Adjacent environments contribute to the increase of zooplankton species in a neotropical river

Bomfim, Francieli de Fátima; Mantovano, Tatiane; Amaral, Diogo Castanho; Palhiarini, Welinton Sousa; Bonecker, Claudia Costa; Lansac-Tôha, Fábio Amodêo

doi:10.1590/S2179-975X10316

Abstracts

Abstract

Aim: The distribution of the zooplankton community along the Paraná River and in adjacent environments (tributaries and lakes) was evaluated, as well as the contribution of the community present in these environments to the species composition of the Paraná River. It was expected that the ensemble of species found in the last sampling site of the Paraná River would represent the accumulation of species found in the upstream sites.

Methods

The community was sampled at 25 sites, during 2013 and 2014, and the species richness and composition were determined. The similarity in the composition of the community between the environments was evaluated using cluster analysis, and the contribution of the species to the Paraná River was evaluated using nestedness analysis, using the NODF index.

Results

Overall, 193 species were registered (116 rotifers, 48 cladocerans and 29 copepods), with the majority of species considered as rare (163 species). In general, the composition of the community in the river was dissimilar to the adjacent environments, although there was a relationship among communities. Rotifers presented broad distribution throughout the area. As expected, the zooplanktonic species presented a nested distribution, with the last river site representing a set of the species registered in the upstream sites.

Conclusion

The results show the importance of the tributaries and lakes to the occurrence of species along the river. The distinct hydrological characteristics of the environments, as well as flow velocity, depth and connectivity, were responsible for the development of planktonic populations in the lakes that arrived in the main river through tributaries. With these results, we suggest the importance of the conservation of adjacent environments of the Paraná River for the maintenance of the zooplanktonic species in this system.

Keywords:
species nestedness; spatial distribution; species dispersal; floodplain

Resumo

Objetivo: A distribuição da comunidade zooplanctônica foi avaliada ao longo do rio Paraná e em ambientes adjacentes (tributários e lagoas), bem como a contribuição da comunidade presente nesses ambientes, para a composição de espécies no rio Paraná. Espera-se que o conjunto de espécies encontrados no último ponto do rio Paraná represente o acúmulo de espécies observadas nos pontos a montante.

Métodos

A comunidade foi amostrada em 25 pontos, em 2013 e 2014. Foram determinadas a riqueza e composição de espécies. A similaridade da composição da comunidade entre os ambientes foi avaliada através da análise de Cluster, e a contribuição das espécies para o rio Paraná, através de uma análise de aninhamento, utilizando o índice NODF.

Resultados

Foram registradas 193 espécies (116 de rotíferos, 48 de cladóceros e 29 de copépodes), sendo a maioria considerada como rara (163 espécies). Em geral, a composição da comunidade do rio foi dissimilar aos ambientes adjacentes, embora haja uma relação entre as comunidades. Os rotíferos apresentaram uma ampla distribuição em toda área. Como esperado, as espécies zooplanctônicas apresentaram distribuição aninhada, sendo que no último ponto do rio foi observado um conjunto de espécies registradas nos pontos a montante deste.

Conclusão

Nossos resultados demonstraram a importância dos tributários e lagoas para a ocorrência de espécies ao longo do rio. As distintas características hidrológicas dos ambientes, como velocidade de fluxo, profundidade e conectividade, foram responsáveis pelo desenvolvimento de populações planctônicas nas lagoas, que depois chegaram ao rio através dos tributários. Com isso, sugerimos a importância da conservação dos ambientes adjacentes ao rio Paraná para a manutenção de espécies zooplanctônicas nesse sistema.

Palavras-chave:
aninhamento de espécies; distribuição espacial; dispersão de espécies; planície de inundação

1. Introduction

In freshwater ecosystems, the hydrology, connectivity, geomorphological complexity and nutrient input can be very distinct among environments, increasing the environmental heterogeneity (Bozelli et al., 2015BOZELLI, R.L., THOMAZ, S.M., PADIAL, A.A., LOPES, P.M. and BINI, L.M. Floods decrease zooplankton beta diversity and environmental heterogeneity in an Amazonian floodplain system. Hydrobiologia, 2015, 753(1), 233-241. http://dx.doi.org/10.1007/s10750-015-2209-1.
http://dx.doi.org/10.1007/s10750-015-220... ). These characteristics enable the high diversity of species found in these fluvial systems (Naiman et al., 2000NAIMAN, R.J., ELLIOT, S.R., HELFIELD, J.M. and O’KEEFE, T.C. Biophysical interactions and the structure and dynamics of riverine ecosystems: the importance of biotic feedbacks. Hydrobiologia, 2000, 410(1), 79-86.; Simões et al., 2012SIMÕES, N.R., LANSAC-TÔHA, F.A., VELHO, L.F.M. and BONECKER, C.C. Intra and inter-annual structure of zooplankton communities in floodplain lakes: a long-term ecological research study. Revista de Biología Tropical, 2012, 60(4), 1819-1836. PMid:23342531. http://dx.doi.org/10.15517/rbt.v60i4.2183.
http://dx.doi.org/10.15517/rbt.v60i4.218... ).

Furthermore, there is higher primary productivity (Thomaz et al., 2004THOMAZ, S.M., PAGIORO, T.A., BINI, L.M., ROBERTO, M.C. and ROCHA, R.R.A. Limnological characterization of the aquatic environments and the influence of hydrometric levels. In: S.M. THOMAZ, A.A. AGOSTINHO and N.S. HAHN (Eds.). The Upper Paraná River and its floodplain: physical aspects, ecology and conservation. Leiden: Backhuys Publishers, 2004, pp. 75-102.), generally in the environments located in the lowland (such as tributaries and lakes), which contributes to a higher availability of feeding resources and favors higher species diversity. Thus, it can be affirmed that there is a tendency for such adjacent environments to function as a propagule source for the communities present in the main river of the floodplain (Braghin et al., 2015BRAGHIN, L.S.M., FIGUEIREDO, B.R.S., MEURER, T., MICHELAN, T.S., SIMÕES, N.R. and BONECKER, C.C. Zooplankton diversity in a dammed river basin is maintained by preserved tributaries in a tropical floodplain. Aquatic Ecology, 2015, 49(2), 175-187. http://dx.doi.org/10.1007/s10452-015-9514-7.
http://dx.doi.org/10.1007/s10452-015-951... ; Bomfim et al., 2015BOMFIM, F.D.F., FATORETO SCHWIND, L.T., BONECKER, C.C. and LANSAC-TÔHA, F.A. Variação espacial de rotíferos planctônicos: diversidade e riqueza de espécies. Arquivos Do Mudi, 2015, 19(1), 45-56. http://dx.doi.org/10.4025/arqmudi.v19i1.28230.
http://dx.doi.org/10.4025/arqmudi.v19i1.... ).

However, the construction of dams represents habitat fragmentation of this fluvial system, and therefore changes the environmental conditions of the whole system, altering both abiotic and interactions between organisms, thus affecting species diversity (Agostinho et al., 2008AGOSTINHO, A.A., PELICICE, F.M. and GOMES, L.C. Dams and the fish fauna of the Neotropical region: impacts and management related to diversity and fisheries. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2008, 68(4), 1119-1132. PMid:19197482. Supplement. http://dx.doi.org/10.1590/S1519-69842008000500019.
http://dx.doi.org/10.1590/S1519-69842008... ; Simões et al., 2015SIMÕES, N.R., NUNES, A.H., DIAS, J.D., LANSAC-TÔHA, F.A., VELHO, L.F.M. and BONECKER, C.C. Impact of reservoirs on zooplankton diversity and implications for the conservation of natural aquatic environments. Hydrobiologia, 2015, 758(1), 3-17. http://dx.doi.org/10.1007/s10750-015-2260-y.
http://dx.doi.org/10.1007/s10750-015-226... ; Winemiller et al., 2016WINEMILLER, K.O., MCINTYRE, P.B., CASTELLO, L., FLUET-CHOUINARD, E., GIARRIZZO, T., NAM, S., BAIRD, I.G., DARWALL, W., LUJAN, N.K., HARRISON, I., STIASSNY, M.L., SILVANO, R.A., FITZGERALD, D.B., PELICICE, F.M., AGOSTINHO, A.A., GOMES, L.C., ALBERT, J.S., BARAN, E., PETRERE JUNIOR, M., ZARFL, C., MULLIGAN, M., SULLIVAN, J.P., ARANTES, C.C., SOUSA, L.M., KONING, A.A., HOEINGHAUS, D.J., SABAJ, M., LUNDBERG, J.G., ARMBRUSTER, J., THIEME, M.L., PETRY, P., ZUANON, J., TORRENTE VILARA, G., SNOEKS, J., OU, C., RAINBOTH, W., PAVANELLI, C.S., AKAMA, A., VAN SOESBERGEN, A. and SÁENZ, L. Balancing hydropower and biodiversity in the Amazon, Congo, and Mekong. Science, 2016, 351(6269), 128-129. PMid:26744397. http://dx.doi.org/10.1126/science.aac7082.
http://dx.doi.org/10.1126/science.aac708... ).

