Development of EPIC-PCR Markers for <i>Lutjanus purpureus</i> (Lutjanidae-Perciformes) and their Potential Applicability in Population Analyses

SILVA, RAIMUNDO DA; SILVA, DANILLO; VENEZA, IVANA; SAMPAIO, IRACILDA; SCHNEIDER, HORACIO; GOMES, GRAZIELLE

doi:10.1590/0001-3765201720150476

ABSTRACT

In the present study, a novel set of eight EPIC primers were developed for Lutjanus purpureus and assayed in five other marine teleosts including three lutjanids, one scianid and one anablepid. Most of the genomic regions used in this study presented genetic diversity indexes equal or greater than the intragenic regions commonly used in population genetics studies. Moreover, six out of eight markers showed cross-amplification with other taxa. Thus, the primers described here may be used to elucidate questions at the intraspecific level for a large number of taxa.

Key words:
EPIC-PCR; intron; Lutjanus; Southern Red Snapper

INTRODUCTION

Advances in DNA sequencing technology have provided access to information of a large number of loci in non-model organisms, and have promoted great significant advances in population genetics and related fields. On the other hand, approaches that employ a limited number of independent and variable genomic regions are useful for describing evolutionary processes that act on a given taxonomic group (Bowen et al. 2014BOWEN BW ET AL. 2014. Phylogeography unplugged: comparative surveys in the genomic era. Bull Mar Sci 90: 13-46.).

Microsatellites are the most commonly used molecular markers in intraspecific studies, and for population-level analyses because they have a high level of polymorphism (Zhang and Hewitt 2003ZHANG DX AND HEWITT GM. 2003. Nuclear DNA analyses in genetic studies of populations: practice, problems and prospects. Mol Ecol 12: 563-584.) and generally reflect population dynamics that have occurred in recent periods (see Morin et al. 2004MORIN PA, LUIKART G, WAYNE RK and THE SNP WORKSHOP GROUP. 2004. SNPs in ecology, evolution and conservation. Trends Ecol Evol 19: 208-216. , Guichoux et al. 2011GUICHOUX E ET AL. 2011. Current trends in microsatellite genotyping. Mol Ecol Resour 11: 591-611. ).

Another class of markers that has been widely used at the population level is the single-copy nuclear DNA sequences (e.g., introns). Introns are untranslated intragenic regions of the nuclear genome that may include polymorphism capable of revealing information regarding the population structure of taxa. Thus, introns are suitable for use in population genetics and phylogeography studies (Zhang and Hewitt 2003ZHANG DX AND HEWITT GM. 2003. Nuclear DNA analyses in genetic studies of populations: practice, problems and prospects. Mol Ecol 12: 563-584.).

Moreover, it has been postulated that DNA sequence-based markers provide more accurate descriptions of historical demographic processes compared with those obtained using microsatellites (Brumfield et al. 2003BRUMFIELD RT, BEERLI P, NICKERSON DA AND EDWARDS SV. 2003. The utility of single nucleotide polymorphisms in inferences of population history. Trends Eco Evol 18: 249-256. ). Thus, the combination of microsatellite markers and introns is of great importance for understanding the evolutionary history of species in different historical periods (Zhang and Hewitt 2003ZHANG DX AND HEWITT GM. 2003. Nuclear DNA analyses in genetic studies of populations: practice, problems and prospects. Mol Ecol 12: 563-584.).

