also collected and quantification of total phosphorus was carried out at the Basic Limnology laboratory of the Universidade Estadual de Maringá. The collections had been authorized by Ibama (SISBIO/64382-4) and Ethics Committee (CEUA Nº 2887071118).

Collection, fixation, and conservation of endoparasites

After collecting the fish, we conducted the taxonomic identification and determination of host biometric, followed by a longitudinal incision on the ventral surface of each fish, as well as removal and separation of all organs. The visceral cavity and each organ were examined under a stereomicroscope to collect endoparasites. The methodology for setting endoparasites differed according to the parasite group, following the recommendations of Eiras et al. (2006)EIRAS JC, TAKEMOTO RM & PAVANELLI GC. 2006. Métodos de estudo e técnicas laboratoriais em parasitologia de peixes, 2ª ed., Maringá: Eduem, 199 p.. Species of endoparasites were identified according Moravec (1998)MORAVEC F. 1998. Nematodes of freshwater fishes of the Neotropical Region, Czech Republic: Academia, Praha, 464 p., Vicente & Pinto (1999)VICENTE JJ & PINTO RM. 1999. Nematóides do Brasil. Nematóides de peixes. Atualização: 1985-1998. Rev Bras Zool 16: 561-610., and Thatcher (2006)THATCHER VE. 2006. Amazon fish parasites. Vol. 1. Pensoft Publishers..

Statistical analysis

To describe the structure and quantitative analysis of the parasites found, we used the parasitic indices described by Bush et al. (1997)BUSH AO, LAFFERTY KD, LOTZ JM & SHOSTAK AW. 1997. Parasitology meets ecology on its own terms: Margolis et al. revisited. J Parasitol 83: 575-583.. Five descriptors based on the structure of the infracommunities were calculated: (1) abundance, (2) richness, (3) diversity, representing the average of the diversity of infracommunities in each fish calculated through Brillouin index, (4) equitability, representing the average species equitability in each fish, and (5) Simpson’s dominance. We performed a non-parametric analysis of variance (Kruskal-Wallis) to verify significant differences in the abundance of parasites among the sampling points.

A (dis)similarity in parasites species composition appeared between the sampling points through a Principal Coordinate Analysis (PCoA) (Legendre & Legendre 1998LEGENDRE P & LEGENDRE L. 1998. Numerical ecology. Amsterdam: Elsevier Science.) using a presence/absence matrix and the Jaccard index. A Multivariate Permutational Variance Analysis (PERMANOVA) assessed changes in parasites species composition according to the sampling point (Anderson 2005ANDERSON MJ. 2005. PERMANOVA: a FORTRAN computer program for permutational multivariate analysis of variance. Department of Statistics, University of Auckland.). We carried out 999 permutations to verify significance and applied a pair-wise PERMANOVA to assess significant differences between the sampling points.

The values of standard length (Ls) and weight (Wt) of each host were fitted to the curve of the Wt/Ls ratio (Wt = a.Lt^b) and the values of the regression coefficients a and b were estimated. The values of a and b were used to estimate the expected weight values (We) using the following equation: We = a.Lt^b. Therefore, we calculated the relative condition factor (Kn), which corresponds to the quotient between observed weight and expected weight for a given length (Kn = Wt/We) (Le Cren 1951LE CREN ED. 1951. The length-weight relationship and seasonal cycle in gonadal weight and condition in the perch (Perca fluviatilis). J Anim Ecol 20: 201-219.).

We conducted an analysis of variance (ANOVA) to assess the differences between the relative condition factor of the hosts between the points. Spearman’s rank correlation coefficients (rs) were calculated to determine possible association between the relative condition factor (Kn) of hosts and the abundance of infection for the hosts (Zar 2010ZAR JH. 2010. Biostatistical analysis, New Jersey: Prentice Hall, 944 p.).

Statistical analyses were performed using the R 3.2.4 software (R Development Core Team 2020R DEVELOPMENT CORE TEAM. 2020. R: a language and environment for statistical computing [online]. Vienna: R Foundation for Statistical Computing, 2013.) on the vegan (Oksanen et al. 2020OKSANEN J, BLANCHET FG, KINDT R, LEGENDRE P, O’HARA RB, SIMPSON GL, STEVENS MHH & WAGNER H. 2020. Vegan: Community Ecology Package. R Package, Version 2, p. 3-4, http://cran.r-project.org/web/packages/vegan.
http://cran.r-project.org/web/packages/v... ) and barter (Simpson 2018SIMPSON GL. 2018. Permute: functions for generating restricted permutations of data. R Package 0.9-4.) packages for PCoA and according to the “adonis2” function of the vegan package (Oksanen et al. 2016) for PERMANOVA. The level of statistical significance adopted was p ≤ 0.05.

RESULTS

Table I presents the values for water quality parameters measured in the field and in the laboratory.

Thumbnail

Table I
Mean values of abiotic variables and nutrient concentration in water samples from the Iguaçu River, Paraná.

We collected 69 specimens of G. brasiliensis from the Iguaçu River: 20 at point 1, 24 at point 2, and 25 at point 3. The average fish length was 12.5 ± 3.35 cm (8.2–33.1 cm) and average weight was 41.37 ± 38.95 g (11.5–301.3 g). Among the fish examined, 32 (46.3%) were parasitized by at least one parasite species of parasite, with a total of 56 specimens of endoparasites belonging to the phylum Nematoda. The fish from point 3 had a higher prevalence of infection (Table II). Table II indicates the parasite species, sites of infection/infestation, and respective parasitological indices.

Thumbnail

Table II
Species of parasites, sites of infestation/infection, point of collection and their parasitological indices found in the host Geophagus brasiliensis in the Iguaçu River, Paraná.

The values of the infracommunity descriptors were similar for points 2 and 3 (Table III). The abundance and richness of nematode species were slightly higher in fish collected in point 3. Point 1 showed the highest values for the indices (diversity and equitability), but its abundance was lower comparing with points 2 and 3.

Thumbnail

Table III
Attributes of the parasites infracommunities of Geophagus brasiliensis.

A comparison of the abundance of nematode species revealed a significant difference between the sampling points (Kruskal-Wallis₂;₆₉ = 8.62; p = 0.01) (Figure 2), swith points 2 and 3 presenting the highest mean abundance in relation to point 1.

Figure 2
Mean values of nematode abundance in Geophagus brasiliensis between the sampling points of the Iguaçu River, Paraná.

The result of the Principal Coordinates Analysis (PCoA) applied to assess the (dis)similarity between sampling points (Figure 3) pointed out to significant differences in species composition (F = 6.95, p = 0.002). The pairwise PERMANOVA showed distinct nematode species compositions between point 1 and points 2 and 3 (Table IV).

Figure 3
Principal Coordinates Analysis (PCoA), showing the variability in the composition of nematode species in Geophagus brasiliensis between the sampling points of the Iguaçu River, Paraná. Some points are overlapping, as the values of the scores are the same.

Thumbnail

Table IV
PERMANOVA pairwise to compare the composition of nematodes between the sampling points. In bold: significant value (p <0.05).

The relative condition factor of the hosts demonstrated that the Kn values did not differ between the sampling points (F₂;₆₆ = 2.54; p = 0.08), but when analyzed separately, points 2 and 3 had a higher average comparing with point 1 (Figure 4).

Figure 4
Mean values of the relative condition factor (Kn) of Geophagus brasiliensis between the sampling points of the Iguaçu River, Paraná.

When verifying the correlation between relative condition factor (Kn) and abundance of nematode infestation for the hosts, the results did not indicate any significant correlation (rs = 0.102; p = 0.402) (Figure 5).

Figure 5
Correlation between the relative condition factor (Kn) and the abundance of nematodes in Geophagus brasiliensis.

