Your search keyword '"Diopere, E."' showing total 12 results

1. Gene-associated markers provide tools for tackling illegal fishing and false eco-certification (vol 3, 851, 2012)

Author

Nielsen, EE, Cariani, A, Mac Aoidh, E, Maes, GE, Milano, I, Ogden, R, Taylor, M, Hemmer-Hansen, J, Babbucci, M, Bargelloni, L, Bekkevold, D, Diopere, E, Grenfell, L, Helyar, S, Limborg, MT, Martinsohn, JT, McEwing, R, Panitz, F, Patarnello, T, Tinti, F, Van Houdt, JKJ, Volckaert, FAM, Waples, RS, Albin, JEJ, Baptista, JMV, Barmintsev, V, Bautista, JM, Bendixen, C, Berge, J-P, Blohm, D, Cardazzo, B, Diez, A, Espineira, M, Geffen, AJ, Gonzalez, E, Gonzalez-Lavin, N, Guarniero, I, Jerome, M, Kochzius, M, Krey, G, Mouchel, O, Negrisolo, E, Piccinetti, C, Puyet, A, Rastorguev, S, Smith, JP, Trentini, M, Verrez-Bagnis, V, Volkov, A, Zanzi, A, De Bruyn, M, and Carvalho, GR

Subjects

Multidisciplinary Sciences, Science & Technology, Science & Technology - Other Topics, FishPopTrace Consortium

Published

2019

2. Gene-associated markers provide tools for tackling illegal fishing and false eco-certification

Author

Nielsen E. E., Cariani A., Aoidh E. M., Maes G. E., MILANO, ILARIA, Ogden R., Taylor M., Hemmer-Hansen J., Babbucci M., Bargelloni L., Bekkevold D., Diopere E., Grenfell L., Helyar S., Limborg M. T., Martinsohn J. T., McEwing R., Panitz F., PATARNELLO, TOMASO, Tinti F., Van Houdt, J. K. J. Volckaert, F. A. M. Waples, R. S. Albin, J. E. J., Vieites Baptista, J. M. Barmintsev, V. Bautista, J. M. Bendixen, C. Bergé, J. -P., Blohm D., Cardazzo B., Diez A., Espiñeira M., Geffen A. J., Gonzalez E., González-Lavín N., Guarniero I., Jeráme M., Kochzius M., Krey G., Mouchel O., Negrisolo E., Piccinetti C., Puyet A., Rastorguev S., Smith J. P., Trentini M., Verrez-Bagnis V., Volkov A., Zanzi A., Carvalho G. R., Nielsen, E.E., Cariani, A., Aoidh, E.M., Maes, G.E., Milano, I., Ogden, R., Taylor, M., Hemmer-Hansen, J., Babbucci, M., Bargelloni, L., Bekkevold, D., Diopere, E., Grenfell, L., Helyar, S., Limborg, M.T., Martinsohn, J.T., McEwing, R., Panitz, F., Patarnello, T., Tinti, F., Van Houdt, J.K.J., Volckaert, F.A.M., Waples, R.S., Albin, J.E.J., Vieites Baptista, J.M., Barmintsev, V., Bautista, J.M., Bendixen, C., Bergé, J.-P., Blohm, D., Cardazzo, B., Diez, A., Espiñeira, M., Geffen, A.J., Gonzalez, E., González-Lavín, N., Guarniero, I., Jeráme, M., Kochzius, M., Krey, G., Mouchel, O., Negrisolo, E., Piccinetti, C., Puyet, A., Rastorguev, S., Smith, J.P., Trentini, M., Verrez-Bagnis, V., Volkov, A., Zanzi, A., Carvalho, G.R., Biology, Ecology and Systematics, and Vrije Universiteit Brussel

Subjects

0106 biological sciences, Conservation of Natural Resources, Population, Fishing, Fisheries, General Physics and Astronomy, Single-nucleotide polymorphism, Certification, Biology, Polymorphism, Single Nucleotide, 010603 evolutionary biology, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, CONSERVATION OF NATURAL RESOURCES, SDG 13 - Climate Action, Animals, SDG 14 - Life Below Water, 14. Life underwater, Author Correction, education, ADAPTATION, POPULATION, 030304 developmental biology, 0303 health sciences, education.field_of_study, Multidisciplinary, Ecology, Fishes, General Chemistry, Illegal fishing, Consumer Organizations, Fishery, Overexploitation, DIFFERENTIATION, Scale (social sciences), SINGLE NUCLEOTIDE POLYMORPHISMS, DIRECTIONAL SELECTION, FISHERIES

