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Effect of sediment on meiofauna and Nematoda structure in different freshwater Amazon environments under the influence of mesotides
Published online by Cambridge University Press: 22 September 2023
Abstract
The present study investigated the horizontal and vertical distribution of meiofauna community and Nematoda assemblages on two sandy beaches and two muddy tidal flats in a freshwater Amazon estuary governed by mesotides. Meiofauna density was significantly higher in muddy environments, explained by the higher food availability. On the one hand, there was no difference between sediment layers in both sandy environments, which suggests that individuals must have migrated to layers deeper than 10 cm. On the other, the highest densities and richness in muddy environments occurred in the upper layer due to higher food and oxygen availability in the surface sediment layer, which decreases with depth. Muddy environments differed on both beaches; they had the highest nematode genera densities and richness. This might be explained by the high nutrient enrichment in these environments. There was no significant difference in Nematoda density and richness between zones in any environment, likely due to the small mid-littoral extension (<40 m), which did not favour the high spatial variability of genera. Nematoda density was higher at a depth of 0–2 cm in both muddy environments, explained by the availability of oxygen and food. The high abundance of deposit-feeder genera in muddy environments indicates high organic enrichment, whereas the distribution of trophic types was more homogeneous on the beaches where abiotic factors tended to be more structuring than food availability.
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References
Agência Nacional de Águas (ANA) (2019) HidroWeb, Sistema de Informações Hidrológicas. Available at http://snirh.gov.br/hidroweb (Accessed 15 December 2019).Google Scholar
Altherr, E (1972) Contribution a la connaissance des Nematodes de l'estuaire de l'Amazone. Amazoniana 3, 141–174.Google Scholar
Altherr, E (1977) Contribution a la connaissance des Nematodes de l'estuaire de l'Amazone. Amazoniana (2 me partie) 6, 145–159.Google Scholar
Anderson, MJ (2001) A new method for non-parametric multivariate analysis of variance. Austral Ecology 26, 32–46.Google Scholar
Anderson, MJ, Gorley, RN and Clarke, KR (2008) Permanova+ for Primer: Guide to Software and Statistical Methods. Plymouth: PRIMER-E.Google Scholar
Andrássy, I (1985) Three new species of Mononchoidea (Nematoda) from the Southern Hemisphere. Opuscula Zoologica (Budapest) 21, 23–30.Google Scholar
Ansari, ZA and Parulekar, AH (1993) Distribution, abundance and ecology of the meiofauna in a tropical estuary along the west coast of India. Hydrobiologia 262, 115–126.CrossRefGoogle Scholar
Armenteros, M, Williams, JP, Creagh, B and Capetillo, N (2008) Spatial and temporal variations of meiofaunal communities from the western sector of the Gulf of Batabanó, Cuba: III. Vertical distribution. Revista de Biologia Tropical 56, 1127–1134.Google ScholarPubMed
Baia, E and Venekey, V (2019) Distribution patterns of meiofauna on a tropical macrotidal sandy beach, with special focus on nematodes (Caixa d’Água, Amazon Coast, Brazil). Brazilian Journal of Oceanography 67, 19230.CrossRefGoogle Scholar
Baia, E, Rollnic, M and Venekey, V (2021) Seasonality of pluviosity and saline intrusion drive meiofauna and nematodes on an Amazon freshwater-oligohaline beach. Journal of Sea Research 170, 102022.CrossRefGoogle Scholar
Beier, S and Traunspurger, W (2003) Temporal dynamics of meiofauna communities in two small submountain carbonate streams with different grain size. Hydrobiologia 498, 107–131.CrossRefGoogle Scholar
Bello, LAL and Huffner, JGP (2012) Análise dos impactos ambientais da expansão urbana na ilha de Cotijuba, Belém-PA. Caminhos de Geografia 13, 286–298.Google Scholar