DISCUSSION

The results obtained in this study indicate that the parasitic community of G. brasiliensis is characterized by the absence of certain species of parasites registered for this host in Iguaçu River. The abundance of nematode species showed varied responses to the pollution gradient, with the lowest abundance for point 1 (critically degraded to polluted), and the highest abundance for point 3 (moderately degraded).

Water quality parameters, such as temperature, pH, and dissolved oxygen, did not vary in values between the sampling points; however, for point 1, the electrical conductivity and phosphorus showed relatively high values comparing with points 2 and 3. These results indicate that altered parameters of water quality may be related to the large supply of organic waste and domestic and industrial sewage released in the region (Carneiro et al. 2014CARNEIRO C, ANDREOLI CV, DA NOBREGA CUNHA CDL & GOBBI EF. 2014. Reservoir eutrophication: Preventive management, IWA Publishing, 480 p., Mizukawa et al. 2017MIZUKAWA A, MOLINS-DELGADO D, DE AZEVEDO JCR, FERNANDES CVS, DÍAZ-CRUZ S & BARCELÓ D. 2017. Sediments as a sink for UV filters and benzotriazoles: the case study of Upper Iguaçu watershed, Curitiba (Brazil). Environ Sci Pollut Res 24: 18284-18294., De Andrade Brito et al. 2018DE ANDRADE BRITO I, GARCIA JRE, SALAROLI AB, FIGUEIRA RCL, DE CASTRO MARTINS C, NETO AC, GUSSO-CHOUERI PK, CHOUERI RB, ARAUJO SBL & DE OLIVEIRA RIBEIRO CA. 2018. Embryo toxicity assay in the fish species Rhamdia quelen (Teleostei, Heptapteridae) to assess water quality in the Upper Iguaçu basin (Parana, Brazil). Chemosphere 208: 207-218., Lehun et al. 2021LEHUN AL, MENDES AB, TAKEMOTO RM & BUENO KRAWCZYK ACDD. 2021. Genotoxic effects of urban pollution in the Iguaçu River on two fish populations. J Environ Sci Health A 56: 984-991.).

Electrical conductivity measurements can be used as a proxy to identify wastes as pollution (Ouedraogo et al. 2016OUEDRAOGO I, DEFOURNY P & VANCLOOSTER M. 2016. Mapping the groundwater vulnerability for pollution at the pan African scale. Sci Total Environ 544: 939-953.) for its close relationship with the content of dissolved salts present in the water column, which is generally associated with organic matter supply, thus representing a well-established water quality parameter (Thompson et al. 2010THOMPSON MY, BRANDES D & KNEY AD. 2010. Using electronic conductivity and hardness data for rapid assessment of stream water quality. In: World Environmental and Water Resources Congress 2010: Challenges of Change, p. 3356-3365., Chalupová et al. 2012CHALUPOVÁ D, HAVLÍKOVÁ P & JANSKÝ B. 2012. Water quality of selected fluvial lakes in the context of the Elbe River pollution and anthropogenic activities in the floodplain. Environ Monit Assess 184: 6283-6295.). High conductivity values are associated with high contamination risks (Rahman 2008RAHMAN A. 2008. A GIS based DRASTIC model for assessing groundwater vulnerability in shallow aquifer in Aligarh, India. Appl Geogr 28: 32-53.), therefore, rivers contaminated by industrial and domestic effluents have higher values of electrical conductivity, the case of point 1 in this study. In turn, environments with low amount of particles in suspension generally have low values of electrical conductivity, as observed for points 2 and 3.

Freshwater ecosystems receive phosphorus leached from the earth and anthropic discharges (Smil 2000SMIL V. 2000. Phosphorus in the environment: natural flows and human interferences. Annu Rev Energ Env 25: 53-88., Vitousek et al. 2010VITOUSEK PM, PORDER S, HOULTON BZ & CHADWICK OA. 2010. Terrestrial phosphorus limitation: mechanisms, implications, and nitrogen–phosphorus interactions. Ecol Applic 20: 5-15.), consequently generating high levels of phosphates to cause eutrophication (Esteves 2011ESTEVES FA. 2011. Fundamentos de Limnologia, 3ª ed., Rio de Janeiro: Interciência, 790 p.). The factor of eutrophication has been found to influence the composition of parasite species in fish (Valtonen et al. 1997VALTONEN ET, HOLMES JC & KOSKIVAARA M. 1997. Eutrophication, pollution and fragmentation: effects on parasite communities in roach (Rutilus rutilus) and perch (Perca fluviatilis) in four lakes in central Finland. Can J Fish Aquat Sci 54: 572-585., Zagar et al. 2012ZARGAR UR, CHISHTI MZ, YOUSUF AR & FAYAZ A. 2012. Infection level of monogenean gill parasite, Diplozoon kashmirensis (Monogenea, Polyopisthocotylea) in the Crucian Carp, Carassius carassius from lake ecosystems of an altered water quality: What factors do have an impact on the Diplozoon infection? Vet Parasitol 189: 218-226.) and can increase or decrease the properties of the infection depending on the parasite and the taxon life history. This means that it depends on the presence, absence, and density of intermediate and definitive hosts, as well as the sensitivity of both hosts and parasites to environmental changes (Sures 2004SURES B. 2004. Environmental parasitology: relevancy of parasites in monitoring environmental pollution. Trends Parasitol 20: 170-177.).

Environments that were altered by pollution, as demonstrated in the phosphorus concentration and high level of conductivity, can present changes in the community structure and abundance of species in response to environmental and pollutant conditions. Environmental changes affect parasites in different manners: pollution can increase parasitism as contaminants can act as immunosuppressants of the host’s immune system, or can be fatal to certain species, especially with parasites from complex life cycles, leading to lower parasitism (Lafferty & Kuris 2005LAFFERTY KD & KURIS AM. 2005. Parasitism and environmental disturbances. In: Thomas RF, Thomas F, Guégan JF, Renaud F, Renaud RF, Guegan JF & Gan JFOG (Eds), Parasitism and ecosystems, Oxford University Press on Demand, p. 113-123.). Generally, infections by ectoparasites tend to increase, while infections by endoparasites tend to decrease with higher levels of pollution (Lafferty 1997LAFFERTY KD. 1997. Environmental parasitology: what can parasites tell us about human impacts on the environment?. Parasitol Today 13: 251-255., Sures 2005SURES B. 2005. Effects of pollution on parasites, and use of parasites in pollution monitoring. Mar Parasitol 421-425., Gilbert & Avenant-Oldewage 2021GILBERT BM & AVENANT-OLDEWAGE A. 2021. Monogeneans as bioindicators: A meta-analysis of effect size of contaminant exposure toward Monogenea (Platyhelminthes). Ecol Indic 130:108062.).

The sampling points showed similar values of richness, diversity, and equitability, however, the abundance of species was relatively higher in points 2 and 3. The species of nematodes found in this study had been registered for this host in Iguaçu River, but due to the absence of species from other groups (for example, digeneans, and acanthocephalans), a low diversity of parasite species was recorded. The low values of diversity can be explained by the dominance of the larvae Contracaecum sp. at point 1 and the adult Procamallanus (Procamallanus) peraccuratus at points 2 and 3. In fact, the dominance of these species may be the most appropriate way to infer the possible effects of anthropogenic stress because of their higher infectious potential (in terms of prevalence), but it also suggests that in terms of population structure, they can change according to the environment.

