Floods drive functional zooplankton diversity in a core area of the Brazilian Pantanal Biosphere Reserve

References

• Allan DJ. 1976. Life history patterns in zooplankton. Am Nat. 110(971):165–180.
   Web of Science ®Google Scholar
• Andrade MdS, Brandimarte AL, Calheiros DF, Tambosi LR. 2015. Spatial and limnological characterization of the Paraguai River floodplain area, Southern Pantanal, with emphasis on the “decoada” phenomenon. Geografia. 40(Número especial):27–38.
   Google Scholar
• [APHA] American Public Health Association. 2023. Lipps WC, Braun-Howland EB, Baxter TE, eds. Standard methods for the examination of water and wastewater. 24th ed. Washington (DC): APHA Press.
   Google Scholar
• Barbosa AM, Real R, Munoz AR, Brown JA. 2013. New measures for assessing model equilibrium and prediction mismatch in species distribution models. Divers Distrib. 19(10):1333–1338.
   Web of Science ®Google Scholar
• Barnett AJ, Finlay K, Beisner BE. 2007. Functional diversity of crustacean zooplankton communities: towards a trait-based classification. Freshw Biol. 52(5):796–813.
   Web of Science ®Google Scholar
• Bomfim FF, Braghin LSM, Bonecker CC, Lansac-Tôha FA. 2018. High food availability linked to dominance of small zooplankton in a subtropical floodplain. Int Rev Hydrobiol. 103(1–2):26–34.
   Web of Science ®Google Scholar
• Bonecker CC, Diniz LP, Braghin LdS, Mantovano T, da Silva JVF, Bomfim FdF, Moi DA, Deosti S, dos Santos GNT, das Candeias DA, et al. 2020. Synergistic effects of natural and anthropogenic impacts on zooplankton diversity in a subtropical floodplain: a long-term study. Oecologia Australis. 24(2):524–537.
   Google Scholar
• Bonecker CC, Simões NR, Minte-Vera CV, Lansac-Tôha FA, Velho LFM, Agostinho ÂA. 2013. Temporal changes in zooplankton species diversity in response to environmental changes in an alluvial valley. Limnologica. 43(2):114–121.
   Web of Science ®Google Scholar
• Botta-Dukát Z, Czúcz B. 2016. Testing the ability of functional diversity indices to detect trait convergence and divergence using individual-based simulation. Methods Ecol Evol. 7(1):114–126.
   Web of Science ®Google Scholar
• Bovo-Scomparin VM, Train S, Rodrigues LC. 2013. Influence of reservoirs on phytoplankton dispersion and functional traits: a case study in the Upper Paraná River, Brazil. Hydrobiologia. 702:115–127.
   Web of Science ®Google Scholar
• Bozelli RL, Thomaz SM, Padial AA, Lopes PM, Bini LM. 2015. Floods decrease zooplankton beta diversity and environmental heterogeneity in an Amazonian floodplain system. Hydrobiologia. 753(1):233–241.
   Web of Science ®Google Scholar
• Braghin LdS, Almeida BdA, Amaral DC, Canella TF, Gimenez BCG, Bonecker CC. 2018. Effects of dams decrease zooplankton functional β-diversity in river-associated lakes. Freshw Biol. 63(7):721–730.
   Web of Science ®Google Scholar
• Braghin LdS, Dias JD, Simões NR, Bonecker CC. 2021. Food availability, depth, and turbidity drive zooplankton functional diversity over time in a Neotropical floodplain. Aquat Sci. 83(1):10.
   Web of Science ®Google Scholar
• Braghin LdS, Simões NR, Bonecker CC. 2016. Hierarchical effects of local factors on zooplankton species diversity. Inland Waters. 6(4):645–654.
   Web of Science ®Google Scholar
• Brancalion PHS, Campoe O, Mendes JCT, Noel C, Moreira GG, van Melis J, Stape JL, Guillemot J. 2019. Intensive silviculture enhances biomass accumulation and tree diversity recovery in tropical forest restoration. Ecol Appl. 29(2):e01847.
