Unstable environment of coastal lagoons drives genetic variation in the amphipod <i>Quadrivisio lutzi</i>

Xavier, Mariana Sampaio; Paiva, Paulo Cesar; Weber, Laura Isabel

doi:10.1590/1678-4685-GMB-2023-0094

Abstract

The freshwater/brackish amphipod Quadrivisio lutzi inhabits coastal lagoons, highly unstable environments subject to sudden inflow of marine water. Our aim was to evaluate how the genetic composition varies in these populations. Brazilian populations were compared by 16S rRNA and COI gene sequences. The genetic structure of four Rio de Janeiro amphipod populations was evaluated during the period of 2011-2019 by COI. Rio de Janeiro population was compared with Alagoas and São Paulo populations, which was genetically distinct, at species level (16S, d > 7%; COI, d >14%). The genetic structure in Rio de Janeiro showed the Imboassica subpopulation as the most divergent (Imboassica & Carapebus, F _ST = 0.238), followed by Lagamar population (Lagamar & Carapebus, F _ST = 0.049). The geographic distance and urbanization around these lagoons explain the degree of genetic isolation of these amphipod subpopulations. Paulista and Carapebus populations were not structured. Temporal variation in haplotype number and frequency were evident in both populations that were evaluated (Carapebus and Imboassica). Changes in salinity and water volume variation at these lagoons may be responsible for the observed changes in genetic composition, which may be the results of genetic drift effects over temporally fluctuating size subpopulations, without loss of genetic diversity.

Keywords:
Crustacea; Maeridae; Brazil; population genetics; mtDNA

Introduction

Complex coastal lagoon systems are observed along the Brazilian coast (Esteves, 1998Esteves FA (1998) Lagoas costeiras: Origem, funcionamento e possibilidades de manejo. In: Esteves FA (ed) Ecologia das Lagoas Costeiras do Parque Nacional da Restinga de Jurubatiba e do Município de Macaé (RJ). 1st edition. Núcleo de Pesquisas Ecológicas de Macaé, Universidade Federal do Rio de Janeiro, Rio de Janeiro, pp 63-87.). At the north of the State of Rio de Janeiro (RJ), a lacunar coastal system was formed in the Campos basin during the Holocene (~5,000 BPY) by sea transgression and regression events (Esteves, 2011aEsteves FA (2011a) Fundamentos da limnologia. 3rd edition. Interciências, Rio de Janeiro, 826 pp.). Most of these lagoons are within the National Park Restinga do Jurubatiba (PARNA Jurubatiba). The PARNA Jurubatiba represents a diverse ecosystem of eighteen coastal lagoons with different physicochemical properties (Enrich-Prast et al., 2004Enrich-Prast A, Bozelli RL, Esteves FA and Meirelles FP (2004) Lagoas costeiras da Restinga de Jurubatiba: Descrição de suas variáveis limnológicas. In: Rocha CFD, Esteves FA and Scarano FR (eds) Pesquisas de longa duração na Restinga de Jurubatiba: Ecologia, história natural e conservação. 1st edition. RIMa, São Carlos, pp 245-253.; Silva and Molisani, 2019Silva LBC and Molisani MM (2019) Revisão histórica sobre o estado trófico de lagoas costeiras do estado do Rio de Janeiro. 1st edition. Essentia Editora, Campos dos Goytacazes, 105 p.). Coastal lagoons are highly unstable environments due to local variations in precipitation, evaporation (Kjerfve, 1994Kjerfve B (1994) Coastal lagoons. In: Kjerfve B (ed) Coastal lagoon processes. 1st edition. Elsevier Oceanographic Series, Amsterdam, pp 1-8.) and the intrusion of marine water due to the frequent rupture of sand barriers, which challenges the survival of most local freshwater species (Esteves, 1998Esteves FA (1998) Lagoas costeiras: Origem, funcionamento e possibilidades de manejo. In: Esteves FA (ed) Ecologia das Lagoas Costeiras do Parque Nacional da Restinga de Jurubatiba e do Município de Macaé (RJ). 1st edition. Núcleo de Pesquisas Ecológicas de Macaé, Universidade Federal do Rio de Janeiro, Rio de Janeiro, pp 63-87.; Camara et al., 2018Camara EM, Caramaschi EP, Di Dario F and Petry AC (2018) Short-term changes in two tropical coastal lagoons: Effects of sandbar openings on fish assemblages. J Coast Res 34:90-105.; Santi et al., 2020Santi F, Petry AC, Plath M and Riesch R (2020) Phenotypic differentiation in a heterogeneous environment: Morphological and life‐history responses to ecological gradients in a livebearing fish. J Zool 310:10-23.).