The prevalence of larvae Contracaecum sp. in point 1 and the use of fish as intermediate host indicate that environmental conditions are somehow adequate to complete their life cycle through planktonic copepods and piscivorous birds (Szalai & Dick 1990SZALAI AJ & DICK TA. 1990. Proteocephalus ambloplitis and Contracaecum sp. from largemouth bass (Micropterus salmoides) stocked into Boundary Reservoir, Saskatchewan. J Parasitol 76: 598-601.). However, the record of low abundance suggests that levels of pollution or anthropogenic stress occurring in the location could have had negative impacts on its intermediate hosts, thus reducing the nematode infectious potential (Fajer-Ávila et al. 2006FAJER-ÁVILA EJ, GARCÍA-VÁSQUEZ A, PLASCENCIA-GONZÁLEZ H, RÍOS-SICAIROS J, GARCÍA-DE LA PARRA LM & BETANCOURT-LOZANO M. 2006. Copepods and larvae of nematodes parasiting the white mullet Mugil curema (Valenciennes, 1836): Indicators of anthropogenic impacts in tropical coastal lagoons? Environ Monit Assess 122: 221-237.).

Among other factors, the diversity of parasites results from interactions between the evolutionary history and ecology of hosts, also associated with the diversity of intermediate and definitive hosts (Von Zuben 1997VON ZUBEN CJ. 1997. Implicações da agregação espacial de parasitas para a dinâmica populacional na interação hospedeiro-parasita. Rev Saúde Púb 31: 523-530.). Thus, the low abundance of adult nematode species in point 1 can be explained by the absence of possible intermediate hosts, indicating that the environment directly affects the life cycle of these parasites. Landsberg et al. (1998)LANDSBERG JH, BLAKESLEY BA, REESE RO, MCRAE G & FORSTCHEN PR. 1998. Parasites of fish as indicators of environmental stress. Environ Monit Assess 51: 211-232. demonstrated that nematodes that typically use crustaceans as intermediate hosts are directly affected by contaminants, as these crustaceans are particularly sensitive to these compounds. Regarding the parasitic community, Nachev & Sures (2009)NACHEV M & SURES B. 2009. The endohelminth fauna of barbel (Barbus barbus) correlates with water quality of the Danube River in Bulgaria. Parasitol 136: 545-552., Chapman et al. (2015)CHAPMAN JM, MARCOGLIESE DJ, SUSKI CD & COOKE SJ. 2015. Variation in parasite communities and health indices of juvenile Lepomis gibbosus across a gradient of watershed land-use and habitat quality. Ecol Indic 57: 564-572. and Blanar et al. (2016)BLANAR CA, HEWITT M, MCMASTER M, KIRK J, WANG Z, NORWOOD W & MARCOGLIESE DJ. 2016. Parasite community similarity in Athabasca River trout-perch (Percopsis omiscomaycus) varies with local-scale land use and sediment hydrocarbons, but not distance or linear gradients. Parasitol Res 115: 3853-3866. reported higher diversity in less polluted sampling sites, while fauna composition and abundance of some parasites showed to be related to the pollution gradient.

At first, environmental conditions are important for the survival and well-being of the host, but the well-being of the host is also extremely important for the survival of the parasites, although their effects may differ depending on the life cycle (Sures 2008SURES B. 2008. Environmental Parasitology. Interactions between parasites and pollutants in the aquatic environment. Parasite 15: 434-438.). The presence of larval stage at point 1 that parasitizing G. brasiliensis indicated that the fish occupies an intermediate position in the trophic web and must be consumed by a definitive host (other fish, piscivorous birds or mammals) (Lacerda et al. 2018LACERDA ACF, ROUMBEDAKIS K, JUNIOR JB, NUÑER APO, PETRUCIO MM & MARTINS ML. 2018. Fish parasites as indicators of organic pollution in southern Brazil. J Helminthol 92: 322-331.). This abundance of nematodes may be related to the omnivorous host, which allows the ingestion of several organisms that act as intermediate hosts, facilitating the infection (Santos & Brasil-Sato 2006SANTOS MD & BRASIL-SATO MC. 2006. Parasitic community of Fransciscodoras marmoratus (Reinhardt, 1874) (Pisces: Siluriformes, Doradidae) from the upper São Francisco river, Brazil. Braz J Biol 66: 931-938.).

The lowest values of condition factor appeared in the hosts collected in point 1, despite the absence of statistically significant difference between the points. Changes in the condition factor values can occur due to the quality or the state of the environment in which the fish is inserted, in addition to parasitism on the hosts (Ranzani-Paiva et al. 2000RANZANI-PAIVA MJT, SILVA-SOUZA AT, PAVANELLI GC & TAKEMOTO RM. 2000. Hematological characteristics and relative condition factor (Kn) associated with parasitism in Schizodon borelli (Osteichthyes, Anostomidae) and Prochilodus lineatus (Ostheichtyes, Prochilodontidae) from Paraná River, Porto Rico, Paraná, Brazil. Acta Sci Biol Sci 22: 515-521.). Although there was no correlation between Kn and the abundance of parasites, points 2 and 3, with the highest values in the condition factor, showed a higher prevalence of infection. Lizama et al. (2006)LIZAMA MAP, TAKEMOTO RM & PAVANELLI GC. 2006. Parasitism influence on the hepato, splenosomatic and weight/length relation and relative condition factor of Prochilodus lineatus (Valenciennes, 1836) (Prochilodontidae) of the upper Paraná River floodplain, Brazil. Rev Bras Parasitol Vet 15: 116-122. demonstrated that parasitized fish had higher values for the condition factor than non-parasitized fish, identifying that larger individuals who also had higher values for Kn tolerated higher levels of parasitism.

A healthy system that does not suffer from anthropogenic changes is rich in parasite species, therefore, parasites are essential to biodiversity and production of ecosystems (Hudson et al. 2006HUDSON PJ, DOBSON AP & LAFFERTY KD. 2006. Is a healthy ecosystem one that is rich in parasites? Trends Ecol Evol 21: 381-385.). Pollution induces a shift in community structure towards dominance by tolerant species (Holt & Miller 2011HOLT EA & MILLER SW. 2011. Bioindicators: using organisms to measure environmental impacts. Nat Educ Knowl 3: 8., Parmar et al. 2016PARMAR TK, RAWTANI D & AGRAWAL YK. 2016. Bioindicators: the natural indicator of environmental pollution. Front Life Sci 9:110-118.), thus, richness decreases as a result of the disappearance of taxa as the level of pollution increases, as well as the abundance of sensitive species is reduced, while the abundance of tolerant species is unaffected or increase (Lafferty 1997LAFFERTY KD. 1997. Environmental parasitology: what can parasites tell us about human impacts on the environment?. Parasitol Today 13: 251-255., Sures 2005SURES B. 2005. Effects of pollution on parasites, and use of parasites in pollution monitoring. Mar Parasitol 421-425., Adewole et al. 2019ADEWOLE SO, ODEYEMI DF, FATUNWASE OP, CHRISTOPHER VN, OMOYENI TE & DADA AO. 2019. Parasites as bioindicator for health status and environmental quality of freshwater fish species in Ekiti State, Nigeria. J Biomed Eng Med Imag 6: 01-07.). In this study, the absence of parasites already reported for the host G. brasiliensis in Iguaçu River demonstrates that the environment can alter species diversity, therefore, pollution of the aquatic environment reflects directly in the organisms. Thus, the use of fish parasites as indicators proved a relevant tool to identify the impact caused by changes in the environment. Thus, parasites can be used to indicate anthropogenic impacts in aquatic environments.

ACKNOWLEDGMENTS

We would like to thank the Research Group in Limnology, Ichthyology and Aquaculture (Nupélia) of the Universidade Estadual de Maringá (UEM) for logistical support; and the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) for the supply of scholarship during the course of postgraduate research. And we would thank Ana Carolina de Deus Bueno Krawczyk and Universidade Estadual do Paraná for support in the sampling.

