Abstract
In alluvial plains, where shallow lakes are subject to inputs of sediments, the impact of turbidity on predator–prey interactions needs to be studied. We conducted an in situ mesocosm study in a shallow floodplain lake during 36 days to evaluate the main and interactive effect of fish predation and turbidity on the abundances, composition and habitat selection of a natural aquatic assemblage, including zooplankton and plant-associated invertebrates, and the cascading effect on phytoplankton biomass. Four treatments were involved: clear water (C), clear water plus fish (CF), turbid water (T), and turbid water plus fish (TF). In each mesocosm, free-floating macrophytes were included to provide environmental heterogeneity, so organisms could display habitat selection. Fish predation was the main factor in structuring the abundances and assemblages composition regardless of turbidity condition. This was explained in part, because turbidity alone did not cause structural changes in the assemblage composition, but produced disorientation of prey organisms, weakening the effect of macrophyte roots as a refuge and favoring the consumption by fish in TF. Therefore, the trophic link between fishes and their prey was the same for zooplankton and stronger for amphipods and chironomids under turbid conditions than in clear waters. Fish caused a cascading effect on phytoplankton biomass, but it was partially counterbalanced under turbid condition due to the negative effect of clay particles on the planktonic algae due to light attenuation. Our results suggest that, within a specific turbidity range, there should be no mismatch in the trophic link between fish and phytoplankton.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Availability of data and materials
All data included in this study are available upon request by contact with the corresponding author.
References
Agostinho AA, Thomaz SM, Gomes LC, Baltar SL (2007) Influence of the macrophyte Eichhornia azurea on fish assemblage of the Upper Paraná River floodplain (Brazil). Aquatic Ecol 41:611–619
Ahlstrom EH (1940) A revision of the rotatorian genera Brachionus and Platyias, with descriptions of one new species and two new varieties. Bull AMNH vol 77:article 3
APHA (2005) Standard methods for the examination of water and wastewater, 21st edn. American Public Health Association, United States
Brooks JL, Dodson SI (1965) Predation, body size, and composition of plankton. Science 150:28–35
Carvalho ML (1984) Influence of predation by fish and water turbidity on a Daphnia gessneri population in an Amazonian floodplain lake, Brazil. In: Tropical Zooplankton. Springer, Dordrecht, pp 243–247
Castro BB, Marques SM, Gonçalves F (2007) Habitat selection and diel distribution of the crustacean zooplankton from a shallow Mediterranean lake during the turbid and clear water phases. Freshw Biol 52:421–433
Chen M, Chen F (2017) Effect of suspended solids on interaction between filter-feeding fish Aristichthys nobilis and zooplankton in a shallow lake using a mesocosm experiment. J Freshw Ecol 32:219–227
Clemente JM, Boll T, Teixeira-de Mello F, Iglesias C, Roer A, Pedersen EJ, Meerhoff M (2019) Role of plant architecture on littoral macroinvertebrates in temperate and subtropical shallow lakes: a comparative manipulative field experiment. Limnetica 38:759–772
Coelho PN, Henry R (2021) Functional groups of microcrustaceans along a horizontal gradient in a Neotropical lake colonized by macrophytes. Aquatic Sci 83:1–13
Cuker BE, Gama PT, Burkholder JM (1990) Type of suspended clay influences lake productivity and phytoplankton community response to phosphorus loading. Limnol Oceanogr 35:830–839