Salinity is an important environmental parameter for many invertebrate species; for example, it determined the spatial structure of mussels (Blot et al., 1989Blot M, Thiriot-Quiévreux C and Soyer J (1989) Genetic differences and environments of mussel populations in Kerguelen Islands. Polar Biol 10:167-174.) and the distribution of stenohaline amphipods (Zaabar et al., 2015Zaabar W, Zakhama-Sraieb R, Charfi-Cheikhrouha F and Achouri MS (2015) Abundance and diversity of amphipods (Crustacea: Peracarida) on shallow algae and seagrass in lagoonal ecosystem of the Mediterranean Tunisian coast. Zool Stud 54:e38.). The amphipod Quadrivisio lutzi (Shoemaker, 1933Shoemaker CR (1933) Amphipoda from Florida and the West Indies. Am Mus Novit 598:1-24.) inhabits some of the coastal lagoons of the north of the State of Rio de Janeiro, and within the PARNA Jurubatiba. This amphipod species shows persistent populations in Carapebus and Imboassica lagoons, which has been attributed to the high reproductive potential (Medeiros and Weber, 2016Medeiros TB and Weber LI (2016) Aspects of the reproductive biology of the freshwater/brackish amphipod Quadrivisio lutzi (Crustacea, Amphipoda) from an unstable coastal lagoon of southeastern Brazil. Nauplius 24:e2016003.). Brazilian records of Q. lutzi include the north of the State of Alagoas (Schellemberg, 1938Schellemberg A (1938) Brasilianische Amphipoden, mit biologischen Bemerkungen. Zoologische Jahrbücher. Abteilung für Systematik, Ökologie und Geographie der Tiere 71:203-218.) and the state of São Paulo (Leite et al., 1980Leite FPP, Tararam AS and Wakabara Y (1980) Composição e distribuição da fauna de Gammaridea na região da Enseada da Fortaleza - Ubatuba, Estado de São Paulo. Bol Instituto Oceanográfico 29:297-299.; Wakabara et al., 1991Wakabara Y, Tararam AS, Valério-Berardo MT, Duleba W and Leite FPP (1991) Gammaridean and caprellidean fauna from Brazil. In: VIIth International Colloquium on Amphipoda, p. 69-77.). The type locality of the species is Georgetown, British Guiana, where it was originally described in the genus Pseudoceradocus (Shoemaker, 1933Shoemaker CR (1933) Amphipoda from Florida and the West Indies. Am Mus Novit 598:1-24.). It has also been registered for the Gulf of Mexico and Venezuela (Escobar-Briones et al., 2002Escobar-Briones E, Winfield I, Ortíz M, Gasca E and Suárez E (2002) Amphipoda. In: Llorente J and Morrone JJ (eds) Biodiversidad, taxonomía y biogeografía de artrópodos de México: Hacia una síntesis de su conocimiento. 1st edition. Las Prensas de Ciencias, Facultad de Ciencias UNAM, México, vol. III, pp 341-371.; Martín et al., 2002Martín A, Ortiz M and Díaz YJ (2002) Nuevos registros de crustáceos anfípodos (Gammaridea) colectados en las costas del Caribe venezolano. INVEMAR 31:15-24.; Capelo et al., 2004Capelo JC, García JV and Pereira G (2004) Diversidad de macroinvertebrados bentónicos del Golfo de Paria y delta del Orinoco. Evaluación rápida de la biodiversidad y aspectos sociales de los ecosistemas acuáticos del delta del rıo Orinoco y Golfo de Paria, Venezuela. Boletin RAP de Evaluación Biológica 37:55-60.; Ortíz et al., 2007Ortíz M, Martín A and Díaz YJ (2007) Lista y referencias de los crustáceos anfípodos (Amphipoda: Gammaridea) del Atlántico occidental tropical. Rev Biol Trop 55:479-498.); and for Aruba and Bonaire islands (Stephensen, 1933Stephensen K (1933) Fresh- and brackish-water Amphipoda from Bonaire, Curacao und Aruba (Zoologische Ergebnisse einer Reise nach Bonaire, Curacao, und Aruba in Jahre 1930). Zoologische Jahrbücher. Abteilung für Systematik, Ökologie und Geographie der Tiere 64:414-436.), at which localities it was described as Q. occidentalis, a synonym of Q. lutzi. All records so far of Q. lutzi are from coastal environments, from brackish estuarine to freshwater habitats (Stephensen, 1933Stephensen K (1933) Fresh- and brackish-water Amphipoda from Bonaire, Curacao und Aruba (Zoologische Ergebnisse einer Reise nach Bonaire, Curacao, und Aruba in Jahre 1930). Zoologische Jahrbücher. Abteilung für Systematik, Ökologie und Geographie der Tiere 64:414-436.; Leite et al., 1980Leite FPP, Tararam AS and Wakabara Y (1980) Composição e distribuição da fauna de Gammaridea na região da Enseada da Fortaleza - Ubatuba, Estado de São Paulo. Bol Instituto Oceanográfico 29:297-299.; Ortíz et al., 2007Ortíz M, Martín A and Díaz YJ (2007) Lista y referencias de los crustáceos anfípodos (Amphipoda: Gammaridea) del Atlántico occidental tropical. Rev Biol Trop 55:479-498.).

Vertebrate and invertebrate species inhabiting coastal lagoons have been genetically studied, showing mostly high levels of haplotype diversity and endemism, which gives these ecosystems high ecological and genetic importance (Vergara-Chen et al., 2010aVergara-Chen C, González‐Wangüemert M, Marcos C and Pérez‐Ruzafa A (2010a) High gene flow promotes the genetic homogeneity of the fish goby Pomatoschistus marmoratus (Risso, 1810) from Mar Menor coastal lagoon and adjacent marine waters (Spain). Mar Ecol 31:270-275.,bVergara-Chen C, González-Wangüemert M, Marcos C and Pérez-Ruzafa A (2010b) Genetic diversity and connectivity remain high in Holothuria polii (Delle Chiaje 1823) across a coastal lagoon-open sea environmental gradient. Genetica 138:895-906.; Mejri et al., 2011Mejri R, Arculeo M, Hassine OKB and Brutto SL (2011) Genetic architecture of the marbled goby Pomatoschistus marmoratus (Perciformes, Gobiidae) in the Mediterranean Sea. Mol Phylogenet Evol 58:395-403.; Vasileiadou et al., 2016Vasileiadou K, Pavloudi C, Sarropoulou E, Fragopoulou N, Kotoulas G and Arvanitidis C (2016) Unique COI haplotypes in Hediste diversicolor populations in lagoons adjoining the Ionian Sea. Aquat Biol 25:7-15.; Seixas et al., 2018Seixas VC, Paiva PC and Russo CADM (2018) Comparative population genetics and demographic history of two polychaete species suggest that coastal lagoon populations evolve under alternate regimes of gene flow. Mar Biol 165:19215.).

Changes in population abundance has been observed in the amphipod Q. lutzi after sudden changes in salinity. Although the amphipod population has been shown to recover in a few months, no genetic study is so far done on how its genetic composition is affected by unstable environments. Therefore, the aim of this study was to evaluate changes in genetic composition and diversity along time at different coastal lagoons situated at the north of the State of Rio de Janeiro, Brazil.

Material and Methods

Amphipod sampling

Quadrivisio lutzi amphipods were collected by hand from macrophyte roots, from algae or under vegetal debris at shallow waters in four coastal lagoons in the state of Rio de Janeiro and in two river/lagoon outlets from the states of Alagoas and São Paulo (Figure 1). Coordinates and salinity were obtained at each location (Table 1). Amphipods were then fixed in 92.8% ethanol and stored in 1.5 mL microtubes.

Figure 1 -
Sites where the amphipod Quadrivisio lutzi was collected.

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Table 1 -
Sampled locations along the Brazilian coast of the amphipod Quadrivisio lutzi.

DNA extraction, amplification, and sequencing

Whole amphipods were homogenized individually with sterilized glass sticks‚ and then DNA extraction was performed using Phenol/Chloroform/Proteinase-K (Sambrook et al., 1989Sambrook J, Fritsch EF and Maniatis T (1989) Molecular cloning: A laboratory manual. 2nd edition. Cold Spring Harbor Laboratory, New York, 310 p.) or Chelex-100 (Sigma) protocols (Hoelzel, 1998Hoelzel AR (1998) Molecular genetic analysis of populations: A practical approach. 2nd edition. Oxford University Press, Oxford, 445 p.) with modifications. For Chelex extraction, each amphipod was homogenized in 75 µL lysis buffer (0.2 mM Tris-HCl, 0.02 mMEDTA, pH 8.0). Then‚ 75 µL Chelex 12% solution and 30 µL Proteinase K (10 mg/mL) were added, mixed with a vortex mixer‚ and incubated overnight at 55 ºC.