REFERENCES

ADAMS SM & GREELEY MS. 2000. Ecotoxicological indicators of water quality: using multi-response indicators to assess the health of aquatic ecosystems. Water Air Soil Pollut 123: 103-115.
ADEWOLE SO, ODEYEMI DF, FATUNWASE OP, CHRISTOPHER VN, OMOYENI TE & DADA AO. 2019. Parasites as bioindicator for health status and environmental quality of freshwater fish species in Ekiti State, Nigeria. J Biomed Eng Med Imag 6: 01-07.
ALIMBA CG & BAKARE AA. 2016. In vivo micronucleus test in the assessment of cytogenotoxicity of landfill leachates in three animal models from various ecological habitats. Ecotoxicol 25: 310-319.
ANDERSON MJ. 2005. PERMANOVA: a FORTRAN computer program for permutational multivariate analysis of variance. Department of Statistics, University of Auckland.
BASTOS LP & ABILHOA V. 2004. A utilização do índice de integridade biótica para avaliação da qualidade de água: um estudo de caso para riachos urbanos da bacia hidrográfica do rio Belém, Curitiba, Paraná. Rev Est Biol 26: 33-44.
BAUMGARTNER G, PAVANELLI CS, BAUMGARTNER D, BIFI AG, DEBONA & FRANA VA. 2012. Peixes do baixo rio Iguaçu, Maringá: Eduem, 225 p.
BELLAY S, TAKEMOTO RM, YAMADA FH & PAVANELLI GC. 2008. A new species of Sciadicleithrum (Monogenea: Ancyrocephalinae), gill parasite of Geophagus brasiliensis (Quoy and Gaimard) (Teleostei: Cichlidae) from reservoirs in the State of Paraná, Brazil. Zootaxa 1700: 63-68.
BELLAY S, UEDA BH, TAKEMOTO RM, LIZAMA MDLAP & PAVANELLI GC. 2012. Fauna parasitária de Geophagus brasiliensis (Perciformes: Cichlidae) em reservatórios do estado do Paraná, Brasil. Rev Bras Biocienc 10: 74-78.
BLANAR CA, HEWITT M, MCMASTER M, KIRK J, WANG Z, NORWOOD W & MARCOGLIESE DJ. 2016. Parasite community similarity in Athabasca River trout-perch (Percopsis omiscomaycus) varies with local-scale land use and sediment hydrocarbons, but not distance or linear gradients. Parasitol Res 115: 3853-3866.
BUSH AO, LAFFERTY KD, LOTZ JM & SHOSTAK AW. 1997. Parasitology meets ecology on its own terms: Margolis et al. revisited. J Parasitol 83: 575-583.
CARNEIRO C, ANDREOLI CV, DA NOBREGA CUNHA CDL & GOBBI EF. 2014. Reservoir eutrophication: Preventive management, IWA Publishing, 480 p.
CARVALHO AR, TAVARES LER & LUQUE JL. 2010. Variação sazonal dos metazoários parasitos de Geophagus brasiliensis (Perciformes: Cichlidae) no rio Guandu, Estado do Rio de Janeiro, Brasil. Acta Sci Biol Sci 32: 159-167.
CHALUPOVÁ D, HAVLÍKOVÁ P & JANSKÝ B. 2012. Water quality of selected fluvial lakes in the context of the Elbe River pollution and anthropogenic activities in the floodplain. Environ Monit Assess 184: 6283-6295.
CHAPMAN JM, MARCOGLIESE DJ, SUSKI CD & COOKE SJ. 2015. Variation in parasite communities and health indices of juvenile Lepomis gibbosus across a gradient of watershed land-use and habitat quality. Ecol Indic 57: 564-572.
DAGA VS & GUBIANI ÉA. 2012. Variations in the endemic fish assemblage of a global freshwater ecoregion: associations with introduced species in cascading reservoirs. Acta Oecol 41: 95-105.
DALZOCHIO T, RODRIGUES GZP, PETRY IE, GEHLEN G & DA SILVA LB. 2016. The use of biomarkers to assess the health of aquatic ecosystems in Brazil: a review. Int Aqua Res 8: 283-298.
DE ANDRADE BRITO I, GARCIA JRE, SALAROLI AB, FIGUEIRA RCL, DE CASTRO MARTINS C, NETO AC, GUSSO-CHOUERI PK, CHOUERI RB, ARAUJO SBL & DE OLIVEIRA RIBEIRO CA. 2018. Embryo toxicity assay in the fish species Rhamdia quelen (Teleostei, Heptapteridae) to assess water quality in the Upper Iguaçu basin (Parana, Brazil). Chemosphere 208: 207-218.
DUARTE GSC, LEHUN AL, LEITE LAR, CONSOLIN-FILHO N, BELLAY S & TAKEMOTO RM. 2020. Acanthocephalans parasites of two Characiformes fishes as bioindicators of cadmium contamination in two neotropical rivers in Brazil. Sci Total Environ 738: 140339.
EIRAS JC, TAKEMOTO RM & PAVANELLI GC. 2006. Métodos de estudo e técnicas laboratoriais em parasitologia de peixes, 2ª ed., Maringá: Eduem, 199 p.
ESTEVES FA. 2011. Fundamentos de Limnologia, 3ª ed., Rio de Janeiro: Interciência, 790 p.
FAJER-ÁVILA EJ, GARCÍA-VÁSQUEZ A, PLASCENCIA-GONZÁLEZ H, RÍOS-SICAIROS J, GARCÍA-DE LA PARRA LM & BETANCOURT-LOZANO M. 2006. Copepods and larvae of nematodes parasiting the white mullet Mugil curema (Valenciennes, 1836): Indicators of anthropogenic impacts in tropical coastal lagoons? Environ Monit Assess 122: 221-237.
FALKENBERG JM, GOLZIO JES, PESSANHA A, PATRÍCIO J, VENDEL AL & LACERDA AC. 2019. Gill parasites of fish and their relation to host and environmental factors in two estuaries in northeastern Brazil. Aquat Ecol 53: 109-118.
FERNANDES BMM & KOHN A. 2001. On some trematodes parasites of fishes from Paraná river. Braz J Biol 61: 461-466.
GILBERT BM & AVENANT-OLDEWAGE A. 2021. Monogeneans as bioindicators: A meta-analysis of effect size of contaminant exposure toward Monogenea (Platyhelminthes). Ecol Indic 130:108062.
HOLT EA & MILLER SW. 2011. Bioindicators: using organisms to measure environmental impacts. Nat Educ Knowl 3: 8.
HUDSON PJ, DOBSON AP & LAFFERTY KD. 2006. Is a healthy ecosystem one that is rich in parasites? Trends Ecol Evol 21: 381-385.
IAP - INSTITUTO AMBIENTAL DO PARANÁ. 2017. Qualidade das Águas – Reservatórios do Estado do Paraná de 2017, 219 p. Ed. Fundamento, Brasil. (in Portuguese). Available in: http://www.iap.pr.gov.br/arquivos/File/Qualidade_das_aguas/RElatoriofinal.pdf
» http://www.iap.pr.gov.br/arquivos/File/Qualidade_das_aguas/RElatoriofinal.pdf
IBGE. 2010. IBGE, Censo 2010. Available in: http://www.censo2010.ibge.gov.br/
» http://www.censo2010.ibge.gov.br/
LACERDA ACF, ROUMBEDAKIS K, JUNIOR JB, NUÑER APO, PETRUCIO MM & MARTINS ML. 2018. Fish parasites as indicators of organic pollution in southern Brazil. J Helminthol 92: 322-331.
LAFFERTY KD. 1997. Environmental parasitology: what can parasites tell us about human impacts on the environment?. Parasitol Today 13: 251-255.
LAFFERTY KD & KURIS AM. 2005. Parasitism and environmental disturbances. In: Thomas RF, Thomas F, Guégan JF, Renaud F, Renaud RF, Guegan JF & Gan JFOG (Eds), Parasitism and ecosystems, Oxford University Press on Demand, p. 113-123.
LANDSBERG JH, BLAKESLEY BA, REESE RO, MCRAE G & FORSTCHEN PR. 1998. Parasites of fish as indicators of environmental stress. Environ Monit Assess 51: 211-232.
LE CREN ED. 1951. The length-weight relationship and seasonal cycle in gonadal weight and condition in the perch (Perca fluviatilis). J Anim Ecol 20: 201-219.
LEGENDRE P & LEGENDRE L. 1998. Numerical ecology. Amsterdam: Elsevier Science.
LEHUN AL, MENDES AB, TAKEMOTO RM & BUENO KRAWCZYK ACDD. 2021. Genotoxic effects of urban pollution in the Iguaçu River on two fish populations. J Environ Sci Health A 56: 984-991.
LIZAMA MAP, TAKEMOTO RM & PAVANELLI GC. 2006. Parasitism influence on the hepato, splenosomatic and weight/length relation and relative condition factor of Prochilodus lineatus (Valenciennes, 1836) (Prochilodontidae) of the upper Paraná River floodplain, Brazil. Rev Bras Parasitol Vet 15: 116-122.
MAACK R. 1981. Geografia física do Estado do Paraná, J. Olympio, 442 p.
MACKENZIE K. 1999. Parasites as pollution indicators in marine ecosystems: a proposed early warning system. Mar Pollut Bull 38: 955-959.