   Web of Science ®Google Scholar
• Brasil. 2000. Regulamenta o art. 225, § 1o, incisos I, II, III e VII da Constituição Federal, institui o Sistema Nacional de Unidades de Conservação da Natureza e dá outras providências [Regulates art. 225, § 1, items I, II, III and VII of the Federal Constitution, establishes the National System of Nature Conservation Units and provides other measures]. http://www.planalto.gov.br/ccivil_03/leis/L9985.htm
   Google Scholar
• Carlucci MB, Brancalion PHS, Rodrigues RR, Loyola R, Cianciaruso Mv. 2020. Functional traits and ecosystem services in ecological restoration. Restor Ecol. 28(6):1372–1383.
   Web of Science ®Google Scholar
• [CETESB] Companhia Ambiental do Estado de São Paulo. 2014. Determinação de Clorofila a e Feofitina a: método espectrofotométrico [Determination of chlorophyll a and pheophytin a: spectrophotometric method]. Technical Standard L5.306, 3rd ed., Environmental Company of the State of São Paulo.
   Google Scholar
• Chaparro G, O’Farrell I, Hein T. 2019. Multi-scale analysis of functional plankton diversity in floodplain wetlands: effects of river regulation. Sci Total Environ. 667:338–347.
   PubMed Web of Science ®Google Scholar
• Cunha P, Bianchini A, Ribeiro CdO, Niencheski LFH, Fillmann G, Santos CSG. 2006. Barrios MAMCU, editors. Avaliação Ambiental de Estuários Brasileiros: Diretrizes Metodológicas [Environmental assessment of Brazilian estuaries. Methodological guidelines]. Rio de Janeiro (Brazil): Museu Nacional.
   Google Scholar
• Debastiani JR, Naliato DAO, Perbiche-Neves G, Nogueira MG. 2016. Ambientes fluviais laterais na bacia do Rio da Prata: efeitos dos barramentos de hidrelétricas e da eutrofização [Fluvial lateral environments in Río de La Plata basin: effects of hydropower damming and eutrophication]. Acta Limnol Bras. 28:e26.
   Google Scholar
• Dias JD, Miracle MR, Bonecker CC. 2017. Do water levels control zooplankton secondary production in Neotropical floodplain lakes? Fund Appl Limnol. 190(1):49–62.
   Web of Science ®Google Scholar
• Dray S, Choler P, Dolédec S, Peres-Neto PR, Thuiller W, Pavoine S, Ter Braak CJF. 2014. Combining the fourth-corner and the RLQ methods for assessing trait responses to environmental variation. Ecology. 95(1):14–21.
   PubMed Web of Science ®Google Scholar
• Dray S, Dufour A. 2007. The ade4 package: implementing the duality diagram for ecologists. J Stat Softw. 22(4):1–20.
   Web of Science ®Google Scholar
• Duarte LDS, Debastiani VJ, Carlucci MB, Diniz-Filho JAF. 2018. Analyzing community-weighted trait means across environmental gradients: should phylogeny stay or should it go? Ecology. 99(2):385–398.
   PubMed Web of Science ®Google Scholar
• Elmoor-Loureiro LMA. 1997. Manual de Identificação de Cladóceros Límnicos do Brasil [Manual for identification of Cladocerans from Brazil]. Brasília. https://www.researchgate.net/publication/264417714
   Google Scholar
• Eskinazi-Sant’Anna EM, Santos GdS, Alves NdS, Brito LAF, Leite MGP. 2020. The relative importance of regional and local factors in shaping zooplankton diversity in high-altitude tropical shallow lakes. J Freshw Ecol. 35(1):203–221.
   Web of Science ®Google Scholar
• Ferreira Barbosa ML, Haddad I, Nascimento ALS, Máximo da Silva G, Moura da Veiga R, Hoffmann TB, et al. 2022. Compound impact of land use and extreme climate on the 2020 fire record of the Brazilian Pantanal. Glob Ecol Biogeogr. 31:1960–1975.
   Web of Science ®Google Scholar
• Fontaneto D. 2019. Long-distance passive dispersal in microscopic aquatic animals. Mov Ecol. 7(1).
   PubMedGoogle Scholar
• Frota AVB, Ikeda-Castrillon SK, Kantek DLZ, Da Silva CJ. 2017. Macrohabitats da Estação Ecológica de Taiamã, no contexto da Área Úmida Pantanal mato-grossense, Brasil [Macrohabitats of the Taiamã Ecological Station, in the context of the Pantanal Wet Area of ⁣⁣Mato Grosso, Brazil]. Boletim do Museu Paraense Emílio Goeldi – Ciências Naturais. 12(2):239–254.