Many of the studies on the impact of reservoirs in fluvial systems discuss the effects upstream of the dam, as flow reduction creates an artificial lake, interrupting the system’s natural flow. However, the impacts downstream of the dam are as important as those upstream, due to the volume and quality of water released by the reservoir’s operation (Agostinho et al., 2008AGOSTINHO, A.A., PELICICE, F.M. and GOMES, L.C. Dams and the fish fauna of the Neotropical region: impacts and management related to diversity and fisheries. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2008, 68(4), 1119-1132. PMid:19197482. Supplement. http://dx.doi.org/10.1590/S1519-69842008000500019.
http://dx.doi.org/10.1590/S1519-69842008... ). These impacts can be even more intense when a floodplain is located downstream of the reservoir, as this system presents unique characteristics, with high species diversity and aquatic communities adapted to the fluviometric dynamics (Agostinho et al., 1994AGOSTINHO, A.A., BENEDITO-CECÍLIO, E., GOMES, L.C. and SAMPAIO, A.A. Spatial and temporal distribution of sardela, Hypophthalmus edentatus (Pisces, Siluroidei), in the area of influence of the Itaipu Reservoir (Paraná, Brasil). Revista Unimar, 1994, 6(3), 27-40.; Ward & Tockner, 2001WARD, J.V. and TOCKNER, K. Biodiversity: towards a unifying theme for river ecology. Freshwater Biology, 2001, 46(6), 807-819. http://dx.doi.org/10.1046/j.1365-2427.2001.00713.x.
http://dx.doi.org/10.1046/j.1365-2427.20... ).

Nevertheless, it is known that, as the river proceeds downstream of the reservoirs, it tends to regain its natural characteristics. This occurs mainly due to the contribution of the environments connected to it, such as lakes and tributaries, which have differing water masses that present distinct physical, chemical and biological characteristics (Ward & Stanford, 1995WARD, J. and STANFORD, J.A. V and STANFORD, J. A. Ecological connectivity in alluvial river ecosystems and its disruption by flow regulation. Regulated Rivers: Research and Management, 1995, 11(1), 105-119. http://dx.doi.org/10.1002/rrr.3450110109.
http://dx.doi.org/10.1002/rrr.3450110109... ).

An important tool that has been used in the conservation and maintenance of systems is the concept of species nestedness (Baber et al., 2004BABER, M.J., FLEISHMAN, E., BABBITT, K.J. and TARR, T.L. The relationship between wetland hydroperiod and nestedness patterns in assemblages of larval amphibians and predatory macroinvertebrates. Oikos, 2004, 107(1), 16-27. http://dx.doi.org/10.1111/j.0030-1299.2004.12968.x.
http://dx.doi.org/10.1111/j.0030-1299.20... ). This concept is based on the non-random distribution of organisms (Worthen, 1996WORTHEN, W.B. Community composition and nested-subset analysis: basic descriptors for community ecology. Oikos, 1996, 76(1), 417-426. http://dx.doi.org/10.2307/3546335.
http://dx.doi.org/10.2307/3546335... ). The central idea is that a relatively poor biological assemblage is composed of a subset of the species that occur in a richer environment (Patterson & Atmar, 1986PATTERSON, B.D. and ATMAR, W. Nested subsets and the structure of insular mammalian faunas and archipelagos. Biological Journal of the Linnean Society, 1986, 28(1), 65-82. http://dx.doi.org/10.1111/j.1095-8312.1986.tb01749.x.
http://dx.doi.org/10.1111/j.1095-8312.19... ). A system is considered perfectly nested when any species found in a site is found in all sites with equal or higher richness, and any species absent in a particular site is absent from all sites with lower richness (Moore & Swihart, 2007MOORE, J.E. and SWIHART, R.K. Toward ecologically explicit null models of nestedness. Oecologia, 2007, 152(4), 763-777. PMid:17370091. http://dx.doi.org/10.1007/s00442-007-0696-0.
http://dx.doi.org/10.1007/s00442-007-069... ). This means the difference in the species richness between sites is what determines the distribution pattern of the community.

The zooplankton community is among the most diverse in aquatic ecosystems and is composed by rotifers, cladocerans and copepods (Lansac-Tôha et al., 2009LANSAC-TÔHA, F.A., BONECKER, C.C., VELHO, L.F.M., SIMÕES, N.R., DIAS, J.D., ALVES, G.M. and TAKAHASHI, E.M. Biodiversity of zooplankton communities in the upper Paraná river floodplain: interannual variation from longterm studies. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2009, 69(2), 539-549. Supplement. PMid:19738961. http://dx.doi.org/10.1590/S1519-69842009000300009.
http://dx.doi.org/10.1590/S1519-69842009... ). These organisms have the capacity to colonize distinct environments according to their development strategies. Such strategies are related to feeding and reproductive habits (Allan, 1976ALLAN, J.D. Life history patterns in zooplankton. American Naturalist, 1976, 110(971), 165-176. http://dx.doi.org/10.1086/283056.
http://dx.doi.org/10.1086/283056... ) that characterize their ecologic niches both in central and littoral regions of the aquatic environments (Monakov, 2006MONAKOV, A.V. Feeding of freshwater zooplankton invertebrates. Hydrobiologia, 2006, 559(1), 467-479.; Colares et al., 2013COLARES, M.A.M., BONECKER, C.C., SIMÕES, N.R., ALVES, G.M. and LANSAC-TÔHA, F.A. Structure of the zooplankton communities in macrophytes stand of a Neotropical floodplain (the Paraná River, Brazil). International Review of Hydrobiology, 2013, 98(2), 89-103. http://dx.doi.org/10.1002/iroh.201301471.
http://dx.doi.org/10.1002/iroh.201301471... ). Zooplankton is also considered as an important link in the aquatic food chain, participating in various trophic relations (Auer et al., 2004AUER, B., ELZER, U. and ARNDT, H. Comparison of pelagic food webs in lakes along a trophic gradient and with seasonal aspects: influence of resource and predation. Journal of Plankton Research, 2004, 26(1), 697-709. http://dx.doi.org/10.1093/plankt/fbh058.
http://dx.doi.org/10.1093/plankt/fbh058... ).