Amplifications of the cytochrome c oxidase, subunit I (COI), and 16S rRNA (16S) mitochondrial genes were performed by polymerase chain reaction (PCR) using universal primers and primers designed specifically for Q. lutzi (Table 2). PCR reactions (25 µL) were performed with 1-10 µL of extracted DNA or dilutions in double distilled water (1:2, 1:5, 1:10, 1:30, 1:50, 1:100); 1x Buffer; 3 mM MgCl₂; 0.12% Triton-X-100; 0.24 mM dNTPs mix; 0.4 mM of each primer; 2 U of GoTaq® DNA polymerase (Promega, Madison, WI, USA). PCR reactions were submitted in a Mastercycler gradient thermocycler (Eppendorf, Hamburg, Germany) to the following cycles: 1 cycle at 94 ºC for 4 min; 36 cycles for 1 min at each of the following temperatures: 94 ºC, 48 ºC -59 ºC (COI) and 52 ºC-57 ºC (16S) and 72 ºC; and one final cycle at 72 ºC for 10 min. All PCR products were purified and sequenced by Macrogen Inc., Korea, using the automated Sanger dideoxide method.

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Table 2 -
Primers used for the amplification by PCR of mitochondrial genes (COI and 16S) of the amphipod Quadrivisio lutzi.

Data analysis

Sequences were edited with ChromasPro (McCarty, 1998McCarty C (1998) CHROMASPRO 1.34, 34, https://technelysium.com.au/wp/chromaspro/ (accessed 31 March 2022).
https://technelysium.com.au/wp/chromaspr... ) and Geneious Prime software (Geneious 11.0.14.1, 2022Geneious Prime (2022) Versão 11.0.14.1, 1, https://www.geneious.com (accessed 30 March 2022).
https://www.geneious.com... ). Alignments were done using CLUSTAL W (Higgins et al., 1994Higgins D, Thompson J, Gibson T, Thompson JD, Higgins DG and Gibson TJ (1994) CLUSTAL W: Improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position-specific gap penalties and weight matrix choice. Nucleic Acids Res 22:4673-4680.) implemented in MEGA11 software (Tamura et al., 2021Tamura K, Stecher G and Kumar S (2021) MEGA11: Molecular evolutionary genetics analysis version 11. Mol Biol Evol 38:3022-3027.). Translation of COI sequences was done by aligning with Daphnia pulex (Accession No. NC000844) and Parhyale hawaensis (Accession No. NC039402) COI gene, using the Invertebrate Mitochondrial CodeInvertebrate Mitochondrial Code, Invertebrate Mitochondrial Code, http://www.ncbi.nim.nih.gov (accessed 12 September 2022).
http://www.ncbi.nim.nih.gov... , for identifying the position of the amplified fragment in the gene and to recognize synonymous and non-synonymous mutations. Sequences obtained for Rio de Janeiro populations were submitted to the Nucleotide GenBank databaseNucleotide GenBank database (NCBI), Nucleotide GenBank database (NCBI), https://www.ncbi.nlm.nih.gov/genbank/ (accessed 6 February 2023).
https://www.ncbi.nlm.nih.gov/genbank/... (16S, OQ361834-OQ361842; COI, OQ401341-OQ401385).

The genetic divergence between Rio de Janeiro population and the amphipod populations from the states of Alagoas and São Paulo were obtained by Kimura 2-parameter model (d; Kimura, 1980Kimura M (1980) A simple method for estimating evolutionary rate of base substitutions through comparative studies of nucleotide sequences. J Mol Evol 16:111-120.) for the 16S and COI genes, using MEGA 11 software. Trees were constructed based on maximum likelihood (ML) and Bayesian inference (BI) at the 16S, COI and concatenated data sets, using evolutionary models determined by jModelTest 2.1 (Darriba et al., 2012Darriba D, Taboada GL, Doallo R and Posada D (2012) jModelTest 2: More models, new heuristics and parallel computing. Nat Methods 9:772.) under the Akaike criterium (GTR+G model and HKY+I+G, respectively). Three outgroups were included in the analysis for tree rooting: for 16S, Elasmopus nkjaf (Accession No. LC215808, LC215809), Maeridae; Quadrimaera pacifica (Accession No. AB432980), Maeridae; and Gammarus pulex (Accession No. AJ269626), Gammaridae. For COI: E. nkjaf (Accession No. LC215812, LC215813); Melita nitida (Accession No. MH826277, MH826279), Melitidae; and G. pulex (Accession No. MN400977). COI trees were performed only for Alagoas and Rio de Janeiro populations, because it was not possible to obtain more amphipods from Ubatuba, São Paulo, although sampling efforts were made. A heuristic search of the ML tree was performed using Garli 2 software (Zwickl, 2006Zwickl DJ (2006) Genetic algorithm approaches for the phylogenetic analysis of large biological sequence datasets under the maximum likelihood criterion. D. Sc. Dissertation, The University of Texas, Austin, 125 p.) with 1,000 replicates and 1,000 bootstrap resampling for tree branch support. The BI analysis was performed using Markov chain Monte Carlo algorithms with four simultaneous chains for 10,000,000 generations with standard deviation of Split frequencies is below 0.01 using MrBayes 3.2 software (Ronquist et al., 2012Ronquist F, Teslenko M, Van Der Mark P, Ayres DL, Darling A, Höhna S, Larget B, Liu L, Suchard MA and Huelsenbeck JP (2012) MRBAYES 3.2: Efficient Bayesian phylogenetic inference and model selection across a large model space. Syst Biol 61:539-542.) and the optimization criterion of the maximum posterior probability. The quality of the Bayesian sampling was evaluated by Tracer v1.7.1 software (Rambaut et al., 2018Rambaut A, Drummond AJ, Xie W, Baele G and Suchard MA (2018) Tracer: MCMC Trace Analysis Tool. Version v1.7.1.) using the burn-in value applied with MrBayes to obtain the mean posterior probability of the consensus tree and the ESS values. Branch support of the BI tree was represented by the posterior probability of the clades obtained using MrBayes software. Broad estimations of times since divergence between pairs of lineages were calculated using the conventional rate of mitochondrial nucleotide substitution of 2 % per mya, using t= 1/2d/µ (Brown et al., 1979Brown WM, Gilbert TL and Wilson AC (1979) Rapid evolution of animal mitochondrial DNA. Proc Natl Acad Sci U S A 76:1967-1971.).