de Wit HA, Ledesma JL, Futter MN (2016) Aquatic DOC export from subarctic Atlantic blanket bog in Norway is controlled by seasalt deposition, temperature and precipitation. Biogeochemistry 127:305–321
Donohue I, Garcia Molinos J (2009) Impacts of increased sediment loads on the ecology of lakes. Biol Rev 84:517–531
Drago EC (2007) The physical dynamics of the river–lake floodplain system. In: The Middle Paraná River. Springer, Berlin, Heidelberg, pp 83–122
Drago EC, Amsler ML (1988) Suspended sediment at a cross section of the Middle Paraná River: concentration, granulometry and influence of the main tributaries. In: Sediment Budgets. IAHS Publication, p 174
Escalante AH (1982) Contribución al conocimiento de las relaciones tróficas de peces de agua dulce del área platense. I: Astyanax eigenmanniorum (Osteichthyes Tetragonopteridae)
Esteves KE (1996) Feeding ecology of three Astyanax species (Characidae, Tetragonopterinae) from a floodplain lake of Mogi-Guaçú River, Paraná River basin, Brazil. Environ Biol Fish 46:83–101
Evans CD, Thomas DN (2016) Controls on the processing and fate of terrestrially-derived organic carbon in aquatic ecosystems: synthesis of special issue. Aquat Sci 78:415–418
Figueiredo BR, Mormul RP, Benedito E (2015) Structural complexity and turbidity do not interact to influence predation rate and prey selectivity by a small visually feeding fish. Mar Freshw Res 66:170–176
Figueiredo BR, Calvo C, López-Rodríguez A, Mormul RP, Teixeira-de Mello F, Benedito E, Meerhoff M (2019) Short-term interactive effects of experimental heat waves and turbidity pulses on the foraging success of a subtropical invertivorous fish. Water 11:2109
Fontanarrosa MS, Chaparro GN, O’Farrell I (2013) Temporal and spatial patterns of macroinvertebrates associated with small and medium-sized free-floating plants. Wetlands 33:47–63
Frau D, Devercelli M, José de Paggi S, Scarabotti P, Mayora G, Battauz Y, Senn M (2015) Can top-down and bottom-up forces explain phytoplankton structure in a subtropical and shallow groundwater-connected lake? Mar Freshw Res 66:1106–1115
Frau D, Gutierrez MF, Rojas Molina F, Teixeira-de Mello F (2021) Drivers assessment of zooplankton grazing on phytoplankton under different scenarios of fish predation and turbidity in an in situ mesocosm experiment. Hydrobiologia 848:485–498
Gardner MB (1981) Mechanisms of size selectivity by planktivorous fish: a test of hypotheses. Ecology 62:571–578
Gelós M, Teixeira-de Mello F, Goyenola G, Iglesias C, Fosalba C, García-Rodríguez F, Pacheco JP, García S, Meerhoff M (2010) Seasonal and diel changes in fish activity and potential cascading effects in subtropical shallow lakes with different water transparency. Hydrobiologia 646:173–185
Gliwicz ZM, Pijanowska J (1989) The role of predation in zooplankton succession. In: Plankton ecology. Springer, Berlin, Heidelberg, pp 253–296
Gonzalez Sagrario MDLA, Balseiro E (2010) The role of macroinvertebrates and fish in regulating the provision by macrophytes of refugia for zooplankton in a warm temperate shallow lake. Freshw Biol 55:2153–2166
Guenther M, Bozelli R (2004) Factors influencing algae–clay aggregation. Hydrobiologia 523:217–223
Hamilton SK, Kellndorfer J, Lehner B, Tobler M (2007) Remote sensing of floodplain geomorphology as a surrogate for biodiversity in a tropical river system (Madre de Dios, Peru). Geomorphology 89:23–38
Hammer Ø, Harper DA, Ryan PD (2013) PAST-Palaeontological Statistics, version 3. University of Oslo, Oslo
Heimstra NW, Damkot DK (1969) 20. Some effects of silt turbidity on behavior of juvenile largemouth bass and green sunfish. Technical Papers of the Bureau of Sport Fisheries and Wildlife 18