However, the establishment of zooplankton organisms in the aquatic environment is driven firstly by their high dispersal capacity (passive and/or active) and then by environmental filters (Padial et al., 2014PADIAL, A.A., CESCHIN, F., DECLERCK, S.A.J., DE MEESTER, L., BONECKER, C.C., LANSAC-TÔHA, F.A., RODRIGUES, L., RODRIGUES, L.C., TRAIN, S., VELHO, L.F. and BINI, L.M. Dispersal ability determines the role of environmental, spatial and temporal drivers of metacommunity structure. PLoS One, 2014, 9(10), e111227. PMid:25340577. http://dx.doi.org/10.1371/journal.pone.0111227.
http://dx.doi.org/10.1371/journal.pone.0... ; Dias et al., 2016DIAS, J.D., SIMÕES, N.R., MEERHOFF, M., LANSAC-TÔHA, F.A., VELHO, L.F.M. and BONECKER, C.C. Hydrological dynamics drives zooplankton metacommunity structure in a Neotropical floodplain. Hydrobiologia, 2016, 781(1), 109-125. http://dx.doi.org/10.1007/s10750-016-2827-2.
http://dx.doi.org/10.1007/s10750-016-282... ). This does not limit zooplankton distribution, as they quickly adapt to varied environmental conditions (Almer et al., 1974ALMER, B., DICKSON, W., EKSTROM, C., HORNSTROM, E. and MILLER, U. Effects of acidification on Swedish lakes. Ambio, 1974, 3(1), 30-36.; Havens, 1991HAVENS, K.E. Summer zooplankton dynamics in the limnetic and littoral zones of a humic acid lake. Hydrobiologia, 1991, 215(1), 21-29. http://dx.doi.org/10.1007/BF00005897.
http://dx.doi.org/10.1007/BF00005897... ), and respond to oscillations through high renovation rates (Pontin & Langley, 1993PONTIN, R.M. and LANGLEY, J.M. The use of rotifer communities to provide a preliminary national classification of small water bodies in England. Hydrobiologia, 1993, 255(1), 411-419. http://dx.doi.org/10.1007/BF00025866.
http://dx.doi.org/10.1007/BF00025866... ), altering the number of organisms and/or species composition in the community (Bonecker et al., 2009BONECKER, C.C., AOYAGUI, A.S.M. and SANTOS, R.M. The impact of impoundment on the rotifer communities in two tropical floodplain environments: interannual pulse variations. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2009, 69(2), 529-537. http://dx.doi.org/10.1590/S1519-69842009000300008.
http://dx.doi.org/10.1590/S1519-69842009... ; Lansac-Tôha et al., 2009LANSAC-TÔHA, F.A., BONECKER, C.C., VELHO, L.F.M., SIMÕES, N.R., DIAS, J.D., ALVES, G.M. and TAKAHASHI, E.M. Biodiversity of zooplankton communities in the upper Paraná river floodplain: interannual variation from longterm studies. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2009, 69(2), 539-549. Supplement. PMid:19738961. http://dx.doi.org/10.1590/S1519-69842009000300009.
http://dx.doi.org/10.1590/S1519-69842009... ). This idea complements the nestedness concept, because the heterogeneity and structure of the habitat influence the distribution and establishment of species and assemblage formation. Thereby, environments that are more complex support higher species richness than simpler environments (Hutchinson, 1959HUTCHINSON, G.E. Homage to Santa Rosalia or why are there so many kinds of animals? American Naturalist, 1959, 93(870), 145-159. http://dx.doi.org/10.1086/282070.
http://dx.doi.org/10.1086/282070... ; Simões et al., 2012SIMÕES, N.R., LANSAC-TÔHA, F.A., VELHO, L.F.M. and BONECKER, C.C. Intra and inter-annual structure of zooplankton communities in floodplain lakes: a long-term ecological research study. Revista de Biología Tropical, 2012, 60(4), 1819-1836. PMid:23342531. http://dx.doi.org/10.15517/rbt.v60i4.2183.
http://dx.doi.org/10.15517/rbt.v60i4.218... ).

Considering the ability of these organisms to respond to variations in local factors, together with the different hydrological characteristics of the environments present in these aquatic systems, and the importance of lakes and tributaries in the increase of species for the system, we aimed to investigate the spatial distribution of the zooplankton community (rotifers, cladocerans and copepods), and whether adjacent environments contribute to the composition of species in the Paraná River, and if this increase is cumulative along this stretch of river.

Therefore, we hypothesized that the composition of species in the Paraná River, after the dam of Porto Primavera, is similar to those recorded in the lakes and tributaries, and that this contribution makes the communities further away from the dam a set of the species constituted by the subsets found in upstream sites.

2. Material and Methods

2.1. Study area

This study was carried out in the high Paraná River floodplain (Paraná River, Baia River and Ivinhema) and adjacent sub-basins (Ivaí, Piquiri, Amambaí and Iguatemi Rivers). This stretch encompasses an area of 230 km² free from damming and located between the Porto Primavera dam (São Paulo, Brasil) (22º 37´S, 53º 6´W) and the backwater of the Itaipu reservoir (Paraná, Brasil) (23º 55´S, 54º 8´W) (Figure 1). In this stretch, three conservation units are included (Área de Proteção Ambiental das Ilhas e Várzeas do Rio Paraná, Parque Estadual das Várzeas do Rio Ivinhema, and Parque Nacional de Ilha Grande).

Figure 1
Study area between the Porto Primavera dam in Rosana city – SP and the beginning of the Itaipu dam, in Guaíra city – PR. P = sampling sites in the Paraná River; T = tributaries and L = lakes.

The high Paraná River floodplain has an important social and economic role for local human communities, enabling tourism and fishery activities (Gubiani et al., 2007GUBIANI, E.A., GOMES, L.C., AGOSTINHO, A.A. and OKADA, E.K. Persistence of fish populations in the upper Paraná River: effects of water regulation by dams. Ecology Freshwater Fish, 2007, 16(1), 191-197.). Furthermore, the floodplain presents high biodiversity, including a high zooplankton diversity of rotifers, cladocerans and copepods (Lansac-Tôha et al., 2009LANSAC-TÔHA, F.A., BONECKER, C.C., VELHO, L.F.M., SIMÕES, N.R., DIAS, J.D., ALVES, G.M. and TAKAHASHI, E.M. Biodiversity of zooplankton communities in the upper Paraná river floodplain: interannual variation from longterm studies. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2009, 69(2), 539-549. Supplement. PMid:19738961. http://dx.doi.org/10.1590/S1519-69842009000300009.
http://dx.doi.org/10.1590/S1519-69842009... ).

2.2. Field sampling and laboratory analysis

A total of 25 sampling points were established, including 10 points in the Paraná River (P1 to P10), eight in tributaries (Paranapanema, Baia, Ivinhema, Ivinheminha, Ivaí, Amambaí, Iguatemi and Piquiri Rivers, T1 to T8), and seven in the lakes located at these river margins (Garças, Xirica, Ivaí, São João, Xambrê, Pavão and Saraiva Lakes, L1 to L7) (Table 1 and Figure 1). This study was carried out in August and November 2013 and February, May and August 2014, encompassing different phases of the region’s hydrological cycle.

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Table 1
Characterization of sampling sites of the high Paraná River floodplain and, nearby subsystems^* * Information extracted for the report “Alto rio Paraná: gradiente longitudinal de variáveis ambientais e comunidades aquáticas no último trecho livre de barramentos entre UHE de Porto Primavera e reservatório de Itaipu/ PIE/PELD-CNPq”, in which this study is inserted (Velho, 2016). .

Zooplankton was sampled at the sub-surface of the pelagic region in each environment, with a motorized pump and plankton net (68 μm), filtering 600 liters of water per sample. The samples were conditioned in polyethylene flasks and preserved in 4% formaldehyde solution buffered with calcium carbonate.

Species identification was carried out according to specialized literature described in Lansac-Tôha et al. (2009)LANSAC-TÔHA, F.A., BONECKER, C.C., VELHO, L.F.M., SIMÕES, N.R., DIAS, J.D., ALVES, G.M. and TAKAHASHI, E.M. Biodiversity of zooplankton communities in the upper Paraná river floodplain: interannual variation from longterm studies. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2009, 69(2), 539-549. Supplement. PMid:19738961. http://dx.doi.org/10.1590/S1519-69842009000300009.
http://dx.doi.org/10.1590/S1519-69842009... , and zooplankton richness was analyzed in each sample until the curve of species-increase stabilized.

2.3. Data analysis

The frequency of species was determined considering the number of samples in which they occurred in relation to the total number of samples. This was calculated with the following formula: C = p.100/P, where C is the constancy index, p is the number of samples where the species occurred, and P is the total number of samples. Also, species were classified as constant (present in > 80% of samples), frequent (50-80%), common (20-50%) and rare (< 20%) (Castilho et al., 2016CASTILHO, M.C.A., WISNIEWSKI, M.J.S., WISNIEWSKI, C. and SILVA, E.S. Quantifying zooplankton species: use of richness estimators. Iheringia. Série Zoologia, 2016, 106(1), e2016011.).

Nestedness was analyzed using the NODF index (nestedness metric based on overlap and decreasing fill), proposed by Almeida-Neto et al. (2008)ALMEIDA-NETO, M., GUIMARÃES, P., GUIMARÃES JUNIOR, P.R., LOYOLA, R.D. and ULRICH, W. A consistent metric for nestedness analysis in ecological systems: reconciling concept and measurement. Oikos, 2008, 117(8), 1227-1239. http://dx.doi.org/10.1111/j.0030-1299.2008.16644.x.
http://dx.doi.org/10.1111/j.0030-1299.20... and Ulrich et al. (2009)ULRICH, W., ALMEIDA-NETO, M. and GOTELLI, N.J. A consumer’s guide to nestedness analysis. Oikos, 2009, 118(1), 3-17. http://dx.doi.org/10.1111/j.1600-0706.2008.17053.x.
http://dx.doi.org/10.1111/j.1600-0706.20... . It was assumed that samples in the Paraná River would have an accumulation of species in the P1 to P10 direction, and that a set of the species found in the previous sites would be found in P10 (with higher species richness), as a result of the contribution of the species of the main river and adjacent tributaries and lakes. Thus, the results for NODF rows were analyzed.