   Google Scholar
• Frutos SM, Neiff ASG, Neiff JJ. 2006. Zooplankton of the Paraguay River: a comparison between sections and hydrological phases. Ann Limnol – Int J Lim. 42(4):277–288.
   Web of Science ®Google Scholar
• Gazulha V. 2012. Zooplâncton límnico: manual ilustrado [Limnic zooplankton: illustrated manual], 1st ed. Rio de Janeiro (Brazil): Technical Books.
   Google Scholar
• Górski K, Collier KJ, Duggan IC, Taylor CM, Hamilton DP. 2013. Connectivity and complexity of floodplain habitats govern zooplankton dynamics in a large temperate river system. Freshw Biol. 58:1458–1470.
   Web of Science ®Google Scholar
• Gotelli NJ, Colwell RK. 2001. Quantifying biodiversity: procedures and pitfalls in the measurement and comparison of species richness. Ecol Lett. 4:379–391.
   Web of Science ®Google Scholar
• Gutierrez MF, Epele LB, Mayora G, Aquino D, Mora C, Quintana R, Mesa L. 2022. Hydro-climatic changes promote shifts in zooplankton composition and diversity in wetlands of the lower Paraná River Delta. Hydrobiologia. 849(16):3463–3480.
   Web of Science ®Google Scholar
• Havens KE, Pinto-Coelho RM, Beklioğlu M, Christoffersen KS, Jeppesen E, Lauridsen TL, Mazumder A, Méthot G, Alloul BP, Tavşanoğlu UN, et al. 2015. Temperature effects on body size of freshwater crustacean zooplankton from Greenland to the tropics. Hydrobiologia. 743(1):27–35.
   Web of Science ®Google Scholar
• [ICMBio] Instituto Chico Mendes de Conservação da Biodiversidade. 2018. https://www.gov.br/icmbio/pt-br/assuntos/noticias/ultimas-noticias/convencao-reconhece-areas-umidas-na-amazonia-e-pantanal
   Google Scholar
• Junk W, Bayley PB, Sparks RE. 1989. The flood pulse concept in river-floodplain systems. Can Spec Publ Fish Aquat Sci. 106:110–127.
   Google Scholar
• Junk WJ, da Cunha CN, Wantzen KM, et al. 2006. Biodiversity and its conservation in the Pantanal of Mato Grosso, Brazil. Aquat. Sci. 68:278–309.
   Web of Science ®Google Scholar
• Junk WJ, da Silva CJ. 1999. O conceito do pulso de inundação e suas implicações para o Pantanal de Mato Grosso [The concept of the flood pulse and its ifmplications for the Pntanal of Mato Grosso]. In: EMBRAPA, editor. Anais do II Simpósio sobre Recursos Naturais e Sócio-econômicos do Pantanal [Proceedings of the II Symposium on Natural and Socio-economic Resources of the Pantanal]. Corumbá (Brazil); p. 17–28.
   Google Scholar
• Junk WJ, Piedade MTF, Lourival R, Wittmann F, Kandus P, Lacerda LD, Bozelli RL, Esteves FA, Nunes da Cunha C, Maltchik L, et al. 2014. Brazilian wetlands: their definition, delineation, and classification for research, sustainable management, and protection. Aquat Conserv. 24(1):5–22.
   Web of Science ®Google Scholar
• Koste W. 1978. Rotatoria, Die Rodertiere Mitteleuropas begründet von Max Voigt – Monogononta [Rotatoria, the harvesting animals of Central Europe founded by Max Voigt – Monogononta]. Stuttgart (Germany): Gebrüder Borntraeger Verlag.
   Google Scholar
• Kraft NJB, Adler PB, Godoy O, James EC, Fuller S, Levine JM. 2015. Community assembly, coexistence and the environmental filtering metaphor. Funct Ecol. 29(5):592–599.
   Web of Science ®Google Scholar
• Krztoń W, Kosiba J, Pociecha A, Wilk-Woźniak E. 2019. The effect of cyanobacterial blooms on bio- and functional diversity of zooplankton communities. Biodivers Conserv. 28(7):1815–1835.
   Web of Science ®Google Scholar
• Laliberté E, Legendre P, Shipley B. 2014. Measuring functional diversity (FD) from multiple traits, and other tools for functional ecology. R package version 1.0-12.1.