In the present study, we used the exon-primed intron-crossing (EPIC-PCR) (Lessa 1992LESSA E. 1992. Rapid surveying of DNA sequence variation in natural populations. Mol Bio Evol 9: 323-330.) technique to develop a set of novel nuclear markers for Lutjanus purpureus that are amplifiable across the Lutjanidae family and other marine teleosts. EPIC is based on the design of primers anchored in the adjacent exons, in order to amplify and sequence the intron (Li et al. 2010LI C, RIETHOVEN J-JM AND MA L. 2010. Exon-primed intron-crossing (EPIC) markers for non-model teleost fishes. BMC Evol Biol 10: 90.). Given the high rate of substitution for the majority of introns, EPIC-PCR has been used to investigate patterns of intraspecific genetic variation in many taxa, including teleosts (Gaither et al. 2010GAITHER MR, TOONEN RJ, ROBERTSON DR, PLANES S AND BOWEN BW. 2010. Genetic evaluation of marine biogeographical barriers: perspectives from two widespread Indo-Pacific snappers (Lutjanus kasmira and Lutjanus fulvus). J Biogeogr 37: 133-147. , 2011, Li et al. 2010, Silva-Oliveira et al. 2012, Chow and Yanagimoto 2016CHOW S AND YANAGIMOTO T. 2016. Universal PCR primers for ribosomal protein gene introns of fish. Int Aquat Res 8: 29-36.). Lutjanidae and several other groups of marine teleosts are organisms that have wide geographic distributions, which make them good models for phylogeographic and population genetic analyses. In addition, isolation and characterization of microsatellite markers has frequently been performed in Lutjanidae (Pinsky and Palumbi 2014PINSKY ML AND PALUMBI SR. 2014. Meta-analysis reveals lower genetic diversity in overfished populations. Mol Ecol 23: 29-39. ). However, a limited number of population analyses have been conducted using introns (i.e., Gaither et al. 2010). Moreover, snappers are important fishery resources; therefore, studies aimed at their genetic characterization are fundamental for delimitation and management of stocks.

MATERIALS AND METHODS

Primers were developed through the EPIC-PCR technique, based on sequences available in the GenBank (http://www.ncbi.nlm.nih.gov/genbank/). We made a manual search in GenBank for nuclear sequences of Lutjanidae and model species of closely taxa in order to find potential regions for primers design using as main criteria of choice the information about the position of introns and exons (Table I), with intron fragments ranging from 200-1000 bp. The primers were designed using the software FastPCR (Kalendar et al. 2009KALENDAR R, LEE D AND SCHULMAN AH. 2009. FastPCR software for PCR primer and probe design and repeat search. Genes Genomes Genomics 3: 1-14. ) using the default parameters.

The primers developed in the present study (Table I) were initially used on specimens of L. purpureus collected along the coast of the state of Pará (North of Brazil), to characterize the levels of polymorphism. For North coast of Brazil, there is a single stock, with elevated levels of variation (Sousa-Júnior et al. 2002, Gomes et al. 2008GOMES G, SCHNEIDER H, VALLINOTO M, SANTOS S, ORTI G AND SAMPAIO I. 2008. Can Lutjanus purpureus (South red snapper) be “legally” considered a red snapper (Lutjanus campechanus)? Genet Mol Biol 31: 372-376., 2012). With the aim to demonstrate that these markers could be used in different groups and phylogenetically distant taxa, cross-amplification was tested in five other marine teleosts (two indvidual per species) including other lutjanids (Lutjanus synagris, Rhomboplites aurorubens, Ocyurus chrysurus), a Sciaenidae (Cynoscion jamaicensis), and Anablepidae (Anableps anableps). All individuals used in the present analysis were purchased in municipal markets of the north coast of Brazil, marketed dead.

The DNA was isolated using the phenol-chloroform protocol (Sambrook et al. 1989SAMBROOK J, FRITSCH EF AND MANIATIS T. 1989. Molecular cloning: a laboratory manual. 2nd ed., New York: Cold Spring Harbor Lab Press, 1626 p. ). The amplicons were amplified by PCR using the primers described in Table I. We also amplified six genomic regions previously used in lutjanids (Table II) for comparisons purpose. The PCR reactions were standardized to a final volume of 15 μL, which contained 200 µM of dNTPs, 1 x of buffer (200 mM Tris-HCl- pH 8.0, 500 mM KCl) , 3 mM of MgCl₂, 5 mM of each primer, approximately 50 ng of DNA template, 0.5 U Taq Polymerase and water up to the reaction final volume. The amplification conditions were: 95°C for 3 minutes followed by 35 cycles at 95°C for 35 seconds, 45 seconds (see Table I for Annealing), 80 seconds at 72°C, and a final cycle of 3 minutes at 72°C. Positive PCRs were sequenced using the dideoxy method (Sanger et al. 1977SANGER F, NICKLEN S AND COULSON AR. 1977. DNA sequencing with chain-terminating inhibitors. Proc Nat Acad Sci USA 74: 5463-5467. ) and the ABI 3500 XL automatic sequencer. All DNA sequences are available in Genbank under the accession codes KT869380 to KT869495 and in Figshare: (http://dx.doi.org/10.6084/m9.figshare.1564736; http://dx.doi.org/10.6084/m9.figshare.1564735).