This index calculates null models (randomly expected communities) and compares them with observed values for the real communities, providing a statistic confidence interval (p) to the results. An occurrence matrix was constructed for each zooplankton group (rotifers, cladocerans and copepods), where rows represented sampled sites and columns represented species. When a species was present in the site, we attributed the value 1, and when it was absent, we attributed the value 0. We ordinated the matrix decreasingly in relation to the sampled sites in the columns (P10 to P1).

To analyze the similarity in species composition between the environmental groups (Paraná River, lakes and tributaries), a cluster analysis was carried out using the Ward algorithm. Cluster analysis separated the environments according to the presence and absence of the species in a way that sites with a higher number of common species were grouped in the same block (Mingoti, 2005MINGOTI, S.A. Análise de dados através de métodos de estatística multivariada: uma abordagem aplicada. Belo Horizonte: Editora UFMG, 2005.).

Both analyses were performed using software R 3.0 (R Development Core Team, 2014R DEVELOPMENT CORE TEAM. R: A language and environment for statistical computing [online]. Vienna: R Foundation for Statistical Computing, 2014 [viewed 29 Nov. 2016]. Available from: http://www.R-project.org/.
http://www.R-project.org/... ), with the vegan package (Oksanen et al., 2010OKSANEN, J., BLANCHET, F.G. and KINDT, R. Vegan: community ecology package! R package version 3.0 [online]. San Francisco: R-Forge, 2010 [viewed 29 Nov. 2016]. Available from: http://vegan.r-forge.r-project.org/
http://vegan.r-forge.r-project.org/... ).

3. Results

3.1. Characterization of the zooplankton community

The zooplankton community was represented by 193 taxa in the sampled sites: these were 116 rotifers, 48 cladocerans and 29 copepods. Species were distributed in 27 families, from which Lecanidae and Brachionidae were the most representative for rotifers (21 and 22 species, respectively); Chydoridae for cladocerans (27 species) followed by Daphniidae (6 species); and Cyclopidae were representative for copepods (19 species) (Table 2).

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Table 2
Inventory of the species in the studied environments of the high Paraná River floodplain and adjacent sub-systems.

The frequency of occurrence of species showed the absence of constant species in the community. Copepods presented a higher number of frequent species (four), Notodiaptomus henseni (75%), Notodiaptomus cearenses (69.14%), Thermocyclops decipiens (59.57%) and Thermocyclops minutus (59.57%), plus three common and 22 rare species. For cladocerans, we registered the occurrence of three frequent species, Bosmina hagmanni (72.34%), Daphnia gessneri (72.34%) and Bosminopsis deitersi (53.19%), seven common, and 38 rare species. Finally, rotifers were represented by only two frequent species (50-80%), Lecane bulla (59.46%) and Keratella cochlearis (50.52%), 11 common species and 103 rare species (Table 2).

Species richness varied little among different environments, but was higher in lakes and tributaries. In lakes, the mean richness was 26 species, and the standard deviation was between 17 and 34 species (higher variation). In tributaries, the mean was 20 species, and the standard deviation was between 12 and 28 species. In the Paraná River, the mean was 19 species, and the standard deviation was between 13 and 25 species (Figure 2).

Figure 2
Zooplankton richness (mean and standard deviation) registered in the environments (river (Paraná), lakes and tributaries).

3.2. Clustering and nestedness

Cluster analysis indicated a separation of the sampling sites in the river, tributaries and lakes in two main groups A and B, according to species occurrences (Figure 3). For cladocerans and copepods, results were more evident, as group A was formed in its majority by sampling sites in the river (P1 to P10), and group B by sites in tributaries (T1 to T8) and lakes (L1 to L7). Although rotifer composition was also separated into two groups, we observed a lower dissimilarity than cladocerans and copepods, between sampling sites in the river, tributaries and lakes.

Figure 3
Cluster analysis dendrogram showing the similarity between zooplankton sampled environments, for (a) rotifers, (b) cladocerans and (c) copepods.

Nestedness analysis indicated that rotifers, cladocerans and copepods followed a nested distribution in this longitudinal stretch of the Paraná River. In P10, we observed a set of species composed of previous subsets (Figure 4), as was shown by significant values of the NODF row indexes of 65.65, 69.99, and 73.46, respectively, for each group (Table 3).

Figure 4
Distribution of presence (black) and absence (white) of rotifer (a), cladocerans (b), and copepod species (c) in the sites of the Paraná River. The most superior line represents the richest site (P10).

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Table 3
Results of the nestedness analysis.

4. Discussion

The families that most contributed to the composition of the community (Lecanidae and Brachionidae for rotifers, Chydoridae for cladocerans, and Cyclopidae for copepods), are commonly registered in floodable areas in the neotropical region (Paggi & José de Paggi, 1990PAGGI, J.C. and JOSÉ DE PAGGI, S. Zooplâncton de ambientes lóticos e lênticos do rio Paraná médio. Acta Limnologica Brasiliensia, 1990, 3(1), 685-719.; Lansac-Tôha et al., 2009LANSAC-TÔHA, F.A., BONECKER, C.C., VELHO, L.F.M., SIMÕES, N.R., DIAS, J.D., ALVES, G.M. and TAKAHASHI, E.M. Biodiversity of zooplankton communities in the upper Paraná river floodplain: interannual variation from longterm studies. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2009, 69(2), 539-549. Supplement. PMid:19738961. http://dx.doi.org/10.1590/S1519-69842009000300009.
http://dx.doi.org/10.1590/S1519-69842009... ; Bozelli et al., 2015BOZELLI, R.L., THOMAZ, S.M., PADIAL, A.A., LOPES, P.M. and BINI, L.M. Floods decrease zooplankton beta diversity and environmental heterogeneity in an Amazonian floodplain system. Hydrobiologia, 2015, 753(1), 233-241. http://dx.doi.org/10.1007/s10750-015-2209-1.
http://dx.doi.org/10.1007/s10750-015-220... ). The higher contribution of rotifer species to the zooplankton composition, including rare species, is due to these organisms being opportunistic, with short life cycles, and consuming a great variety of food items, from bacteria to other rotifers (Auer et al., 2004AUER, B., ELZER, U. and ARNDT, H. Comparison of pelagic food webs in lakes along a trophic gradient and with seasonal aspects: influence of resource and predation. Journal of Plankton Research, 2004, 26(1), 697-709. http://dx.doi.org/10.1093/plankt/fbh058.
http://dx.doi.org/10.1093/plankt/fbh058... ; Kalinowska et al., 2015KALINOWSKA, K., EJSMONT-KARABIN, J., RZEPECKI, M., KOSTRZEWSKA-SZLAKOWSKA, I., FENIOVA, I.Y., PALASH, A. and DZIALOWSKI, A.R. Impacts of large-bodied crustaceans on the microbial loop. Hydrobiologia, 2015, 744(1), 115-125. http://dx.doi.org/10.1007/s10750-014-2066-3.
http://dx.doi.org/10.1007/s10750-014-206... ). This varied diet favors the simultaneous presence of many species in the same environment, or of the same species in different environments (Neves et al., 2003NEVES, I.F., ROCHA, O., ROCHE, K.F. and PINTO, A.A. Zooplankton community structure of two marginal lakes of the River Cuiabá (Mato Grosso, Brazil) with analysis of Rotifera and Cladocera diversity. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2003, 63(2), 329-343. PMid:14509855. http://dx.doi.org/10.1590/S1519-69842003000200018.
http://dx.doi.org/10.1590/S1519-69842003... ), increasing their representativeness in sites with distinct characteristics (Branco et al., 2002BRANCO, C.W.C., ROCHA, M.I.A., PINTO, G.F.S., GOMARA, G.A. and FILIPPO, R.D. Limnological features of Funil reservoir (RJ, Brazil) and indicator properties of rotifers and cladocerans of the zooplankton community. Lakes and Reservoirs: Research and Management, 2002, 7(2), 87-92. http://dx.doi.org/10.1046/j.1440-169X.2002.00177.x.
http://dx.doi.org/10.1046/j.1440-169X.20... ; Lansac-Tôha et al., 2005LANSAC-TÔHA, F.A., BONECKER, C.C. and VELHO, L.F.M. Estrutura da comunidade zooplânctonica em reservatórios. In: L. RODRIGUES, S.M. THOMAZ, A.A. AGOSTINHO and L.C. GOMES, eds. Biocenoses em reservatórios: padrões espaciais e temporais. São Carlos: Rima, 2005, pp. 115-127.).