   Google Scholar
• Lansac-Tôha FA, Bonecker CC, Velho LFM, Simões NR, Dias JD, Alves GM, Takahashi EM. 2009. Biodiversity of zooplankton communities in the upper Paraná River floodplain: interannual variation from long-term studies. Braz J Biol. 69(2 Suppl):539–549.
   Google Scholar
• Lansac-Tôha FA, Velho LFM, Higuti J, Takahashi EM. 2002. Cyclopidae (Crustacea, Copepoda) from the upper Paraná River floodplain, Brazil. Braz J Biol. 62(1):125–133.
   PubMedGoogle Scholar
• Lavorel S, Garnier E. 2002. Predicting changes in community composition and ecosystem functioning from plant traits: revisiting the Holy Grail. Funct Ecol. 16(5):545–556.
   Web of Science ®Google Scholar
• Lavorel S, Grigulis K, McIntyre S, Williams NSG, Garden D, Dorrough J, Berman S, Quétier F, Thébault A, Bonis A. 2008. Assessing functional diversity in the field – methodology matters! Funct Ecol. 22(1):134–147.
   Web of Science ®Google Scholar
• Lázaro WL, Oliveira-Júnior ES, da Silva CJ, Castrillon SKI, Muniz CC. 2020. Climate change reflected in one of the largest wetlands in the world: an overview of the northern Pantanal water regime. Acta Limnol Bras. 32:1–8.
   Google Scholar
• Lazzaro X. 1987. A review of planktivorous fishes: their evolution, feeding behaviours, selectivities, and impacts. Hydrobiologia. 146:97–167.
   Web of Science ®Google Scholar
• Li Y, Chen F. 2020. Are zooplankton useful indicators of water quality in subtropical lakes with high human impacts? Ecol Indic. 113:106067.
   Web of Science ®Google Scholar
• Luck GW, Carter A, Smallbone L. 2013. Changes in bird functional diversity across multiple land uses: interpretations of functional redundancy depend on functional group identity. PLoS One. 8(5):e63671.
   Web of Science ®Google Scholar
• Marengo JA, Cunha AP, Cuartas LA, Deusdará Leal KR, Broedel E, Seluchi ME, Michelin CM, De Praga Baião CF, Chuchón Ângulo E, Almeida EK, et al. 2021. Extreme drought in the Brazilian Pantanal in 2019–2020: characterization, causes, and impacts. Front Water. 3:639204.
   Google Scholar
• Mason NW, Mouillot D, Lee WG, Wilson JB. 2005. Functional richness, functional evenness and functional divergence: the primary components of functional diversity. Oikos. 111:112–118.
   Web of Science ®Google Scholar
• McGann BN, Strecker AL. 2022. Zooplankton recovery from a whole-lake disturbance: examining roles of abiotic factors, biotic interactions, and traits. Ecosphere. 13(4):e3983.
   Web of Science ®Google Scholar
• Mouchet MA, Villéger S, Mason NWH, Mouillot D. 2010. Functional diversity measures: an overview of their redundancy and their ability to discriminate community assembly rules. Funct Ecol. 24(4):867–876.
   Web of Science ®Google Scholar
• Mouillot D, Graham NAJ, Villéger S, Mason NWH, Bellwood DR. 2013. A functional approach reveals community responses to disturbances. Trends Ecol Evol. 28(3):167–177.
   PubMed Web of Science ®Google Scholar
• Neiff JJ. 1990. Ideas para la interpretacion ecológica del Paraná [Ideas for the ecological interpretation of the Paraná]. Interciencia. 15:424–441.
   Web of Science ®Google Scholar
• Oksanen FJ, et al. 2017. vegan: community ecology package. R package version 2.4-3. https://CRAN.R-project.org/package=vegan
   Google Scholar
• Özkan K, Jeppesen E, Davidson TA, Søndergaard M, Lauridsen TL, Bjerring R, Johansson LS, Svenning J-C. 2014. Cross-taxon congruence in lake plankton largely independent of environmental gradients. Ecology. 95(10):2778–2788.
   Web of Science ®Google Scholar
• Petsch DK, Cottenie K, Padial AA, et al. 2021. Floods homogenize aquatic communities across time but not across space in a Neotropical floodplain. Aquat Sci. 83(19):1–11.