The sequences were edited with the BioEdit software (Hall 1999HALL TA. 1999. BioEdit: A user-friendly biological sequence alignment editor and analysis program for Windows 95/98/NT. Nucleic Acids Symp Ser 41: 95-98. ), and aligned using the parameter default of ClustalW (Thompson et al. 1994THOMPSON 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(22): 4673-4680.) available in BioEdit. Heterozygous insertion and deletion events were resolved in the Mixed Sequences Reader (Chang et al. 2012CHANG CT ET AL. 2012. Mixed sequence reader: a program for analyzing DNA sequences with heterozygous base calling. Sci World J 2012: 1-12.). The gametic phase was reconstructed with PHASE (Stephens et al. 2001STEPHENS M, SMITH NJ AND DONNELLY P. 2001. A new statistical method for haplotype reconstruction from population data. Am J Hum Genet 68: 978-989. ), implemented in the DNAsp v. 5.10. (Librado and Rozas 2009LIBRADO P AND ROZAS J. 2009. DnaSP v5: a software for comprehensive analysis of DNA polymorphism data. Bioinformatics 25: 1451-1452.), based on 1,000 burn-in iterations, 1,000 main iterations, thinning interval of 1 and using a threshold of 0.6. In certain cases, haplotypes returning with a probability lower than 0.6 were resolved by the Clark’s method (Clark 1990CLARK AG. 1990. Inference of haplotypes from PCR-amplified samples of diploid populations. Mol Biol Evol 7: 111-122.). In order to assess the level of polymorphism of the markers, the number of polymorphic sites, haplotype diversity (h) and nucleotide diversity (π) were estimated using DNAsp software (Librado and Rozas 2009).

RESULTS AND DISCUSSION

In the present study, a set of eight EPIC-PCR markers (Table I) for L. purpureus ranging from 172 to 637 bp were developed, amplified and sequenced for L. purpureus (Table II).The success rate of positive PCR amplification remained near 90% for all loci, except for Interferon - Intron 2, and IGF 1 (≈ 70%). Almost all of these markers (except Interferon - Intron 2), presented polymorphism (Table II). For the polymorphic markers, the number of segregating sites ranged between 2 (LWSCO 1) and 12 (Insulin-like Growth Factor - Intron 1). The genetic diversity values ranged from 0.090 (LWSCO 1) to 0.94 (Delta 6 - Intron 10) for h values and from 0.053% (LWSCO 1) to 1.053% (Try 1) for π values.

Six out of eight of the EPIC-PCR markers developed here have been successfully amplified in other species (Table II). Thus, the markers reported here are useful for population genetics and phylogeographic studies at a vast taxonomic level.

All the markers showed genetic variation levels similar to or higher than intragenic regions previously used in other marine teleosts, including lutjanids (e.g., Gaither et al. 2010GAITHER MR, TOONEN RJ, ROBERTSON DR, PLANES S AND BOWEN BW. 2010. Genetic evaluation of marine biogeographical barriers: perspectives from two widespread Indo-Pacific snappers (Lutjanus kasmira and Lutjanus fulvus). J Biogeogr 37: 133-147. , 2011, da Silva et al. 2015) (Table II). In certain cases, the genetic variation values were comparable to the variation indicated by mitochondrial regions. For example, Delta 10 showed a genetic diversity value (h) of 0.94, which was similar to the values commonly presented by hypervariable regions of mitochondrial DNA. Even for the other markers (except Int 2, LWSCO 1 h = 0.09), the levels of observed genetic variation (h ≥ 0.75; Table II) were comparable or higher than the polymorphism presented by mitochondrial genome segments commonly used in intraspecific studies, such Cytochrome B and ND4.

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TABLE I
Description for the markers developed in the present study.

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TABLE II
Statistics for the markers analyzed in the present study (for L. purpureus), and the results of cross-amplifications.

In addition, with the development of coalescent methodologies used for estimation of evolutionary parameters of taxa, the use of multiple genomic regions has been growing in popularity (Li et al. 2010LI C, RIETHOVEN J-JM AND MA L. 2010. Exon-primed intron-crossing (EPIC) markers for non-model teleost fishes. BMC Evol Biol 10: 90.). In this way the use of nuclear sequences such as variable introns, has become very common in the study of shallow evolutionary process including species delimitation, population analysis and population dynamics (Li et al. 2010). Thus, the markers described in the present study may provide robust information to elucidate the evolutionary processes that act on marine fish populations and help to identify and accurately delimit fish stocks.