The variation in species richness between the river, tributaries and lakes may be related to morphological heterogeneity and highly productive microhabitats (Thomaz et al., 2007THOMAZ, S.M., BINI, L.M. and BOZELLI, R.L. Floods increase similarity among aquatic habitats in river-floodplain systems. Hydrobiologia, 2007, 579(1), 1-13. http://dx.doi.org/10.1007/s10750-006-0285-y.
http://dx.doi.org/10.1007/s10750-006-028... ), enabling variations in the zooplankton community. Thus, the variation in flow velocity may be important in structuring the community. The lowest flow, commonly found in lakes, favors the establishment and development of planktonic populations (Aoyagui & Bonecker, 2004AOYAGUI, A.S.M. and BONECKER, C.C. Rotifers in different environments of the Upper Paraná River floodplain (Brazil): richness, abundance and the relationship with connectivity. Hydrobiologia, 2004, 522(1), 281-290. http://dx.doi.org/10.1023/B:HYDR.0000029980.49859.40.
http://dx.doi.org/10.1023/B:HYDR.0000029... ). In general, there is also a higher phytoplankton biomass registered in these environments (Roberto et al., 2009ROBERTO, M.C., SANTANA, N.F. and THOMAZ, S.M. Limnology in the Upper Paraná river floodplain: large-scale spatial and temporal patterns, and the influence of reservoirs. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2009, 69(2), 717-725. Supplement. PMid:19738977. http://dx.doi.org/10.1590/S1519-69842009000300025.
http://dx.doi.org/10.1590/S1519-69842009... ), which is an important feeding resource for zooplankton (Simões et al., 2012SIMÕES, N.R., LANSAC-TÔHA, F.A., VELHO, L.F.M. and BONECKER, C.C. Intra and inter-annual structure of zooplankton communities in floodplain lakes: a long-term ecological research study. Revista de Biología Tropical, 2012, 60(4), 1819-1836. PMid:23342531. http://dx.doi.org/10.15517/rbt.v60i4.2183.
http://dx.doi.org/10.15517/rbt.v60i4.218... ).

In the river, the flow is faster, and few species are able to stay in the water column, independent of the hydrological period (Lansac-Tôha et al., 2009LANSAC-TÔHA, F.A., BONECKER, C.C., VELHO, L.F.M., SIMÕES, N.R., DIAS, J.D., ALVES, G.M. and TAKAHASHI, E.M. Biodiversity of zooplankton communities in the upper Paraná river floodplain: interannual variation from longterm studies. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2009, 69(2), 539-549. Supplement. PMid:19738961. http://dx.doi.org/10.1590/S1519-69842009000300009.
http://dx.doi.org/10.1590/S1519-69842009... ). This relationship has also been reflected in the smaller variation in species richness in the river. On the other hand, in lakes, where variation in the number of species was higher, population fluctuations may occur according to the hydrological period. In general, in the drought periods, there is a high concentration of individuals, and in the flood, a higher dilution (Simões et al., 2013SIMÕES, N.R., DIAS, J.D., LEAL, C.M., BRAGHIN, L.S.M., LANSAC-TÔHA, F.A. and BONECKER, C.C. Floods control the influence of the environmental gradients on the diversity of zooplankton communities in a neotropical floodplain. Aquatic Sciences, 2013, 75(1), 607-617. http://dx.doi.org/10.1007/s00027-013-0304-9.
http://dx.doi.org/10.1007/s00027-013-030... ).

The relatively high species richness (25 species) in some sites of the Paraná River may be attributed to the contribution of the fauna of important tributaries present in these stretches, two of them being located inside conservation units. These tributaries also receive a contribution of the fauna of the lakes connected to them. Lakes have a high diversity of species (Lansac-Tôha et al., 2009LANSAC-TÔHA, F.A., BONECKER, C.C., VELHO, L.F.M., SIMÕES, N.R., DIAS, J.D., ALVES, G.M. and TAKAHASHI, E.M. Biodiversity of zooplankton communities in the upper Paraná river floodplain: interannual variation from longterm studies. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2009, 69(2), 539-549. Supplement. PMid:19738961. http://dx.doi.org/10.1590/S1519-69842009000300009.
http://dx.doi.org/10.1590/S1519-69842009... ), making them a source of propagules, and contribute to the increase in biodiversity of the whole system (Braghin et al., 2015BRAGHIN, L.S.M., FIGUEIREDO, B.R.S., MEURER, T., MICHELAN, T.S., SIMÕES, N.R. and BONECKER, C.C. Zooplankton diversity in a dammed river basin is maintained by preserved tributaries in a tropical floodplain. Aquatic Ecology, 2015, 49(2), 175-187. http://dx.doi.org/10.1007/s10452-015-9514-7.
http://dx.doi.org/10.1007/s10452-015-951... ; Bomfim et al., 2015BOMFIM, F.D.F., FATORETO SCHWIND, L.T., BONECKER, C.C. and LANSAC-TÔHA, F.A. Variação espacial de rotíferos planctônicos: diversidade e riqueza de espécies. Arquivos Do Mudi, 2015, 19(1), 45-56. http://dx.doi.org/10.4025/arqmudi.v19i1.28230.
http://dx.doi.org/10.4025/arqmudi.v19i1.... ). We believe that tributaries and lakes are increasing the species richness in the Paraná River, since the first sampling sites in this main river have few zooplankton species. Furthermore, the connectivity between the river and lakes, especially during the drought period, is preponderant for this dispersal, allowing a constant exchange of fauna among environments (Petry et al., 2003PETRY, A.C., AGOSTINHO, A.A. and GOMES, L.C. Fish assemblages of tropical floodplain lagoons: exploring the role of connectivity in a dry year. Neotropical Ichthyology, 2003, 1(2), 111-119. http://dx.doi.org/10.1590/S1679-62252003000200005.
http://dx.doi.org/10.1590/S1679-62252003... ; Lansac-Tôha et al., 2009LANSAC-TÔHA, F.A., BONECKER, C.C., VELHO, L.F.M., SIMÕES, N.R., DIAS, J.D., ALVES, G.M. and TAKAHASHI, E.M. Biodiversity of zooplankton communities in the upper Paraná river floodplain: interannual variation from longterm studies. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2009, 69(2), 539-549. Supplement. PMid:19738961. http://dx.doi.org/10.1590/S1519-69842009000300009.
http://dx.doi.org/10.1590/S1519-69842009... ).

The results of the cluster analysis (species dissimilarity) highlighted that the microcrustacean species composition differs more clearly between the environments of the floodplain (lakes and tributaries) and the main river. This can be related to the differences between these environments and organisms’ adaptations. The Paraná River has been suffering from the oligotrophization process, with a reduction in the concentration of nutrients and increasing water transparency in the last 15 years (Roberto et al., 2009ROBERTO, M.C., SANTANA, N.F. and THOMAZ, S.M. Limnology in the Upper Paraná river floodplain: large-scale spatial and temporal patterns, and the influence of reservoirs. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2009, 69(2), 717-725. Supplement. PMid:19738977. http://dx.doi.org/10.1590/S1519-69842009000300025.
http://dx.doi.org/10.1590/S1519-69842009... ), affecting aquatic communities, such as macrophytes, fishes, phytoplankton, and others (Thomaz et al., 2009THOMAZ, S.M., CARVALHO, P., PADIAL, A.A. and KOBAYASHI, J.T. Temporal and spatial patterns of aquatic macrophyte diversity in the upper Paraná River floodplain. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2009, 69(2), 617-625. Supplement. PMid:19738968. http://dx.doi.org/10.1590/S1519-69842009000300016.
http://dx.doi.org/10.1590/S1519-69842009... ; Fernandes et al., 2009FERNANDES, R., AGOSTINHO, A.A., FERREIRA, E.A., PAVANELLI, C.S., SUZUKI, H.I., LIMA, D.P. and GOMES, L.C. Effects of the hydrological regime on the ichthyofauna of riverine environments of the Upper Paraná River floodplain. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2009, 69(2), 669-680. Supplement. PMid:19738973. http://dx.doi.org/10.1590/S1519-69842009000300021.
http://dx.doi.org/10.1590/S1519-69842009... ; Rodrigues et al., 2009RODRIGUES, L.C., TRAIN, S., BOVO-SCOMPARIN, V.M., JATI, S., BORSALLI, C.C.J. and MARENGONI, E. Interannual variability of phytoplankton in the main rivers of the Upper Paraná River floodplain, Brazil: influence of upstream reservoirs. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2009, 69(2), 501-516. Supplement. PMid:19738958. http://dx.doi.org/10.1590/S1519-69842009000300006.
http://dx.doi.org/10.1590/S1519-69842009... ), and these changes reflect in the microcrustacean species establishment.