MACKENZIE K, WILLIAMS HH, WILLIAMS B, MCVICAR AH & SIDDALL R. 1995. Parasites as indicators of water quality and the potential use of helminth transmission in marine pollution studies. Adv Parasit 35: 85-144.
MADI RR & UETA MT. 2009. O papel de Ancyrocephalinae (Monogenea: Dactylogyridae), parasita de Geophagus brasiliensis (Pisces: Cichlidae), como indicador ambiental. Rev Bras Parasitol V 18: 38-41.
MADI RR & UETA MT. 2012. Parasitas de peixes como indicadores ambientais. In: Silva-Souza AT, Lizama MAP & Takemoto RM (Eds), Patologia e Sanidade de Organismos Aquáticos, Maringá: Massoni, p. 33-58.
MARCOGLIESE DJ. 2004. Parasites: small players with crucial roles in the ecological theater. EcoHealth 1: 151-164.
MARCOGLIESE DJ. 2005. Parasites of the superorganism: are they indicators of ecosystem health? Int J Parasitol 35: 705-716.
MARCOGLIESE DJ & CONE DK. 1997. Parasite communities as indicators of ecosystem stress. Parassitologia 39: 227-232.
MIZUKAWA A, MOLINS-DELGADO D, DE AZEVEDO JCR, FERNANDES CVS, DÍAZ-CRUZ S & BARCELÓ D. 2017. Sediments as a sink for UV filters and benzotriazoles: the case study of Upper Iguaçu watershed, Curitiba (Brazil). Environ Sci Pollut Res 24: 18284-18294.
MORAVEC F. 1998. Nematodes of freshwater fishes of the Neotropical Region, Czech Republic: Academia, Praha, 464 p.
NACHEV M & SURES B. 2009. The endohelminth fauna of barbel (Barbus barbus) correlates with water quality of the Danube River in Bulgaria. Parasitol 136: 545-552.
NEGREIROS LP, PEREIRA FB, TAVARES-DIAS M & TAVARES LE. 2018. Community structure of metazoan parasites from Pimelodus blochii in two rivers of the Western Brazilian Amazon: same seasonal traits, but different anthropogenic impacts. Parasitol Res 117: 3791-3798.
OKSANEN J, BLANCHET FG, KINDT R, LEGENDRE P, O’HARA RB, SIMPSON GL, STEVENS MHH & WAGNER H. 2020. Vegan: Community Ecology Package. R Package, Version 2, p. 3-4, http://cran.r-project.org/web/packages/vegan
» http://cran.r-project.org/web/packages/vegan
OUEDRAOGO I, DEFOURNY P & VANCLOOSTER M. 2016. Mapping the groundwater vulnerability for pollution at the pan African scale. Sci Total Environ 544: 939-953.
OVERSTREET RM. 1997. Parasitological data as monitors of environmental health. Parasitologia 39: 169-175.
PARMAR TK, RAWTANI D & AGRAWAL YK. 2016. Bioindicators: the natural indicator of environmental pollution. Front Life Sci 9:110-118.
RAHMAN A. 2008. A GIS based DRASTIC model for assessing groundwater vulnerability in shallow aquifer in Aligarh, India. Appl Geogr 28: 32-53.
RANZANI-PAIVA MJT, SILVA-SOUZA AT, PAVANELLI GC & TAKEMOTO RM. 2000. Hematological characteristics and relative condition factor (Kn) associated with parasitism in Schizodon borelli (Osteichthyes, Anostomidae) and Prochilodus lineatus (Ostheichtyes, Prochilodontidae) from Paraná River, Porto Rico, Paraná, Brazil. Acta Sci Biol Sci 22: 515-521.
R DEVELOPMENT CORE TEAM. 2020. R: a language and environment for statistical computing [online]. Vienna: R Foundation for Statistical Computing, 2013.
REID AJ ET AL. 2019. Emerging threats and persistent conservation challenges for freshwater biodiversity. Biol Rev 94: 849-873.
SANTOS MD & BRASIL-SATO MC. 2006. Parasitic community of Fransciscodoras marmoratus (Reinhardt, 1874) (Pisces: Siluriformes, Doradidae) from the upper São Francisco river, Brazil. Braz J Biol 66: 931-938.
SILVA JVF, LANSAC-TÔHA FM, SEGOVIA BT, AMADEO FE, BRAGHIN LDSM, VELHO LFM, SARMENTO H & BONECKER CC. 2022. Experimental evaluation of microplastic consumption by using a size-fractionation approach in the planktonic communities. Sci Total Environ 821: 153045.
SILVA-SOUZA AT, SHIBATTA OA, MATSUMURA-TUNDISI T, TUNDISI JG & DUPAS FA. 2006. Parasitas de peixes como indicadores de estresse ambiental e eutrofização. In: Tundisi JG, Matsumura-Tundisi T & Sidagis Galli C (Eds), Eutrofização na América do Sul: causas, tecnologias de gerenciamento e controle. São Carlos: IIE, p. 373-386.
SIMPSON GL. 2018. Permute: functions for generating restricted permutations of data. R Package 0.9-4.
SMIL V. 2000. Phosphorus in the environment: natural flows and human interferences. Annu Rev Energ Env 25: 53-88.
SUPERINTENDÊNCIA DE DESENVOLVIMENTO DE RECURSOS HÍDRICOS E SANEAMENTO AMBIENTAL. 1997. Qualidade das águas interiores do Estado do Paraná. 1987-1995, Curitiba: SUDERHSA, 257 p.
SURES B. 2004. Environmental parasitology: relevancy of parasites in monitoring environmental pollution. Trends Parasitol 20: 170-177.
SURES B. 2005. Effects of pollution on parasites, and use of parasites in pollution monitoring. Mar Parasitol 421-425.
SURES B. 2008. Environmental Parasitology. Interactions between parasites and pollutants in the aquatic environment. Parasite 15: 434-438.
SURES B, NACHEV M, SELBACH C & MARCOGLIESE DJ. 2017. Parasite responses to pollution: what we know and where we go in ‘Environmental Parasitology’. Parasit Vector 10: 65.
SURES B & STREIT B. 2001. Eel parasite diversity and intermediate host abundance in the River Rhine, Germany. Parasitol 123: 185-191.
SZALAI AJ & DICK TA. 1990. Proteocephalus ambloplitis and Contracaecum sp. from largemouth bass (Micropterus salmoides) stocked into Boundary Reservoir, Saskatchewan. J Parasitol 76: 598-601.
THATCHER VE. 2006. Amazon fish parasites. Vol. 1. Pensoft Publishers.
THOMPSON MY, BRANDES D & KNEY AD. 2010. Using electronic conductivity and hardness data for rapid assessment of stream water quality. In: World Environmental and Water Resources Congress 2010: Challenges of Change, p. 3356-3365.
TIMI JT & POULIN R. 2020. Why ignoring parasites in fish ecology is a mistake. Int J Parasitol 50: 755-761.
TUNDISI JG & TUNDISI MT. 2008. Limnologia, São Paulo: Oficina de Textos, 631 p.
VALTONEN ET, HOLMES JC & KOSKIVAARA M. 1997. Eutrophication, pollution and fragmentation: effects on parasite communities in roach (Rutilus rutilus) and perch (Perca fluviatilis) in four lakes in central Finland. Can J Fish Aquat Sci 54: 572-585.
VICENTE JJ & PINTO RM. 1999. Nematóides do Brasil. Nematóides de peixes. Atualização: 1985-1998. Rev Bras Zool 16: 561-610.
VIDAL-MARTÍNEZ VM, PECH D, SURES B, PURUCKER T & POULIN R. 2010. Can parasites really reveal environmental impact? Trends Parasitol 26: 44-51.
VIDAL-MARTÍNEZ VM & WUNDERLICH AC. 2017. Parasites as bioindicators of environmental degradation in Latin America: a meta-analysis. J Helminthol 91: 165-173.
VITOUSEK PM, PORDER S, HOULTON BZ & CHADWICK OA. 2010. Terrestrial phosphorus limitation: mechanisms, implications, and nitrogen–phosphorus interactions. Ecol Applic 20: 5-15.
VON ZUBEN CJ. 1997. Implicações da agregação espacial de parasitas para a dinâmica populacional na interação hospedeiro-parasita. Rev Saúde Púb 31: 523-530.
ZAR JH. 2010. Biostatistical analysis, New Jersey: Prentice Hall, 944 p.
ZARGAR UR, CHISHTI MZ, YOUSUF AR & FAYAZ A. 2012. Infection level of monogenean gill parasite, Diplozoon kashmirensis (Monogenea, Polyopisthocotylea) in the Crucian Carp, Carassius carassius from lake ecosystems of an altered water quality: What factors do have an impact on the Diplozoon infection? Vet Parasitol 189: 218-226.
ZAWADZKI CH, RENESTO E & BINI LM. 1999. Genetic and morphometric analysis of three species of the genus Hypostomus Lacépède, 1803 (Osteichthyes: Loricariidae) from the Iguaçu basin (Brazil). Rev Suisse Zool 106: 91-105.