REFERENCES

AREVALO E, DAVIS SK AND SITES JW. 1994. Mitochondrial DNA Sequence Divergence and Phylogenetic Relationships among Eight Chromosome Races of the Sceloporus grammicus Complex (Phrynosomatidae) in Central. Syst Biol 43: 387-418.
BIELAWSKI JP AND GOLD JR. 2002. Mutation patterns of mitochondrial H- and L-strand DNA in closely related Cyprinid fishes. Genetics 161: 1589-1597.
BOWEN BW ET AL. 2014. Phylogeography unplugged: comparative surveys in the genomic era. Bull Mar Sci 90: 13-46.
BRUMFIELD RT, BEERLI P, NICKERSON DA AND EDWARDS SV. 2003. The utility of single nucleotide polymorphisms in inferences of population history. Trends Eco Evol 18: 249-256.
CHANG CT ET AL. 2012. Mixed sequence reader: a program for analyzing DNA sequences with heterozygous base calling. Sci World J 2012: 1-12.
CHOW S AND YANAGIMOTO T. 2016. Universal PCR primers for ribosomal protein gene introns of fish. Int Aquat Res 8: 29-36.
CLARK AG. 1990. Inference of haplotypes from PCR-amplified samples of diploid populations. Mol Biol Evol 7: 111-122.
DA SILVA R, VENEZA I, SAMPAIO I, ARARIPE J, SCHNEIDER H AND GOMES G. 2015. High levels of genetic connectivity among populations of yellowtail snapper, Ocyurus chrysurus (Lutjanidae - Perciformes), in the Western South Atlantic revealed through multilocus analysis. PLoS ONE. 10(3): 1-19
GAITHER MR, BOWEN BW, BORDENAVE T-R, ROCHA LA, NEWMAN SJ, GOMEZ JA, VAN HERWERDEN L AND CRAIG MT. 2011. Phylogeography of the reef fish Cephalopholis argus (Epinephelidae) indicates Pleistocene isolation across the Indo-Pacific Barrier with contemporary overlap in The Coral Triangle. BMC Evol Biol 11: 1-15.
GAITHER MR, TOONEN RJ, ROBERTSON DR, PLANES S AND BOWEN BW. 2010. Genetic evaluation of marine biogeographical barriers: perspectives from two widespread Indo-Pacific snappers (Lutjanus kasmira and Lutjanus fulvus). J Biogeogr 37: 133-147.
GOMES G, SAMPAIO I AND SCHNEIDER H. 2012. Population structure of Lutjanus purpureus (Lutjanidae - Perciformes) on the Brazilian coast: further existence evidence of a single species of red snapper in the western Atlantic. An Acad Bras Cienc 84: 979-999.
GOMES G, SCHNEIDER H, VALLINOTO M, SANTOS S, ORTI G AND SAMPAIO I. 2008. Can Lutjanus purpureus (South red snapper) be “legally” considered a red snapper (Lutjanus campechanus)? Genet Mol Biol 31: 372-376.
GUICHOUX E ET AL. 2011. Current trends in microsatellite genotyping. Mol Ecol Resour 11: 591-611.
HALL TA. 1999. BioEdit: A user-friendly biological sequence alignment editor and analysis program for Windows 95/98/NT. Nucleic Acids Symp Ser 41: 95-98.
HASSAN M, LEMAIRE C, FAUVELOT C AND BONHOMME F. 2002. Seventeen new exon-primed intron-crossing polymerase chain reaction amplifiable introns in fish. Mol Ecol Notes 2: 334-340.
JARMAN SN, WARD RD AND ELLIOTT NG. 2002. Oligonucleotide primers for PCR amplification of Coelomate introns. Mar Biotechnol 4: 347-355.
KALENDAR R, LEE D AND SCHULMAN AH. 2009. FastPCR software for PCR primer and probe design and repeat search. Genes Genomes Genomics 3: 1-14.
LESSA E. 1992. Rapid surveying of DNA sequence variation in natural populations. Mol Bio Evol 9: 323-330.
LI C, RIETHOVEN J-JM AND MA L. 2010. Exon-primed intron-crossing (EPIC) markers for non-model teleost fishes. BMC Evol Biol 10: 90.
LIBRADO P AND ROZAS J. 2009. DnaSP v5: a software for comprehensive analysis of DNA polymorphism data. Bioinformatics 25: 1451-1452.
MORIN PA, LUIKART G, WAYNE RK and THE SNP WORKSHOP GROUP. 2004. SNPs in ecology, evolution and conservation. Trends Ecol Evol 19: 208-216.
PINSKY ML AND PALUMBI SR. 2014. Meta-analysis reveals lower genetic diversity in overfished populations. Mol Ecol 23: 29-39.
SAMBROOK J, FRITSCH EF AND MANIATIS T. 1989. Molecular cloning: a laboratory manual. 2nd ed., New York: Cold Spring Harbor Lab Press, 1626 p.
SANGER F, NICKLEN S AND COULSON AR. 1977. DNA sequencing with chain-terminating inhibitors. Proc Nat Acad Sci USA 74: 5463-5467.
SEVILLA RG ET AL. 2007. Primers and polymerase chain reaction conditions for DNA barcoding teleost fish based on the mitochondrial cytochrome b and nuclear rhodopsin genes. Mol Ecol Notes 7: 730-734.
SILVA-OLIVEIRA GC, SILVA ABC, OLIVEIRA Y, NUNES ZP, TORRES RA, SAMPAIO I AND VALLINOTO M. 2012. New nuclear primers for molecular studies of Epinephelidae fishes. Conserv Genet Resour 5: 165-168.
SOUSA JÚNIOR JP, VIANA MSR AND SAKER-SAMPAIO S. 2002. Diversificação intra-específica do pargo, Lutjanus purpureus Poey, no Norte e Nordeste do Brasil. I - Caracteres morfométricos. Acta Scient 24: 973-980.
STEPHENS M, SMITH NJ AND DONNELLY P. 2001. A new statistical method for haplotype reconstruction from population data. Am J Hum Genet 68: 978-989.
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(22): 4673-4680.
ZHANG DX AND HEWITT GM. 2003. Nuclear DNA analyses in genetic studies of populations: practice, problems and prospects. Mol Ecol 12: 563-584.