The cladocerans and copepods are more selective about their food resources and, have longer life cycles than rotifers (Allan, 1976ALLAN, J.D. Life history patterns in zooplankton. American Naturalist, 1976, 110(971), 165-176. http://dx.doi.org/10.1086/283056.
http://dx.doi.org/10.1086/283056... ). Thus, the reduced primary productivity in the main river, together with the higher flow velocity and increase in water transparency (Schwind et al., 2016SCHWIND, L.T.F., ARRIEIRA, R.L., DIAS, J.D., SIMÕES, N.R., BONECHER, C.C. and LANSAC-TÔHA, F.A. The structure of planktonic communities of testate amoebae (Arcellinida and Euglyphida) in three environments of the Upper Paraná River basin, Brazil. Journal of Limnology, 2016, 75(1), 78-89.), seem to have influenced the establishment of different species of these microcrustaceans in distinct environments (river and adjacent environments). Considering this, while the Paraná River is poor in food resources, the lagoons of this plain have high availability of foods, such as phytoplankton and protozoa (Bomfim, F. F. unpublished data), in addition to the physical differences between them.

The rotifers, on the other hand, presented a higher dispersal in the system, which is related to their opportunistic characteristics, such as short life cycle, higher niche amplitude, and smaller size of individuals (Allan, 1976ALLAN, J.D. Life history patterns in zooplankton. American Naturalist, 1976, 110(971), 165-176. http://dx.doi.org/10.1086/283056.
http://dx.doi.org/10.1086/283056... ; Bonecker et al., 2009BONECKER, C.C., AOYAGUI, A.S.M. and SANTOS, R.M. The impact of impoundment on the rotifer communities in two tropical floodplain environments: interannual pulse variations. Brazilian Journal of Biology = Revista Brasileira de Biologia, 2009, 69(2), 529-537. http://dx.doi.org/10.1590/S1519-69842009000300008.
http://dx.doi.org/10.1590/S1519-69842009... ). Therefore, some sites of the Paraná River were grouped to adjacent environments in the dissimilarity analysis.

The observed pattern of zooplankton species nestedness demonstrates the contribution of the adjacent environments to the increase of species along the river stretch (Moretto & Nogueira, 2003MORETTO, E.M. and NOGUEIRA, M.G. Physical and chemical characteristics of Lavapés and Capivara Rivers, tributaries of Barra Bonita Reservoir (São Paulo - Brazil). Acta Limnologica Brasiliensia, 2003, 15(1), 27-39.). This suggests that this environment has a tendency to return to some of its natural characteristics, such as species richness, which occurs from its connectivity with the lakes and tributaries of its margins (Ward & Stanford, 1995WARD, J. and STANFORD, J.A. V and STANFORD, J. A. Ecological connectivity in alluvial river ecosystems and its disruption by flow regulation. Regulated Rivers: Research and Management, 1995, 11(1), 105-119. http://dx.doi.org/10.1002/rrr.3450110109.
http://dx.doi.org/10.1002/rrr.3450110109... ). The upstream reservoir (Porto Primavera) contributed to the composition of species in the first sampling points of the Paraná River, but during the 230 km to the last collection point (P10), there was an accumulation of species, which in this point (P10) was a set of species formed by subsets of the points before it. We thus emphasize that this is due to the contribution of the environments adjacent to this river.

Some studies have also found the same nestedness distribution pattern for the zooplankton community (Boecklen, 1997BOECKLEN, W.J. Nestedness, biogeographic theory, and the design of nature reserves. Oecologia, 1997, 112(1), 123-142. PMid:28307369. http://dx.doi.org/10.1007/s004420050292.
http://dx.doi.org/10.1007/s004420050292... ; Ramos-Jiliberto et al., 2009RAMOS-JILIBERTO, R., OYANEDEL, J. P., VEGA-RETTER, C. and VALDOVINOS, F. S. Nested structure of plankton communities from Chilean freshwaters. Limnologica - Ecology and Management of Inland Waters, 2009, 39(4), 319-324.). More structured habitats favor the establishment of a higher number of species than more simple environments (Simões et al., 2012SIMÕES, N.R., LANSAC-TÔHA, F.A., VELHO, L.F.M. and BONECKER, C.C. Intra and inter-annual structure of zooplankton communities in floodplain lakes: a long-term ecological research study. Revista de Biología Tropical, 2012, 60(4), 1819-1836. PMid:23342531. http://dx.doi.org/10.15517/rbt.v60i4.2183.
http://dx.doi.org/10.15517/rbt.v60i4.218... ), and a nested distributive pattern implies that poorer sites are subsets of richer sites. Considering this, conservation practices must be concentrated in such environments and in species exchanges between them to protect the zooplankton diversity (De Meester et al., 2005DE MEESTER, L., DECLERCK, S., STOKS, R., LOUETTE, G., VAN DE MEUTTER, F., DE BIE, T., MICHELS, E. and BRENDONCK, L. Ponds and pools as model systems in conservation biology, ecology and evolutionary biology. Aquatic Conservation, 2005, 15(1), 715-725. http://dx.doi.org/10.1002/aqc.748.
http://dx.doi.org/10.1002/aqc.748... ).

Thus, our hypothesis was partially corroborated. Only the species composition of rotifers was similar between some sites of the main river and adjacent environments, due to the intrinsic characteristics of this group. However, the contribution of the fauna from lakes and tributaries for the river was determinant for the composition of species in this environment. This contribution was also responsible for the accumulation of species in the river, along the stretch to the beginning of the Itaipu reservoir (P10, with higher species richness).

Some physical characteristics of the environments (such as flow and depth) and the oligotrophization process of the main river have also influenced structuring of the community, but these factors were surpassed by the connectivity between the river and the lowland. With this, we suggest the importance of the conservation of environments adjacent to the main river for the maintenance of zooplankton species in the floodplain, considering the dynamics of this system and the important roles of the zooplankton in its trophic dynamics. Furthermore, the lowland environments support the restitution of the structure and dynamics of the Paraná River, which is highly impacted by damming, mainly in the stretch in which there is connectivity between the river and the conservation units in protected areas, like lakes, side channels and tributaries.

Acknowledgements

The authors would like to thank the research project “Alto rio Paraná: gradiente longitudinal de variáveis ambientais e comunidades aquáticas no último trecho livre de barramentos entre UHE de Porto Primavera e reservatório de Itaipu/ PIE/PELD-CNPq.”, which inspired this research. We are also grateful for the grants provided by the Brazilian National Council of Research and Development (CNPq) and the Coordination for the Improvement of Higher Education Personnel (CAPES). C.C.B. and F.A.M.L. are grateful for the research productivity grant provided by CNPq.

Cite as: Bomfim, F.F. et al. Adjacent environments contribute to the increase of zooplankton species in a neotropical river. Acta Limnologica Brasiliensia, 2017, vol. 29, e103.

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BRAGHIN, L.S.M., FIGUEIREDO, B.R.S., MEURER, T., MICHELAN, T.S., SIMÕES, N.R. and BONECKER, C.C. Zooplankton diversity in a dammed river basin is maintained by preserved tributaries in a tropical floodplain. Aquatic Ecology, 2015, 49(2), 175-187. http://dx.doi.org/10.1007/s10452-015-9514-7
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Publication Dates

Publication in this collection
2017

History

Received
29 Nov 2016
Accepted
25 Aug 2017

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] Cite as: Bomfim, F.F. et al. Adjacent environments contribute to the increase of zooplankton species in a neotropical river. Acta Limnologica Brasiliensia, 2017, vol. 29, e103.

