Genetic connectivity of lionfish (Pterois volitans) in marine protected areas of the Gulf of Mexico and Caribbean Sea
Lionfish (Pterois volitans) have rapidly invaded the tropical Atlantic and spread across the wider Caribbean in a relatively short period of time. Because of its high invasion capacity, we used it as a model to identify the connectivity among nine marine protected areas (MPAs) situated in four count...
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| Vydané v: | Ecology and evolution Ročník 10; číslo 9; s. 3844 - 3855 |
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| Hlavní autori: | , , , , , , , , , , , , , |
| Médium: | Journal Article |
| Jazyk: | English |
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England
John Wiley & Sons, Inc
01.05.2020
Wiley Open Access John Wiley and Sons Inc Wiley |
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| ISSN: | 2045-7758, 2045-7758 |
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| Abstract | Lionfish (Pterois volitans) have rapidly invaded the tropical Atlantic and spread across the wider Caribbean in a relatively short period of time. Because of its high invasion capacity, we used it as a model to identify the connectivity among nine marine protected areas (MPAs) situated in four countries in the Gulf of Mexico and the Caribbean Sea. This study provides evidence of local genetic differentiation of P. volitans in the Gulf of Mexico and the Caribbean Sea. A total of 475 lionfish samples were characterized with 12 microsatellites, with 6–20 alleles per locus. Departures from Hardy–Weinberg equilibrium (HWE) were found in 10 of the 12 loci, all caused by heterozygous excess. Moderate genetic differentiation was observed between Chiriviche, Venezuela and Xcalak, México localities (FST = 0.012), and between the Los Roques and the Veracruz (FST = 0.074) sites. STRUCTURE analysis found that four genetic entities best fit our data. A unique genetic group in the Gulf of Mexico may imply that the lionfish invasion unfolded both in a counterclockwise manner in the Gulf of Mexico. In spite of the notable dispersion of P. volitans, our results show some genetic structure, as do other noninvasive Caribbean fish species, suggesting that the connectivity in some MPAs analyzed in the Caribbean is limited and caused by only a few source individuals with subsequent genetic drift leading to local genetic differentiation. This indicates that P. volitans dispersion could be caused by mesoscale phenomena, which produce stochastic connectivity pulses. Due to the isolation of some MPAs from others, these findings may hold a promise for local short‐term control of by means of intensive fishing, even in MPAs, and may have regional long‐term effects.
Our findings demonstrate that there is genetic differentiation at local and regional scales.We suggest that the colonization of each geographic area has been temporary pulses, probably caused by mesoscale phenomena, and intensified with the presence of self‐recruitment. The genetic diversity of Pterois volitans in the Gulf and the Caribbean showed that the number of organisms that originated the invasion was much higher than the one mentioned in the literature. |
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| AbstractList | Lionfish (Pterois volitans) have rapidly invaded the tropical Atlantic and spread across the wider Caribbean in a relatively short period of time. Because of its high invasion capacity, we used it as a model to identify the connectivity among nine marine protected areas (MPAs) situated in four countries in the Gulf of Mexico and the Caribbean Sea. This study provides evidence of local genetic differentiation of P. volitans in the Gulf of Mexico and the Caribbean Sea. A total of 475 lionfish samples were characterized with 12 microsatellites, with 6–20 alleles per locus. Departures from Hardy–Weinberg equilibrium (HWE) were found in 10 of the 12 loci, all caused by heterozygous excess. Moderate genetic differentiation was observed between Chiriviche, Venezuela and Xcalak, México localities (FST = 0.012), and between the Los Roques and the Veracruz (FST = 0.074) sites. STRUCTURE analysis found that four genetic entities best