Hilton J, Rigg E (1983) Determination of nitrate in lake water by the adaptation of the hydrazine-copper reduction method for use on a discrete analyser: performance statistics and an instrument-induced difference from segmented flow conditions. Analyst 108:1026–1028
Horppila J, Liljendahl-Nurminen A, Malinen T (2004) Effects of clay turbidity and light on the predator prey interaction between smelts and chaoborids. Can J Fish Aquatic Sci 61:1862–1870
Horppila J, Eloranta P, Liljendahl-Nurminen A, Niemistö J, Pekcan-Hekim Z (2009) Refuge availability and sequence of predators determine the seasonal succession of crustacean zooplankton in a clay-turbid lake. Aquat Ecol 43:91–103
Huotari J, Nykänen H, Forsius M, Arvola L (2013) Effect of catchment characteristics on aquatic carbon export from a boreal catchment and its importance in regional carbon cycling. Global Change Biol 19:3607–3620
Iglesias C, Mazzeo N, Meerhoff M, Lacerot G, Clemente JM, Scasso F, Kruk C, Goyenola G, García-Alonso J, Amsinck SL, Paggi JC, José-de Paggi S, Jeppesen E (2011) High predation is of key importance for dominance of small-bodied zooplankton in warm shallow lakes: evidence from lakes, fish exclosures and surface sediments. Hydrobiologia 667:133–147
Iglesias C, Mazzeo N, Goyenola G, Fosalba C, Teixeira-de Mello F, Garcia S, Jeppesen E (2008) Field and experimental evidence of the effect of Jenynsia multidentata, a small omnivorous–planktivorous fish, on the size distribution of zooplankton in subtropical lakes. Freshw Biol 53:1797–1807
Iriondo MH, Paggi JC, Parma MJ (eds) (2007) The Middle Paraná River limnology of a subtropical wetland. Springer Science and Business Media
Jeppesen E, Meerhoff M, Jacobsen BA, Hansen RS, Søndergaard M, Jensen JP, Lauridsen TL, Mazzeo N, Branco CWC (2007) Restoration of shallow lakes by nutrient control and biomanipulation—the successful strategy varies with lake size and climate. Hydrobiologia 581:269–285
José de Paggi SB, Muñoz S, Frau D, Paggi JC, Scarabotti P, Devercelli M, Meerhoff M (2012) Horizontal distribution of rotifers in a subtropical shallow lake (Paraná floodplain, Argentina). Fund Appl Limnol/Archiv für Hydrobiologie 180:321–333
Koste W (1978) Rotatoria. Die Radertiere Mitteleuropas, Gebruder Borntraeger, p 673
Larsen S, Andersen TOM, Hessen DO (2011) Climate change predicted to cause severe increase of organic carbon in lakes. Global Change Biol 17:1186–1192
Lauridsen TL, Jeppesen E, Søndergaard M, Lodge DM (1998) Horizontal migration of zooplankton: predator-mediated use of macrophyte habitat. In: The structuring role of submerged macrophytes in lakes. Springer, New York, pp 233–239
Lehtiniemi M, Engström-Öst J, Viitasalo M (2005) Turbidity decreases anti-predator behaviour in pike larvae, Esox lucius. Environ Biol Fish 73:1–8
Leibold MA, Norberg J (2004) Biodiversity in metacommunities: plankton as complex adaptive systems? Limnol Oceanogr 49:1278–1289
Lewis WM, Hamilton SK, Lasi MA, Rodríguez M, Saunders JF (2000) Ecological determinism on the Orinoco Floodplain: a 15-year study of the Orinoco floodplain shows that this productive and biotically diverse ecosystem is functionally less complex than it appears. Hydrographic and geomorphic controls induce a high degree of determinism in biogeochemical and biotic processes. Bioscience 50:681–692
Liu T, Zhang AN, Wang J, Liu S, Jiang X, Dang C, Ma T, Liu S, Chen Q, Xie S, Zhang T, Ni J, Zhang T (2018) Integrated biogeography of planktonic and sedimentary bacterial communities in the Yangtze River. Microbiome 6:16
Lobson C, Luong K, Seburn D, White M, Hann B, Prosser RS, Wong CS, Hanson ML (2018) Fate of thiamethoxam in mesocosms and response of the zooplankton community. Sci Tot Environ 637:1150–1157