Publication Dates

Publication in this collection
18 Sept 2023
Date of issue
2023

History

Received
06 Mar 2020
Accepted
02 Aug 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ADAMS SM & GREELEY MS. 2000. Ecotoxicological indicators of water quality: using multi-response indicators to assess the health of aquatic ecosystems. Water Air Soil Pollut 123: 103-115.

[2] ADEWOLE SO, ODEYEMI DF, FATUNWASE OP, CHRISTOPHER VN, OMOYENI TE & DADA AO. 2019. Parasites as bioindicator for health status and environmental quality of freshwater fish species in Ekiti State, Nigeria. J Biomed Eng Med Imag 6: 01-07.

[3] ALIMBA CG & BAKARE AA. 2016. In vivo micronucleus test in the assessment of cytogenotoxicity of landfill leachates in three animal models from various ecological habitats. Ecotoxicol 25: 310-319.

[4] ANDERSON MJ. 2005. PERMANOVA: a FORTRAN computer program for permutational multivariate analysis of variance. Department of Statistics, University of Auckland.

[5] BASTOS LP & ABILHOA V. 2004. A utilização do índice de integridade biótica para avaliação da qualidade de água: um estudo de caso para riachos urbanos da bacia hidrográfica do rio Belém, Curitiba, Paraná. Rev Est Biol 26: 33-44.

[6] BAUMGARTNER G, PAVANELLI CS, BAUMGARTNER D, BIFI AG, DEBONA & FRANA VA. 2012. Peixes do baixo rio Iguaçu, Maringá: Eduem, 225 p.

[7] BELLAY S, TAKEMOTO RM, YAMADA FH & PAVANELLI GC. 2008. A new species of Sciadicleithrum (Monogenea: Ancyrocephalinae), gill parasite of Geophagus brasiliensis (Quoy and Gaimard) (Teleostei: Cichlidae) from reservoirs in the State of Paraná, Brazil. Zootaxa 1700: 63-68.

[8] BELLAY S, UEDA BH, TAKEMOTO RM, LIZAMA MDLAP & PAVANELLI GC. 2012. Fauna parasitária de Geophagus brasiliensis (Perciformes: Cichlidae) em reservatórios do estado do Paraná, Brasil. Rev Bras Biocienc 10: 74-78.

[9] BLANAR CA, HEWITT M, MCMASTER M, KIRK J, WANG Z, NORWOOD W & MARCOGLIESE DJ. 2016. Parasite community similarity in Athabasca River trout-perch (Percopsis omiscomaycus) varies with local-scale land use and sediment hydrocarbons, but not distance or linear gradients. Parasitol Res 115: 3853-3866.

[10] BUSH AO, LAFFERTY KD, LOTZ JM & SHOSTAK AW. 1997. Parasitology meets ecology on its own terms: Margolis et al. revisited. J Parasitol 83: 575-583.

[11] CARNEIRO C, ANDREOLI CV, DA NOBREGA CUNHA CDL & GOBBI EF. 2014. Reservoir eutrophication: Preventive management, IWA Publishing, 480 p.

[12] CARVALHO AR, TAVARES LER & LUQUE JL. 2010. Variação sazonal dos metazoários parasitos de Geophagus brasiliensis (Perciformes: Cichlidae) no rio Guandu, Estado do Rio de Janeiro, Brasil. Acta Sci Biol Sci 32: 159-167.

[13] CHALUPOVÁ D, HAVLÍKOVÁ P & JANSKÝ B. 2012. Water quality of selected fluvial lakes in the context of the Elbe River pollution and anthropogenic activities in the floodplain. Environ Monit Assess 184: 6283-6295.

[14] CHAPMAN JM, MARCOGLIESE DJ, SUSKI CD & COOKE SJ. 2015. Variation in parasite communities and health indices of juvenile Lepomis gibbosus across a gradient of watershed land-use and habitat quality. Ecol Indic 57: 564-572.

[15] DAGA VS & GUBIANI ÉA. 2012. Variations in the endemic fish assemblage of a global freshwater ecoregion: associations with introduced species in cascading reservoirs. Acta Oecol 41: 95-105.

[16] DALZOCHIO T, RODRIGUES GZP, PETRY IE, GEHLEN G & DA SILVA LB. 2016. The use of biomarkers to assess the health of aquatic ecosystems in Brazil: a review. Int Aqua Res 8: 283-298.

[17] DE ANDRADE BRITO I, GARCIA JRE, SALAROLI AB, FIGUEIRA RCL, DE CASTRO MARTINS C, NETO AC, GUSSO-CHOUERI PK, CHOUERI RB, ARAUJO SBL & DE OLIVEIRA RIBEIRO CA. 2018. Embryo toxicity assay in the fish species Rhamdia quelen (Teleostei, Heptapteridae) to assess water quality in the Upper Iguaçu basin (Parana, Brazil). Chemosphere 208: 207-218.

[18] DUARTE GSC, LEHUN AL, LEITE LAR, CONSOLIN-FILHO N, BELLAY S & TAKEMOTO RM. 2020. Acanthocephalans parasites of two Characiformes fishes as bioindicators of cadmium contamination in two neotropical rivers in Brazil. Sci Total Environ 738: 140339.

[19] EIRAS JC, TAKEMOTO RM & PAVANELLI GC. 2006. Métodos de estudo e técnicas laboratoriais em parasitologia de peixes, 2ª ed., Maringá: Eduem, 199 p.