Publication Dates

Publication in this collection
29 June 2017
Date of issue
2017

History

Received
09 July 2015
Accepted
25 May 2016

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

[1] AREVALO E, DAVIS SK AND SITES JW. 1994. Mitochondrial DNA Sequence Divergence and Phylogenetic Relationships among Eight Chromosome Races of the Sceloporus grammicus Complex (Phrynosomatidae) in Central. Syst Biol 43: 387-418.

[2] BIELAWSKI JP AND GOLD JR. 2002. Mutation patterns of mitochondrial H- and L-strand DNA in closely related Cyprinid fishes. Genetics 161: 1589-1597.

[3] BOWEN BW ET AL. 2014. Phylogeography unplugged: comparative surveys in the genomic era. Bull Mar Sci 90: 13-46.

[4] BRUMFIELD RT, BEERLI P, NICKERSON DA AND EDWARDS SV. 2003. The utility of single nucleotide polymorphisms in inferences of population history. Trends Eco Evol 18: 249-256.

[5] CHANG CT ET AL. 2012. Mixed sequence reader: a program for analyzing DNA sequences with heterozygous base calling. Sci World J 2012: 1-12.

[6] CHOW S AND YANAGIMOTO T. 2016. Universal PCR primers for ribosomal protein gene introns of fish. Int Aquat Res 8: 29-36.

[7] CLARK AG. 1990. Inference of haplotypes from PCR-amplified samples of diploid populations. Mol Biol Evol 7: 111-122.

[8] DA SILVA R, VENEZA I, SAMPAIO I, ARARIPE J, SCHNEIDER H AND GOMES G. 2015. High levels of genetic connectivity among populations of yellowtail snapper, Ocyurus chrysurus (Lutjanidae - Perciformes), in the Western South Atlantic revealed through multilocus analysis. PLoS ONE. 10(3): 1-19

[9] GAITHER MR, BOWEN BW, BORDENAVE T-R, ROCHA LA, NEWMAN SJ, GOMEZ JA, VAN HERWERDEN L AND CRAIG MT. 2011. Phylogeography of the reef fish Cephalopholis argus (Epinephelidae) indicates Pleistocene isolation across the Indo-Pacific Barrier with contemporary overlap in The Coral Triangle. BMC Evol Biol 11: 1-15.

[10] GAITHER MR, TOONEN RJ, ROBERTSON DR, PLANES S AND BOWEN BW. 2010. Genetic evaluation of marine biogeographical barriers: perspectives from two widespread Indo-Pacific snappers (Lutjanus kasmira and Lutjanus fulvus). J Biogeogr 37: 133-147.

[11] GOMES G, SAMPAIO I AND SCHNEIDER H. 2012. Population structure of Lutjanus purpureus (Lutjanidae - Perciformes) on the Brazilian coast: further existence evidence of a single species of red snapper in the western Atlantic. An Acad Bras Cienc 84: 979-999.

[12] GOMES G, SCHNEIDER H, VALLINOTO M, SANTOS S, ORTI G AND SAMPAIO I. 2008. Can Lutjanus purpureus (South red snapper) be “legally” considered a red snapper (Lutjanus campechanus)? Genet Mol Biol 31: 372-376.

[13] GUICHOUX E ET AL. 2011. Current trends in microsatellite genotyping. Mol Ecol Resour 11: 591-611.

[14] HALL TA. 1999. BioEdit: A user-friendly biological sequence alignment editor and analysis program for Windows 95/98/NT. Nucleic Acids Symp Ser 41: 95-98.

[15] HASSAN M, LEMAIRE C, FAUVELOT C AND BONHOMME F. 2002. Seventeen new exon-primed intron-crossing polymerase chain reaction amplifiable introns in fish. Mol Ecol Notes 2: 334-340.

[16] JARMAN SN, WARD RD AND ELLIOTT NG. 2002. Oligonucleotide primers for PCR amplification of Coelomate introns. Mar Biotechnol 4: 347-355.

[17] KALENDAR R, LEE D AND SCHULMAN AH. 2009. FastPCR software for PCR primer and probe design and repeat search. Genes Genomes Genomics 3: 1-14.

[18] LESSA E. 1992. Rapid surveying of DNA sequence variation in natural populations. Mol Bio Evol 9: 323-330.

[19] LI C, RIETHOVEN J-JM AND MA L. 2010. Exon-primed intron-crossing (EPIC) markers for non-model teleost fishes. BMC Evol Biol 10: 90.

[20] LIBRADO P AND ROZAS J. 2009. DnaSP v5: a software for comprehensive analysis of DNA polymorphism data. Bioinformatics 25: 1451-1452.

[21] MORIN PA, LUIKART G, WAYNE RK and THE SNP WORKSHOP GROUP. 2004. SNPs in ecology, evolution and conservation. Trends Ecol Evol 19: 208-216.

[22] PINSKY ML AND PALUMBI SR. 2014. Meta-analysis reveals lower genetic diversity in overfished populations. Mol Ecol 23: 29-39.

[23] SAMBROOK J, FRITSCH EF AND MANIATIS T. 1989. Molecular cloning: a laboratory manual. 2nd ed., New York: Cold Spring Harbor Lab Press, 1626 p.

[24] SANGER F, NICKLEN S AND COULSON AR. 1977. DNA sequencing with chain-terminating inhibitors. Proc Nat Acad Sci USA 74: 5463-5467.

[25] SEVILLA RG ET AL. 2007. Primers and polymerase chain reaction conditions for DNA barcoding teleost fish based on the mitochondrial cytochrome b and nuclear rhodopsin genes. Mol Ecol Notes 7: 730-734.

[26] SILVA-OLIVEIRA GC, SILVA ABC, OLIVEIRA Y, NUNES ZP, TORRES RA, SAMPAIO I AND VALLINOTO M. 2012. New nuclear primers for molecular studies of Epinephelidae fishes. Conserv Genet Resour 5: 165-168.

[27] SOUSA JÚNIOR JP, VIANA MSR AND SAKER-SAMPAIO S. 2002. Diversificação intra-específica do pargo, Lutjanus purpureus Poey, no Norte e Nordeste do Brasil. I - Caracteres morfométricos. Acta Scient 24: 973-980.