fit our data. A unique genetic group in the Gulf of Mexico may imply that the lionfish invasion unfolded both in a counterclockwise manner in the Gulf of Mexico. In spite of the notable dispersion of P. volitans, our results show some genetic structure, as do other noninvasive Caribbean fish species, suggesting that the connectivity in some MPAs analyzed in the Caribbean is limited and caused by only a few source individuals with subsequent genetic drift leading to local genetic differentiation. This indicates that P. volitans dispersion could be caused by mesoscale phenomena, which produce stochastic connectivity pulses. Due to the isolation of some MPAs from others, these findings may hold a promise for local short‐term control of by means of intensive fishing, even in MPAs, and may have regional long‐term effects. Lionfish ( Pterois volitans ) have rapidly invaded the tropical Atlantic and spread across the wider Caribbean in a relatively short period of time. Because of its high invasion capacity, we used it as a model to identify the connectivity among nine marine protected areas (MPAs) situated in four countries in the Gulf of Mexico and the Caribbean Sea. This study provides evidence of local genetic differentiation of P. volitans in the Gulf of Mexico and the Caribbean Sea. A total of 475 lionfish samples were characterized with 12 microsatellites, with 6–20 alleles per locus. Departures from Hardy–Weinberg equilibrium (HWE) were found in 10 of the 12 loci, all caused by heterozygous excess. Moderate genetic differentiation was observed between Chiriviche, Venezuela and Xcalak, México localities ( F ST = 0.012), and between the Los Roques and the Veracruz ( F ST = 0.074) sites. STRUCTURE analysis found that four genetic entities best fit our data. A unique genetic group in the Gulf of Mexico may imply that the lionfish invasion unfolded both in a counterclockwise manner in the Gulf of Mexico. In spite of the notable dispersion of P. volitans , our results show some genetic structure, as do other noninvasive Caribbean fish species, suggesting that the connectivity in some MPAs analyzed in the Caribbean is limited and caused by only a few source individuals with subsequent genetic drift leading to local genetic differentiation. This indicates that P. volitans dispersion could be caused by mesoscale phenomena, which produce stochastic connectivity pulses. Due to the isolation of some MPAs from others, these findings may hold a promise for local short‐term control of by means of intensive fishing, even in MPAs, and may have regional long‐term effects. Lionfish ( ) have rapidly invaded the tropical Atlantic and spread across the wider Caribbean in a relatively short period of time. Because of its high invasion capacity, we used it as a model to identify the connectivity among nine marine protected areas (MPAs) situated in four countries in the Gulf of Mexico and the Caribbean Sea. This study provides evidence of local genetic differentiation of in the Gulf of Mexico and the Caribbean Sea. A total of 475 lionfish samples were characterized with 12 microsatellites, with 6-20 alleles per locus. Departures from Hardy-Weinberg equilibrium (HWE) were found in 10 of the 12 loci, all caused by heterozygous excess. Moderate genetic differentiation was observed between Chiriviche, Venezuela and Xcalak, México localities ( = 0.012), and between the Los Roques and the Veracruz ( = 0.074) sites. STRUCTURE analysis found that four genetic entities best fit our data. A unique genetic group in the Gulf of Mexico may imply that the lionfish invasion unfolded both in a counterclockwise manner in the Gulf of Mexico. In spite of the notable dispersion of , our results show some genetic structure, as do other noninvasive Caribbean fish species, suggesting that the connectivity in some MPAs analyzed in the Caribbean is limited and caused by only a few source individuals with subsequent genetic drift leading to local genetic differentiation. This indicates that dispersion could be caused by mesoscale phenomena, which produce stochastic connectivity pulses. Due to the isolation of some MPAs from others, these findings may hold a promise for local short-term control of by means of intensive fishing, even in MPAs, and may have regional long-term effects. Lionfish (Pterois volitans) have rapidly invaded the tropical Atlantic and spread across the wider Caribbean in a relatively short period of time. Because of its high invasion capacity, we used it as a model to identify the connectivity among nine marine protected areas (MPAs) situated in four countries in the Gulf of Mexico and the Caribbean Sea. This study provides evidence of local genetic differentiation of P. volitans in the Gulf of Mexico and the Caribbean Sea. A total of 475 lionfish samples were characterized with 12 microsatellites, with 6-20 alleles per locus. Departures from Hardy-Weinberg equilibrium (HWE) were found in 10 of the 12 loci, all caused by heterozygous excess. Moderate genetic differentiation was observed between Chiriviche, Venezuela and Xcalak, México localities (F ST = 0.012), and between the Los Roques and the Veracruz (F ST = 0.074) sites. STRUCTURE analysis found that four genetic entities best fit our data. A unique genetic group in the Gulf of Mexico may imply that the lionfish invasion unfolded both in a counterclockwise manner in the Gulf of Mexico. In spite of the notable dispersion of P. volitans, our results show some genetic structure, as do other noninvasive Caribbean fish species, suggesting that the connectivity in some MPAs analyzed in the Caribbean is limited and caused by only a few source individuals with subsequent genetic drift leading to local genetic differentiation. This indicates that P. volitans dispersion could be caused by mesoscale phenomena, which produce stochastic connectivity pulses. Due to the isolation of some MPAs from others, these findings may hold a promise for local short-term control of by means of intensive fishing, even in MPAs, and may have regional long-term effects.Lionfish (Pterois volitans) have rapidly invaded the tropical Atlantic and spread across the wider Caribbean in a relatively short period of time. Because of its high invasion capacity, we used it as a model to identify the connectivity among nine marine protected areas (MPAs) situated in four countries in the Gulf of Mexico and the Caribbean Sea. This study provides evidence of local genetic differentiation of P. volitans in the Gulf of Mexico and the Caribbean Sea. A total of 475 lionfish samples were characterized with 12 microsatellites, with 6-20 alleles per locus. Departures from Hardy-Weinberg equilibrium (HWE) were found in 10 of the 12 loci, all caused by heterozygous excess. Moderate genetic differentiation was observed between Chiriviche, Venezuela and Xcalak, México localities (F ST = 0.012), and between the Los Roques and the Veracruz (F ST = 0.074) sites. STRUCTURE analysis found that four genetic entities best fit our data. A unique genetic group in the Gulf of Mexico may imply that the lionfish invasion unfolded both in a counterclockwise manner in the Gulf of Mexico. In spite of the notable dispersion of P. volitans, our results show some genetic structure, as do other noninvasive Caribbean fish species, suggesting that the connectivity in some MPAs analyzed in the Caribbean is limited and caused by only a few source individuals with subsequent genetic drift leading to local genetic differentiation. This indicates that P. volitans dispersion could be caused by mesoscale phenomena, which produce stochastic connectivity pulses. Due to the isolation of some MPAs from others, these findings may hold a promise for local short-term control of by means of intensive fishing, even in MPAs, and may have regional long-term effects. Lionfish (Pterois volitans) have rapidly invaded the tropical Atlantic and spread across the wider Caribbean in a relatively short period of time. Because of its high invasion capacity, we used it as a model to identify the connectivity among nine marine protected areas (MPAs) situated in four countries in the Gulf of Mexico and the Caribbean Sea. This study provides evidence of local genetic differentiation of P. volitans in the Gulf of Mexico and the Caribbean Sea. A total of 475 lionfish samples were characterized with 12 microsatellites, with 6–20 alleles per locus. Departures from Hardy–Weinberg equilibrium (HWE) were found in 10 of the 12 loci, all caused by heterozygous excess. Moderate genetic differentiation was observed between Chiriviche, Venezuela and Xcalak, México localities (F ST = 0.012), and between the Los Roques and the Veracruz (F ST = 0.074) sites. STRUCTURE analysis found that four genetic entities best fit our data. A unique genetic group in the Gulf of Mexico may imply that the lionfish invasion unfolded both in a counterclockwise manner in the Gulf of Mexico. In spite of the notable dispersion of P. volitans, our results show some genetic structure, as do other noninvasive Caribbean fish species, suggesting that the connectivity in some MPAs analyzed in the Caribbean is limited and caused by only a few source individuals with subsequent genetic drift leading to local genetic differentiation. This indicates that P. volitans dispersion could be caused by mesoscale phenomena, which produce stochastic connectivity pulses. Due to the isolation of some MPAs from others, these findings may hold a promise for local short‐term control of by means of intensive fishing, even in MPAs, and may have regional long‐term effects. Our findings demonstrate that there is genetic differentiation at local and regional scales.We suggest that the colonization of each geographic area has been temporary pulses, probably caused by mesoscale phenomena, and intensified with the presence of self‐recruitment. The genetic diversity of Pterois volitans in the Gulf and the Caribbean showed that the number of organisms that originated the invasion was much higher than the one mentioned in the literature. Abstract Lionfish (Pterois volitans) have rapidly invaded the tropical Atlantic and spread across the wider Caribbean in a relatively short period of time. Because of its high invasion capacity, we used it as a model to identify the connectivity among nine marine protected areas (MPAs) situated in four countries in the Gulf of Mexico and the Caribbean Sea. This study provides evidence of local genetic differentiation of P. volitans in the Gulf of Mexico and the Caribbean Sea. A total of 475 lionfish samples were characterized with 12 microsatellites, with 6–20 alleles per locus. Departures from Hardy–Weinberg equilibrium (HWE) were found in 10 of the 12 loci, all caused by heterozygous excess. Moderate genetic differentiation was observed between Chiriviche, Venezuela and Xcalak, México localities (FST = 0.012), and between the Los Roques and the Veracruz (FST = 0.074) sites. STRUCTURE analysis found that four genetic entities best fit our data. A unique genetic group in the Gulf of Mexico may imply that the lionfish invasion unfolded both in a counterclockwise manner in the Gulf of Mexico. In spite of the notable dispersion of P. volitans, our results show some genetic structure, as do other noninvasive Caribbean fish species, suggesting that the connectivity in some MPAs analyzed in the Caribbean is limited and caused by only a few source individuals with subsequent genetic drift leading to local genetic differentiation. This indicates that P. volitans dispersion could be caused by mesoscale phenomena, which produce stochastic connectivity pulses. Due to the isolation of some MPAs from others, these findings may hold a promise for local short‐term control of by means of intensive fishing, even in MPAs, and may have regional long‐term effects. Lionfish (Pterois volitans) have rapidly invaded the tropical Atlantic and spread across the wider Caribbean in a relatively short period of time. Because of its high invasion capacity, we used it as a model to identify the connectivity among nine marine protected areas (MPAs) situated in four countries in the Gulf of Mexico and the Caribbean Sea. This study provides evidence of local genetic differentiation of P. volitans in the Gulf of Mexico and the Caribbean Sea. A total of 475 lionfish samples were characterized with 12 microsatellites, with 6–20 alleles per locus. Departures from Hardy–Weinberg equilibrium (HWE) were found in 10 of the 12 loci, all caused by heterozygous excess. Moderate genetic differentiation was observed between Chiriviche, Venezuela and Xcalak, México localities (FST = 0.012), and between the Los Roques and the Veracruz (FST = 0.074) sites. STRUCTURE analysis found that four genetic entities best fit our data. A unique genetic group in the Gulf of Mexico may imply that the lionfish invasion unfolded both in a counterclockwise manner in the Gulf of Mexico. In spite of the notable dispersion of P. volitans, our results show some genetic structure, as do other noninvasive Caribbean fish species, suggesting that the connectivity in some MPAs analyzed in the Caribbean is limited and caused by only a few source individuals with subsequent genetic drift leading to local genetic differentiation. This indicates that P. volitans dispersion could be caused by mesoscale phenomena, which produce stochastic connectivity pulses. Due to the isolation of some MPAs from others, these findings may hold a promise for local short‐term control of by means of intensive fishing, even in MPAs, and may have regional long‐term effects. Our findings demonstrate that there is genetic differentiation at local and regional scales.We suggest that the colonization of each geographic area has been temporary pulses, probably caused by mesoscale phenomena, and intensified with the presence of self‐recruitment. The genetic diversity of Pterois volitans in the Gulf and the Caribbean showed that the number of organisms that originated the invasion was much higher than the one mentioned in the literature. |
| Author | Perez‐España, Horacio Rivera‐Madrid, Renata Luque, Jenny Aguilar‐Espinosa, Margarita Boissin, Emilie Arguelles Jiménez, Jimmy Giro‐Petersen, Ana García‐Rivas, María del C. González‐Gándara, Carlos Guzmán‐Méndez, Irán A. Agudo-Adriani, Esteban Arias‐González, Jesus E. Planes, Serge Cróquer, Aldo |
| AuthorAffiliation | 1 Laboratorio de Ecología de Ecosistemas de Arrecifes Coralinos Departamento de Recursos del Mar Centro de Investigación y de Estudios Avanzados del I.P.N.‐ Unidad Mérida Mérida México 7 Laboratorio de Arrecifes Coralinos. Carrera de Biología Universidad Veracruzana Tuxpan México 11 Comisión Nacional de Áreas Naturales Protegidas Parque Nacional Arrecifes de Puerto Morelos Puerto Morelos México 5 Laboratoire d'Excellence « CORAIL » Perpignan Cedex France 6 Departamento de Estudios Ambientales Universidad Simón Bolívar Caracas Venezuela 9 Healthy Reefs for Healthy People Initiative Ciudad de Guatemala Guatemala 4 PSL Research University: EPHE‐UPVD‐CNRS USR 3278 CRIOBE Université de Perpignan Perpignan Cedex France 10 Bay Islands Association Utila Honduras Utila Honduras 3 Unidad de Bioquímica Molecular de Plantas Centro de Investigación Científica de Yucatán Mérida México 8 Instituto de Ciencias Marinas y Pesquerías Universidad Veracruzana Boca del Río México 2 Department of Biological Sciences M |
| AuthorAffiliation_xml | – name: 8 Instituto de Ciencias Marinas y Pesquerías Universidad Veracruzana Boca del Río México – name: 4 PSL Research University: EPHE‐UPVD‐CNRS USR 3278 CRIOBE Université de Perpignan Perpignan Cedex France – name: 7 Laboratorio de Arrecifes Coralinos. Carrera de Biología Universidad Veracruzana Tuxpan México – name: 5 Laboratoire d'Excellence « CORAIL » Perpignan Cedex France – name: 2 Department of Biological Sciences Marquette University Milwaukee WI USA – name: 9 Healthy Reefs for Healthy People Initiative Ciudad de Guatemala Guatemala – name: 3 Unidad de Bioquímica Molecular de Plantas Centro de Investigación Científica de Yucatán Mérida México – name: 6 Departamento de Estudios Ambientales Universidad Simón Bolívar Caracas Venezuela – name: 11 Comisión Nacional de Áreas Naturales Protegidas Parque Nacional Arrecifes de Puerto Morelos Puerto Morelos México – name: 1 Laboratorio de Ecología de Ecosistemas de Arrecifes Coralinos Departamento de Recursos del Mar Centro de Investigación y de Estudios Avanzados del I.P.N.‐ Unidad Mérida Mérida México – name: 10 Bay Islands Association Utila Honduras Utila Honduras |
| Author_xml | – sequence: 1 givenname: Irán A. orcidid: 0000-0001-5217-2689 surname: Guzmán‐Méndez fullname: Guzmán‐Méndez, Irán A. organization: Marquette University – sequence: 2 givenname: Renata orcidid: 0000-0003-1368-9639 surname: Rivera‐Madrid fullname: Rivera‐Madrid, Renata organization: Centro de Investigación Científica de Yucatán – sequence: 3 givenname: Serge orcidid: 0000-0002-5689-5371 surname: Planes fullname: Planes, Serge organization: Laboratoire d'Excellence « CORAIL » – sequence: 4 givenname: Emilie orcidid: 0000-0002-4110-790X surname: Boissin fullname: Boissin, Emilie organization: Laboratoire d'Excellence « CORAIL » – sequence: 5 givenname: Aldo orcidid: 0000-0001-8880-9338 surname: Cróquer fullname: Cróquer, Aldo organization: Universidad Simón Bolívar – sequence: 6 givenname: Esteban orcidid: 0000-0001-7815-4120 surname: Agudo-Adriani fullname: Agudo-Adriani, Esteban organization: Universidad Simón Bolívar – sequence: 7 givenname: Carlos orcidid: 0000-0003-4155-9719 surname: González‐Gándara fullname: González‐Gándara, Carlos organization: Universidad Veracruzana – sequence: 8 givenname: Horacio orcidid: 0000-0003-4888-4688 surname: Perez‐España fullname: Perez‐España, Horacio organization: Universidad Veracruzana – sequence: 9 givenname: Ana surname: Giro‐Petersen fullname: Giro‐Petersen, Ana organization: Healthy Reefs for Healthy People Initiative – sequence: 10 givenname: Jenny surname: Luque fullname: Luque, Jenny organization: Bay Islands Association Utila Honduras – sequence: 11 givenname: María del C. surname: García‐Rivas fullname: García‐Rivas, María del C. organization: Parque Nacional Arrecifes de Puerto Morelos – sequence: 12 givenname: Margarita surname: Aguilar‐Espinosa fullname: Aguilar‐Espinosa, Margarita organization: Centro de Investigación Científica de Yucatán – sequence: 13 givenname: Jimmy orcidid: 0000-0002-1968-2692 surname: Arguelles Jiménez fullname: Arguelles Jiménez, Jimmy organization: Universidad Veracruzana – sequence: 14 givenname: Jesus E. orcidid: 0000-0002-9563-2064 surname: Arias‐González fullname: Arias‐González, Jesus E. email: earias@cinvestav.mx organization: Centro de Investigación y de Estudios Avanzados del I.P.N.‐ Unidad Mérida |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/32489615$$D View this record in MEDLINE/PubMed https://univ-perp.hal.science/hal-03206341$$DView record in HAL |
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| CitedBy_id | crossref_primary_10_1007_s10811_025_03457_5 crossref_primary_10_1002_aqc_3712 crossref_primary_10_1016_j_scitotenv_2022_153093 |
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| ContentType | Journal Article |
| Copyright | 2019 The Authors. published by John Wiley & Sons Ltd. 2019 The Authors. Ecology and Evolution published by John Wiley & Sons Ltd. 2020. This work is published under http://creativecommons.org/licenses/by/4.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License. Distributed under a Creative Commons Attribution 4.0 International License |
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| GeographicLocations | Guatemala Los Roques Gulf of Mexico Caribbean Sea |
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| Snippet | Lionfish (Pterois volitans) have rapidly invaded the tropical Atlantic and spread across the wider Caribbean in a relatively short period of time. Because of... Lionfish ( Pterois volitans ) have rapidly invaded the tropical Atlantic and spread across the wider Caribbean in a relatively short period of time. Because of... Lionfish ( ) have rapidly invaded the tropical Atlantic and spread across the wider Caribbean in a relatively short period of time. Because of its high... Abstract Lionfish (Pterois volitans) have rapidly invaded the tropical Atlantic and spread across the wider Caribbean in a relatively short period of time.... |
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| SubjectTerms | Biodiversity and Ecology Caribbean Sea Deoxyribonucleic acid Differentiation Dispersion DNA Environmental Sciences founder event Genetic analysis Genetic diversity Genetic drift Genetic structure Invasive fish invasive species lionfish Loci Long-term effects Marine protected areas Mesoscale phenomena Microsatellites Original Research Population Protected areas Pterois Pterois volitans Structural analysis |
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| Title | Genetic connectivity of lionfish (Pterois volitans) in marine protected areas of the Gulf of Mexico and Caribbean Sea |
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