Abstract

Illegal, Unreported and Unregulated fishing has had a major role in the overexploitation of global fish populations. In response, international regulations have been imposed and many fisheries have been 'eco-certified' by consumer organizations, but methods for independent control of catch certificates and eco-labels are urgently needed. Here we show that, by using gene-associated single nucleotide polymorphisms, individual marine fish can be assigned back to population of origin with unprecedented high levels of precision. By applying high differentiation single nucleotide polymorphism assays, in four commercial marine fish, on a pan-European scale, we find 93-100% of individuals could be correctly assigned to origin in policy-driven case studies. We show how case-targeted single nucleotide polymorphism assays can be created and forensically validated, using a centrally maintained and publicly available database. Our results demonstrate how application of gene-associated markers will likely revolutionize origin assignment and become highly valuable tools for fighting illegal fishing and mislabelling worldwide.

Published

2012

3. Gene-associated markers provide tools for tackling illegal fishing and false eco-certification

Author

Nielsen, E.E., Cariani, A., Mac Aoidh, E., Maes, G.E., Milano, I., Ogden, R., Taylor, M., Hemmer-Hansen, J., Babbucci, M., Bargelloni, L., Bekkevold, D., Diopere, E., Grenfell, L., Helyar, S., Limborg, M.T., Martinsohn, J. Th., McEwing, R., Panitz, F., Patarnello, T., Tinti, F., Van Houdt, J.K.J., Volckaert, F.A.M., Waples, R.S., FishPopTrace Consortium, and Carvalho, G.R.

Subjects

Certification, Genetic markers, Biomarkers, Illegal fishing

Abstract

Illegal, Unreported and Unregulated fishing has had a major role in the overexploitation of global fish populations. In response, international regulations have been imposed and many fisheries have been 'eco-certified' by consumer organizations, but methods for independent control of catch certificates and eco-labels are urgently needed. Here we show that, by using gene-associated single nucleotide polymorphisms, individual marine fish can be assigned back to population of origin with unprecedented high levels of precision. By applying high differentiation single nucleotide polymorphism assays, in four commercial marine fish, on a pan-European scale, we find 93–100% of individuals could be correctly assigned to origin in policy-driven case studies. We show how case-targeted single nucleotide polymorphism assays can be created and forensically validated, using a centrally maintained and publicly available database. Our results demonstrate how application of gene-associated markers will likely revolutionize origin assignment and become highly valuable tools for fighting illegal fishing and mislabelling worldwide.

Published

2012

4. Evaluating genetic traceability methods for captive‑bred marine fish and their applications in fisheries management and wildlife forensics

Author

Bylemans, J, primary, Maes, GE, additional, Diopere, E, additional, Cariani, A, additional, Senn, H, additional, Taylor, MI, additional, Helyar, S, additional, Bargelloni, L, additional, Bonaldo, A, additional, Carvalho, G, additional, Guarniero, I, additional, Komen, H, additional, Martinsohn, JT, additional, Nielsen, EE, additional, Tinti, F, additional, Volckaert, FAM, additional, and Ogden, R, additional

Published

2016

5. Genetic adaptation in common sole (Solea solea) under natural and artificial selection

Author

Diopere, E., Volckaert, F.A.M., and Maes, G.E.

Subjects

Solea solea [Sole], Overfishing, Management

Published

2010

6. The molecular basis of phenotypic adaptive changes in the common sole (Solea solea L.): disentangling fisheries from climate induced evolution

Author

Maes, G.E., Diopere, E., Cuveliers, E., Mollet, F.M., Hellemans, B., Rijnsdorp, A.D., and Volckaert, F.A.M.

Subjects

Solea solea [Sole], Fisheries, Overfishing, Climatic changes, Management

Published

2010

7. A genetic linkage map of Sole (Solea solea): A tool for evolutionary and comparative analyses of exploited (flat)fishes

Author

Diopere, E., Maes, G.E., Komen, J., Volckaert, F.A.M., Groenen, M., Diopere, E., Maes, G.E., Komen, J., Volckaert, F.A.M., and Groenen, M.

Abstract

Linkage maps based on markers derived from genes are essential evolutionary tools for commercial marine fish to help identify genomic regions associated with complex traits and subject to selective forces at play during exploitation or selective breeding. Additionally, they allow the use of genomic information from other related species for which more detailed information is available. Sole (solea solea L.) is a commercially important flatfish species in the North Sea, subject to overexploitation and showing evidence of fisheries-induced evolutionary changes in growth- and maturation-related traits. Sole would definitely benefit from a linkage map to better understand how evolution has shaped its genome structure. This study presents a linkage map of sole based on 423 single nucleotide polymorphisms derived from expressed sequence tags and 8 neutral microsatellite markers. The total map length is 1233.8 cM and consists of 38 linkage groups with a size varying between 0 to 92.1 cM. Being derived from expressed sequence tags allowed us to align the map with the genome of four model fish species, namely medaka (Oryzias latipes), Nile tilapia (Oreochromis niloticus), three-spined stickleback (Gasterosteus aculeatus) and green spotted pufferfish (Tetraodon nigroviridis). This comparison revealed multiple conserved syntenic regions with all four species, and suggested that the linkage groups represent 21 putative sole chromosomes. The map was also compared to the linkage map of turbot (Scophthalmus maximus), another commercially important flatfish species and closely related to sole. For all putative sole chromosomes (except one) a turbot homolog was detected, confirming the even higher degree of synteny between these two flatfish species.

Published

2014

8. Application of SNPs for population genetics of nonmodel organisms: new opportunities and challenges

Author

Helyar, S.J., Hansen, Jakob Hemmer, Bekkevold, Dorte, Taylor, M. I., Ogden, R., Limborg, Morten, Cariani, A., Maes, G. E., Diopere, E., Carvalho, G. R., Eg Nielsen, Einar, Helyar, S.J., Hansen, Jakob Hemmer, Bekkevold, Dorte, Taylor, M. I., Ogden, R., Limborg, Morten, Cariani, A., Maes, G. E., Diopere, E., Carvalho, G. R., and Eg Nielsen, Einar

Abstract

Recent improvements in the speed, cost and accuracy of next generation sequencing are revolutionizing the discovery of single nucleotide polymorphisms (SNPs). SNPs are increasingly being used as an addition to the molecular ecology toolkit in nonmodel organisms, but their efficient use remains challenging. Here, we discuss common issues when employing SNP markers, including the high numbers of markers typically employed, the effects of ascertainment bias and the inclusion of nonneutral loci in a marker panel. We provide a critique of considerations specifically associated with the application and population genetic analysis of SNPs in nonmodel taxa, focusing specifically on some of the most commonly applied methods.

Published

2011

9. Evaluating genetic traceability methods for captive-bred marine fish and their applications in fisheries management and wildlife forensics

Author

Filip Volckaert, Luca Bargelloni, Helen Senn, Fausto Tinti, Alessio Bonaldo, Gary R. Carvalho, Alessia Cariani, Einar Eg Nielsen, Jann Th. Martinsohn, Jonas Bylemans, Ilaria Guarniero, Sarah J. Helyar, Eveline Diopere, Martin I. Taylor, Hans Komen, Rob Ogden, Gregory E. Maes, Bylemans, J, Maes, Ge, Diopere, E, Cariani, A, Senn, H, Taylor, Mi, Helyar, S, Bargelloni, L, Bonaldo, A, Carvalho, G, Guarniero, I, Komen, H, Martinsohn, Jt, Nielsen, Ee, Tinti, F, Volckaert, Fam, and Ogden, R

Subjects

0106 biological sciences, 0301 basic medicine, Conservation genetics, Aquaculture · Conservation genetics · Escapees · Fisheries management · Wildlife forensics, SOLE SOLEA-SENEGALENSIS, Wildlife forensics, Broodstock, Aquaculture, 01 natural sciences, Escapees, Effective population size, ATLANTIC SALMON, Aquaculture. Fisheries. Angling, Gadus, QH540-549.5, Water Science and Technology, education.field_of_study, Ecology, Policy and Law, PARENTAGE ANALYSIS, Management, GADOID CULTURE, Fisheries management, Monitoring, Population, SH1-691, Management, Monitoring, Policy and Law, Biology, Aquatic Science, Animal Breeding and Genomics, 010603 evolutionary biology, MARKET SUBSTITUTION, STOCK ENHANCEMENT PROGRAMS, 03 medical and health sciences, POPULATION ASSIGNMENT, Captive breeding, Fokkerij en Genomica, 14. Life underwater, COMMON SOLE, SDG 14 - Life Below Water, education, CHARR SALVELINUS-FONTINALIS, business.industry, biology.organism_classification, Fishery, 030104 developmental biology, WIAS, business, FISHERIES, MARINE, NATURAL-POPULATIONS

Abstract

Growing demands for marine fish products is leading to increased pressure on already depleted wild populations and a rise in the aquaculture production. Consequently, more captive bred fish are released into the wild through accidental escape or deliberate restocking, stock enhancement and sea ranching programs. The increased mixing of captive bred fish with wild conspecifics may affect the ecological and/or genetic integrity of wild fish populations. From a fisheries management perspective unambiguous identification tools for captive bred fish will be highly valuable to manage risks. Additionally there is great potential to use these tools in wildlife forensics (i.e. tracing back escapees to their origin and determining mislabelling of seafood products). Using SNP data from captive bred and wild populations of Atlantic cod (Gadus morhua L.) and sole (Solea solea L.), we explored the efficiency of population and parentage assignment techniques for the identification and tracing of captive bred fish. Simulated and empirical data were used to correct for stochastic genetic effects. Overall, parentage assignment performed well when a large effective population size characterizes the broodstock and escapees originate from early generations of captive breeding. Consequently, parentage assignments are particularly useful from a fisheries management perspective to monitor the effects of deliberate releases of captive bred fish on wild populations. Population assignment proved to be more efficient after several generations of captive breeding, which makes it a useful method in forensic applications for well-established aquaculture species. We suggest the implementation of a case by case strategy when choosing the best method.

Published

2016

10. Reconciling seascape genetics and fisheries science in three codistributed flatfishes.

Author

Vandamme S, Raeymaekers JAM, Maes GE, Cottenie K, Calboli FCF, Diopere E, and Volckaert FAM

Abstract

Uncertainty hampers innovative mixed-fisheries management by the scales at which connectivity dynamics are relevant to management objectives. The spatial scale of sustainable stock management is species-specific and depends on ecology, life history and population connectivity. One valuable approach to understand these spatial scales is to determine to what extent population genetic structure correlates with the oceanographic environment. Here, we compare the level of genetic connectivity in three codistributed and commercially exploited demersal flatfish species living in the North East Atlantic Ocean. Population genetic structure was analysed based on 14, 14 and 10 neutral DNA microsatellite markers for turbot, brill and sole, respectively. We then used redundancy analysis (RDA) to attribute the genetic variation to spatial (geographical location), temporal (sampling year) and oceanographic (water column characteristics) components. The genetic structure of turbot was composed of three clusters and correlated with variation in the depth of the pycnocline, in addition to spatial factors. The genetic structure of brill was homogenous, but correlated with average annual stratification and spatial factors. In sole, the genetic structure was composed of three clusters, but was only linked to a temporal factor. We explored whether the management of data poor commercial fisheries, such as in brill and turbot, might benefit from population-specific information. We conclude that the management of fish stocks has to consider species-specific genetic structures and may benefit from the documentation of the genetic seascape and life-history traits., Competing Interests: None declared., (© 2020 The Authors. Evolutionary Applications published by John Wiley & Sons Ltd.)

Published

2020

11. Author Correction: Gene-associated markers provide tools for tackling illegal fishing and false eco-certification.

Author

Nielsen EE, Cariani A, Aoidh EM, Maes GE, Milano I, Ogden R, Taylor M, Hemmer-Hansen J, Babbucci M, Bargelloni L, Bekkevold D, Diopere E, Grenfell L, Helyar S, Limborg MT, Martinsohn JT, McEwing R, Panitz F, Patarnello T, Tinti F, Van Houdt JKJ, Volckaert FAM, Waples RS, and Carvalho GR

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2019

12. A genetic linkage map of sole (Solea solea): a tool for evolutionary and comparative analyses of exploited (flat)fishes.

Author

Diopere E, Maes GE, Komen H, Volckaert FA, and Groenen MA

Subjects

Animals, Evolution, Molecular, Genome, Phylogeny, Polymorphism, Single Nucleotide, Synteny, Flatfishes classification, Flatfishes genetics, Genetic Linkage

Abstract

Linkage maps based on markers derived from genes are essential evolutionary tools for commercial marine fish to help identify genomic regions associated with complex traits and subject to selective forces at play during exploitation or selective breeding. Additionally, they allow the use of genomic information from other related species for which more detailed information is available. Sole (solea solea L.) is a commercially important flatfish species in the North Sea, subject to overexploitation and showing evidence of fisheries-induced evolutionary changes in growth- and maturation-related traits. Sole would definitely benefit from a linkage map to better understand how evolution has shaped its genome structure. This study presents a linkage map of sole based on 423 single nucleotide polymorphisms derived from expressed sequence tags and 8 neutral microsatellite markers. The total map length is 1233.8 cM and consists of 38 linkage groups with a size varying between 0 to 92.1 cM. Being derived from expressed sequence tags allowed us to align the map with the genome of four model fish species, namely medaka (Oryzias latipes), Nile tilapia (Oreochromis niloticus), three-spined stickleback (Gasterosteus aculeatus) and green spotted pufferfish (Tetraodon nigroviridis). This comparison revealed multiple conserved syntenic regions with all four species, and suggested that the linkage groups represent 21 putative sole chromosomes. The map was also compared to the linkage map of turbot (Scophthalmus maximus), another commercially important flatfish species and closely related to sole. For all putative sole chromosomes (except one) a turbot homolog was detected, confirming the even higher degree of synteny between these two flatfish species.

Published

2014