Mamani A, Koncurat ML, Boveri M (2019) Combined effects of fish and macroinvertebrate predation on zooplankton in a littoral mesocosm experiment. Hydrobiologia 829:19–29
Mangini SP, Prendes HH, Amsler ML, Huespe J (2003) Importancia de la floculación en la sedimentación de la carga de lavado en ambientes del río Paraná, Argentina. Tecnología ciencias agua 18:55–69
Mayora G, Devercelli M, dos Santos AM (2017) Effects of the hydrosedimentological regime on nitrogen transport and speciation in a large subtropical floodplain river. Inland Water 7:461–472
Mayora G, Schneider B, Rossi A (2018) Turbidity and dissolved organic matter as significant predictors of spatio-temporal dynamics of phosphorus in a large river-floodplain system. River Res Appl 34:629–639
Mazzeo N, Lacerot G, Kruk C, Gorga J, Scasso F, Rodríguez-Gallego L, Clemente JM, García J (2000) Lago Rivera, situación actual y estrategias para su recuperación. Reporte Técnico. Facultad de Ciencias-Sección Limnología, Montevideo
Mazzeo N, Iglesias C, Teixeira-de Mello F, Borthagaray A, Fosalba C, Ballabio R, Larrea D, Vilches J, García S, Pacheco JP, Jeppesen E (2010) Trophic cascade effects of Hoplias malabaricus (Characiformes, Erythrinidae) in subtropical lakes food webs: a mesocosm approach. Hydrobiologia 644:325–335
Meerhoff M, Iglesias C, Teixeira de Mello F, Clemente JM, Jensen E, Lauridsen TL, Jeppesen E (2007) Effects of habitat complexity on community structure and predator avoidance behaviour of littoral zooplankton in temperate versus subtropical shallow lakes. Freshw Biol 52:1009–1021
Neiff JJ (1990) Ideas para la interpretación ecológica del Paraná. Interciencia 15:424–441
Nicolle A, Hansson LA, Brönmark C (2010) Habitat structure and juvenile fish ontogeny shape zooplankton spring dynamics. Hydrobiologia 652:119–125
Ohman MD, Romagnan JB (2016) Nonlinear effects of body size and optical attenuation on diel vertical migration by zooplankton. Limnol Oceanogr 61(2):765–770
Oksanen J (2015) Vegan: an introduction to ordination. http://cran.r-project.org/web/packages/vegan/vignettes/introvegan.pdf 8, 19
Oliveros OB (1980) Campaña limnológica" Keratella I" en el río Paraná medio: aspectos tróficos de los peces de ambientes leníticos. Ecología 4:115–126
Paggi JC (1979) Revisión de las especies argentinas del género Bosmina Baird agrupadas en el subgénero Neobosmina Lieder (Crustacea: Cladocera)
Paggi JC (1995) Crustacea cladocera. Ecosistemas de Aguas Continentales, Metodologías para su estudio
Paira AR, Drago EC (2007) Origin, evolution, and types of floodplain water bodies. In: The Middle Paraná River. Springer, Berlin, Heidelberg, pp 53–81
Quintana XD, Arim M, Badosa A, Blanco JM, Boix D, Brucet S, Compte J, Egozcue JJ, Eyto E, Gaedke U, Gascón S, Gil de Solá L, Irvine K, Jeppesen E, Lauridsen TL, López-Flores R, Mehner T, Romo S, Søndergaard M (2015) Predation and competition effects on the size diversity of aquatic communities. Aquat Sci 77:45–57
R Core Team (2018) R: A language and environment for statistical computing. Version 3.3.0. R Foundation for Statistical Computing, Vienna
Reid JW (1985) Chave de identificação e lista de referências bibliográficas para as espécies continentais sulamericanas de vida livre da ordem Cyclopoida (Crustacea, Copepoda). Instituto de Biociências, Universidade de São Paulo
Sallenave RM, Barton DR (1990) The distribution of benthic invertebrates along a natural turbidity gradient in Lake Temiskaming, Ontario-Quebec. Hydrobiologia 206:225–234