Environments	Environmental characterization
Paraná River (P1 to P10)	(22º 62´S, 53º 15´W; 24º 10´S, 54º 31´W): Non-dammed stretch extending for 230 km, from Porto Primavera dam to the backwater of Itaipu reservoir.
Garças Lake (L1)	(22º 79´S, 53º 24´W): Located in the Paraná River, with a length of 2.1 km, mean depth of 2.0 m, area of 150 m² and perimeter of 5 km.
Xirica Lake (L2)	(22º 47´S, 53º 21´W): Communicates with the Paraná River through a canal of approximately 200 m. Has an area of 10 m², perimeter of 1.31 km and mean depth of 1.12 m.
Ivai Lake (L3)	(23º 41´S, 53º 75´W): Has permanent communication with the Paraná River. Has an area of 100 m², perimeter of 2 km and mean depth of 2 m.
São João Lake (L4)	(23º 84´S, 53º 07´W): Communicates with the Paraná River through a canal of approximately 1.3 km. Presents an area of 2.21 km², perimeter of 6 km and mean depth of 1.70 m.
Xambrê Lake (L5)	(23º 51´S, 45º 1´W): Without communication with the Paraná River. Has an area of 4.78 km², perimeter of 12.3 km and mean depth of 3.6 m.
Pavão Lake (L6)	(24º 06´S, 54º 29´W): Communicates with the Paraná River through a canal of 150 m. Has an area of 4.5 km², perimeter of 770 m and mean depth of 2.7 m.
Saraiva Lake (L7)	(24º 12´S, 54º 19´W). Communicates with the Paraná River through a canal of approximately 1.5 km. Has an area of 1.14 km², perimeter of 19.5 km and depth of 1.6 m.
Paranapanema River (T1)	(22º 39´S, 53º 4´W): Tributary from the left margin of the Paraná River, has its headsprings in eastern São Paulo state. Has a total extension of 929 km and drained area of 100.800 km².
Baia River (T2)	(22º 46´S, 53º 19´W): Tributary from the right margin of the Paraná River, has varied width and mean depth of 3.2 m, with narrower stretches when margins are higher.
Ivinhema River (T3)/ Ivinheminha River (T4)	(22º 59´S, 53º 39´W/ 23º 14´S 53º 43´W): Tributary of the right margin of the Paraná River, has a length/width ratio of 22:1, flow velocity of approximately 0.85 m s^-1 and mean depth of 3.9 m.
Ivai River (T5)	(23º 17´S, 53º 40´W): Tributary of the left margin of the Paraná River, has its headwaters in Serra da Esperança, southeast Paraná state. Extends for approximately 685 km and has a drainage basin of more than 35,000 km².
Amambai River (T6)	(23º 21´S, 53º 53´W): Tributary of the right margin of the Paraná River, has its headwaters in Serra do Maracaju, Mato Grosso do Sul state. Has a hydrographic basin with total area of 10.206 km² and an extension of 354 km, flowing into the Paraná River at an altitude of 240 m.
Iguatemi River (T7)	(24º 01´S, 54º 9´W): Tributary of the right margin of the Paraná River, has its headwaters in the extreme South of Mato Grosso do Sul state. Extends for around 300 km. Has its headwater at an altitude of approximately 520 m and flows into the Paraná River at an altitude of 226 m.
Piquiri River (T8)	(23º 55´S, 54º 9´W): Tributary of the left margin of the Paraná River, has its headwaters in Serra do São João, in the border between the municipalities of Turvo and Guarapuava, Paraná state.

ROTIFERA	P	L	T		P	L	T
Lecanidae
Lecane aculeata (Jakubski, 1912)+			X	L. ungulata (Gosse, 1887)+	X		X
L. bulla (Gosse, 1851)+++	X	X	X	L. stenroosi (Meissner, 1908)+	X		X
L. closterocerca (Schmarda, 1859)+	X		X	L. signifera (Jennings, 1896)+	X
L. cornuta (Muller, 1786)+	X	X	X	L. quadridentata (Ehrenberg, 1832)+	X		X
L. curvicornis (Murray, 1913)++	X	X	X	L. proeicta (Hauer, 1956)+	X	X	X
L. elsa Hauer, 1931+	X	X	X	L. papuana (Murray, 1913)+	X	X	X
L. halyclista Harring & Myers, 1926+		X		L. papuana (Murray, 1913)+	X
L. hastata (Murray, 1913)+	X			L. mira (Murray, 1913)+		X	X
L. hornemanni (Ehrenberg, 1834)+	X			L. lunaris (Ehrenberg, 1832)++	X	X	X
L. leontina (Turner, 1892)+	X	X	X	L. lunaris (Ehrenberg, 1832)++	X	X	X
L. ludwigii (Eckstein, 1883)+	X	X	X
Brachionidae
Brachionus angularis Gosse, 1851+	X	X	X	Platyias leloupi Gillard, 1967+	X	X	X
B. budapestinensis Daday, 1885+	X	X	X	Plationus macrachantus (Daday, 1905)+	X	X	X
B. calyciflorusPallas, 1766++	X	X	X	P. quadricornis (Ehrenberg, 1832)+	X	X	X
B. calyciflorus spinosus Rousselet, 1901+		X		P. patulus patulus(Müller,1786)+	X	X	X
B caudatus Barrois & Daday, 1894+	X	X	X	Keratella americana Carlin, 1943++	X	X	X
B. c. personatus Ahlstrom, 1940+	X	X	X	K. cochlearis (Gosse, 1851)+++	X	X	X
B. dolabratus Harring, 1915+	X	X	X	K. c. macracantha (Lauterborn, 1900)+		X
B. falcatus Zacharias, 1898+	X	X	X	K. lenzi Hauer, 1953++	X	X	X
B. forficula Wierzejski, 1891+	X	X		K. tropica (Apstein, 1907)++	X	X	X
B. mirus Daday, 1905+	X	X	X	Kellicottia bostoniensis (Rousselet, 1908)++	X	X	X
B. quadridentatus Hermann, 1783+	X	X	X
B. urceolaris O. F. Müller, 1773+	X		X
Trichocercidae
Trichocerca agnatha Wulfert, 1939+		X		T. stylata (Gosse, 1851)+	X	X
T. bicristata (Gosse, 1887)+	X	X	X	T. similis (Wierzejski, 1893)+			X
T. bidens (Lucks, 1912)+	X		X	T. pusilla (Jennings, 1903)+	X		X
T. capucina (Wierzejski & Zacharias, 1893)+			X	T. porcellus (Gosse, 1851)+			X
T. cylindrica (Imhof, 1891)+	X	X	X	T. myersi (Hauer, 1931)+	X		X
T. elongata (Gosse, 1886)+	X		X	T. longiseta (Schrank, 1802)+	X	X	X
T. gracillis (Tessin, 1890)+	X	X	X	T. heterodactyla (Tschugunoff, 1921)+		X
Euchlanidae
Dipleuchanis propatula (Gosse, 1886)+	X	X	X	E. meneta Myers, 1930+		X
Euchlanis deflexa (Gosse, 1851)+			X	E. i. mucronata Ahlstrom, 1934+	X		X
E. dilatata Ehrenberg, 1832++	X	X	X	E. incisa Carlin, 1939+	X		X
Mytilinidae
Mytilina acanthophora Hauer, 1939+	X			M. ventralis (Ehrenberg, 1830)+	X
M. macrocerca (Jennings, 1894)+	X			M. m.spinigera (Ehrenberg, 1830)+	X
M. mucronata (Muller 1773)+	X		X
Testudinellidae
Testudinella ahlstromi Hauer 1956+	X		X	T. truncata Gosse, 1886+			X
T. ohlei Koste, 1972+	X	X	X	T. patina (Hermann, 1783)+	X	X	X
T. mucronata (Gosse,1886)+	X
Filinidae
Filinia longiseta(Ehrenberg, 1834)+	X	X	X	F. terminalis(Plate, 1886)++	X	X	X
F. opoliensis(Zacharias, 1898)+	X	X	X
Synchaetidae
Ploesoma triacanthum(Bergendal, 1892)+	X			Synchaeta oblonga Ehrenberg, 1832++	X	X	X
P. truncatum (Levander, 1894)+	X	X	X	S. pectinata Ehrenberg 1832+	X	X	X
Polyarthra dolichoptera Idelson, 1925+	X	X	X	S. stylata Wierzejski,1893+	X	X
P. vulgaris Carlin, 1943+	X	X	X
Notommatidae
Cephalodella forficula Ehrenberg, 1830+	X		X	Monommata dentata Wulfert, 1940+			X
C. mucronata Myers, 1924+	X			Notommata copeus Ehrenberg, 1834+	X
C. obvia Donner, 1950+			X	N. pachyura (Gosse, 1886)+	X
Lepadellidae
Lepadella. oblonga (Ehrenberg, 1834)+	X		X	L. patella oblonga (Ehrenberg, 1834)+	X	X	X
L. ovalis (Müller, 1786)+	X		X	L. triptera (Ehrenberg, 1832)+	X
L. patella (Muller, 1773)+	X
Conochilidae
Conochilus coenobasis (Skorikov, 1914)+	X	X	X	C. natans (Seligo, 1900)+	X	X	X
C. dossuaris (Hudson, 1885)+	X	X		C. unicornis Rousselet, 1892+	X	X	X
Gastropodidae
Ascomorpha cf. agilis Zacharias, 1893+	X		X	Gastropus hyptopus (Ehrenberg, 1838)+		X	X
A. ecaudis Perty, 1850+		X	X	G. stilifer Imhof, 1891+	X	X
A. ovalis Carlin, 1943+	X	X	X
Dicranophoridae
Aspelta angusta Harring & Myers, 1928+			X	Dicranophorus forcipatus (Müller, 1786)+			X
Dicranophoroides caudatus (Ehrenberg, 1834)+	X	X	X	Dicranophorus epicharis Harring & Myers, 1928+	X
Trichotriidae
Trichotria tetractis(Ehrenberg, 1830)+	X	X	X
Hexarthridae
Hexarthra intermedia intermedia (Wiszniewski, 1929)+			X	Hexarthra mira (Hudson, 1871)+		X
Asplanchnidae
Asplanchna priodonta Gosse, 1850+	X		X	A. sieboldi (Leydig, 1854)+	X	X	X
Epiphanidae
Epiphanes clavulata (Ehrenberg, 1832)+	X	X	X	E. senta (Müller, 1773)+			X
E. macroura (Barrois & Daday, 1894)+	X		X
Ituridae
Itura myersi Wulfert, 1935+			X
CLADOCERA
Moinidae
Moina micrura Kurz, 1874+		X	X	M. reticulata (Daday, 1905)+	X	X
M. minuta Hansen, 1899++	X	X	X
Bosminidae
Bosmina hagmanni Stingelin, 1904+++	X	X	X	Bosmina tubicen Brehm, 1953+	X	X	X
Bosmina longirostris (De Melo; Herbert, 1994)+	X	X	X	Bosminopsis deitersi Richard, 1895+++	X	X	X
Daphniidae
Ceriodaphnia cornuta Sars, 1886++	X	X	X	Daphnia gessneri (Herbst, 1967)+++	X	X	X
C. reticulata (Jurine, 1820)+			X	D. lumholtzi Sars, 1885++	X	X	X
C. silvestrii Daday, 1902+	X	X	X	Simocephalus semisseratus (Kock, 1841)+	X
Sididae
Diaphanosoma birgei Korinek, 1981++	X	X	X	D. spinulosum Herbst, 1967+	X	X	X
D. brevireme Sars, 1901+	X	X		D. polyspina Korovchinsky, 1982+		X
D. fluviatilis Hansen, 1899+	X	X	X
Ilyocryptidae
Ilyocryptus spinifer Herrich, 1884++	X	X	X
Macrothricidae
Macrothrix elegans (Sars, 1901)+	X	X	X	Macrothrix squamosa Sars, 1901+	X	X	X
Chydoridae
Acroperus tupinamba Sinev & Elmoor-Loureiro, 2010+	X		X	Notoalona sculpta (Sars, 1901)+	X	X	X
Alona dentifera (Sars, 1901)+		X	X	Nicsmirnovius fitiztatricki (Chien, 1970)+	X	X	X
A. glabra Sars, 1901+	X			Leydigia ipojucae Brehm, 1938+	X
A.gutatta Sars, 1862++	X	X	X	L. propinqua Sars, 1903+			X
A. iheringula Sars, 1901+	X			Karualona muelleri (Richard, 1897)+	X	X	X
A. intermedia Sars, 1862+	X		X	Graptoleberis occidentalis Sars, 1901+	X
Alonella clathratula Sars, 1896+	X		X	Euryalona brasiliensis Brehm & Thomsen, 1936+	X		X
A. dadayi Birge, 1910+	X	X	X	Ephemeroporus. barroisi (Richard, 1894)+			X
Anthalona verrucosa (Sars, 1901)+	X	X	X	E. hybridus(Dadayi, 1905)+	X	X
Camptocercus australis Sars, 1896++	X	X	X	E. tridentatus (Bergamin, 1931)+		X
Chydorus eurynotus Sars, 1901+	X	X	X	Coronatella monocantha (Sars, 1901)+	X	X	X
Chydorus parvireticulatusFrey, 1897+	X	X	X	C. poppei (Richard, 1897)+	X	X	X
Chydorus pubescens Sars, 1901+	X		X	Dunhevedia odontoplax Sars, 1901+	X	X	X
Chydorus cf. sphaericus (O. F. Müller, 1776)+	X
COPEPODA
Cyclopidae
Acanthocyclops robustus (Sars, 1863)+	X			T. minutus (Lowndes, 1934)+++	X	X	X
Ectocyclops rubescens Brady, 1904+			X	Thermocyclops decipiens (Kiefer, 1929)+++	X	X	X
Eucyclops ensifer (Fischer, 1853)+	X	X	X	Paracyclops chiltoni (Thomson, 1883)+	X	X	X
Eucyclops prinophorus Kiefer, 1931+		X		P. pilosus Dussart, 1983+		X
Eucyclops elegans (Herrick, 1884)+	X	X	X	Microcyclops alius (Kiefer, 1935)+	X
Macrocyclops albidus (Jurine, 1820)+		X		Microcyclops anceps (Richard, 1897)+	X	X	X
Mesocyclops aspericornis (Daday, 1906)+	X	X		Microcyclops finitmus (Dussart, 1984)+		X	X
M. longisetus (Thiébaud, 1914)+	X			Metacyclops laticornis(Lowndes, 1934)+		X	X
M. meridianus (Kiefer, 1926)+	X	X	X	Metacyclops mendocinus (Wierzejski, 1892)+			X
M. ogunnus Onabamiro, 1957+
Diaptomidae
Argyrodiaptomus azevedoi (Wright, 1935)++	X	X	X	N. coniferoides (Wrigth, 1927)++	X	X	X
A. denticulatus (Pesta, 1927)+		X	X	N. deitersi (Poppe, 1891)+	X
A. furcatus (Sars, 1901)+	X	X	X	N. henseni (Dahl, 1894)+++	X	X	X
Notodiaptomus cearensis Wright, 1936+++	X	X	X	N. iheringi (Wright, 1935)++	X	X	X
N. cf. spinuliferus Reid & Moreno, 1990+	X	X	X	N. isabelae (Wright, 1936)+	X	X	X

NODF index
Rotifers	Statistic	Z	2.50%	50%	97.50%	P	Filling %
N.columns	36.46	34.67	32.62	34.63	36.78	0.127
N.rows	65.65	34.23	30.37	34.31	37.60	0.001
NODF	36.64	34.66	32.62	34.62	36.78	0.071	36.60
Cladocerans
N.columns	41.96	38.10	34.82	38.05	41.64	0.041
N.rows	69.99	37.62	32.28	37.65	42.24	0.001
NODF	42.75	38.09	34.88	38.06	41.61	0.017	36.96
Copepods
N.columns	28.34	37.33	31.99	37.41	42.36	0.003
N.rows	73.46	37.17	30.63	37.15	43.73	0.001
NODF	32.33	37.31	32.20	37.41	42.31	0.055	36.12

Brasil

Brasil

Adjacent environments contribute to the increase of zooplankton species in a neotropical river

Ambientes adjacentes contribuem no incremento de espécies zooplanctônicas em um rio neotropical

Abstracts

Abstract

Methods

Results

Conclusion

Resumo

Métodos

Resultados

Conclusão

1. Introduction

2. Material and Methods

2.1. Study area

2.2. Field sampling and laboratory analysis

2.3. Data analysis

3. Results

3.1. Characterization of the zooplankton community

3.2. Clustering and nestedness

4. Discussion

Acknowledgements

References

Publication Dates

History