[20] ESTEVES FA. 2011. Fundamentos de Limnologia, 3ª ed., Rio de Janeiro: Interciência, 790 p.

[21] FAJER-ÁVILA EJ, GARCÍA-VÁSQUEZ A, PLASCENCIA-GONZÁLEZ H, RÍOS-SICAIROS J, GARCÍA-DE LA PARRA LM & BETANCOURT-LOZANO M. 2006. Copepods and larvae of nematodes parasiting the white mullet Mugil curema (Valenciennes, 1836): Indicators of anthropogenic impacts in tropical coastal lagoons? Environ Monit Assess 122: 221-237.

[22] FALKENBERG JM, GOLZIO JES, PESSANHA A, PATRÍCIO J, VENDEL AL & LACERDA AC. 2019. Gill parasites of fish and their relation to host and environmental factors in two estuaries in northeastern Brazil. Aquat Ecol 53: 109-118.

[23] FERNANDES BMM & KOHN A. 2001. On some trematodes parasites of fishes from Paraná river. Braz J Biol 61: 461-466.

[24] GILBERT BM & AVENANT-OLDEWAGE A. 2021. Monogeneans as bioindicators: A meta-analysis of effect size of contaminant exposure toward Monogenea (Platyhelminthes). Ecol Indic 130:108062.

[25] HOLT EA & MILLER SW. 2011. Bioindicators: using organisms to measure environmental impacts. Nat Educ Knowl 3: 8.

[26] HUDSON PJ, DOBSON AP & LAFFERTY KD. 2006. Is a healthy ecosystem one that is rich in parasites? Trends Ecol Evol 21: 381-385.

[27] IAP - INSTITUTO AMBIENTAL DO PARANÁ. 2017. Qualidade das Águas – Reservatórios do Estado do Paraná de 2017, 219 p. Ed. Fundamento, Brasil. (in Portuguese). Available in: http://www.iap.pr.gov.br/arquivos/File/Qualidade_das_aguas/RElatoriofinal.pdf
» http://www.iap.pr.gov.br/arquivos/File/Qualidade_das_aguas/RElatoriofinal.pdf

[28] IBGE. 2010. IBGE, Censo 2010. Available in: http://www.censo2010.ibge.gov.br/
» http://www.censo2010.ibge.gov.br/

[29] LACERDA ACF, ROUMBEDAKIS K, JUNIOR JB, NUÑER APO, PETRUCIO MM & MARTINS ML. 2018. Fish parasites as indicators of organic pollution in southern Brazil. J Helminthol 92: 322-331.

[30] LAFFERTY KD. 1997. Environmental parasitology: what can parasites tell us about human impacts on the environment?. Parasitol Today 13: 251-255.

[31] LAFFERTY KD & KURIS AM. 2005. Parasitism and environmental disturbances. In: Thomas RF, Thomas F, Guégan JF, Renaud F, Renaud RF, Guegan JF & Gan JFOG (Eds), Parasitism and ecosystems, Oxford University Press on Demand, p. 113-123.

[32] LANDSBERG JH, BLAKESLEY BA, REESE RO, MCRAE G & FORSTCHEN PR. 1998. Parasites of fish as indicators of environmental stress. Environ Monit Assess 51: 211-232.

[33] LE CREN ED. 1951. The length-weight relationship and seasonal cycle in gonadal weight and condition in the perch (Perca fluviatilis). J Anim Ecol 20: 201-219.

[34] LEGENDRE P & LEGENDRE L. 1998. Numerical ecology. Amsterdam: Elsevier Science.

[35] LEHUN AL, MENDES AB, TAKEMOTO RM & BUENO KRAWCZYK ACDD. 2021. Genotoxic effects of urban pollution in the Iguaçu River on two fish populations. J Environ Sci Health A 56: 984-991.

[36] LIZAMA MAP, TAKEMOTO RM & PAVANELLI GC. 2006. Parasitism influence on the hepato, splenosomatic and weight/length relation and relative condition factor of Prochilodus lineatus (Valenciennes, 1836) (Prochilodontidae) of the upper Paraná River floodplain, Brazil. Rev Bras Parasitol Vet 15: 116-122.

[37] MAACK R. 1981. Geografia física do Estado do Paraná, J. Olympio, 442 p.

[38] MACKENZIE K. 1999. Parasites as pollution indicators in marine ecosystems: a proposed early warning system. Mar Pollut Bull 38: 955-959.

[39] MACKENZIE K, WILLIAMS HH, WILLIAMS B, MCVICAR AH & SIDDALL R. 1995. Parasites as indicators of water quality and the potential use of helminth transmission in marine pollution studies. Adv Parasit 35: 85-144.

[40] MADI RR & UETA MT. 2009. O papel de Ancyrocephalinae (Monogenea: Dactylogyridae), parasita de Geophagus brasiliensis (Pisces: Cichlidae), como indicador ambiental. Rev Bras Parasitol V 18: 38-41.

[41] MADI RR & UETA MT. 2012. Parasitas de peixes como indicadores ambientais. In: Silva-Souza AT, Lizama MAP & Takemoto RM (Eds), Patologia e Sanidade de Organismos Aquáticos, Maringá: Massoni, p. 33-58.

[42] MARCOGLIESE DJ. 2004. Parasites: small players with crucial roles in the ecological theater. EcoHealth 1: 151-164.

[43] MARCOGLIESE DJ. 2005. Parasites of the superorganism: are they indicators of ecosystem health? Int J Parasitol 35: 705-716.

[44] MARCOGLIESE DJ & CONE DK. 1997. Parasite communities as indicators of ecosystem stress. Parassitologia 39: 227-232.

[45] MIZUKAWA A, MOLINS-DELGADO D, DE AZEVEDO JCR, FERNANDES CVS, DÍAZ-CRUZ S & BARCELÓ D. 2017. Sediments as a sink for UV filters and benzotriazoles: the case study of Upper Iguaçu watershed, Curitiba (Brazil). Environ Sci Pollut Res 24: 18284-18294.

[46] MORAVEC F. 1998. Nematodes of freshwater fishes of the Neotropical Region, Czech Republic: Academia, Praha, 464 p.

[47] NACHEV M & SURES B. 2009. The endohelminth fauna of barbel (Barbus barbus) correlates with water quality of the Danube River in Bulgaria. Parasitol 136: 545-552.

[48] NEGREIROS LP, PEREIRA FB, TAVARES-DIAS M & TAVARES LE. 2018. Community structure of metazoan parasites from Pimelodus blochii in two rivers of the Western Brazilian Amazon: same seasonal traits, but different anthropogenic impacts. Parasitol Res 117: 3791-3798.

[49] OKSANEN J, BLANCHET FG, KINDT R, LEGENDRE P, O’HARA RB, SIMPSON GL, STEVENS MHH & WAGNER H. 2020. Vegan: Community Ecology Package. R Package, Version 2, p. 3-4, http://cran.r-project.org/web/packages/vegan
» http://cran.r-project.org/web/packages/vegan

[50] OUEDRAOGO I, DEFOURNY P & VANCLOOSTER M. 2016. Mapping the groundwater vulnerability for pollution at the pan African scale. Sci Total Environ 544: 939-953.

[51] OVERSTREET RM. 1997. Parasitological data as monitors of environmental health. Parasitologia 39: 169-175.

[52] PARMAR TK, RAWTANI D & AGRAWAL YK. 2016. Bioindicators: the natural indicator of environmental pollution. Front Life Sci 9:110-118.

[53] RAHMAN A. 2008. A GIS based DRASTIC model for assessing groundwater vulnerability in shallow aquifer in Aligarh, India. Appl Geogr 28: 32-53.