Scanferla AFLDS, Súarez YR (2016) Flood pulse are the main determinant of feeding dynamics and composition of Odontostilbe pequira (Characiformes: Characidae) in southern Pantanal. Brazil. Acta Limnol Bras 28:e19
Scarabotti PA, Lopez JA, Pouilly M (2011) Flood pulse and the dynamics of fish assemblage structure from neotropical floodplain lakes. Ecol Freshwat Fish 20:605–618
Schou MO, Risholt C, Lauridsen TL, Søndergaard M, Grønkjær P, Jacobsen L, Berg S, Skov C, Brucet S, Jeppesen E (2009) Restoring lakes by using artificial plant beds: habitat selection of zooplankton in a clear and a turbid shallow lake. Freshw Biol 54:1520–1531
Schulze PC (2011) Evidence that fish structure the zooplankton communities of turbid lakes and reservoirs. Freshw Biol 56:352–365
Smirnov NN (1992) Guides to the identification of the microinvertebrates of the continental waters of the world. 1. The Macrothricidae of the world. SPB Academic Publishing, The Hague
Solomon SC, Qian L, Roble RG (2015) New 3-D simulations of climate change in the thermosphere. J Geophys Res Space Phys 120:2183–2193
Tavşanoğlu ÜN, Brucet S, Levi EE, Bucak T, Bezirci G, Özen A, Johansson LS, Jeppesen BM (2015) Size-based diel migration of zooplankton in Mediterranean shallow lakes assessed from in situ experiments with artificial plants. Hydrobiologia 753:47–59
Teixeira-de Mello F, Meerhoff M, González-Bergonzoni I, Kristensen EA, Baattrup-Pedersen A, Jeppesen E (2016) Influence of riparian forests on fish assemblages in temperate lowland streams. Environ Biol Fish 99:133–144
Van den Brink PJ, Braak CJFT (1999) Principal response curves: analysis of time-dependent multivariate responses of biological community to stress. Environ Toxicol Chem 18:138–148
Vellend M (2016) The theory of ecological communities (MPB-57). Princeton University Press
Wolf R, Heuschele J (2018) Water browning influences the behavioral effects of ultraviolet radiation on zooplankton. Front Ecol Evol 6:26
Zhou J, Qin B, Han X (2018) The synergetic effects of turbulence and turbidity on the zooplankton community structure in large, shallow Lake Taihu. Enviro Sci Poll Res 25:1168–1175
Acknowledgements
We thank the authorities of the Reserva Ecológica “El Pozo” for allowing us to establish the mesocosms in the lake. We also especially thank Osvaldo Gutierrez, Cristian De Bonis, Celeste Mora and Diana Alberto for their technical assistance in the field and with the physical and chemical analyses of the water, to Dr. Rodrigo Lorenzón for its suggestions on the statistical analyses, and two anonymous reviewers for their helpful comments. This experiment was supported by the project PIP 0395CO (Consejo Nacional de Investigaciones Científicas y Técnicas, Argentina). MFG, FRM, DF and CA were supported by the Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET), and FTM was supported by the Sistema Nacional de Investigadores (SNI), and the Programa de Desarrollo de las Ciencias Básicas (PEDECIBA, Uruguay).
Funding
This experiment was supported by the project PIP 0395CO (Consejo Nacional de Investigaciones Científicas y Técnicas, Argentina).
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflicts of interest
The authors declare no conflicts of interest.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Below is the link to the electronic supplementary material.
Rights and permissions
About this article
Cite this article
Gutierrez, M.F., Molina, F.R., Teixeira-de-Mello, F. et al. Influence of fish predation on the dynamic of zooplankton and macroinvertebrates in floodplain lakes under different turbidity conditions: an experimental study. Aquat Sci 83, 48 (2021). https://doi.org/10.1007/s00027-021-00805-8
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s00027-021-00805-8