The genetic structure and temporal variation of the amphipod population of the north of the state of Rio de Janeiro (Rio de Janeiro population) was evaluated using COI gene. A TCS network (Clement et al., 2002Clement M, Snell Q, Walker P, Posada D and Crandall K (2002) TCS: Estimating gene genealogies. In: 16th International Parallel and Distributed Processing Symposium, Fort Lauderdale, p 184.) was performed using PopArt software (Leigh and Bryant, 2015Leigh JW and Bryant D (2015) PopART: Full-feature software for haplotype network construction. Methods Ecol Evol 6:1110-1116.) for amphipod haplotypes from four lagoons (Lagamar, Paulista, Carapebus and Imboassica; Figure 1), showing haplotype frequencies. Nucleotide diversity and the pairwise population structure parameter, F _ST , were obtained by Arlequin (Excoffier and Lischer, 2010Excoffier L and Lischer HE (2010) Arlequin suite ver 3.5: A new series of programs to perform population genetics analyses under Linux and Windows. Mol Ecol Resour 10:564-567.). The genetic divergence of the populations was evaluated by the Kimura 2-parameter model using MEGA 11 software. Haplotype diversity and the neutrality tests of Tajima (1989Tajima F (1989) Statistical method for testing the neutrality mutation hypothesis by DNA polymorphism. Genetics 123:585-595.) and Fu (1997Fu YX (1997) Statistical tests of neutrality of mutations against population growth, hitchhiking and background selection. Genetics 147:915-925.) were obtained using DnaSP v6 software (Rozas et al., 2017Rozas J, Ferrer-Mata A, Sánchez-DelBarrio JC, Guirao-Rico S, Librado P, Ramos-Onsins SE and Sánchez-Gracia A (2017) DnaSP v6: DNA Sequence polymorphism analysis of large datasets. Mol Biol Evol 34:3299-3302.) for each population/year compared. Genetic changes through time were evaluated for the two largest amphipod populations (Carapebus and Imboassica) with evidence of bar opening events and strong salinity changes.

Rainfall data were obtained from Instituto Nacional de Meteorologia (INMET)Instituto Nacional de Meteorologia (INMET), Instituto Nacional de Meteorologia (INMET), https://portal.inmet.gov.br/dadoshistoricos (accessed 1 March 2023).
https://portal.inmet.gov.br/dadoshistori... from the daily registrations of the automatic station A608 at Macaé, state of Rio de Janeiro, Brazil. The sum of rainfall at each month between 2011 and 2019 was calculated.

Results

Seven haplotypes for 16S were obtained from 48 sequences with a length of 425 bp. For COI, 22 haplotypes of 236 sequences with a length of 588 bp were obtained.

Divergence of amphipod populations along the Brazilian coast

The degrees of divergence among the Brazilian populations of Q. lutzi are shown in Figure 2. Populations at different states show independent branches with high bootstrap support and Bayesian posterior probability (Figure 2a). Genetic distances among them, confirm that Rio de Janeiro population is highly divergent from Alagoas (16S, d = 0.0795 ± 0.0003) and to São Paulo (16S, d = 0.0879 ± 0.0007) populations. Alagoas and São Paulo were the most divergent (16S, d = 0.0969) populations. The high divergence observed between Rio de Janeiro and Alagoas population was confirmed with COI gene sequences (Figure 2b) which showed high distance (d = 0.1472).

Figure 2 -
Brazilian populations of Quadrivisio. Bayesian inference trees. A) based on 16S sequences, showing the divergence between Rio de Janeiro, Alagoas and São Paulo populations. B) based on COI sequences, showing the divergence between Rio de Janeiro and Alagoas populations. Numbers (in blue) bootstrap branch support; (in red) posterior probability from Bayesian inference.

**Population structure of the amphipod Q. lutzi at the north of the State of Rio de Janeiro (Rio de Janeiro population)**

Four coastal lagoons were found with large numbers of amphipods (Lagamar, Paulista, Carapebus and Imboassica). Other lagoons from which a few amphipods were collected in previous sampling events, but in which they were no longer found (Maria Menina, Ubatuba, Preta and Garças), were not included in the analysis. Pairwise genetic distance, F _ST and diversity parameters for the four studied populations are shown in Table 3. The mean genetic distance among the four populations was d = 0.0009 ± 0.0002. Imboassica showed a significantly high F _ST from all other populations (0.163-0.238), showing that Rio de Janeiro population is structured. Paulista amphipod population did not show significant differences from Lagamar and Carapebus; and Lagamar showed significant, but low level of structuring with Carapebus (Table 3).

A total of 22 haplotypes with a total of 24 segregating sites of which 10 were parsimony informative, were found at Rio de Janeiro population. The most frequent haplotype (H1) was represented at all subpopulations (Figure 3). Each subpopulation (Lagamar, Carapebus-Paulista and Imboassica) had haplotypes found nowhere else. All diversity parameters showed Imboassica as the most diverse subpopulation, followed by Carapebus. (Table 3). Time since divergence of Imboassica subpopulation was estimated at 86,000 years ago and divergence between Lagamar and Carapebus was estimated around 50,000 years ago.

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Table 3 -
Genetic structure of Rio de Janeiro population of Quadrivisio lutzi. Pairwise Kimura 2-parameter distance (above the diagonal), F _ST values (below the diagonal) and diversity parameters of amphipod populations from different lagoons, based on COI sequence analysis. Significant values (p < 0.05) are shown in bold.

Figure 3 -
Rio de Janeiro population of Quadrivisio lutzi. Network of COI haplotypes found in different lagoons. Haplotype frequencies are relative to circle size.

Genetic changes along time in the Rio de Janeiro population of Q. lutzi

Temporal changes were observed in Carapebus and Imboassica subpopulations (Table 4). The population structure parameter, F _ST, showed that Imboassica amphipod subpopulation increased its divergence from Lagamar and Carapebus-Paulista subpopulations from 2016 to 2018; and Carapebus diverged significantly from Lagamar and Paulista in 2019, while no such differences were show previous years (2011 and 2015; Table 4).

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Table 4 -
Temporal genetic changes in Rio de Janeiro population of Quadrivisio lutzi. Pairwise Kimura 2-parameter distance (above the diagonal), F _ST values (below the diagonal) and diversity parameters of amphipod populations from different lagoons and years, based on COI sequence analysis. Significant values (p < 0.05) are shown in bold. In yellow, comparisons from the same or following year.

Diversity parameters (haplotype and nucleotype diversity) also changed during time in Carapebus and Imboassica subpopulations, increasing in 2018/2019 compared to 2015/2016 (Table 4). In more recent years (2018/2019) a dramatic change was observed in the most common allele (H1) from 2011-2016, turning H2 and H3, the most common alleles in Carapebus and Imboassica, respectively. In 2015, the Carapebus amphipod population showed an increase of low frequency haplotypes compared to 2011; and in 2019, low-frequency haplotypes declined (Figure 4; Table 5). In Imboassica, low-frequency haplotypes of 2016 increased their frequencies in 2018 (Figure 4; Table 5). The neutrality tests were non-significant for most populations at the different years; only Lagamar (Tajima’s D = -2.1039, p < 0.05; Fu’s Fs = -1.097, p < 0.05) and Carapebus subpopulation of the year 2015 (Tajima’s D = -2.2295, p < 0.01; and Fu’s Fs = -3.562, p < 0.02) showed deviation from neutrality.

Figure 4 -
Changes in COI haplotype frequencies (circles) between 2011 and 2019 in the amphipod Quadrivisio lutzi at two localities (Carapebus and Imboassica lagoons) are shown over rainfall variation (INMET). Most common haplotypes (H1, H2 and H3) are indicated within the circle and other haplotypes are represented by different colors. Sandbar breaks are represented by red arrows at the localities of Carapebus (c) and Imboassica (i); and blue and purple arrows indicate sampling events at Carapebus and Imboassica, respectively. The number under sampling events indicates the salinity at the time of collection.

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Table 5 -
Temporal changes in haplotype frequency in populations of Quadrivisio lutzi from Carapebus and Imboassica lagoons.

Discussion

Divergence of amphipod populations along the Brazilian coast

Along the Brazilian coast, three distinct populations (Alagoas, Rio de Janeiro and São Paulo) with high levels of divergence, a strong indication of the presence of more than one species in Brazil for the genus Quadrivisio. The levels of divergence (16S, > 7 %; COI, > 14%) found between them are higher than those found at 16S locus for conspecific crustacean populations (in crabs, 1.3%, Avise et al., 1994Avise JC, Nelson WS and Sugita H (1994) A speciational history of “living fossils”: Molecular evolutionary patterns in horseshoe crabs. Evolution 48:1986-2001.; copepods, 0.3-2.6%, Bucklin et al., 1995Bucklin A, Frost BW and Kocher TD (1995) Molecular systematics of six Calanus and three Metridia species (Calanoida: Copepoda). Mar Biol 121:655-664.; amphipods: 1-3.9%, Jażdżewska and Mamos, 2019Jażdżewska AM and Mamos T (2019) High species richness of Northwest Pacific deep-sea amphipods revealed through DNA barcoding. Prog Oceanogr 178:102184.). Interspecific distances at 16S locus have been reported for crustaceans within the range of 4.4 to 25.7% (Machado et al., 1993Machado EG, Suarez MO, Dennebouy N, Monnerot M and Mounolou JC (1993) Mitochondrial 16S-rRNA gene of two species of shrimps: Sequence variability and secondary structure. Crustaceana 65:279-286.; Bucklin et al., 1995Bucklin A, Frost BW and Kocher TD (1995) Molecular systematics of six Calanus and three Metridia species (Calanoida: Copepoda). Mar Biol 121:655-664.; France and Kocher, 1996France SC and Kocher TD (1996) Geographic and bathymetric patterns of mitochondrial 16S rRNA sequence divergence among deep-sea amphipods, Eurythenes gryllus. Mar Biol 126:633-643.). The high level of divergence at COI gene found between Alagoas and Rio de Janeiro population (> 14%) also support the multispecific status of the genus Quadrivisio. COI gene has great potential to complement traditional taxonomy in the identification of crustacean species (Costa et al., 2007Costa FO, DeWaard JR, Boutillier J, Ratnasingham S, Dooh RT, Hajibabaei M and Hebert PD (2007) Biological identifications through DNA barcodes: The case of the Crustacea. Can J Fish Aquat Sci 64:272-295.). In accordance to Costa et al. (2009Costa FO, Henzler CM, Lunt DH, Whiteley NM and Rock J (2009) Probing marine Gammarus (Amphipoda) taxonomy with DNA barcodes. Syst Biodivers 7:365-379.), studying 15 species of the genus Gammarus and three pair of species of other amphipod genera, intraspecific range of distances was 0-4.3%, while the interspecific range was 5.2-34.2%. Corroborating that the degree of divergence of the Brazilian populations of Quadrivisio from different states is within the range of interspecific populations, it is a strong indicative of the presence of cryptic or semi-cryptic species of this genus in the surveyed area. The morphological description and identification of diagnostic characters will be necessary for the delimitation and recognition of these potential species.

Genetic structure of the Rio de Janeiro amphipod subpopulations

Taxonomic reviews and catalogs of Brazilian Amphipoda have already shown the sparse and rare distribution of Quadrivisio (Wakabara et al., 1991Wakabara Y, Tararam AS, Valério-Berardo MT, Duleba W and Leite FPP (1991) Gammaridean and caprellidean fauna from Brazil. In: VIIth International Colloquium on Amphipoda, p. 69-77.; Serejo and Siqueira, 2018Serejo CS and Siqueira SGL (2018) Catalogue of the Order Amphipoda from Brazil (Crustacea, Peracarida): Suborders Amphilochidea, Senticaudata and Order Ingolfiellida. Zootaxa 4431:139.). Sampling efforts in coastal lagoons of the states of Espírito Santo, Santa Catarina and Rio Grande do Sul have not reported the species (unpublished). Despite the sampling effort of the present study in the known locations of the Quadrivisio distribution in Brazil, the abundance was very low in environments permanently open to the sea. The low representation of the species may be reflecting historical events on its distribution and environmental requirements of the species.

The population of Q. lutzi in the state of Rio de Janeiro is abundant and it was found to be highly structured, as expected from fragmented environments (Astolfi et al., 2005Astolfi L, Dupanloup I, Rossi R, Bisol PM, Faure E and Congiu L (2005) Mitochondrial variability of sand smelt Atherina boyeri populations from north Mediterranean coastal lagoons. Mar Ecol Prog Ser 297:233-243.). The amphipod population is divided into three subpopulations (Lagamar, Carapebus-Paulista and Imboassica). Levels of differentiation among them may be explained by the degree of isolation due to the geographic distance that separate them and by the progressive urbanization around them, in the cases of Imboassica and Lagamar. Connectivity in the past may have moderated differentiation between them, in the cases of Lagamar and Carapebus-Paulista subpopulations; and present day connectivity may prevent further differentiation between amphipods from different lagoons, in the cases of Carapebus and Paulista.

In the past, a large floodable area, called the “Pantanal Fluminense”, interconnected Lagoa Feia to all the PARNA Jurubatiba lagoons (Lamego, 1946Lamego AR (1946) O homem e a restinga. 2nd edition. IBGE, Rio de Janeiro, 327 p.), which includes Paulista and Carapebus. Lagamar lagoon is a remnant of the Lagoa Feia drainage canal (Soffiati, 2013Soffiati AA (2013) As lagoas do Norte Fluminense: Contribuição à história de uma luta. Essentia Editora, Campos dos Goytacazes , 203 p.), that became isolated from the PARNA Jurubatiba with the progression of drainage activities and urbanization (Silva and Molisani, 2019Silva LBC and Molisani MM (2019) Revisão histórica sobre o estado trófico de lagoas costeiras do estado do Rio de Janeiro. 1st edition. Essentia Editora, Campos dos Goytacazes, 105 p.). Past connectivity may explain the present low values of subdivision between Lagamar and Carapebus-Paulista subpopulations. Although genetic differences were lower in previous years between Lagamar and Carapebus-Paulista subpopulations, the increased urbanization around Lagamar will prevent any future gene flow between them, therefore it is expected that genetic differences will increase with time.

Paulista and Carapebus lagoons show variable connectivity, determined by an inner arm of Carapebus lagoon, which may increase its extent in rainy periods allowing gene flow (Esteves, 2011bEsteves FA (2011b) Do índio goitacá à economia do petróleo: Uma viagem pela história e ecologia da maior restinga protegida do Brasil. Essentia, Campos dos Goytacazes, 232 p.) or became interrupted on severe dry seasons.

Imboassica was the most genetically differentiated subpopulation. According to Esteves (2011aEsteves FA (2011a) Fundamentos da limnologia. 3rd edition. Interciências, Rio de Janeiro, 826 pp.), the Imboassica River micro basin was formed by sea transgression and regression events during the Holocene (~5,000 years ago). At the time, the river flow was small and the sand deposition by winds and currents led to the formation of the Imboassica lagoon orthogonal to the coastline (Silva and Molisani, 2019Silva LBC and Molisani MM (2019) Revisão histórica sobre o estado trófico de lagoas costeiras do estado do Rio de Janeiro. 1st edition. Essentia Editora, Campos dos Goytacazes, 105 p.). About 3,000 years ago‚ the first sandbar was formed (paleobar), semi-isolating the lagoon from the sea. A probable rupture of the paleobar happened 1,000 years ago, advancing the lagoon to its current position (Panosso et al., 1998Panosso RF, Attayde JL and Muehe D (1998) Morfometria das Lagoas Imboassica, Comprida e Carapebus: Implicações para seu funcionamento e manejo. In: Esteves FA (ed) Ecologia das lagoas costeiras do Parque Nacional da Restinga de Jurubatiba e do Município de Macaé (RJ). 1st edition. Universidade Federal do Rio de Janeiro, Rio de Janeiro, pp 91-105.). Imboassica is situated at ~29 km from Carapebus lagoon. Although Cabiúnas lagoon is closer to Imboassica (~18 km) than Carapebus lagoon, physicochemical conditions at Cabiúnas and Comprida lagoons are not suitable for amphipod survival. Imboassica lagoon has also been affected by urbanization and farming, decreasing its extent, and causing urban waste contamination at some points (Barreto, 2009Barreto GS (2009) Mapeamento ambiental da bacia hidrográfica da Lagoa Imboacica: Subsídio para construção de planos de bacia. Bol Observ Amb Alberto Ribeiro Lamego 3:125-144.).

The genetic divergence of Imboassica from the other Rio de Janeiro subpopulations suggests that divergence may have started around 86.000 years ago, dating back to the beginning of the fourth transgressive-regressive cycle at the Atlantic South American coast (Carreño et al., 1999Carreño AL, Coimbra JC and Carmo DA (1999) Late Cenozoic sea level changes evidenced by ostracods in the Pelotas basin, southernmost Brazil. Mar Micropaleontol 37:117-129.). This estimation is much older than suggested by Esteves (2011aEsteves FA (2011a) Fundamentos da limnologia. 3rd edition. Interciências, Rio de Janeiro, 826 pp.), of ~5,000 years ago of the Imboassica lagoon emergence. Repetitive drastic changes in lagoon water volumes and salinities may have increased divergence among subpopulations submitted to different regimens of stochastic and directional selective events. Therefore, in populations submitted to unstable environments with temporal variation of effective population size, any estimation of date from divergence should be interpreted carefully (Whitlock, 1992Whitlock MC (1992) Temporal fluctuations in demographic parameters and the genetic variance among populations. Evolution 46:608-615.; Pisa et al., 2019Pisa H, Hermisson J and Polechová J (2019) The influence of fluctuating population densities on evolutionary dynamics. Evolution 73:1341-1355.). Nevertheless, genetic divergence among Rio de Janeiro subpopulations suggests that amphipod colonization in the region occurred before the formation of the contemporary lagoons.

The long-term isolation of Imboassica lagoon may explains the presence of exclusive haplotypes, which is characteristic of coastal lagoons (Pérez-Ruzafa et al., 2019Pérez-Ruzafa A, Pérez-Ruzafa IM, Newton A and Marcos C (2019) Coastal lagoons: Environmental variability, ecosystem complexity, and goods and services uniformity. In: Wolanski E, Day JW, Elliott M and Ramachandran R (eds) Coasts and estuaries. 1st edition. Elsevier, pp 253-276.). Micro-invertebrates transport at different life cycle stages may occur by waterbirds (Silva et al., 2021Silva GG, Green AJ, Stenert C and Maltchik L (2021) Invertebrate dispersal by waterbird species in neotropical wetlands. Braz J Biol 84:e250280.), but may not be frequent, having minimal effect on gene flow among large isolated amphipod populations.

Temporal genetic variation in Carapebus and Imboassica subpopulations

Strong variation in genetic composition was observed at both localities (Carapebus and Imboassica) in the years of 2018/2019 compared to previous years. The genetic changes were evident on the increased diversity of haplotypes and the change of the most common haplotype at each subpopulation. Deviation from neutrality indicates population expansion at Carapebus in 2015‚ which predict large population size. Population growth determine the increase of amphipods with rare haplotypes, therefore retaining diversity (Pavesi and Matthaeis, 2009Pavesi L and Matthaeis E (2009) Life history of the talitrid amphipod Macarorchestia remyi (Schellenberg, 1950) on a Tyrrhenian sandy beach, Italy. Hydrobiologia 635:171-180.; Vergara-Chen et al., 2010bVergara-Chen C, González-Wangüemert M, Marcos C and Pérez-Ruzafa A (2010b) Genetic diversity and connectivity remain high in Holothuria polii (Delle Chiaje 1823) across a coastal lagoon-open sea environmental gradient. Genetica 138:895-906.; Pavesi et al., 2011Pavesi L, Matthaeis E, Tiedemann R and Ketmaier V (2011) Temporal population genetics and COI phylogeography of the sandhopper Macarorchestia remyi (Amphipoda: Talitridae). Zool Stud 50:220-229.). At Carapebus lagoon, optimal environmental conditions were observed (Salinity of 0.3-0.6 ppt; large rain volumes) from 2011 until middle of 2013 (Figure 4), when large volumes of amphipods were easily obtained. Large reproductive potential (Medeiros and Weber, 2016Medeiros TB and Weber LI (2016) Aspects of the reproductive biology of the freshwater/brackish amphipod Quadrivisio lutzi (Crustacea, Amphipoda) from an unstable coastal lagoon of southeastern Brazil. Nauplius 24:e2016003.) may have contributed to population increase at these years. In late 2013 the sandbar was artificially opened twice. Although there was a drastic salinity increase after the sandbar breaks in 2013, amphipod population appears to have been unaffected. In March of 2014, amphipods were not easily found close to the sandbar of Carapebus lagoon, where salinity was > 13 ppt; however, amphipods were found in the innermost part of Carapebus lagoon and in Paulista lagoon, where water remained at 0.5-0.6 ppt of salinity. The artificial sandbar opening in the end of 2013 was followed by a severe dry period that lasted from the beginning of 2014 to the end of 2015 (Figure 4). Although, no genetic differentiation were found at Carapebus in August of 2015, when amphipods were abundant at 9.3 ppt of salinity. Therefore, the dry period did not affect the amphipod population. What happened in the Carapebus amphipod population between August 2015 and April 2019 is discussed below.

The Imboassica lagoon also showed a drastic change in genetic composition from March 2016 to July 2018. Imboassica lagoon suffered a strong drop of water level and a sudden increase of salinity in November 2016. Imboassica is smaller (3.3 km²) than Carapebus lagoon (6.5 km²; Panosso et al., 1998Panosso RF, Attayde JL and Muehe D (1998) Morfometria das Lagoas Imboassica, Comprida e Carapebus: Implicações para seu funcionamento e manejo. In: Esteves FA (ed) Ecologia das lagoas costeiras do Parque Nacional da Restinga de Jurubatiba e do Município de Macaé (RJ). 1st edition. Universidade Federal do Rio de Janeiro, Rio de Janeiro, pp 91-105.) and it is surrounded by urbanized areas that motivate frequent artificial sand bar openings to prevent the flooding of houses around the lagoon. In addition, since 1980 the Imboassica lagoon gradually deteriorated, reaching in 2015 the hypertrophic condition (Silva and Molisani, 2019Silva LBC and Molisani MM (2019) Revisão histórica sobre o estado trófico de lagoas costeiras do estado do Rio de Janeiro. 1st edition. Essentia Editora, Campos dos Goytacazes, 105 p.). Therefore, amphipod population is restricted to the southern anterior margin of the Imboassica lagoon, without routes or other areas to escape under conditions of salinity changes.

In both lagoons, the change of the most frequent haplotype may have happened by a drastic temporarily reduction in population size, followed by a sweepstakes chance event that led to the increase in frequency of new dominant haplotypes mainly due to the effect of genetic drift. At Imboassica, certainly the sudden lagoon volume reduction and salinity increase may explain the severe reduction in population size. However, for Carapebus subpopulation, may not be the case. The environmental instability caused by the sudden intrusion of seawater in Carapebus and Imboassica lagoons has driven changes in fish assemblage (Camara et al., 2018Camara EM, Caramaschi EP, Di Dario F and Petry AC (2018) Short-term changes in two tropical coastal lagoons: Effects of sandbar openings on fish assemblages. J Coast Res 34:90-105.). Euryhaline amphipod predators that deal well with salinity variations may have increased their population size intensifying amphipod predation and therefore reducing their population size. On the other hand, osmoregulation of the amphipod Q. lutzi suggest that osmotic stress may be related to population decline in Carapebus (unpublished data). During 2014 and most of 2015, surviving and newborn amphipods had to live in areas close to the sea under a salinity range of 8-13 ppt, on which they are able to osmoconform (unpublished data). At the end of 2015, salinity dropped, and amphipods needed to activate the hyper-regulation system, which would have demanded time and energy, causing probably population size reduction in the amphipod at Carapebus lagoon.

We do not understand exactly how and when different mechanisms of osmoregulation are activated in the new born amphipods or in adult amphipods, which remained most of their life in a specific level of salinity. Therefore, we cannot rule out completely the possibility that selection may have taken place when population size was still elevated, acting against amphipods not well adapted to a specific new salinity regimen.

The instability in coastal lagoons due to strong water volume and salinity variations has driven changes in the genetic composition of Q. lutzi by genetic drift acting over a fluctuating population size, which causes changes in haplotype frequencies, without diversity loss.

The high diversity and endemism observed in coastal lagoons (Vergara-Chen et al., 2010bVergara-Chen C, González-Wangüemert M, Marcos C and Pérez-Ruzafa A (2010b) Genetic diversity and connectivity remain high in Holothuria polii (Delle Chiaje 1823) across a coastal lagoon-open sea environmental gradient. Genetica 138:895-906.; Milana et al., 2012Milana V, Franchini P, Sola L, Angiulli E and Rossi AR (2012) Genetic structure in lagoons: The effects of habitat discontinuity and low dispersal ability on populations of Atherina boyeri. Mar Biol 159:399-411.; Pérez-Ruzafa et al., 2019Pérez-Ruzafa A, Pérez-Ruzafa IM, Newton A and Marcos C (2019) Coastal lagoons: Environmental variability, ecosystem complexity, and goods and services uniformity. In: Wolanski E, Day JW, Elliott M and Ramachandran R (eds) Coasts and estuaries. 1st edition. Elsevier, pp 253-276.) and the ability of species to survive in such unstable environmental conditions (González-Wangüemert et al., 2006González-Wangüemert M, Giménez-Casalduero F and Pérez-Ruzafa A (2006) Genetic differentiation of Elysia timida (Risso, 1818) populations in the Southwest Mediterranean and Mar Menor coastal lagoon. Biochem Syst Ecol 34:514-527.; Pérez-Ruzafa et al., 2019Pérez-Ruzafa A, Pérez-Ruzafa IM, Newton A and Marcos C (2019) Coastal lagoons: Environmental variability, ecosystem complexity, and goods and services uniformity. In: Wolanski E, Day JW, Elliott M and Ramachandran R (eds) Coasts and estuaries. 1st edition. Elsevier, pp 253-276.), reinforce the need of protection of these peculiar ecosystems.

Acknowledgements

This paper is part of the Ph.D. requirements of Mariana Sampaio Xavier for the Biodiversity and Evolutionary Biology Graduate Program at the Federal University of Rio de Janeiro. We are very grateful to CAPES for the doctoral grant given to MSX and to the program for granting PROAP aid for collections. This research was conducted in accordance with ICMBio Licenses 25689 and 26145.

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» http://www.ncbi.nim.nih.gov
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Author Contributions

MSX, LIW, and PCP conceptualized the study; LIW supervised laboratory analysis; MSX performed the laboratory analysis and curated the data; MSX and LIW analyzed the data; MSX, LIW‚ and PCP supervised the study and provided resources; MSX wrote the original draft of the manuscript; all authors participated in the revision and editing of the manuscript and approved the final version.

Edited by

Associate Editor:

Antonio Matteo Solé-Cava

Publication Dates

Publication in this collection
13 Oct 2023
Date of issue
2023

History

Received
27 Mar 2023
Accepted
14 July 2023

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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Locality	Coordinates	Collection date	Salinity (ppt)	Number of amphipods
Locality	Coordinates	Collection date	Salinity (ppt)	16S	COI
State of Alagoas
Roteiro lagoon, Barra de São Miguel	9º50’6”S; 35º55’19.2”W	August 27, 2021	0.2	1	4
Roteiro lagoon, Barra de São Miguel	9º50’6”S; 35º55’19.2”W	December 19, 2021	0.2	1	1
State of Rio de Janeiro
Lagamar outlet, Campos dos Goytacazes	22º3’35.1”S; 41º5’00.7”W	April 24, 2019	6.7	7	28
Paulista lagoon, Quissamã*	22°14’2.5”S; 41º32’40.4”W	April 1, 2014	0.6	10	23
Paulista lagoon, Quissamã*	22°14’2.5”S; 41º32’40.4”W	August 8, 2015	0.5	4	5
Carapebus lagoon, Carapebus*	22°14’11.9”S; 41º35’28.8”W	October 21, 2011	0.3	0	39
		November 1, 2013	0.6	0	4
		November 1, 2014	8.3	6	1
		August 11, 2015	9.3	9	28
		April 13, 2016	3.9	0	7
		April 24, 2019	4.5	9	41
Imboassica lagoon, Macaé	22º24’42.3”S; 41º49’48.5”W	March 7, 2016	0.3	3	36
Imboassica lagoon, Macaé	22º24’42.3”S; 41º49’48.5”W	July 2, 2018	0.5	3	19
State of São Paulo
Escuro River, Ubatuba	23º29’27”S; 45º05’50”W	December 19, 2020	2.1	2	0
Escuro River, Ubatuba	23º29’27”S; 45º05’50”W	February 12, 2022	0.6-3.4	2	0

Target gene	Primer sequence (5’-3’)	Expected size (bp)	Reference
COI	LCO1490: TAAACTTCAGGGTGACCAAAAAATCA	710	Folmer et al. (1994Folmer O, Black M, Hoeh W, Lutz R and 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.)
	HCO2198: GGTCAACAAATCATAAAGATATTGG	710
	QCOI-R1: TAGGTGCTGGAATAAAATAGGG	685	Weber, L.I. unpublished
	QCOI-F1: ACACTCTACCTTATTACCGGAT	655
	QCOI-R1: TAGGTGCTGGAATAAAATAGGG	655
	QCOI-F3: CGNATAGARCTTTTAGTCCC	485	Present study
	QCOI-R3: AGRGAGAGTAGAAGAAGTGT	485
	QCOI-F4: TGRGCAGGACTYCTRGGTAGATC	545
	QCOI-R5: ATRGCCCCTGCTAAKACRGG	545
16S	16sar: CGCCTGTTTATCAAAAACAT	515	Palumbi et al. (2002Palumbi SR, Martin AP, Romano S, McMillan WO, Stice L and Grabowski G (2002) The simple tool’s guide to PCR. 2nd edition. University of Hawaii, Honolulu, 45 p.)
	16sbr: CCGGTCTGAACTCAGATCACGT	515
	Q16s-F2: CGTACATAGTACCTGCCCAGTG	445	Present study
	Q16s-R3: GGATGAACAATCCCACTCTC	445	Present study

Population (N)	Lagamar	Paulista	Carapebus	Imboassica	Diversity Parameters
Population (N)	Lagamar	Paulista	Carapebus	Imboassica	NH	HD	ND
Lagamar (28)	***	0.00207	0.00198	0.00394	6	0.439	0.212 ± 0.154
Paulista* (28)	0.036	***	0.00175	0.00345	3	0.315	0.185 ± 0.140
Carapebus* (108)	0.049	0.000	***	0.00343	9	0.545	0.166 ± 0.126
Imboassica* (55)	0.231	0.163	0.238	***	10	0.705	0.376 ± 0.234

Population and Year (N)	Lagamar 2019	Paulista 2014/15	Carapebus 2011	Carapebus 2015	Carapebus 2019	Imboassica 2016	Imboassica 2018	Diversity parameters
Population and Year (N)	Lagamar 2019	Paulista 2014/15	Carapebus 2011	Carapebus 2015	Carapebus 2019	Imboassica 2016	Imboassica 2018	NH	HD	ND
Lagamar 2019 (28)	***	0.002	0.002	0.002	0.003	0.003	0.020	6	0.439	0.2115± 0.1536
Paulista 2014/15 (28)	0.036	***	0.001	0.001	0.002	0.003	0.019	3	0.315	0.1849± 0.1395
Carapebus 2011 (39)	0.027	0.014	***	0.001	0.002	0.003	0.019	2	0.157	0.0991 ± 0.0907
Carapebus 2015 (28)	0.009	0.024	0.000	***	0.002	0.003	0.020	4	0.221	0.097 ± 0.0904
Carapebus 2019 (41)	0.190	0.114	0.250	0.220	***	0.003	0.019	6	0.645	0.2024 ± 0.1471
Imboassica 2016 (36)	0.160	0.102	0.208	0.198	0.120	***	0.019	7	0.571	0.3466 ± 0.2215
Imboassica 2018 (19)	0.474	0.418	0.583	0.566	0.361	0.150	***	7	0.792	0.3543± 0.2339

Haplotypes	Population and Year (N)
	Carapebus lagoon			Imboassica lagoon
	2011 (39)	2015 (28)	2019 (41)	2016 (36)	2018 (19)
H1	0.820	0.741	0.317	0.697	0.157
H2	0	0	0.512	0	0
H3	0	0	0	0	0.474
H4	0.103	0.074	0.024	0	0
H5	0	0.037	0.049	0	0
H6	0	0	0	0.152	0.157
H7	0.077	0.037	0.049	0	0
H9	0	0	0.049	0	0
H11	0	0	0	0.030	0.053
H12	0	0	0	0.061	0
H15	0	0.037	0	0	0
H16	0	0.037	0	0	0
H17	0	0	0	0	0.053
H19	0	0.037	0	0	0
H25	0	0	0	0	0.053
H30	0	0	0	0.030	0
H31	0	0	0	0.030	0
H32	0	0	0	0	0.053

Brasil

Brasil

Unstable environment of coastal lagoons drives genetic variation in the amphipod Quadrivisio lutzi

Abstract

Introduction

Material and Methods

Amphipod sampling

DNA extraction, amplification, and sequencing

Data analysis

Results

Divergence of amphipod populations along the Brazilian coast

Population structure of the amphipod Q. lutzi at the north of the State of Rio de Janeiro (Rio de Janeiro population)

Genetic changes along time in the Rio de Janeiro population of Q. lutzi

Discussion

Divergence of amphipod populations along the Brazilian coast

Genetic structure of the Rio de Janeiro amphipod subpopulations

Temporal genetic variation in Carapebus and Imboassica subpopulations

Acknowledgements

References

Internet Resources

Author Contributions

Edited by

Associate Editor:

Publication Dates

History

**Population structure of the amphipod Q. lutzi at the north of the State of Rio de Janeiro (Rio de Janeiro population)**