[54] RANZANI-PAIVA MJT, SILVA-SOUZA AT, PAVANELLI GC & TAKEMOTO RM. 2000. Hematological characteristics and relative condition factor (Kn) associated with parasitism in Schizodon borelli (Osteichthyes, Anostomidae) and Prochilodus lineatus (Ostheichtyes, Prochilodontidae) from Paraná River, Porto Rico, Paraná, Brazil. Acta Sci Biol Sci 22: 515-521.

[55] R DEVELOPMENT CORE TEAM. 2020. R: a language and environment for statistical computing [online]. Vienna: R Foundation for Statistical Computing, 2013.

[56] REID AJ ET AL. 2019. Emerging threats and persistent conservation challenges for freshwater biodiversity. Biol Rev 94: 849-873.

[57] SANTOS MD & BRASIL-SATO MC. 2006. Parasitic community of Fransciscodoras marmoratus (Reinhardt, 1874) (Pisces: Siluriformes, Doradidae) from the upper São Francisco river, Brazil. Braz J Biol 66: 931-938.

[58] SILVA JVF, LANSAC-TÔHA FM, SEGOVIA BT, AMADEO FE, BRAGHIN LDSM, VELHO LFM, SARMENTO H & BONECKER CC. 2022. Experimental evaluation of microplastic consumption by using a size-fractionation approach in the planktonic communities. Sci Total Environ 821: 153045.

[59] SILVA-SOUZA AT, SHIBATTA OA, MATSUMURA-TUNDISI T, TUNDISI JG & DUPAS FA. 2006. Parasitas de peixes como indicadores de estresse ambiental e eutrofização. In: Tundisi JG, Matsumura-Tundisi T & Sidagis Galli C (Eds), Eutrofização na América do Sul: causas, tecnologias de gerenciamento e controle. São Carlos: IIE, p. 373-386.

[60] SIMPSON GL. 2018. Permute: functions for generating restricted permutations of data. R Package 0.9-4.

[61] SMIL V. 2000. Phosphorus in the environment: natural flows and human interferences. Annu Rev Energ Env 25: 53-88.

[62] SUPERINTENDÊNCIA DE DESENVOLVIMENTO DE RECURSOS HÍDRICOS E SANEAMENTO AMBIENTAL. 1997. Qualidade das águas interiores do Estado do Paraná. 1987-1995, Curitiba: SUDERHSA, 257 p.

[63] SURES B. 2004. Environmental parasitology: relevancy of parasites in monitoring environmental pollution. Trends Parasitol 20: 170-177.

[64] SURES B. 2005. Effects of pollution on parasites, and use of parasites in pollution monitoring. Mar Parasitol 421-425.

[65] SURES B. 2008. Environmental Parasitology. Interactions between parasites and pollutants in the aquatic environment. Parasite 15: 434-438.

[66] SURES B, NACHEV M, SELBACH C & MARCOGLIESE DJ. 2017. Parasite responses to pollution: what we know and where we go in ‘Environmental Parasitology’. Parasit Vector 10: 65.

[67] SURES B & STREIT B. 2001. Eel parasite diversity and intermediate host abundance in the River Rhine, Germany. Parasitol 123: 185-191.

[68] SZALAI AJ & DICK TA. 1990. Proteocephalus ambloplitis and Contracaecum sp. from largemouth bass (Micropterus salmoides) stocked into Boundary Reservoir, Saskatchewan. J Parasitol 76: 598-601.

[69] THATCHER VE. 2006. Amazon fish parasites. Vol. 1. Pensoft Publishers.

[70] THOMPSON MY, BRANDES D & KNEY AD. 2010. Using electronic conductivity and hardness data for rapid assessment of stream water quality. In: World Environmental and Water Resources Congress 2010: Challenges of Change, p. 3356-3365.

[71] TIMI JT & POULIN R. 2020. Why ignoring parasites in fish ecology is a mistake. Int J Parasitol 50: 755-761.

[72] TUNDISI JG & TUNDISI MT. 2008. Limnologia, São Paulo: Oficina de Textos, 631 p.

[73] VALTONEN ET, HOLMES JC & KOSKIVAARA M. 1997. Eutrophication, pollution and fragmentation: effects on parasite communities in roach (Rutilus rutilus) and perch (Perca fluviatilis) in four lakes in central Finland. Can J Fish Aquat Sci 54: 572-585.

[74] VICENTE JJ & PINTO RM. 1999. Nematóides do Brasil. Nematóides de peixes. Atualização: 1985-1998. Rev Bras Zool 16: 561-610.

[75] VIDAL-MARTÍNEZ VM, PECH D, SURES B, PURUCKER T & POULIN R. 2010. Can parasites really reveal environmental impact? Trends Parasitol 26: 44-51.

[76] VIDAL-MARTÍNEZ VM & WUNDERLICH AC. 2017. Parasites as bioindicators of environmental degradation in Latin America: a meta-analysis. J Helminthol 91: 165-173.

[77] VITOUSEK PM, PORDER S, HOULTON BZ & CHADWICK OA. 2010. Terrestrial phosphorus limitation: mechanisms, implications, and nitrogen–phosphorus interactions. Ecol Applic 20: 5-15.

[78] VON ZUBEN CJ. 1997. Implicações da agregação espacial de parasitas para a dinâmica populacional na interação hospedeiro-parasita. Rev Saúde Púb 31: 523-530.

[79] ZAR JH. 2010. Biostatistical analysis, New Jersey: Prentice Hall, 944 p.

[80] ZARGAR UR, CHISHTI MZ, YOUSUF AR & FAYAZ A. 2012. Infection level of monogenean gill parasite, Diplozoon kashmirensis (Monogenea, Polyopisthocotylea) in the Crucian Carp, Carassius carassius from lake ecosystems of an altered water quality: What factors do have an impact on the Diplozoon infection? Vet Parasitol 189: 218-226.

[81] ZAWADZKI CH, RENESTO E & BINI LM. 1999. Genetic and morphometric analysis of three species of the genus Hypostomus Lacépède, 1803 (Osteichthyes: Loricariidae) from the Iguaçu basin (Brazil). Rev Suisse Zool 106: 91-105.

Point	WT	pH	DO	C	Total-p
Point 1	29.4±1.2	8.5±0.2	13.08±0.4	154.1±6.1	283.5
Point 2	27.3±1.1	7.84±0.03	15.5±0.7	65.6±6.1	96.5
Point 3	27.1±1	7.4±0.2	14.46±0.1	58±4	78.8

Parasites	Prevalence (%)			Mean intensity (±SD)			Mean abundance (±SD)
Parasites	Point 1	Point 2	Point 3	Point 1	Point 2	Point 3	Point 1	Point 2	Point 3
Contracaecum larvae type 2 described by Moravec, Kohn and Fernandes, 1993 Mesentery	5	0	0	1	-	-	0.15 ±0.37	-	-
Procamallanus (Procamallanus) peraccuratus Intestine	10	40	68	1	2.3 ±1.4	1.64 ±1.11	0.1	0.92 ±1.33	1.12 ±1.2
Procamallanus sp. 1 Intestine	0	4	0	-	1	-	-	0.04	-
Procamallanus sp. 2 Intestine	0	0	4	-	-	1	-	-	0.04
Procamallanus (Spirocamallanus) sp. Intestine	0	0	4	-	-	1	-	-	0.04

Descriptors	Point 1	Point 2	Point 3
Total abundance (N)	4	22	30
Richness (S)	2	2	4
Diversity	0.34	0.14	0.22
Equitability	0.81	0.26	0.26
Simpson’s dominance	0.62	0.91	0.87
Dominant specie	Contracaecum larvae type 2	Procamallanus (Procamallanus) peraccuratus	Procamallanus (Procamallanus) peraccuratus

	Pseudo-F	P
Point 1 vs Point 2	8.74	0.01
Point 1 vs Point 3	14.23	0.005
Point 2 vs Point 3	0.60	1.0