Boaden, PJS and Platt, HM (1971) Daily migration patterns in an intertidal meiobenthic community. Thalassia Jugoslavica 7, 1–12.Google Scholar
Coomans, A and Eyualem-Abebe, EA (2006) Order Monhysterida. In Eyualem-Abebe, EA, Andrássy, I and Traunspurger, W (eds), Freshwater Nematodes: Ecology and Taxonomy. Wallingford, UK: CABI, pp. 574–603.CrossRefGoogle Scholar
Costa, KG and Netto, SA (2014) Effects of small-scale trawling on benthic communities of estuarine vegetated and non-vegetated habitats. Biodiversity and Conservation 23, 1041–1055.CrossRefGoogle Scholar
Coull, BC (1988) Ecology of the marine meiofauna. In Higgins, RP and Thiel, H (eds), Introduction to the Study of Meiofauna. Washington, DC: Smithsonian Institution Press, pp. 18–38.Google Scholar
Dankers, N and Beukema, JJ (1983) Distributional patterns of macrozoobenthic species in relation to some environmental factors. Ecology of the Wadden Sea 1, 69–103.Google Scholar
De Grisse, AT (1969) Redescription ou modification de quelques techniques utilisés dans l″étude des nématodes phytoparasitaires. Mededelingen Rijksfakulteit Landbouwwetenschappen Gent 34, 351–369.Google Scholar
Dittmann, S (2000) Zonation of benthic communities in a tropical tidal flat of north-east Australia. Journal of Sea Research 43, 33–51.CrossRefGoogle Scholar
Du, Y, Gao, S, Liu, X, Wang, D, Zhang, L and Ingels, J (2018) Meiofauna and nematode community characteristics indicate ecological changes induced by geomorphic evolution: a case study on tidal creek systems. Ecological Indicators 87, 97–106.CrossRefGoogle Scholar
Dupuy, C, Hien, TN, Mizrahi, D, Jourde, J, Bréret, M, Agogué, H, Beaugeard, L and Bocher, P (2015) Structure and functional characteristics of the meiofauna community in highly unstable intertidal mudbanks in Suriname and French Guiana (North Atlantic coast of South America). Continental Shelf Research 110, 39–47.Google Scholar
El-Robrini, M, Silva, MAMA, Souza Filho, PWM, El-Robrini, MHS, Silva, OGS Jr. and França, CF (2006) Erosão e Progradação do Litoral Brasileiro. Belém: Ministério do Meio Ambiente.Google Scholar
Eyualem-Abebe, EA, Andrássy, I and Traunspurger, W (eds) (2006) Freshwater Nematodes: Ecology and Taxonomy. Wallingford, UK: CABI.CrossRefGoogle Scholar
Ferreira, HLM, Gomes, MB and López, CM (2008) Avaliação dos métodos de amostragem para fauna perifítica em macrófitas na Reserva da Biosfera, Serra do Espinhaço, Estado de Minas Gerais, Brasil. Acta Scientiarum. Biological Sciences 30, 253–259.Google Scholar
Flach, PZ, Ozorio, CP and Melo, AS (2012) Alpha and beta components of diversity of freshwater nematodes at different spatial scales in subtropical coastal lakes. Fundamental and Applied Limnology/Archiv für Hydrobiologie 180, 249–258.CrossRefGoogle Scholar
Fonseca, G, Hutchings, P and Gallucci, F (2011) Meiobenthic communities of seagrass beds (Zostera capricorni) and unvegetated sediments along the coast of the New South Wales, Australia. Estuarine Coast and Shelf Science 91, 69–77.CrossRefGoogle Scholar
Gallucci, F, Christofoletti, RA, Fonseca, G and Dias, GM (2020) The effects of habitat heterogeneity at distinct spatial scales on hard-bottom-associated communities. Diversity 12, 39.CrossRefGoogle Scholar
Gerlach, SA (1957) Die Nematodenfauna Des Sandstrandes an Der Küste von Mittelbrasilien (Brasilianische Meeres-Nematoden IV). Mitteilungen aus dem Museum für Naturkunde in Berlin. Zoologisches Museum und Institut für Spezielle Zoologie 33, 411–459.CrossRefGoogle Scholar
Gerlach, SA (1966) Bemerkunen zur Phylogenie der Nematoden. Mitteilungenaus der Biologischen Bundesanstalt fur Land- und Forstwirtschaft Berlim-Dahlem 118, 5–39.Google Scholar
Giere, O (2009) Meiobenthology: The Microscopic Motile Fauna of Aquatic Sediments, 2nd Edn. Berlin: Springer Science & Business Media.Google Scholar
Gomes, TP and Rosa Filho, JS (2009) Composição e variabilidade espaço-temporal da meiofauna de uma praia arenosa na região amazônica (Ajuruteua, Pará). Iheringia 99, 210–216.CrossRefGoogle Scholar
Gregório, AMS and Mendes, AC (2009) Characterization of sedimentary deposits at the confluence of two tributaries of the Pará River estuary (Guajará Bay, Amazon). Continental Shelf Research 29, 609–618.CrossRefGoogle Scholar
Guerra, GA (2007) Os efeitos da ocupação urbana no extrativismo vegetal da Ilha de Cotijuba. Belém: Editora Unama.Google Scholar
Heip, C, Vincx, M and Vranken, G (1985) The ecology of marine nematodes. Oceanography and Marine Biology: An Annual Review 23, 399–489.Google Scholar
Ingels, J, Santos, G, Hicks, N, Vazquez, YV, Neres, PF, Pontes, LP, Amorim, MN, Roman, S, Du, Y, Stahl, H, Somerfield, PJ and Widdicombe, S (2018) Short-term CO2 exposure and temperature rise effects on metazoan meiofauna and free-living nematodes in sandy and muddy sediments: results from a flume experiment. Journal of Experimental Marine Biology and Ecology 502, 211–226.CrossRefGoogle Scholar
Kjerfve, B and Lacerda, LD (1993) Mangroves of Brazil. In Lacerda, LD (ed.), Conservation and Sustainable Utilization of Mangrove Forest in Latin America and Africa Regions: Part I – Latin America. Okinawa: International Society for Mangrove Ecosystems. Technical Report No.2. ITTO/ISME, pp. 245–272.Google Scholar
Leduc, D and Probert, PK (2011) Small-scale effect of intertidal seagrass (Zostera muelleri) on meiofaunal abundance, biomass, and nematode community structure. Journal of the Marine Biological Association of the United Kingdom 91, 579–591.CrossRefGoogle Scholar
Lisboa, LK, Silva, ALLD and Petrucio, MM (2011) Aquatic invertebrate's distribution in a freshwater coastal lagoon of southern Brazil in relation to water and sediment characteristics. Acta Limnologica Brasiliensia 23, 119–127.CrossRefGoogle Scholar
Mare, MF (1942) A study of marine benthic community with special reference to the microorganisms. Journal of the Marine Biological Association of the United Kingdom 25, 517–554.CrossRefGoogle Scholar
Maria, TF, Silva Filho, MG, Souza, TP, Vanaverbeke, J, Vanreusel, A and Esteves, AM (2018) Is the vertical distribution of meiofauna similar in two contrasting microhabitats? A case study of a macrotidal sandy beach. Journal of Experimental Marine Biology and Ecology 502, 39–51.CrossRefGoogle Scholar
Martins, MDO, Almeida, TCMD and Domenico, MD (2015) Vertical distribution of meiofauna on reflective sandy beaches. Brazilian Journal of Oceanography 63, 469–480.CrossRefGoogle Scholar
Mascarenhas, BM, Guimarães, DG, Santa Brígida, M, Pinto, CS, Gomes Neto, HA and Pereira, JDB (2009) Estudo de anofelinos antropofílicos peridomiciliares da Praia da Saudade na Ilha de Cotijuba: uma área endêmica de malária em Belém, Pará. Acta Amazonica 39, 453–458.CrossRefGoogle Scholar
McLachlan, A (1977) Composition, distribution, abundance and biomass of the macrofauna and meiofauna of four sandy beaches. African Zoology 12, 279–306.CrossRefGoogle Scholar
McLachlan, A and Brown, AC (2006) The Ecology of Sandy Shores. Burlington: Academic Press.Google Scholar
Meira, JR, Moura, FR and Garraffoni, ARS (2013) Lotic meiofauna communities as bioindicators of aquatic pollution in the State Park, Minas Gerais State, Brazil. Australian Journal of Basic and Applied Sciences 7, 991–1003.Google Scholar
Meurer, AZ and Netto, SA (2007) Seasonal dynamics of benthic communities in a shallow sublittoral site of Laguna Estuarine System (South, Brazil). Brazilian Journal of Aquatic Science and Technology 11, 53–62.CrossRefGoogle Scholar
Moens, T, Braeckman, U, Derycke, S, Fonseca, G, Gallucci, F, Gingold, R, Guilini, K, Ingels, J, Leduc, D, Vanaverbeke, J, Van Colen, C, Vanreusel, A and Vincx, M (2014) Ecology of free-living marine nematodes. In Schmidt-Rhaesa, A (ed.), Handbook of Zoology. Berlin: De Gruyter, pp. 109–152.Google Scholar
Nemys eds (2021) Nemys: World Database of Nematodes. Available at http://nemys.ugent.be. doi: 10.14284/366 Accessed several times in 2021.CrossRefGoogle Scholar
Netto, SA and Fonseca, G (2017) Regime shifts in coastal lagoons: evidence from free-living marine nematodes. PLoS ONE 12, e0172366.CrossRefGoogle ScholarPubMed
Netto, SA and Pereira, TJ (2009) Benthic community response to a passive fishing gear in a coastal lagoon (South Brazil). Aquatic Ecology 43, 521–538.CrossRefGoogle Scholar
Noguera, SG and Hendrickx, ME (1997) Distribution and abundance of meiofauna in a subtropical coastal lagoon in the south-eastern Gulf of California, Mexico. Marine Pollution Bulletin 34, 582–587.CrossRefGoogle Scholar
Palmer, MA (1990) Temporal and spatial dynamics of meiofauna within the hyporheic zone of Goose Creek, Virginia. Journal of the North American Benthological Society 9, 17–25.CrossRefGoogle Scholar
Pejrup, M (1988) The triangular diagram used for classification of estuarine sediments; a new approach. In de Boer, PL, Van Gelder, A and Nio, SD (eds), Tide-Influenced Sedimentary Environments, and Facies: Sedimentology and Petroleum Geology. Dordrecht, The Netherlands: D. Reidel, pp. 289–299.CrossRefGoogle Scholar
Pereira, LCC, Vila-Concejo, A and Short, AD (2013) Influence of sub-tidal sand banks on tidal modulation of waves and beach morphology in Amazon macrotidal beaches. Journal of Coastal Research 65, 1821–1826.CrossRefGoogle Scholar
Pereira, LCC, Vila-Concejo, A and Short, A (2016) Coastal morpho-dynamic processes on the macro-tidal beaches of Pará state under tidally-modulated wave conditions. In Short, AD and Klein, AHF (eds), Brazilian Beach Systems. Switzerland: Springer, pp. 95–124.CrossRefGoogle Scholar
Pinto, TK, Netto, SA, Esteves, AM, de Castro, FJV, Neres, PF and Silva, MC (2021) Free-living freshwater nematodes from Brazil: checklist of genera and regional patterns of diversity. Nematology 23, 1125–1138.Google Scholar
Radwell, AJ and Brown, AV (2008) Benthic meiofauna assemblage structure of headwater streams: density and distribution of taxa relative to substrate size. Aquatic Ecology 42, 405–414.CrossRefGoogle Scholar
Reinicke, GB (2000) Small-scale patchiness of benthos and sediment parameters in a freshwater tidal mud-flat of the River Elbe estuary (Germany). Limnologica 30, 183–192.CrossRefGoogle Scholar
Reise, K and Ax, P (1979) A meiofaunal ‘thiobios’ limited to the anaerobic sulfide system of marine sand does not exist. Marine Biology 54, 225–237.CrossRefGoogle Scholar
Riemann, F (1972) Kinonchulus sattleri ng. n.sp. (Enoplida, Tripyloidea) an aberrant freeliving nematode from the lower Amazonas. Verroff Institut for Meeresforschung, Bremerhaven 13, 317–326.Google Scholar
Ristau, K, Faupel, M and Traunspurger, W (2013) Effects of microcosm enrichment on the trophic structure and species composition of freshwater nematodes – a microcosmos study. Freshwater Science 32, 155–168.CrossRefGoogle Scholar
Rosa-Filho, JS, Gomes, TP, Almeida, MF and Silva, RF (2011) Benthic fauna of macrotidal sandy beaches along a small-scale morphodynamic gradient on the Amazon coast (Algodoal Island, Brazil). Journal of Coastal Research SI 64, 435–439.Google Scholar
Rosário, RP, Borba, TA, Santos, AS and Rollnic, M (2016) Variability of salinity in Pará river estuary: 2D analysis with flexible mesh model. Journal of Coastal Research 75, 128–132.CrossRefGoogle Scholar
Schrijvers, J, Van Gansbeke, D and Vincx, M (1995) Macrobenthic infauna of mangroves and surrounding beaches at Gazi Bay, Kenya. Hydrobiologia 306, 53–66.CrossRefGoogle Scholar
Schubel, JR and Carter, HH (1984) The estuary as a filter for fine-grained suspended sediment. In Kennedy, V (ed.), The Estuary as a Filter. New York: Academic Press, pp. 81–105.CrossRefGoogle Scholar
Somerfield, PJ, Gee, JM and Warwick, RM (2005) Soft sediment meiofaunal community structure in relation to a long-term heavy metal gradient in the Fal estuary system. Marine Ecology Progress Series 105, 9–88.Google Scholar
Sousa, RC, Pereira, LCC, Costa, RM and Jiménez, JA (2017) Management of estuarine beaches on the Amazon coast though the application of recreational carrying capacity indices. Tourism Management 59, 216–225.CrossRefGoogle Scholar
Steyaert, MPMJ, Herman, PMJ, Moens, T, Widdows, J and Vincx, M (2001) Tidal migration of nematodes on an estuarine tidal flat (the Molenplaat, Schelde Estuary, SW Netherlands). Marine Ecology Progress Series 224, 299–304.CrossRefGoogle Scholar
Steyaert, M, Vanaverbeke, J, Vanreusel, A, Barranguet, C, Lucas, C and Vincx, M (2003) The importance of fine-scale, vertical profiles in characterising nematode community structure. Estuarine, Coastal and Shelf Science 58, 353–366.CrossRefGoogle Scholar
Sutherland, TF, Garcia-Hoyos, LM, Poon, P, Krassovski, MV, Foreman, MG, Martin, AJ and Amos, CL (2018) Seabed attributes and meiofaunal abundance associated with a hydrodynamic gradient in Baynes Sound, British Columbia, Canada. Journal of Coastal Research 34, 1021–1034.CrossRefGoogle Scholar
Swan, CM and Palmer, MA (2000) What drives small-scale spatial patterns in lotic meiofauna communities? Freshwater Biology 44, 109–121.CrossRefGoogle Scholar
Traunspurger, W (1997) Bathymetric, seasonal and vertical distribution of feeding-types of nematodes in an oligotrophic lake. Vie et Milieu 47, 1–7.Google Scholar
Traunspurger, W (2000) The biology and ecology of lotic nematodes. Freshwater Biology 44, 29–45.CrossRefGoogle Scholar
Traunspurger, W, Michiels, IC and Eyualem-Abebe, EA (2006) Composition and distribution of free-living freshwater nematodes: global and local perspectives. In Eyualem-Abebe, EA, Andrássy, I and Traunspurger, W (eds), Freshwater Nematodes: Ecology and Taxonomy. Wallingford, UK: CABI, pp. 46–76.CrossRefGoogle Scholar
Venekey, V (2017) Updates on information about free-living marine nematodes in Brazil: new records and comments on problems in taxonomic studies. Zootaxa 4337, 38–72.CrossRefGoogle ScholarPubMed
Venekey, V, Fonseca-Genevois, VG and Santos, PJ (2010) Biodiversity of free-living marine nematodes on the coast of Brazil: a review. Zootaxa 2568, 39–66.CrossRefGoogle Scholar
Venekey, V, Gheller, PF, Maria, TF, Brustolin, MC, Kandratavicius, N, Vieira, DC, Brito, S, Souza, GS and Fonseca, G (2014) The state of the art of Xyalidae (Nematoda, Monhysterida) with reference to the Brazilian records. Marine Biodiversity 44, 367–390.CrossRefGoogle Scholar
Venekey, V, Melo, TPG and Rosa Filho, JS (2019) Effects of seasonal fluctuation of Amazon river discharge on the spatial and temporal changes of meiofauna and nematodes in the Amazonian coast. Estuarine, Coastal and Shelf Science 227, 106330.CrossRefGoogle Scholar
Vieira, DC and Fonseca, G (2013) The importance of vertical and horizontal dimensions of the sediment matrix in structuring nematodes across spatial scales. PLoS ONE 8, e77704.CrossRefGoogle ScholarPubMed
Warwick, RM, Platt, HM and Somerfield, PJ (1998) Free-Living Marine Nematodes: Part III: Monhysterids. Synopsis of the British fauna (New series) no. 53. Shrewsbury: Field Studies Council.Google Scholar
Wei, T, Chen, Z, Duan, L, Gu, J, Saito, Y, Zhang, W, Wang, Y and Kanai, Y (2007) Sedimentation rates in relation to sedimentary processes of the Yangtze Estuary, China. Estuarine, Coastal and Shelf Science 71, 37–46.CrossRefGoogle Scholar
Wu, X, Vanreusel, A, Hauquier, F and Moens, T (2019) Environmental drivers of nematode abundance and genus composition at two spatial scales on an estuarine intertidal flat. Hydrobiologia 846, 193–214.CrossRefGoogle Scholar
Zullini, A (2010) Identification Manual for Freshwater Nematode Genera. Milano: Università di Milano-Bicocca.Google Scholar
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