Your search keyword '"Rondeau, Eric B."' showing total 11 results

1. Assessing the effects of genotype-by-environment interaction on epigenetic, transcriptomic, and phenotypic response in a Pacific salmon

Author

Christensen, Kris A, Le Luyer, Jeremy, Chan, Michelle T T, Rondeau, Eric B, Koop, Ben F, Bernatchez, Louis, Devlin, Robert H, Christensen, Kris A, Le Luyer, Jeremy, Chan, Michelle T T, Rondeau, Eric B, Koop, Ben F, Bernatchez, Louis, and Devlin, Robert H

Abstract

Genotype-by-environment (GxE) interactions are non-parallel reaction norms among individuals with different genotypes in response to different environmental conditions. GxE interactions are an extension of phenotypic plasticity and consequently studying such interactions improves our ability to predict effects of different environments on phenotype as well as the fitness of genetically distinct organisms and their capacity to interact with ecosystems. Growth hormone transgenic coho salmon grow much faster than non-transgenics when raised in tank environments, but show little difference in growth when reared in nature-like streams. We used this model system to evaluate potential mechanisms underlying this growth rate GxE interaction, performing RNA-seq to measure gene transcription and whole-genome bisulfite sequencing to measure gene methylation in liver tissue. Gene ontology (GO) term analysis revealed stress as an important biological process potentially influencing growth rate GxE interactions. While few genes with transcription differences also had methylation differences, in promoter or gene regions, many genes were differentially methylated between tank and stream environments. A GO term analysis of differentially methylated genes between tank and stream environments revealed increased methylation in the stream environment of more than 95% of the differentially methylated genes, many with biological processes unrelated to liver function. The lower nutritional condition of the stream environment may cause increased negative regulation of genes less vital for liver tissue function than when fish are reared in tanks with unlimited food availability. These data show a large effect of rearing environment both on gene expression and methylation, but it is less clear that the detected epigenetic marks are responsible for the observed altered growth and physiological responses.

Published

2021

2. Assessing the effects of genotype-by-environment interaction on epigenetic, transcriptomic, and phenotypic response in a Pacific salmon

Author

Christensen, Kris A, Le Luyer, Jeremy, Chan, Michelle T T, Rondeau, Eric B, Koop, Ben F, Bernatchez, Louis, Devlin, Robert H, Christensen, Kris A, Le Luyer, Jeremy, Chan, Michelle T T, Rondeau, Eric B, Koop, Ben F, Bernatchez, Louis, and Devlin, Robert H

Abstract

Genotype-by-environment (GxE) interactions are non-parallel reaction norms among individuals with different genotypes in response to different environmental conditions. GxE interactions are an extension of phenotypic plasticity and consequently studying such interactions improves our ability to predict effects of different environments on phenotype as well as the fitness of genetically distinct organisms and their capacity to interact with ecosystems. Growth hormone transgenic coho salmon grow much faster than non-transgenics when raised in tank environments, but show little difference in growth when reared in nature-like streams. We used this model system to evaluate potential mechanisms underlying this growth rate GxE interaction, performing RNA-seq to measure gene transcription and whole-genome bisulfite sequencing to measure gene methylation in liver tissue. Gene ontology (GO) term analysis revealed stress as an important biological process potentially influencing growth rate GxE interactions. While few genes with transcription differences also had methylation differences, in promoter or gene regions, many genes were differentially methylated between tank and stream environments. A GO term analysis of differentially methylated genes between tank and stream environments revealed increased methylation in the stream environment of more than 95% of the differentially methylated genes, many with biological processes unrelated to liver function. The lower nutritional condition of the stream environment may cause increased negative regulation of genes less vital for liver tissue function than when fish are reared in tanks with unlimited food availability. These data show a large effect of rearing environment both on gene expression and methylation, but it is less clear that the detected epigenetic marks are responsible for the observed altered growth and physiological responses.

Published

2021

3. Assessing the effects of genotype-by-environment interaction on epigenetic, transcriptomic, and phenotypic response in a Pacific salmon

Author

Christensen, Kris A, Le Luyer, Jeremy, Chan, Michelle T T, Rondeau, Eric B, Koop, Ben F, Bernatchez, Louis, Devlin, Robert H, Christensen, Kris A, Le Luyer, Jeremy, Chan, Michelle T T, Rondeau, Eric B, Koop, Ben F, Bernatchez, Louis, and Devlin, Robert H

Abstract

Genotype-by-environment (GxE) interactions are non-parallel reaction norms among individuals with different genotypes in response to different environmental conditions. GxE interactions are an extension of phenotypic plasticity and consequently studying such interactions improves our ability to predict effects of different environments on phenotype as well as the fitness of genetically distinct organisms and their capacity to interact with ecosystems. Growth hormone transgenic coho salmon grow much faster than non-transgenics when raised in tank environments, but show little difference in growth when reared in nature-like streams. We used this model system to evaluate potential mechanisms underlying this growth rate GxE interaction, performing RNA-seq to measure gene transcription and whole-genome bisulfite sequencing to measure gene methylation in liver tissue. Gene ontology (GO) term analysis revealed stress as an important biological process potentially influencing growth rate GxE interactions. While few genes with transcription differences also had methylation differences, in promoter or gene regions, many genes were differentially methylated between tank and stream environments. A GO term analysis of differentially methylated genes between tank and stream environments revealed increased methylation in the stream environment of more than 95% of the differentially methylated genes, many with biological processes unrelated to liver function. The lower nutritional condition of the stream environment may cause increased negative regulation of genes less vital for liver tissue function than when fish are reared in tanks with unlimited food availability. These data show a large effect of rearing environment both on gene expression and methylation, but it is less clear that the detected epigenetic marks are responsible for the observed altered growth and physiological responses.

Published

2021

4. Parallel epigenetic modifications induced by hatchery rearing in a Pacific Salmon

Author

Le Luyer, Jeremy, Laporte, Martin, Beacham, Terry D., Kaukinen, Karia H., Withler, Ruth E., Leong, Jong S., Rondeau, Eric B., Koop, Ben F., Bernatchez, Louis, Le Luyer, Jeremy, Laporte, Martin, Beacham, Terry D., Kaukinen, Karia H., Withler, Ruth E., Leong, Jong S., Rondeau, Eric B., Koop, Ben F., and Bernatchez, Louis

Abstract

A puzzling question in conservation biology is how to maintain overall fitness of individuals bred in captive environment upon release into the wild, especially for rehabilitating declining or threatened species [1,2]. For salmonid species, a heritable change in fitness related traits and gene expression has been reported to occur in a single generation of captivity in hatchery environment [3–5]. Such rapid changes are congruent with models of inadvertent domestication selection which may lead to maladaptation in the natural environment [4]. Arguably, the underlying mechanism by which captivity may induce fitness difference between wild and captive congeners is still poorly understood. Short- term selection on complex phenotypic traits is expected to induce subtle changes in allele frequency over multiple loci [7–9]. Yet, most studies investigating the molecular basis for rapid change in fitness related traits occurring in hatchery have concentrated their effort on 34 finding evidence for selection at the genome level by identifying loci with large effect. Numerous wild stocks of Pacific anadromous salmon and trout (genus Oncorhynchus and Salmo) have experienced fluctuating abundance over the past century, with a series of sharp declines [6–8]. With the objectives of preserving ecosystem integrity, enhancing. declining populations and sustaining fisheries, conservation hatcheries have been flourishing. This is particularly true along the North American Pacific coast where billions of salmonids, all species included, are released each year. Despite substantial improvement of production management, the beneficial ecological role of hatcheries in enhancing and restoring wild stocks is still debated, mainly because of the reduced fitness and maladaptation of hatchery-fish when released in the wild [3,5,9]. Although previous studies showed that domestication selection was involved in such fitness impairment, they also observed that different environmental

Published

2017

5. Parallel epigenetic modifications induced by hatchery rearing in a Pacific Salmon

Author

Le Luyer, Jeremy, Laporte, Martin, Beacham, Terry D., Kaukinen, Karia H., Withler, Ruth E., Leong, Jong S., Rondeau, Eric B., Koop, Ben F., Bernatchez, Louis, Le Luyer, Jeremy, Laporte, Martin, Beacham, Terry D., Kaukinen, Karia H., Withler, Ruth E., Leong, Jong S., Rondeau, Eric B., Koop, Ben F., and Bernatchez, Louis

Abstract

A puzzling question in conservation biology is how to maintain overall fitness of individuals bred in captive environment upon release into the wild, especially for rehabilitating declining or threatened species [1,2]. For salmonid species, a heritable change in fitness related traits and gene expression has been reported to occur in a single generation of captivity in hatchery environment [3–5]. Such rapid changes are congruent with models of inadvertent domestication selection which may lead to maladaptation in the natural environment [4]. Arguably, the underlying mechanism by which captivity may induce fitness difference between wild and captive congeners is still poorly understood. Short- term selection on complex phenotypic traits is expected to induce subtle changes in allele frequency over multiple loci [7–9]. Yet, most studies investigating the molecular basis for rapid change in fitness related traits occurring in hatchery have concentrated their effort on 34 finding evidence for selection at the genome level by identifying loci with large effect. Numerous wild stocks of Pacific anadromous salmon and trout (genus Oncorhynchus and Salmo) have experienced fluctuating abundance over the past century, with a series of sharp declines [6–8]. With the objectives of preserving ecosystem integrity, enhancing. declining populations and sustaining fisheries, conservation hatcheries have been flourishing. This is particularly true along the North American Pacific coast where billions of salmonids, all species included, are released each year. Despite substantial improvement of production management, the beneficial ecological role of hatcheries in enhancing and restoring wild stocks is still debated, mainly because of the reduced fitness and maladaptation of hatchery-fish when released in the wild [3,5,9]. Although previous studies showed that domestication selection was involved in such fitness impairment, they also observed that different environmental

Published

2017

6. Parallel epigenetic modifications induced by hatchery rearing in a Pacific Salmon

Author

Le Luyer, Jeremy, Laporte, Martin, Beacham, Terry D., Kaukinen, Karia H., Withler, Ruth E., Leong, Jong S., Rondeau, Eric B., Koop, Ben F., Bernatchez, Louis, Le Luyer, Jeremy, Laporte, Martin, Beacham, Terry D., Kaukinen, Karia H., Withler, Ruth E., Leong, Jong S., Rondeau, Eric B., Koop, Ben F., and Bernatchez, Louis

Abstract

A puzzling question in conservation biology is how to maintain overall fitness of individuals bred in captive environment upon release into the wild, especially for rehabilitating declining or threatened species [1,2]. For salmonid species, a heritable change in fitness related traits and gene expression has been reported to occur in a single generation of captivity in hatchery environment [3–5]. Such rapid changes are congruent with models of inadvertent domestication selection which may lead to maladaptation in the natural environment [4]. Arguably, the underlying mechanism by which captivity may induce fitness difference between wild and captive congeners is still poorly understood. Short- term selection on complex phenotypic traits is expected to induce subtle changes in allele frequency over multiple loci [7–9]. Yet, most studies investigating the molecular basis for rapid change in fitness related traits occurring in hatchery have concentrated their effort on 34 finding evidence for selection at the genome level by identifying loci with large effect. Numerous wild stocks of Pacific anadromous salmon and trout (genus Oncorhynchus and Salmo) have experienced fluctuating abundance over the past century, with a series of sharp declines [6–8]. With the objectives of preserving ecosystem integrity, enhancing. declining populations and sustaining fisheries, conservation hatcheries have been flourishing. This is particularly true along the North American Pacific coast where billions of salmonids, all species included, are released each year. Despite substantial improvement of production management, the beneficial ecological role of hatcheries in enhancing and restoring wild stocks is still debated, mainly because of the reduced fitness and maladaptation of hatchery-fish when released in the wild [3,5,9]. Although previous studies showed that domestication selection was involved in such fitness impairment, they also observed that different environmental

Published

2017

7. The Atlantic salmon genome provides insights into rediploidization

Author

Lien, Sigbjorn, Koop, Ben F., Sandve, Simen R., Miller, Jason R., Kent, Matthew P., Nome, Torfinn, Hvidsten, Torgeir R., Leong, Jong S., Minkley, David R., Zimin, Aleksey, Grammes, Fabian, Grove, Harald, Gjuvsland, Arne, Walenz, Brian, Hermansen, Russell A., von Schalburg, Kris, Rondeau, Eric B., Di Genova, Alex, Samy, Jeevan K. A., Vik, Jon Olav, Vigeland, Magnus D., Caler, Lis, Grimholt, Unni, Jentoft, Sissel, Vage, Dag Inge, de Jong, Pieter, Moen, Thomas, Baranski, Matthew, Palti, Yniv, Smith, Douglas R., Yorke, James A., Nederbragt, Alexander J., Tooming-Klunderud, Ave, Jakobsen, Kjetill S., Jiang, Xuanting, Fan, Dingding, Liberles, David A., Vidal, Rodrigo, Iturra, Patricia, Jones, Steven J. M., Jonassen, Inge, Maass, Alejandro, Omholt, Stig W., Davidson, William S., Lien, Sigbjorn, Koop, Ben F., Sandve, Simen R., Miller, Jason R., Kent, Matthew P., Nome, Torfinn, Hvidsten, Torgeir R., Leong, Jong S., Minkley, David R., Zimin, Aleksey, Grammes, Fabian, Grove, Harald, Gjuvsland, Arne, Walenz, Brian, Hermansen, Russell A., von Schalburg, Kris, Rondeau, Eric B., Di Genova, Alex, Samy, Jeevan K. A., Vik, Jon Olav, Vigeland, Magnus D., Caler, Lis, Grimholt, Unni, Jentoft, Sissel, Vage, Dag Inge, de Jong, Pieter, Moen, Thomas, Baranski, Matthew, Palti, Yniv, Smith, Douglas R., Yorke, James A., Nederbragt, Alexander J., Tooming-Klunderud, Ave, Jakobsen, Kjetill S., Jiang, Xuanting, Fan, Dingding, Liberles, David A., Vidal, Rodrigo, Iturra, Patricia, Jones, Steven J. M., Jonassen, Inge, Maass, Alejandro, Omholt, Stig W., and Davidson, William S.

Abstract

The whole-genome duplication 80 million years ago of the common ancestor of salmonids (salmonid-specific fourth vertebrate whole-genome duplication, Ss4R) provides unique opportunities to learn about the evolutionary fate of a duplicated vertebrate genome in 70 extant lineages. Here we present a high-quality genome assembly for Atlantic salmon (Salmo salar), and show that large genomic reorganizations, coinciding with bursts of transposon-mediated repeat expansions, were crucial for the post-Ss4R rediploidization process. Comparisons of duplicate gene expression patterns across a wide range of tissues with orthologous genes from a pre-Ss4R outgroup unexpectedly demonstrate far more instances of neofunctionalization than subfunctionalization. Surprisingly, we find that genes that were retained as duplicates after the teleost-specific whole-genome duplication 320 million years ago were not more likely to be retained after the Ss4R, and that the duplicate retention was not influenced to a great extent by the nature of the predicted protein interactions of the gene products. Finally, we demonstrate that the Atlantic salmon assembly can serve as a reference sequence for the study of other salmonids for a range of purposes.

Published

2016

8. The Atlantic salmon genome provides insights into rediploidization

Author

Lien, Sigbjorn, Koop, Ben F., Sandve, Simen R., Miller, Jason R., Kent, Matthew P., Nome, Torfinn, Hvidsten, Torgeir R., Leong, Jong S., Minkley, David R., Zimin, Aleksey, Grammes, Fabian, Grove, Harald, Gjuvsland, Arne, Walenz, Brian, Hermansen, Russell A., von Schalburg, Kris, Rondeau, Eric B., Di Genova, Alex, Samy, Jeevan K. A., Vik, Jon Olav, Vigeland, Magnus D., Caler, Lis, Grimholt, Unni, Jentoft, Sissel, Vage, Dag Inge, de Jong, Pieter, Moen, Thomas, Baranski, Matthew, Palti, Yniv, Smith, Douglas R., Yorke, James A., Nederbragt, Alexander J., Tooming-Klunderud, Ave, Jakobsen, Kjetill S., Jiang, Xuanting, Fan, Dingding, Liberles, David A., Vidal, Rodrigo, Iturra, Patricia, Jones, Steven J. M., Jonassen, Inge, Maass, Alejandro, Omholt, Stig W., Davidson, William S., Lien, Sigbjorn, Koop, Ben F., Sandve, Simen R., Miller, Jason R., Kent, Matthew P., Nome, Torfinn, Hvidsten, Torgeir R., Leong, Jong S., Minkley, David R., Zimin, Aleksey, Grammes, Fabian, Grove, Harald, Gjuvsland, Arne, Walenz, Brian, Hermansen, Russell A., von Schalburg, Kris, Rondeau, Eric B., Di Genova, Alex, Samy, Jeevan K. A., Vik, Jon Olav, Vigeland, Magnus D., Caler, Lis, Grimholt, Unni, Jentoft, Sissel, Vage, Dag Inge, de Jong, Pieter, Moen, Thomas, Baranski, Matthew, Palti, Yniv, Smith, Douglas R., Yorke, James A., Nederbragt, Alexander J., Tooming-Klunderud, Ave, Jakobsen, Kjetill S., Jiang, Xuanting, Fan, Dingding, Liberles, David A., Vidal, Rodrigo, Iturra, Patricia, Jones, Steven J. M., Jonassen, Inge, Maass, Alejandro, Omholt, Stig W., and Davidson, William S.

Abstract

The whole-genome duplication 80 million years ago of the common ancestor of salmonids (salmonid-specific fourth vertebrate whole-genome duplication, Ss4R) provides unique opportunities to learn about the evolutionary fate of a duplicated vertebrate genome in 70 extant lineages. Here we present a high-quality genome assembly for Atlantic salmon (Salmo salar), and show that large genomic reorganizations, coinciding with bursts of transposon-mediated repeat expansions, were crucial for the post-Ss4R rediploidization process. Comparisons of duplicate gene expression patterns across a wide range of tissues with orthologous genes from a pre-Ss4R outgroup unexpectedly demonstrate far more instances of neofunctionalization than subfunctionalization. Surprisingly, we find that genes that were retained as duplicates after the teleost-specific whole-genome duplication 320 million years ago were not more likely to be retained after the Ss4R, and that the duplicate retention was not influenced to a great extent by the nature of the predicted protein interactions of the gene products. Finally, we demonstrate that the Atlantic salmon assembly can serve as a reference sequence for the study of other salmonids for a range of purposes.

Published

2016

9. The Atlantic salmon genome provides insights into rediploidization

Author

Lien, Sigbjorn, Koop, Ben F., Sandve, Simen R., Miller, Jason R., Kent, Matthew P., Nome, Torfinn, Hvidsten, Torgeir R., Leong, Jong S., Minkley, David R., Zimin, Aleksey, Grammes, Fabian, Grove, Harald, Gjuvsland, Arne, Walenz, Brian, Hermansen, Russell A., von Schalburg, Kris, Rondeau, Eric B., Di Genova, Alex, Samy, Jeevan K. A., Vik, Jon Olav, Vigeland, Magnus D., Caler, Lis, Grimholt, Unni, Jentoft, Sissel, Vage, Dag Inge, de Jong, Pieter, Moen, Thomas, Baranski, Matthew, Palti, Yniv, Smith, Douglas R., Yorke, James A., Nederbragt, Alexander J., Tooming-Klunderud, Ave, Jakobsen, Kjetill S., Jiang, Xuanting, Fan, Dingding, Liberles, David A., Vidal, Rodrigo, Iturra, Patricia, Jones, Steven J. M., Jonassen, Inge, Maass, Alejandro, Omholt, Stig W., Davidson, William S., Lien, Sigbjorn, Koop, Ben F., Sandve, Simen R., Miller, Jason R., Kent, Matthew P., Nome, Torfinn, Hvidsten, Torgeir R., Leong, Jong S., Minkley, David R., Zimin, Aleksey, Grammes, Fabian, Grove, Harald, Gjuvsland, Arne, Walenz, Brian, Hermansen, Russell A., von Schalburg, Kris, Rondeau, Eric B., Di Genova, Alex, Samy, Jeevan K. A., Vik, Jon Olav, Vigeland, Magnus D., Caler, Lis, Grimholt, Unni, Jentoft, Sissel, Vage, Dag Inge, de Jong, Pieter, Moen, Thomas, Baranski, Matthew, Palti, Yniv, Smith, Douglas R., Yorke, James A., Nederbragt, Alexander J., Tooming-Klunderud, Ave, Jakobsen, Kjetill S., Jiang, Xuanting, Fan, Dingding, Liberles, David A., Vidal, Rodrigo, Iturra, Patricia, Jones, Steven J. M., Jonassen, Inge, Maass, Alejandro, Omholt, Stig W., and Davidson, William S.

Abstract

The whole-genome duplication 80 million years ago of the common ancestor of salmonids (salmonid-specific fourth vertebrate whole-genome duplication, Ss4R) provides unique opportunities to learn about the evolutionary fate of a duplicated vertebrate genome in 70 extant lineages. Here we present a high-quality genome assembly for Atlantic salmon (Salmo salar), and show that large genomic reorganizations, coinciding with bursts of transposon-mediated repeat expansions, were crucial for the post-Ss4R rediploidization process. Comparisons of duplicate gene expression patterns across a wide range of tissues with orthologous genes from a pre-Ss4R outgroup unexpectedly demonstrate far more instances of neofunctionalization than subfunctionalization. Surprisingly, we find that genes that were retained as duplicates after the teleost-specific whole-genome duplication 320 million years ago were not more likely to be retained after the Ss4R, and that the duplicate retention was not influenced to a great extent by the nature of the predicted protein interactions of the gene products. Finally, we demonstrate that the Atlantic salmon assembly can serve as a reference sequence for the study of other salmonids for a range of purposes.

Published

2016

10. The Atlantic salmon genome provides insights into rediploidization

Author

Lien, Sigbjorn, Koop, Ben F., Sandve, Simen R., Miller, Jason R., Kent, Matthew P., Nome, Torfinn, Hvidsten, Torgeir R., Leong, Jong S., Minkley, David R., Zimin, Aleksey, Grammes, Fabian, Grove, Harald, Gjuvsland, Arne, Walenz, Brian, Hermansen, Russell A., von Schalburg, Kris, Rondeau, Eric B., Di Genova, Alex, Samy, Jeevan K. A., Vik, Jon Olav, Vigeland, Magnus D., Caler, Lis, Grimholt, Unni, Jentoft, Sissel, Vage, Dag Inge, de Jong, Pieter, Moen, Thomas, Baranski, Matthew, Palti, Yniv, Smith, Douglas R., Yorke, James A., Nederbragt, Alexander J., Tooming-Klunderud, Ave, Jakobsen, Kjetill S., Jiang, Xuanting, Fan, Dingding, Liberles, David A., Vidal, Rodrigo, Iturra, Patricia, Jones, Steven J. M., Jonassen, Inge, Maass, Alejandro, Omholt, Stig W., Davidson, William S., Lien, Sigbjorn, Koop, Ben F., Sandve, Simen R., Miller, Jason R., Kent, Matthew P., Nome, Torfinn, Hvidsten, Torgeir R., Leong, Jong S., Minkley, David R., Zimin, Aleksey, Grammes, Fabian, Grove, Harald, Gjuvsland, Arne, Walenz, Brian, Hermansen, Russell A., von Schalburg, Kris, Rondeau, Eric B., Di Genova, Alex, Samy, Jeevan K. A., Vik, Jon Olav, Vigeland, Magnus D., Caler, Lis, Grimholt, Unni, Jentoft, Sissel, Vage, Dag Inge, de Jong, Pieter, Moen, Thomas, Baranski, Matthew, Palti, Yniv, Smith, Douglas R., Yorke, James A., Nederbragt, Alexander J., Tooming-Klunderud, Ave, Jakobsen, Kjetill S., Jiang, Xuanting, Fan, Dingding, Liberles, David A., Vidal, Rodrigo, Iturra, Patricia, Jones, Steven J. M., Jonassen, Inge, Maass, Alejandro, Omholt, Stig W., and Davidson, William S.

Abstract

The whole-genome duplication 80 million years ago of the common ancestor of salmonids (salmonid-specific fourth vertebrate whole-genome duplication, Ss4R) provides unique opportunities to learn about the evolutionary fate of a duplicated vertebrate genome in 70 extant lineages. Here we present a high-quality genome assembly for Atlantic salmon (Salmo salar), and show that large genomic reorganizations, coinciding with bursts of transposon-mediated repeat expansions, were crucial for the post-Ss4R rediploidization process. Comparisons of duplicate gene expression patterns across a wide range of tissues with orthologous genes from a pre-Ss4R outgroup unexpectedly demonstrate far more instances of neofunctionalization than subfunctionalization. Surprisingly, we find that genes that were retained as duplicates after the teleost-specific whole-genome duplication 320 million years ago were not more likely to be retained after the Ss4R, and that the duplicate retention was not influenced to a great extent by the nature of the predicted protein interactions of the gene products. Finally, we demonstrate that the Atlantic salmon assembly can serve as a reference sequence for the study of other salmonids for a range of purposes.

Published

2016

11. The Atlantic salmon genome provides insights into rediploidization

Author

Lien, Sigbjorn, Koop, Ben F., Sandve, Simen R., Miller, Jason R., Kent, Matthew P., Nome, Torfinn, Hvidsten, Torgeir R., Leong, Jong S., Minkley, David R., Zimin, Aleksey, Grammes, Fabian, Grove, Harald, Gjuvsland, Arne, Walenz, Brian, Hermansen, Russell A., von Schalburg, Kris, Rondeau, Eric B., Di Genova, Alex, Samy, Jeevan K. A., Vik, Jon Olav, Vigeland, Magnus D., Caler, Lis, Grimholt, Unni, Jentoft, Sissel, Vage, Dag Inge, de Jong, Pieter, Moen, Thomas, Baranski, Matthew, Palti, Yniv, Smith, Douglas R., Yorke, James A., Nederbragt, Alexander J., Tooming-Klunderud, Ave, Jakobsen, Kjetill S., Jiang, Xuanting, Fan, Dingding, Liberles, David A., Vidal, Rodrigo, Iturra, Patricia, Jones, Steven J. M., Jonassen, Inge, Maass, Alejandro, Omholt, Stig W., Davidson, William S., Lien, Sigbjorn, Koop, Ben F., Sandve, Simen R., Miller, Jason R., Kent, Matthew P., Nome, Torfinn, Hvidsten, Torgeir R., Leong, Jong S., Minkley, David R., Zimin, Aleksey, Grammes, Fabian, Grove, Harald, Gjuvsland, Arne, Walenz, Brian, Hermansen, Russell A., von Schalburg, Kris, Rondeau, Eric B., Di Genova, Alex, Samy, