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Benthic macrofauna associated to the invasive bivalve Mytilopsis leucophaeata (Dreissenidae) in a coastal lagoon in Rio de Janeiro, Brazil

Abstract

The invasion record for the estuarine bivalve Mytilopsis leucophaeata in Brazil is in Rio de Janeiro city, including the Rodrigo de Freitas Lagoon, where high densities of this invader were registered. This work aimed to (1) assess the composition and structure of the benthic macrofauna associated with this invader in Rodrigo de Freitas Lagoon, (2) analyze the spatiotemporal variation of richness, density and diversity of the associated benthic community, and (3) correlate changes on the density of the associated benthic species with some water quality variables and the density of M. leucophaeata. Clusters of M. leucophaeata were collected monthly (two years) in four sites. Nine taxa associated with M. leucophaeata were found; Heleobia sp. (Gastropoda) and Melita mangrovi (Amphipoda) showed the highest densities. The structure of the benthic macrofauna slightly differed among sampling sites, but not between dry and wet seasons. The water quality parameters, specific patterns of each taxon and high densities of M. leucophaeata contribute to variations in density of the associated species. Oscillations in the densities of M. leucophaeata and the native bivalve Brachidontes darwinianus suggest some agonistic relationship between them, such as a competition for space.

Key words
Biological invasion; engineer species; dark false mussel; estuary; Rodrigo de Freitas Lagoon

INTRODUCTION

Ecosystem engineers are species that may lead to considerable changes in the availability of resources for other species; such modifications may be biotic or abiotic, and the most common ones are related to the expansion or creation of new habitats (Jones et al. 1994JONES CO, LAWTON JH & SHACHAK M. 1994. Organisms as ecosystem engineers. Oikos 69: 373-386., Sousa et al. 2009SOUSA R, GUTIÉRREZ JL & ALDRIDGE DC. 2009. Non-indigenous invasive bivalves as ecosystem engineers. Biol Invasions 11: 2367-2385., Darrigran & Damborenea 2011DARRIGRAN G & DAMBORENEA C. 2011. Ecosystem engineering impact of Limnoperna fortunei in South America. Zool Sci 28: 1-7.). Some bivalves are regarded as engineer species owing to their typical gregarious behavior and high biomass production, affecting ecosystems and communities at various levels, i.e., increasing species richness and environment heterogeneity (Gutiérrez et al. 2003GUTIÉRREZ JL, JONES CG, STRAYER DL & IRIBARNE OO. 2003. Mollusks as ecosystem engineers: the role of shell production in aquatic habitats. Oikos 101: 79-90., Prado & Castilla 2006PRADO L & CASTILLA JC. 2006. The bioengineer Perumytilus purpuratus (Mollusca: Bivalvia) in central Chile: biodiversity, habitat structural complexity and environmental heterogeneity. J Mar Biol Assoc UK 86: 417-421., Linares et al. 2017LINARES MS, CALLISTO M & MARQUES JC. 2017. Invasive bivalves increase benthic communities complexity in neotropical reservoirs. Ecol Indic 75: 279-285.). Filter-feeding of massive populations of invasive bivalves may also interfere with local biodiversity, and adverse effects are recurrently recorded on the concentration of suspended particles and over the composition and structure of plankton communities (Karatayev et al. 2007KARATAYEV AY, PADILLA DK, MINCHIN D, BOLTOVSKOY D & BURLAKOVA LE. 2007. Changes in global economies and trade: the potential spread of exotic freshwater bivalves. Biol Invasions 9: 161-180., Sousa et al. 2013SOUSA R, NOVAIS A, COSTA R & STRAYER DL. 2013. Invasive bivalves in fresh waters: impacts from individuals to ecosystems and possible control strategies. Hydrobiologia 735: 233-251., Modesto et al. 2019MODESTO V, CASTRO P, LOPES-LIMA M, ANTUNES C, ILARRI M & SOUSA R. 2019. Potential impacts of the invasive species Corbicula fluminea on the survival of glochidia. Sci Total Environ 673: 157-164.).

The number of aquatic invasive species is escalating worldwide as a result of the increasingly exchange of goods and growing globalization process. The introduction of non-native bivalves is mainly related to inadequate management of ballast water or biofouling of ship hulls (Teixeira et al. 2010TEIXEIRA RM, BARBOSA JSP, LÓPEZ MS, FERREIRA-SILVA MAG, COUTINHO R & VILLAÇA RC. 2010. Bioinvasão marinha: os bivalves exóticos de substrato consolidado e suas interações com a comunidade receptora. Oecol Aust 14: 381-402., Seebens et al. 2013SEEBENS H, GASTNER MT & BLASIUS B. 2013. The risk of marine bioinvasion caused by global shipping. Ecol Lett 16: 782-790., Teixeira & Creed 2020TEIXEIRA LMP & CREED JC. 2020. A decade on: an updated assessment of the status of marine non-indigenous species in Brazil. Aquat Invasions 15: 30-43.). Among the aquatic environments, estuarine systems are often the most affected for the introduction and spreading of non-native bivalves (Nehring 2006NEHRING S. 2006. Four arguments why so many alien species settle into estuaries, with special reference to the German river Elbe. Helgol Mar Res 60: 127-134.). Although detrimental impacts are frequent and commonly observed soon after the establishment of the invader (e.g., predation or competition effects over native species), some positive ones (e.g., predatory or competitive release; habitat improvement) might also occur (Rodriguez 2006RODRIGUEZ LF. 2006. Can invasive species facilitate native species? Evidence of how, when, and why these impacts occur. Biol Invasions 8: 927-939., Boltovskoy et al. 2018BOLTOVSKOY D, SYLVESTER F & PAOLUCCI EM. 2018. Invasive species denialism: sorting out facts, beliefs, and definitions. Ecol Evol 8: 11190-11198.).

The estuarine dark false mussel Mytilopsis leucophaeata (Conrad, 1831) is native from the Gulf of Mexico and Atlantic coast of North America, but has invaded several sites in Europe, Asia and America (Kennedy 2011KENNEDY VS. 2011. The invasive dark false mussel Mytilopsis leucophaeata (Bivalvia: Dreissenidae): a literature review. Aquat Ecol 45: 163-183., Forsström et al. 2016FORSSTRÖM T, FOWLER AE, LINDQVIST M & VESAKOSKI O. 2016. The introduced dark false mussel, Mytilopsis leucophaeata (Conrad, 1831) has spread in the northern Baltic Sea. BioInvasions Rec 5: 81-84., Fernandes et al. 2018FERNANDES MR, SALGUEIRO F, MIYAHIRA IC & CAETANO CHS. 2018. mtDNA analysis of Mytilopsis (Bivalvia, Dreissenidae) invasion in Brazil reveals the existence of two species. Hydrobiologia 817: 97-110., Lodeiros et al. 2019LODEIROS C, GONZÁLEZ-HENRÍQUEZ N, CUÉLLAR-ANJEL J, HERNÁNDEZ-REYES D, MEDINA-ALCARAZ C, QUINTEIRO J & REY-MÉNDEZ M. 2019. Invasion of the dark false mussel in shrimp farms in Venezuela: species identification and genetic analysis. BioInvasions Rec 8: 838-847.). The few confirmed records for the established non-native populations of M. leucophaeata in Brazil are restricted for two coastal systems of the Rio de Janeiro city: Rodrigo de Freitas Lagoon (Rizzo et al. 2014RIZZO AE, MIYAHIRA IC, MOSER G & SANTOS SB. 2014. A new record of Mytilopsis leucophaeata (Bivalvia: Dreissenidae) in Rio de Janeiro (Brazil). Mar Biodivers Rec 7: 1-6., Fernandes et al. 2018FERNANDES MR, SALGUEIRO F, MIYAHIRA IC & CAETANO CHS. 2018. mtDNA analysis of Mytilopsis (Bivalvia, Dreissenidae) invasion in Brazil reveals the existence of two species. Hydrobiologia 817: 97-110.) and Marapendi Lagoon (Fernandes et al. 2020FERNANDES MR, MIYAHIRA IC, CAETANO CHS & SALGUEIRO F. 2020. The spreading of the invasive bivalve Mytilopsis leucophaeata (Dreissenidae) into estuaries of Rio de Janeiro, Brazil. An Acad Bras Cienc 93: e20190045.). Contrasting with low densities usually found in its native range, dense clusters of M. leucophaeata are often registered within the invaded sites (Kennedy 2011KENNEDY VS. 2011. The invasive dark false mussel Mytilopsis leucophaeata (Bivalvia: Dreissenidae): a literature review. Aquat Ecol 45: 163-183., Van der Gaag et al. 2017VAN DER GAAG M, VAN DER VELDE G & LEUVEN RSEW. 2017. Settlement, seasonal size distribution, and growth of the invasive bivalve Mytilopsis leucophaeata (Conrad, 1831) (Dreissenidae) in relation to environmental factors. J Shellfish Res 36: 417-426.). Several ecological and economic impacts are recorded for Mytilopsis species, such as competition with native species, changes on planktonic communities, financial losses in aquaculture, and biofouling in pipes of power-generating stations (Lin & Yang 2006LIN GM & YANG QL. 2006. Impacts of alien species Mytilopsis sallei on phytoplankton at Maluan Bay in Xiamen, Fujian, China. J Trop Oceanogr 25: 63-67., Aldridge et al. 2008ALDRIDGE DC, SALAZAR M, SERNA A & COCK J. 2008. Density-dependent effects of a new invasive false mussel, Mytilopsis trautwineana (Tryon 1866), on shrimp, Litopenaeus vannamei (Boone 1931), aquaculture in Colombia. Aquaculture 281: 34-42., Florin et al. 2013FLORIN AB, MO K, SVENSSON F, SCHAGERSTRÖM E, KAUTSKY L & BERGSTRÖM L. 2013. First records of Conrad’s false mussel, Mytilopsis leucophaeata in the Southern Bothnian Sea, Sweden, near a nuclear power plant. BioInvasions Rec 2: 303-309., Cai et al. 2014CAI LZ, HWANG JS, DAHMS HU, FU SJ, ZHUO Y & GUO T. 2014. Effect of the invasive bivalve Mytilopsis sallei on the macrofaunal fouling community and the environment of Yundang Lagoon, Xiamen, China. Hydrobiologia 741: 101-111., Freitas-Galeão & Souza 2015FREITAS-GALEÃO GMR & SOUZA JRB. 2015. Distribuição espaço-temporal do bivalve exótico Mytilopsis leucophaeta (Conrad, 1831) em áreas estuarinas do Rio Capibaribe, Recife, Estado de Pernambuco. Arquivos de Ciências do Mar 48: 33-38.).

The benthic fauna associated to invasive populations of M. leucophaeata has been increasingly addressed, but most studies are restricted to identification of the taxa living over M. leucophaeata shells (Kelleher et al. 1999KELLEHER B, VAN DER VELDE G & BIJ DE VAATE A. 1999. Nu ook levende Mytilopsis leucophaeata (Dreissenidae) in de Waal. Correspondentieblad NMV 307: 26-29., Heiler et al. 2010HEILER KCM, NAHAVANDI N & ALBRECHT C. 2010. A new invasion into an ancient lake - The invasion history of the Dreissenid mussel Mytilopsis leucophaeata (Conrad, 1831) and its first record in the Caspian Sea. Malacologia 53: 185-192.) or to record the co-occurring bivalves with M. leucophaeata (Rajagopal et al. 2005RAJAGOPAL S, VAN DER GAAG M, VAN DER VELDE G & JENNER HA. 2005. Upper temperature tolerances of exotic brackish-water mussel, Mytilopsis leucophaeata (Conrad): an experimental study. Mar Environ Res 60: 512-530., Brzana et al. 2017BRZANA R, JANAS U & BORECKA A. 2017. New records of Conrad’s false mussel Mytilopsis leucophaeata (Conrad, 1831) in the Vistula Delta. Oceanol Hydrobiol St 46: 231-236.). Few recent studies have properly assessed the benthic fauna associated to clusters of M. leucophaeata (Richardson & Hammond 2016RICHARDSON DJ & HAMMOND CI. 2016. Dark false mussel, Mytilopsis leucophaeata (Bivalvia: Dreissenidae), in the Lower West River, New Haven, New Haven County, Connecticut. B Peabody Mus Nat Hi 57: 117-125., Brzana et al. 2017BRZANA R, JANAS U & BORECKA A. 2017. New records of Conrad’s false mussel Mytilopsis leucophaeata (Conrad, 1831) in the Vistula Delta. Oceanol Hydrobiol St 46: 231-236.), or to invasive populations of other Mytilopsis species (G.M.R. Freitas, unpublished data, Cai et al. 2014CAI LZ, HWANG JS, DAHMS HU, FU SJ, ZHUO Y & GUO T. 2014. Effect of the invasive bivalve Mytilopsis sallei on the macrofaunal fouling community and the environment of Yundang Lagoon, Xiamen, China. Hydrobiologia 741: 101-111., Magni et al. 2019MAGNI P, COMO S, GRAVINA MF, GUO D, LI C & HUANG L. 2019. Trophic features, benthic recovery, and dominance of the invasive Mytilopsis sallei in the Yundang Lagoon (Xiamen, China) following long-term restoration. Water 11: 1692., Queiroz et al. 2020QUEIROZ RNM, DA SILVA PM, DESOUZA AM, SILVA LB & DIAS TLP. 2020. Effects of environmental factors on the distribution of the exotic species Mytilopsis sallei (Récluz, 1849) (Bivalvia: Dreissenidae) on the Northeast coast of Brazil. J Sea Res 165, 101954.).

This work aims to assess the composition and structure of the benthic macrofauna associated to M. leucophaeata in Rodrigo de Freitas Lagoon, an urban, estuarine and multi-impacted coastal system located in Rio de Janeiro city to which high densities of this non-native bivalve were recorded (Rizzo et al. 2014RIZZO AE, MIYAHIRA IC, MOSER G & SANTOS SB. 2014. A new record of Mytilopsis leucophaeata (Bivalvia: Dreissenidae) in Rio de Janeiro (Brazil). Mar Biodivers Rec 7: 1-6.). In addition to analyzing the spatiotemporal variation of richness, density and diversity of the associated benthic community, the relationship of the density of the associated benthic species with some water quality variables and the density of M. leucophaeata is also addressed. The potential impacts of the dark false mussel on the composition and structure of benthic macrofauna are also briefly discussed.

MATERIALS AND METHODS

Study site

The Rodrigo de Freitas Lagoon (22°57’02”–22°58’09”S, 43°11’09”–43°13’03”W) is a coastal and urban system situated in the Rio de Janeiro city, showing several recreational areas and high levels of human occupation on its margins (Enrich-Prast 2012ENRICH-PRAST A. 2012. Lagoa Rodrigo de Freitas: futuro. Oecol Aust 16: 721-727.). This estuarine system receives diffuse inputs of domestic sewage from vicinities or through inflowing of polluted rivers (Baptista-Neto et al. 2011BAPTISTA-NETO JA, SILVA CG, DIAS GTM & FONSECA EM. 2011. Distribuição sedimentar da Lagoa Rodrigo de Freitas através de sísmica de alta resolução. Rev Bras Geof 29: 187-195., Braz et al. 2012BRAZ L, FERREIRA WJ, SILVA MG, ALVALÁ PC, MARANI L, BATISTA GT & HAMZA VM. 2012. Influência de características físico-químicas da água no transporte de metano para a atmosfera na Lagoa Rodrigo de Freitas, RJ. Rev Ambient Água 7: 99-112., Soares et al. 2012SOARES MF, DOMINGOS P, SOARES FFL & TELLES LFR. 2012. 10 anos de monitoramento da qualidade ambiental das águas da Lagoa Rodrigo De Freitas. Oecol Aust 16: 581-614.). Most of the original perimeter of this lagoon was changed due to grounding (Enrich-Prast 2012ENRICH-PRAST A. 2012. Lagoa Rodrigo de Freitas: futuro. Oecol Aust 16: 721-727.).

The current area of Rodrigo de Freitas Lagoon is 2.2 km², with an estimated volume of 6,200,000 m³ and mean depth of 2.8 m (Domingos et al. 2012DOMINGOS P, GÔMARA GA, SAMPAIO GF, SOARES MF & SOARES FFL. 2012. Eventos de mortandade de peixes associados a florações fitoplanctônicas na Lagoa Rodrigo de Freitas: programa de 10 anos de monitoramento. Oecol Aust 16: 441-466., RIOÁGUAS 2013RIOÁGUAS. 2013. Atualização do plano de gestão ambiental da Lagoa Rodrigo de Freitas (PGALRF). Prefeitura da Cidade do Rio de Janeiro, Fundação Instituto das Águas do Município do Rio de Janeiro. Avaliable on: http://www.rio.rj.gov.br/web/smac/gestao-da-lagoa-rodrigo-de-freitas.
http://www.rio.rj.gov.br/web/smac/gestao...
). The single direct connection between the lagoon and sea is controlled by floodgates, leading to a low water renewal and high concentrations of organic matter and suspended particles (Soares et al. 2012SOARES MF, DOMINGOS P, SOARES FFL & TELLES LFR. 2012. 10 anos de monitoramento da qualidade ambiental das águas da Lagoa Rodrigo De Freitas. Oecol Aust 16: 581-614., RIOÁGUAS 2013RIOÁGUAS. 2013. Atualização do plano de gestão ambiental da Lagoa Rodrigo de Freitas (PGALRF). Prefeitura da Cidade do Rio de Janeiro, Fundação Instituto das Águas do Município do Rio de Janeiro. Avaliable on: http://www.rio.rj.gov.br/web/smac/gestao-da-lagoa-rodrigo-de-freitas.
http://www.rio.rj.gov.br/web/smac/gestao...
). Rodrigo de Freitas Lagoon is a mesohaline system and its brackish waters (6–25 ppt) are thermally stratified according to dry and wet seasons (Soares et al. 2012SOARES MF, DOMINGOS P, SOARES FFL & TELLES LFR. 2012. 10 anos de monitoramento da qualidade ambiental das águas da Lagoa Rodrigo De Freitas. Oecol Aust 16: 581-614.). During a brief period in the beginning of the XX century, the lagoon had very low salinity levels, typical of freshwater systems (Oliveira et al. 1957OLIVEIRA LPH, NASCIMENTO R, KRAU L & MIRANDA A. 1957. Observações hidrobiológicas e mortandade de peixes na Lagoa Rodrigo de Freitas. Mem Inst Oswaldo Cruz 55: 211-275.).

Methodology

Field works were performed monthly between March 2016 and March 2018. During the 2016 Olympic Games conducted in Rio de Janeiro, the access to the Rodrigo de Freitas Lagoon was partly closed, hindering the samplings in July and August of this year; additional samplings were done in November 2016 and July 2017. Four sampling sites (P1 to P4) were distanced by 1.0 to 2.5 km along the margin (Fig. 1). The highest marine influence is expected to occur at P1 (the site closest to the connection with the sea), whereas P2 is situated near the discharge of a polluted river; P3 is a deck used to the practice of rowing, located near a dump of pluvial waters, and P4 is situated within a recreational area with paddle boats. Clusters of M. leucophaeata were collected after scraping the hard substrata, with the aid of a spatula and a quadrat of 0.04 m². Three replicates were collected in each site. Samplings were conducted in the morning (09:00 to 11:00 am), regardless of tide levels, as the water level is altered by the artificial system of floodgates in this lagoon. Clusters of the invasive bivalve were collected about 0.5 to 1.0 m below the water surface. Water temperature, conductivity, salinity, pH, chlorophyll a and dissolved oxygen were measured through a multi-parameter probe (YSI 6-6920-V2-4).

Figure 1
Satellite images of the Rodrigo de Freitas Lagoon (modified from ArcGIS Online), showing the four sampling sites (P1 to P4). Top right: clusters of M. leucophaeata in Rodrigo de Freitas Lagoon.

The sampled clusters of M. leucophaeata were kept in plastic bags and stored in a freezer (-20°C) for posterior sorting of the associated macrofauna. The taxonomic identification was based on available literature (e.g. Oliveira 1953OLIVEIRA LPH. 1953. Crustacea Amphipoda do Rio de Janeiro. Mem Inst Oswaldo Cruz 51: 289-376., Loyola-e-Silva 2005LOYOLA-E-SILVA J. 2005. Sphaeromatidae dos litorais do Brasil (Isopoda: Crustacea). In: Monteiro-Filho ELA & Aranha JMR (Eds), Revisões em Zoologia, Curitiba: UFPR, Brasil, p. 106-152., Rios 2009RIOS EC. 2009. Compendium of Brazilian sea shells, Rio Grande: Evangraf, 676 p., Senna et al. 2012SENNA AR, SORRENTINO R, MACHADO ANS & TORRENT P. 2012. A new species of Melita Leach, 1814 (Amphipoda: Hadzioidea: Melitidae) from Patos Lagoon, southern Brazil. Nauplius 20: 125-135.) and confirmed by taxonomists (see Acknowledgments). Photographs were made using a Zeiss AxioCam ICc5 camera coupled to a Zeiss Discovery V20 stereomicroscope. The specimens were counted, stored in 70% ethanol and catalogued in the collections of MNRJ (Museu Nacional do Rio de Janeiro) and UERJ (Universidade do Estado do Rio de Janeiro).

The mean densities of M. leucophaeata were obtained as in Maia-Neto et al. (2020)MAIA-NETO AS, CAETANO CHS & CARDOSO RS. 2020. Population dynamics and secondary production of the invasive bivalve Mytilopsis leucophaeata (Bivalvia, Dreissenidae) in Lagoa Rodrigo De Freitas, Rio de Janeiro, Brazil. J Shellfish Res 39: 655-669., whereas mean densities of the associated fauna were calculated for each species through the averaged abundance of individuals per area of each replicate (N = 3). Dry season was set as between April to September whereas the wet season as between October and March, following a 10-year monitoring study on the water quality of the Rodrigo de Freitas Lagoon (Soares et al. 2012SOARES MF, DOMINGOS P, SOARES FFL & TELLES LFR. 2012. 10 anos de monitoramento da qualidade ambiental das águas da Lagoa Rodrigo De Freitas. Oecol Aust 16: 581-614.).

Statistical analyses

Species richness, Shannon-Weaver´s diversity (H’) and uniformity (J’) were calculated to be used as ecological descriptors of associated benthic community (Moreno 2001MORENO CE. 2001. Métodos para medir la biodiversidad. Zaragoza: M&T - Manuales y Tesis SEA, 84 p.). Excel 2016 graphics were built to show the spatiotemporal variation of these three ecological descriptors, mean density of the associated species, and the six water quality variables. Simple linear regressions were performed between mean density values of M. leucophaeata (independent variable) with mean density of the total benthic macrofauna and with mean densities of each associated species (dependent variables). A correlation test was made to verify a possible competition between M. leucophaeata and the native bivalve Brachidontes darwinianus (d’Orbigny, 1842), regarding separately the density of the first samplings (March 2016–April 2017) and the latter ones (May 2017–March 2018) of each sampling site. Other linear regressions were conducted to explore possible relationships within the associated species. All univariate analyses were performed in the software PAST 3.26

A Non-metric Multidimensional Scaling (nMDS) analysis was performed, through PAST 3.26, on the data matrix of benthic species (mean density; square-root transformed) to appraise possible changes of the associated community among sampling sites and seasons. Bray-Curtis dissimilarity index was used as distance measure of the nMDS (999 permutations). Analysis of Similarities (ANOSIM) were applied to test for the significance of the spatial and temporal pattern shown by nMDS.

Partial Redundancy Analysis (RDA) was applied on the matrix of benthic community density to address the relationship between the density of macrofauna benthic species and water quality variables. Time as used as covariable (i.e. measured as days after the first sampling date) to deal with possible effects of temporal autocorrelation on species density and environmental variables. Conductivity was removed from the analysis since it was highly correlated with salinity (Pearson’s` r = 0.99). Species data were log10 x + 1 transformed whilst environmental data were normalized (i.e. centered and reduced by standard deviation). The stepwise forward selection criterion was used priorly (Monte Carlo`s test; 999 permutations) to detect which environmental variables have significant contributions (p < 0.05) to the model, and the significance of RDA axis was tested through Monte Carlo’s test (999 permutations).

Generalized linear models (GLMs) were used to assess the relationship of the density (log10 x + 1 transformed data) of each benthic species with the suite of environmental variables simultaneously. Thus, the unconstrained scores (i.e. full variation of the water quality variables) of the first two environmental axes of the RDA were retrieved (i.e. controlled thus for potential temporal autocorrelation) and used as independent variables, while the density of benthic species was used as dependent variables in all GLM analyses. Gaussian distribution was performed and a 95% confidence interval (p ≤ 0.05) was assumed. GLMs were chosen using the stepwise selection procedure, through the Akaike information criterion (AIC). RDAs and GLMs were performed with CANOCO 4.5 (Lepš & Šmilauer 2003LEPŠ J & ŠMILAUER P. 2003. Multivariate analysis of ecological data using CANOCO. Cambridge University Press, Cambridge, UK.).

Genetic confirmation

An unidentified crab species was found associated to clusters of M. leucophaeata. Three individuals of this crab were thus DNA-sequenced for the cytochrome c oxidase subunit I (COI), following general procedures described in Fernandes et al. (2018)FERNANDES MR, SALGUEIRO F, MIYAHIRA IC & CAETANO CHS. 2018. mtDNA analysis of Mytilopsis (Bivalvia, Dreissenidae) invasion in Brazil reveals the existence of two species. Hydrobiologia 817: 97-110., to confirm its taxonomic identity. DNA was extracted by a salting-out technique and purified with a Macherey-Nagel commercial kit. DNA amplification was achieved with primers HCO2198 and LCO1490 (Folmer et al. 1994FOLMER O, BLACK M, HOEH W, LUTZ R & VRIJENHOEK R. 1994. DNA primers for amplification of mitochondrial cytochrome c oxidase subunit I from diverse metazoan invertebrates. Mol Mar Biol Biotech 3: 294-299.) and sequenced by Macrogen Inc. (Seoul, South Korea) for both directions. A BLAST search was conducted in NCBI website, matching, at 99.8%–100% of accuracy, the identity with a sequence of a panopeid crab (reference number: KF682792). All three generated sequences are available in GenBank (reference numbers: MN498019–MN498021).

RESULTS

The benthic macrofauna samples associated to the invasive bivalve M. leucophaeata were composed of 95,396 individuals belonging to nine taxa: Cassidinidea fluminensis (Mañe-Garzón, 1944) (Isopoda), Melita mangrovi Oliveira, 1953 (Amphipoda), Sinelobus stanfordi (Richardson, 1901) (Tanaidacea), Eurypanopeus dissimilis (Benedict & Rathbun, 1891) (Decapoda), Amphibalanus spp. (Cirripedia), Heleobia sp. (Gastropoda), Brachidontes darwinianus (Bivalvia), Alitta succinea (Leuckart, 1847) (Polychaeta) and Chironomidae larvae (Diptera) (Fig. 2). The gastropod Heleobia sp., with 3,017 (± 1,922 S.D.) individuals/m², and the amphipod M. mangrovi, with 1,734 (± 689 S.D.) individuals/m² were the species with the highest mean density.

Figure 2
Macrofauna benthic species associated to Mytilopsis leucophaeata in the Rodrigo de Freitas Lagoon. a. Cassidinidea fluminensis (Mañe-Garzón, 1944). b. Sinelobus stanfordi (Richardson, 1901). c. Melita mangrovi Oliveira, 1953. d. Eurypanopeus dissimilis (Benedict & Rathbun, 1891). e. Amphibalanus sp. f. Brachidontes darwinianus (d’Orbigny, 1842). g. Heleobia sp. H. Alitta succinea (Leuckart, 1847). i. Chironomidae larvae. Scale bars: a-c, g, i, 1 mm; d, f, h, 5 mm; e, 2 mm.

The nine taxa were found in all sampling sites (Table I). The highest mean density of individuals/m² (± S.D.) was recorded in P2 (1,427 ± 1,776), contrasting to the lowest one found in P4 (472 ± 537) (Table I). Species richness per month was always higher than four in any sampling site (Fig. 3a). Species density varied with sites and seasons, and peaks were observed in September 2016 for P2, June 2016 for P3, and a gradual increase for P3 that peaked in November 2017 (Fig. 3b). The mean value of the Shannon-Weaver (H’) index was highest in P4 (H’ = 1.33 ± 0.28 S.D.), whereas the lowest value appeared in P1 (H’ = 1.07 ± 0.27 S.D.) (Fig. 3c). The same pattern was observed for the uniformity index (J’) (Table I).

Figure 3
Temporal variation of total richness (a), mean density (b) and diversity (c) of the associated benthic macrofauna associated to Mytilopsis leucophaeata per sampling site, between March 2016–March 2018.
Table I
Mean values of density of species and density of total macrofauna per sampling site, diversity (H’), uniformity (J’) and values of richness. Numbers inside parentheses indicate standard deviations (± S.D.).

Amphibalanus spp. and S. stanfordi showed high population oscillations (Fig. 4). High densities of C. fluminensis were found in the first sampling year, whereas high densities of M. mangrovi, E. dissimilis, B. darwinianus and A. succinea were recorded in the second year. Heleobia sp. showed high densities during all sampling periods. Low densities of Chironomidae larvae were found between January–October 2017 (Fig. 4).

Figure 4
Temporal variation of the mean density (with standard deviation) for each species of the benthic macrofauna associated to Mytilopsis leucophaeata per sampling site, between March 2016–March 2018.

Most simple linear regressions of the mean density of M. leucophaeata with mean densities of the associated benthic macrofauna were not significant (p > 0.05). Linear regressions of the mean density of M. leucophaeata were significant for mean density of the total macrofauna (r = -0.29, r² = 0.08, p = 0.002), A. succinea (r = - 0.20, r² = 0.04, p = 0.04) and M. mangrovi (r = -0.28, r² = 0.07, p = 0.004), however with low r² values. Mean densities of M. leucophaeata and B. darwinianus were significantly correlated for the site P3. Density of M. leucophaeata was higher and directly associated with increased densities of B. darwinianus (r = 0.61, p = 0.02) in the first samplings, whereas densities of both species were inversely related in the latter samplings (r = -0.58, p = 0.04).

The spatiotemporal variation of the six water parameters is shown (Fig. 5). The ANOSIM test revealed that the structure of the benthic macrofauna slightly differed between sampling sites (Global R = 0.24, p = 0.0001), despite a considerable overlap of the groups showed in the nMDS (Fig. 6a). Most ANOSIM paired tests revealed significant differences among sampling sites, except between site P2 and P3 (Global R = 0.02, p = 0.17). No seasonal difference was observed for the composition and structure of the associated benthic macrofauna (Global R = 0.02, p = 0.10; Fig. 6b).

Figure 5
Temporal variation of mean temperature (a), conductivity (b), salinity (c), pH (d), chlorophyll a (e) and dissolved oxygen (f) per sampling site, between March 2016–March 2018.
Figure 6
nMDS of the mean density of species associated to Mytilopsis leucophaeata per sampling site (a) and per season (b).

Partial RDA was significant (F = 3.34; Monte Carlo test: p = 0.001 for all axes) revealing that, after the influence of temporal autocorrelation was taking into account, axis 1 and 2 accounted respectively for 47.3% and 33.5% of data variance on the composition and structure of the associated benthic macrofauna (Fig. 7). Chlorophyll a was not included in the model, since this variable did not contribute significantly to explaining the distribution of the associated macrofauna (Monte Carlo test: p = 0.39). Only the mean densities of A. succinea and E. dissimilis were positively and weakly correlated to RDA axis 1, and thus with increased values of salinity and oxygen, contrasting to the densities of Chironomidae larvae, which were negatively correlated to RDA axis 1, and thus with decreased values of salinity and oxygen. The other species were also negatively associated with RDA axis 1, but they were weakly correlated with this axis. Melita mangrovi was positively and highly correlated to RDA axis 2, and thus with increased values of pH and decreased values of temperature, contrasting with the opposite pattern found for Amphibalanus spp., and secondarily, B. darwinianus (Fig. 7). After controlling for possible autocorrelation effects, temporal patterns were weak and limited to few species, such as the apparently higher densities of Amphibalanus spp. and B. darwinianus between September-March of the second sampling year.

Figure 7
Ordinal diagram of the partial Redundancy Analysis (RDA) showing the relationship between the densities of the macrofauna benthic species associated to Mytilopsis leucophaeata and water quality variables. Samples were labelled by month, wherein number one represents the first sampling month (i.e. March 2016), and subsequently.

The Akaike information criterion (AIC) selected significant (F ≥ 7.25; p < 0.01 for all) and negative linear responses for the densities of seven macrofauna benthic species with the unconstrained scores of the environmental axis 1 from RDA (Fig. 8a). However, the densities of Chironomidae larvae, S. stanfordi, and Heleobia sp. decreased more sharply with oxygen and salinity than C. fluminensis, and especially in relation to those of Amphibalanus spp. and B. darwinianus. AIC also selected significant (F ≥ 4.16; p < 0.04 for all) linear responses for the densities of six macrofauna benthic species with the unconstrained scores of the environmental axis 2 from RDA, but the patterns varied more with each species (Fig. 8b). The densities of M. mangrovi, E. dissimilis, and S. stanfordi, but particularly of the first two species, were positively associated with increased values of pH and decreased values of temperature. In contrast, the opposite pattern was found for the densities of Chironomidae larvae, Amphibalanus spp. and B. darwinianus, particularly for the first species.

Figure 8
Relationships of the densities of the macrofauna benthic species associated to Mytilopsis leucophaeata and the suite of the environmental variables retrieved from RDA axes one (a) and two (b). Lines represent the generalized linear model (GLM) selected by the AIC.

DISCUSSION

Benthic macrofauna of the Rodrigo de Freitas Lagoon

Most knowledge on the benthic estuarine macrofauna in Brazil came from studies performed on the Southeastern and Southern regions (Neves & Valentin 2011NEVES RAF & VALENTIN JL. 2011. Revisão bibliográfica sobre a macrofauna bentônica de fundos não-consolidados, em áreas costeiras prioritárias para conservação no Brasil. Arquivos de Ciências do Mar 44: 59-80., Bernardino et al. 2016BERNARDINO AF, PAGLIOSA PR, CHRISTOFOLETTI RA, BARROS F, NETTO SA, MUNIZ P & LANA PC. 2016. Benthic estuarine communities in Brazil: moving forward to long term studies to assess climate change impacts. Braz J Oceanogr 64: 81-96.). In Rio de Janeiro state, some studies covered the Imboassica Lagoon (Callisto et al. 1998CALLISTO M, GONÇALVES-JUNIOR JF, LEAL JJF & PETRUCIO MM. 1998. Macroinvertebrados bentônicos nas lagoas Imboassica, Cabiúnas e Comprida. In: Esteves FA (Eds), Ecologia das Lagoas Costeiras do Parque Nacional da Restinga de Jurubatiba e do Município de Macaé (RJ), Rio de Janeiro: NUPEM/UFRJ, p. 283-298., Albertoni et al. 2001ALBERTONI EF, PALMA-SILVA C & ESTEVES FA. 2001. Macroinvertebrates associated with Chara in a tropical coastal lagoon (Imboassica lagoon, Rio de Janeiro, Brazil). Hydrobiologia 457: 215-224., Figueiredo-Barros et al. 2006FIGUEIREDO-BARROS MP, LEAL JJF, ESTEVES FA, ROCHA AM & BOZELLI RL. 2006. Life cycle, secondary production and nutrient stock in Heleobia australis (d’Orbigny 1835) (Gastropoda: Hydrobiidae) in a tropical coastal lagoon. Estuar Coast Shelf S 69: 87-95., Henriques-de-Oliveira et al. 2007HENRIQUES-DE-OLIVEIRA C, BAPTISTA DF & NESSIMIAN JL. 2007. Sewage input effects on the macroinvertebrate community associated to Typha domingensis Pers in a coastal lagoon in southeastern Brazil. Braz J Biol 67: 73-80.), Jaconé Lagoon (Mendes & Soares-Gomes 2011MENDES CLT & SOARES-GOMES A. 2011. Macrobenthic community structure in a Brazilian chocked lagoon system under environmental stress. Zoologia 28: 365-378.), Maricá Lagoon (Oliveira et al. 1955OLIVEIRA LPH, NASCIMENTO R, KRAU L & MIRANDA A. 1955. Observações biogeográficas e hidrobiológicas sôbre a lagôa de Maricá. Mem Inst Oswaldo Cruz 53: 171-262., M.A.K Dominguez, unpublished data apud Neves & Valentin 2011NEVES RAF & VALENTIN JL. 2011. Revisão bibliográfica sobre a macrofauna bentônica de fundos não-consolidados, em áreas costeiras prioritárias para conservação no Brasil. Arquivos de Ciências do Mar 44: 59-80.), Piratininga-Itaipu lagoon system (Oliveira 1948OLIVEIRA LPH. 1948. Estudo hidrobiológico das lagôas de Piratininga e Itaipú. Mem Inst Oswaldo Cruz 46: 673-718., Mendes & Soares-Gomes 2013MENDES CLT & SOARES-GOMES A. 2013. First signs of changes to a tropical lagoon system in the southeastern Brazilian coastline. J Coast Conserv 17: 11-23.), Marapendi Lagoon (L.V. Carvalheira, unpublished data) and Guanabara Bay (Santi & Tavares 2009SANTI L & TAVARES M. 2009. Polychaete assemblage of an impacted estuary, Guanabara Bay, Rio de Janeiro, Brazil. Braz J Oceanogr 57: 287-303., Echeverría et al. 2010ECHEVERRÍA CA, NEVES RAF, PESSOA LA & PAIVA PC. 2010. Spatial and temporal distribution of the gastropod Heleobia australis in an eutrophic estuarine system suggests a metapopulation dynamics. Nat Sci 2: 860-867., Soares-Gomes et al. 2012SOARES-GOMES A, MENDES CLT, TAVARES M & SANTI L. 2012. Taxonomic sufficiency of polychaete taxocenes for estuary monitoring. Ecol Indic 15: 149-156., 2016SOARES-GOMES A, DA-GAMA BAP, BAPTISTA-NETO JA, FREIRE DG, CORDEIRO RC, MACHADO W, BERNARDES MC, COUTINHO R, THOMPSON F & PEREIRA RC. 2016. An environmental overview of Guanabara Bay, Rio de Janeiro. Reg Stud Mar Sci 8: 319-330.). However, except for a single study addressing benthic assemblages associated with patches of the algae Chara spp. (Albertoni et al. 2001ALBERTONI EF, PALMA-SILVA C & ESTEVES FA. 2001. Macroinvertebrates associated with Chara in a tropical coastal lagoon (Imboassica lagoon, Rio de Janeiro, Brazil). Hydrobiologia 457: 215-224.), all other ones have targeted soft, unconsolidated, and structurally-simple substrata. Even though, some taxa found in our study, such as C. fluminensis, A. succinea and Heleobia sp. [the most common cited species in the literature is Heleobia australis (d’Orbigny, 1835)] were often listed by these studies.

Oliveira et al. (1957)OLIVEIRA LPH, NASCIMENTO R, KRAU L & MIRANDA A. 1957. Observações hidrobiológicas e mortandade de peixes na Lagoa Rodrigo de Freitas. Mem Inst Oswaldo Cruz 55: 211-275. is the single study that previously dealt with the macroinvertebrate fauna of the Rodrigo de Freitas Lagoon. They verified the occurrence of Chironomidae larvae, amphipods Platorchestia platensis (Krøyer, 1845), crabs Neohelice granulata (Dana, 1851), gastropods Lymnaea sp. and barnacles Balanus sp. and Amphibalanus amphitrite (Darwin, 1854) in this lagoon during a brief period of fish mortality. They sampled soft substrata and water in three sites (all close to the Piraquê Island), with salinity levels measuring 18–20 ppt. Gastropods were found in the soft substratum and in aquatic plants, and named Lymnaea sp.; however, Lymnaea species usually live in freshwater habitats (Stanisic 1998STANISIC J. 1998. Order Basommatophora. In: Beesley PL, Ross GJB & Wells A (Eds), Mollusca: The Southern Synthesis, Environment Australia, CSIRO.), and this identification was possibly incorrect [Heleobia sp., for example, also has a slight globose shell shape and small dimensions]. Oliveira et al. (1957)OLIVEIRA LPH, NASCIMENTO R, KRAU L & MIRANDA A. 1957. Observações hidrobiológicas e mortandade de peixes na Lagoa Rodrigo de Freitas. Mem Inst Oswaldo Cruz 55: 211-275. also found P. platensis in a site dominated by seagrasses, and A. amphitrite in an artificial substratum; none of these species (in addition to N. granulata) were found in association with M. leucophaeata in our study.

The composition and structure of the benthic community differed slightly among sites in Rodrigo de Freitas Lagoon, except between sites P2 and P3, which presented highest densities of the associated macrofauna especially due to population peaks of Heleobia sp. (influencing the similar composition of these two sites). High abundances of Heleobia sp. are possibly related to great accumulation of organic matter (Bemvenuti et al. 2003BEMVENUTI CE, ROSA-FILHO JS & ELLIOTT M. 2003. Changes in soft-bottom macrobenthic assemblages after a sulphuric acid spill in the Rio Grande Harbor (RS, Brazil). Braz J Biol 63: 183-194., 2005BEMVENUTI CE, ANGONESI LG & GANDRA MS. 2005. Effects of dredging operations on soft bottom macrofauna in a harbour in the Patos Lagoon estuarine region of Southern Brazil. Braz J Biol 65: 573-581., Neves et al. 2011NEVES RAF, ECHEVERRÍA CA & PESSOA LA. 2011. Resposta da espécie Heleobia australis (Gastropoda: Hydrobiidae) a variações de salinidade e exposição a hidrocarbonetos. Boletim do Laboratório de Hidrobiologia 24: 19-25.); conversely, dissolved oxygen levels were usually lower in sites P2 and P3 (Fig. 5).

The Rodrigo de Freitas Lagoon has an artificial system of floodgates, which are located near to sites P1 and P2, leading to a cyclical exchange of marine and fresh-water into the lagoon. The opening of the floodgates is usually related to periods of atypical rainstorms or when there is a need to renew the waters of the estuary (RIOÁGUAS 2013RIOÁGUAS. 2013. Atualização do plano de gestão ambiental da Lagoa Rodrigo de Freitas (PGALRF). Prefeitura da Cidade do Rio de Janeiro, Fundação Instituto das Águas do Município do Rio de Janeiro. Avaliable on: http://www.rio.rj.gov.br/web/smac/gestao-da-lagoa-rodrigo-de-freitas.
http://www.rio.rj.gov.br/web/smac/gestao...
). Some water parameters (e.g., salinity and conductivity) seem to be more directly influenced by this man-made control system. Even though, the community composition was quite similar between dry and wet seasons.

Water temperature was inversely related to the density of the amphipod M. mangrovi in the Rodrigo de Freitas Lagoon, with maximum densities occurring during winter and spring (Fig. 4), whereas Bemvenuti (1987)BEMVENUTI CE. 1987. Predation effects on a benthic community in estuarine soft sediments. Atlântica 9: 5-32. apud L.G. Angonesi (unpublished data) found most specimens between autumn and winter in Patos Lagoon (southern Brazil). The density of E. dissimilis was also inversely related to temperature, in contrast to the supposed ideal temperature ranges of 21ºC–35ºC in a population of this crab from Florida, U.S.A. (Garcés 1987GARCÉS HA. 1987. Comparative behavior of Eurypanopeus depressus (Smith) and Eurypanopeus dissimilis (Benedict and Rathbun) (Decapoda: Brachyura: Xanthidae). Rev Biol Trop 35: 173-181.). In addition to Heleobia sp., reduced salinity and oxygen levels favored higher densities of Chironomidae larvae (Fig. 8a), a common trend for this group (Machado et al. 2015MACHADO NG, NASSARDEN DCS, SANTOS F, BOAVENTURA ICG, PERRIER G, SOUZA FSC, MARTINS EL & BIUDES MS. 2015. Chironomus larvae (Chironomidae: Diptera) as water quality indicators along an environmental gradient in a neotropical urban stream. Rev Ambient Água 10: 298-309.), which is also directly related to higher water temperatures (Fig. 8b). Salinity and oxygen levels were inversely related to the density of S. stanfordi, contrary to results obtained by N.M. Santos (unpublished data) in a population from Rio Grande do Sul (southern Brazil) and by Ambrosio et al. (2014)AMBROSIO ES, FERREIRA AC & CAPÍTULO AR. 2014. The potential use of Sinelobus stanfordi (Richardson, 1901) (Crustacea, Tanaidacea) as a biological indicator of water quality in a temperate estuary of South America. Limnetica 33: 139-152. in Argentina. In relation to pH, the water of Rodrigo de Freitas Lagoon is usually alkaline (Fig. 5); slight changes in acidification may result in different behavioral and physiological responses between taxa (Courtney & Clements 1998COURTNEY LA & CLEMENTS WH. 1998. Effects of acidic pH on benthic macroinvertebrate communities in stream microcosms. Hydrobiologia 379: 135-145.), as observed in the varied relationships with this parameter (Fig. 8b). We also cannot ignore the effects of other constraints on species distribution, such as the concentration of recalcitrant and toxic pollutants in the water and substrate, the composition and spatial distribution of marginal habitats, possible interactions with other species, and synergetic effects.

Possible impacts of Mytilopsis leucophaeata in the benthic macrofauna

Invasive bivalves, such as some species of Dreissenidae, may increase habitat availability and three-dimensionality and alter the trophic dynamics in the associated communities (Sousa et al. 2013SOUSA R, NOVAIS A, COSTA R & STRAYER DL. 2013. Invasive bivalves in fresh waters: impacts from individuals to ecosystems and possible control strategies. Hydrobiologia 735: 233-251.), thus affecting native species. Great amount of feces and pseudofeces produced by invasive bivalves may lead to an enrichment of organic matter in the nearby sediments of the bivalve clusters, providing additional feeding resources for depositivorous species (Rodriguez 2006RODRIGUEZ LF. 2006. Can invasive species facilitate native species? Evidence of how, when, and why these impacts occur. Biol Invasions 8: 927-939.), such as the gastropod Heleobia sp. Species of Heleobia are able to inhabit diverse types of substrata (e.g., soft sediment, rocks, macrophytes), being also commonly found within bivalve clusters (Mansur et al. 2008MANSUR MCD, SANTOS CP, RICHINITTI LMZ, PEREIRA D, BATISTA CB, SILVEIRA MB, ALBERTO RMF & SILVA MCP. 2008. Ocorrência de moluscos límnicos e crustáceo em macroaglomerados do mexilhão dourado, Limnoperna fortunei (Dunker, 1857) sobre sarandi no lago Guaíba (RS, Brasil). Biotemas 21: 179-182.). Crustaceans from Rodrigo de Freitas Lagoon might be favored from M. leucophaeata or B. darwinianus clusters, regarding that the increase of physical complexity may increase the availability of habitat and refuge against predators, also reducing the risk of desiccation and the effects of water turbulence (Palmer & Ricciardi 2005PALMER ME & RICCIARDI A. 2005. Community interactions affecting the relative abundances of native and invasive amphipods in the St. Lawrence River. Can J Fish Aquat Sci 62: 1111-1118., Borthagaray & Carranza 2007BORTHAGARAY AI & CARRANZA A. 2007. Mussels as ecosystem engineers: Their contribution to species richness in a rocky littoral community. Acta Oecol 31: 243-250.). Melita mangrovi and C. fluminensis are often found in macroalgae, feeding preferentially on macro and microalgae (M. mangrovi: L.G. Angonesi, unpublished data) or microalgae and detritus (C. fluminensis: Seeliger 2001SEELIGER U. 2001. The Patos Lagoon Estuary, Brazil. In: Seeliger U & Kjerfve B (Eds), Coastal marine ecosystems of Latin America, Berlin: Ecological Studies 144, Springer, p. 167-183.). Clusters of M. leucophaeata might be used as substrata for the construction of tubes by S. stanfordi, due to the generally high retention level of suspended particles. Although this tanaidacean is usually associated with substrata colonized by macrophytes, it was also observed in clusters of a similar freshwater and invasive mussel Limnoperna fortunei (Dunker, 1857) (N.M. Santos, unpublished data, Spaccesi & Capítulo 2012SPACCESI FG & CAPÍTULO AR. 2012. Benthic communities on hard substrates covered by Limnoperna fortunei Dunker (Bivalvia, Mytilidae) at an estuarine beach (Río de la Plata, Argentina). J Limnol 71: 144-153.). The usual epibiosis of Amphibalanus spp. over M. leucophaeata specimens may be related to a higher ecological fitness of barnacles over the invader (Buschbaum 2001BUSCHBAUM C. 2001. Selective settlement of the barnacle Semibalanus balanoides (L.) facilitates its growth and reproduction on mussel beds in the Wadden Sea. Hel Mar Res 55: 128-134.), but demands further investigation. Crabs of the genus Eurypanopeus seem to be omnivorous, feeding on detritus, algae and a variety of animals, such as amphipods, polychaetes, oysters and mussels [data based on Eurypanopeus depressus (Smith, 1869) - Mcdonald 1982MCDONALD J. 1982. Divergent life history patterns in the co-occurring intertidal crabs Panopeus herbstii and Eurypanopeus depressus (Crustacea: Brachyura: Xanthidae). Mar Ecol Prog Ser 8: 173-180., O’Shaughnessy et al. 2014O’SHAUGHNESSY KA, HARDING JM & BURGE EJ. 2014. Ecological effects of the invasive parasite Loxothylacus panopaei on the flatback mud crab Eurypanopeus depressus with implications for estuarine communities. B Mar Sci 90: 611-621.]. The robust increase of E. dissimilis in the second year of this study (Fig. 4) may be related to the concomitant increase of some prey(s) (e.g., A. succinea, r = 0.47, r² = 0.22, p = 4.84E-08). The nereidid A. succinea is favored by the shelter provided by M. leucophaeata clusters, as observed for other mobile polychaetes (Borthagaray & Carranza 2007BORTHAGARAY AI & CARRANZA A. 2007. Mussels as ecosystem engineers: Their contribution to species richness in a rocky littoral community. Acta Oecol 31: 243-250.).

The presence of M. leucophaeata in the Rodrigo de Freitas Lagoon enhances the availability of biogenic hard substrata to native species. The densities of most associated benthic species were not directly related to that of M. leucophaeata, possibly owing to particular species-specific recruitment periods of native macrofauna species, natural variations of abiotic variables and population peaks, and the combination of these factors. However, the lowest density values recorded for M. leucophaeata in our study were still high (Maia-Neto et al. 2020MAIA-NETO AS, CAETANO CHS & CARDOSO RS. 2020. Population dynamics and secondary production of the invasive bivalve Mytilopsis leucophaeata (Bivalvia, Dreissenidae) in Lagoa Rodrigo De Freitas, Rio de Janeiro, Brazil. J Shellfish Res 39: 655-669.), and more robust analysis, particularly using bare hard substrata and sparser clusters of M. leucophaeata, should be performed to test the influence of this invasive bivalve on native species (Ricciardi et al. 1997RICCIARDI A, WHORISKEY FG & RASMUSSEN JB. 1997. The role of the zebra mussel (Dreissena polymorpha) in structuring macroinvertebrate communities on hard substrata. Can J Fish Aquat Sci 54: 2596-2608., Sardiña et al. 2008SARDIÑA P, CATALDO DH & BOLTOVSKOY D. 2008. The effects of the invasive mussel, Limnoperna fortunei, on associated fauna in South American freshwaters: importance of physical structure and food supply. Fund Appl Limnol 173: 135-144.).

The native estuarine bivalve B. darwinianus co-occurs with M. leucophaeata in the Rodrigo de Freitas Lagoon. In the first year of samplings, B. darwinianus was exclusively found in the core of M. leucophaeata clusters, being completely covered by the high densities of this invader. During the second year, a segregated distribution pattern was observed for these bivalves in sites P2 and P3, suggesting a possible spatial competition that should be better investigated by further studies. The increased densities of B. darwinianus in the second year were moderately or weakly related to high densities of M. mangrovi (r = 0.36, r² = 0.13, p = 0.0001), S. stanfordi (r = 0.36, r² = 0.13, p = 0.0001) and A. succinea (r = 0.52, r² = 0.27, p = 2.66E-08). In the Vistula Delta (Poland), M. leucophaeata has similar habitat requirements to two other bivalves, the native Mytilus trossulus (Gould, 1850) and the invasive Dreissena polymorpha (Pallas, 1771), possibly generating interspecific competition (Brzana et al. 2017BRZANA R, JANAS U & BORECKA A. 2017. New records of Conrad’s false mussel Mytilopsis leucophaeata (Conrad, 1831) in the Vistula Delta. Oceanol Hydrobiol St 46: 231-236.). Similarly, in northeastern Brazil M. cf. sallei altered the distribution of the native Mytella charruana (d’Orbigny, 1842) in the estuary of the Capibaribe River, Pernambuco (Freitas-Galeão & Souza 2015FREITAS-GALEÃO GMR & SOUZA JRB. 2015. Distribuição espaço-temporal do bivalve exótico Mytilopsis leucophaeta (Conrad, 1831) em áreas estuarinas do Rio Capibaribe, Recife, Estado de Pernambuco. Arquivos de Ciências do Mar 48: 33-38.) and probably competed with M. charruana in the estuary of the Paraíba River, Paraíba (Queiroz et al. 2020QUEIROZ RNM, DA SILVA PM, DESOUZA AM, SILVA LB & DIAS TLP. 2020. Effects of environmental factors on the distribution of the exotic species Mytilopsis sallei (Récluz, 1849) (Bivalvia: Dreissenidae) on the Northeast coast of Brazil. J Sea Res 165, 101954.).

Some studies have dealt with the macroinvertebrate fauna associated to Mytilopsis species. Clusters of M. cf. sallei in Recife (Brazil) harbored 48 taxa, although most of these clusters were located in near-marine sites (G.M.R. Freitas, unpublished data), which probably affected the total amount of species. In the Yundang Lagoon (China), 28 taxa were associated to M. sallei in polyhaline sites, with decreased diversity levels in the benthic community after this invasion (Cai et al. 2014CAI LZ, HWANG JS, DAHMS HU, FU SJ, ZHUO Y & GUO T. 2014. Effect of the invasive bivalve Mytilopsis sallei on the macrofaunal fouling community and the environment of Yundang Lagoon, Xiamen, China. Hydrobiologia 741: 101-111.). Contrastingly, Magni et al. (2019)MAGNI P, COMO S, GRAVINA MF, GUO D, LI C & HUANG L. 2019. Trophic features, benthic recovery, and dominance of the invasive Mytilopsis sallei in the Yundang Lagoon (Xiamen, China) following long-term restoration. Water 11: 1692. recorded higher species richness where M. sallei clusters were more abundant, at the same lagoon. Mytilopsis sallei apparently lead to a decrement of the macrofauna richness in the Visakhapatnam harbour (India) and competed intensively with A. amphitrite in Hong Kong (Morton 1981MORTON B. 1981. The biology and functional morphology of Mytilopsis sallei (Recluz) (Bivalvia: Dreissenacea) fouling Visakhapatnam Harbour, Andhra Pradesh, India. J Mollus Stud 47: 25-42., 1989MORTON B. 1989. Life-history characteristics and sexual strategy of Mytilopsis sallei (Bivalvia: Dreissenacea), introduced into Hong Kong. J Zool 219: 469-485.). Other barnacles were observed in association with M. leucophaeata, e.g., A. eburneus in the Caspian Sea (Heiler et al. 2010HEILER KCM, NAHAVANDI N & ALBRECHT C. 2010. A new invasion into an ancient lake - The invasion history of the Dreissenid mussel Mytilopsis leucophaeata (Conrad, 1831) and its first record in the Caspian Sea. Malacologia 53: 185-192.) and A. improvisus in The Netherlands and Poland (Van der Gaag et al. 1998VAN DER GAAG M, RAJAGOPAL S, VAN DER VELDE G & JENNER HA. 1998. Settlement and growth of barnacles, Balanus improvisus Darwin, 1854, in the brackish Noordzeekanaal, The Netherlands. In: Schramm FR & Von Vaupel Klein JC (Eds), Crustaceans and the Biodiversity Crisis. Proceedings of the Fourth International Crustacean Congress, Amsterdan, The Netherlands, p. 663-674., Brzana et al. 2017BRZANA R, JANAS U & BORECKA A. 2017. New records of Conrad’s false mussel Mytilopsis leucophaeata (Conrad, 1831) in the Vistula Delta. Oceanol Hydrobiol St 46: 231-236.). In New Haven, Connecticut (U.S.A.), 10 taxa were associated to M. leucophaeata clusters (Richardson & Hammond 2016RICHARDSON DJ & HAMMOND CI. 2016. Dark false mussel, Mytilopsis leucophaeata (Bivalvia: Dreissenidae), in the Lower West River, New Haven, New Haven County, Connecticut. B Peabody Mus Nat Hi 57: 117-125.). All those studies show that clusters of dreissenids can harbor some variety of species, because the associated fauna may take advantage of the new formed habitats and promptly colonizes them. Therefore, the benthic species found in M. leucophaeata clusters in the Rodrigo de Freitas Lagoon are found in other substrata, but probably expanded their local distributions after this invasion.

Studies about the interactions between invasive and native species are essential for the comprehension of the impacts caused by invasions. This is the case of the apparent competition between M. leucophaeata and B. darwinianus in the Rodrigo de Freitas Lagoon. The anthropic pressure in this coastal lagoon may be a major cause for the well-succeeded invasion of that bivalve, because disturbed sites are usually simplified and often have low species richness. A regular monitoring program along estuarine sites in Rio de Janeiro coast is essential to identify possible new records of M. leucophaeata and thus limit the spread of this invader. Studies of the native benthic macrofauna, particularly those obtained from sites prior to the invasion of M. leucophaeata, are therefore crucial to assess the impacts of this invader over native species and ecosystem.

ACKNOWLEDGMENTS

We are greatly indebted to: Dr. Alexandra Rizzo (UERJ), Dr. André Senna (UERJ), Dr. Cristiana Serejo (MNRJ), Dr. Fábio Pitombo (UFF), Dr. Isabela Gonçalves (UERJ) and Dr. Juliana Segadilha (MNRJ) for the confirmation of some taxonomic identifications. Dr. Andrea Junqueira (UFRJ) and Dr. Tatiana Cabrini (UNIRIO) made valuable comments on an early version of the manuscript. Nathalia Gomes and Dr. Fabiano Salgueiro (UNIRIO) helped with the genetic confirmation of E. dissimilis. The Department of Invertebrates (MNRJ) for access to equipment used for specimens’ photographs. UNIRIO for the scholarship received by the first author. The Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) and Fundação Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de Janeiro (FAPERJ) partially supported the present study through research grants attributed to Luciano Neves dos Santos (314379/2018-5; E-26/202.840/2015; E-26/202.755/2018).

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Publication Dates

  • Publication in this collection
    03 Sept 2021
  • Date of issue
    2021

History

  • Received
    04 Oct 2019
  • Accepted
    08 June 2020
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