[28] STEPHENS M, SMITH NJ AND DONNELLY P. 2001. A new statistical method for haplotype reconstruction from population data. Am J Hum Genet 68: 978-989.

[29] 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(22): 4673-4680.

[30] ZHANG DX AND HEWITT GM. 2003. Nuclear DNA analyses in genetic studies of populations: practice, problems and prospects. Mol Ecol 12: 563-584.

Locus (Abbreviation)	Primers	Sequence 5’-3’	Annealing (◦C)	GenBank Access Code
Delta 6 desaturase - Intron 8 (Delta 8)	Delt6 F8	TTACTACCTTCGCTACCTGTGCT	64	Sparus aurata (AF525692)
	Delt6 R8	AGTCACCCACACAAACCAGTKAC
Delta 6 desaturase- Intron 10 (Delta 10)	Delt6 F10	GTTCAGCGGACACCTCAACT	50	Sparus aurata (AF525692)
	Delt6 F10	CACACAGTGCGTGGACAAG
Myostatin - Intron1 (Myo 1)	Myo 1F	ATGAGCATGCCATCACAGAG	64	Lates calcarifer (EF672685)
	Myo 1R	ATGCGATTGGCTTGAAACTT		Lutjanus russellii (JQ068866)
Myostatin - Intron2 (Myo 2)	Myo 2F	GCATCGAGATTAACGCCTTC	64	Lates calcarifer (EF672685)
	Myo 2R	GGCCCTCTGAGATCTTCACC		Lutjanus russellii (JQ068866)
Trypsin - Intron1 (Try 1)	Try 2F	CCTGATCTCCAGCACCTGGGTK	60	Lutjanus fulvus (AB738891)
	Try 2R	GATGTCATTGTYCAGGTTGCSGCT
LWSCO - Intron1 (LWSCO 1)	LWSCO 1F	GCTGATCTGGGAGAGACAGTTT	60	Lutjanus johnii (FJ824756)
	LWSCO 1R	CATTTGGCATCAAACTTGACAT
Insulin-like Growth Factor (IGF 1)	FC-F1	AGCGCTCTTTCCTTTCAGTG	59	Dicentrarchus labrax (GQ924783)
	FC-R1	CRCACAGCAGTAGTGAGAGG
Interferon - Intron2 (Int 2)	Int 2F	GTACAGMCAGGCGTCCAAAGCAT	64	Dicentrarchus labrax (AM946400)
	Int 2R	GTTCTCCTCCCATGATGCMGAG		Sparus aurata (FM882244)

Locus	N	bp	Nh	S	h ± sd	π (in %) ± sd	Indel	Results of cross-amplification
¹Delta 8	20	571	11	11	0.871 ± 0.028	0.557± 0.039	1	Positive: L. synagris, R. aurorubens, O. chrysurus, C. jamaicensis
¹Delta10	20	535	18	13	0.94 ± 0.018	0.7 ± 0.058	3	Positive: L. synagris, R. aurorubens, A. anableps
¹Myo1	22	363	13	10	0.857 ± 0.033	0.876 ± 0.049	3	Positive: L. synagris, R. aurorubens, O. chrysurus, C. jamaicensis, A. anableps
¹Myo2	22	637	10	8	0.782 ± 0.042	0.272 ± 0.028	1	Positive: L. synagris, R. aurorubens, O. chrysurus,C. jamaicensis, A. anableps
¹Try1	22	259	9	7	0.755 ± 0.049	1.053 ± 0.046	2	Positive: L. synagris, R. aurorubens, O. chrysurus,C. jamaicensis, A. anableps
¹LWSCO1	22	172	3	2	0.090 ± 0.059	0.053 ± 0.035	0	Positive: L. synagris, R. aurorubens, O. chrysurus,C. jamaicensis, A. anableps
¹FC1	20	468	14	12	0.849± 0.039	0.465± 0.050	2	Negative
¹Int2	22	530	1	0	0	0	0	Negative
²ANT 1	19	290	3	2	0.104±0.067	0.036±0.024	0	Not aplicable
²Gh 5	22	146	3	3	0.369±0.075	0.308±0.085	0	Not aplicable
²Cyt B	21	779	10	11	0.862±0.057	0.301±0.038	0	Not aplicable
²ND4	21	515	10	13	0.776±0.093	0.322±0.067	0	Not aplicable

Brasil