   Web of Science ®Google Scholar
• R Core Team. 2022 R: a language and environment for statistical computing. R Foundation for Statistical Computing, Vienna (Austria). https://www.R-project.org
   Google Scholar
• Rodrigues CKO, Delmadi LC, Santos AJS, et al. 2023. Between batumes and swamps: the life of the isqueiros of the north Pantanal. Res Soc Devel. 11(15):e31111536912.
   Google Scholar
• Rong Y, Tang Y, Ren L, Taylor WD, Razlutskij V, Naselli-Flores L, Liu Z, Zhang X. 2021. Effects of the filter-feeding benthic bivalve Corbicula fluminea on plankton community and water quality in aquatic ecosystems: a mesocosm study. Water. 13(13):1827.
   Web of Science ®Google Scholar
• Segovia BT, Pereira DG, Bini LM, de Meira BR, Nishida VS, Lansac-Tôha FA, Velho LFM. 2015. The role of microorganisms in a planktonic food web of a floodplain lake. Microb Ecol. 69(2):225–233.
   PubMed Web of Science ®Google Scholar
• Silva CJ, Nunes JRS, Simoni J. 2012. Água, biodiversidade e cultura do Pantanal: estudos ecológicos e etnobiológicos no sistema de Baías Chacororé - Sinhá Mariana [Water, biodiversity and culture in the Pantanal: ecological and ethnobiological studies in the Chacororé Bay system - Sinhá Mariana]. Carlini & Caniata Editorial; UNEMAT Editora.
   Google Scholar
• Simões NR, Dias JD, Leal CM, de Souza Magalhães Braghin L, Lansac-Tôha FA, Bonecker CC. 2013. Floods control the influence of environmental gradients on the diversity of zooplankton communities in a Neotropical floodplain. Aquat Sci. 75(4):607–617.
   Web of Science ®Google Scholar
• Sparks RE, Bayley PB, Kohler SL, Osborne LL. 1990. Disturbance and recovery of large floodplain rivers. Environ Manage. 14(5):699–709.
   Web of Science ®Google Scholar
• Strom KM. 1946. The ecological niche. Nature. 157(3986):375–375.
   Web of Science ®Google Scholar
• Thomaz SM, Bini LM, Bozelli RL. 2007. Floods increase similarity among aquatic habitats in river-floodplain systems. Hydrobiologia. 579(1):1–13.
   Web of Science ®Google Scholar
• Villéger S, Mason NWH, Mouillot D. 2008. New multidimensional functional diversity indices for a multifaceted framework in functional ecology. Ecology. 89(8):2290–2301.
   PubMed Web of Science ®Google Scholar
• Vincent F, Bertolo A, Lacroix G, Mouchet M, Edeline E. 2020. Trait-dependency of trophic interactions in zooplankton food webs. Oikos. 129(6):891–902.
   Web of Science ®Google Scholar
• Violle C, Navas ML, Vile D, Kazakou E, Fortunel C, Hummel I, Garnier E. 2007. Let the concept of trait be functional! Oikos. 116:882–892.
   Google Scholar
• Wallace JB, Merritt RW. 1980. Filter-feeding ecology of aquatic insects. Annu Rev Entomol. 25:103–132.
   Web of Science ®Google Scholar
• Waya RK, Limbu SM, Ngupula GW, Mwita CJ, Mgaya YD. 2017. Temporal patterns in phytoplankton, zooplankton and fish composition, abundance and biomass in Shirati Bay, Lake Victoria, Tanzania. Lakes Reserv. 22(1):19–42.
   Google Scholar
• Wickham H. 2016. ggplot2: elegant graphics for data analysis. New York (NY): Springer-Verlag. ISBN 978-3-319-24277-4.
   Google Scholar
• Wilman H, Belmaker J, Simpson J, De C, Rosa LA, Rivadeneira MM, Jetz W. 2014. Eltontraits 1.0: species-level foraging attributes of the world’s birds and mammals. Ecology. 95:2027–2027.
   Google Scholar
• Xiong W, Ni P, Chen Y, Gao Y, Li S, Zhan A. 2019. Biological consequences of environmental pollution in running water ecosystems: a case study in zooplankton. Environ Pollut. 252:1483–1490.
   PubMed Web of Science ®Google Scholar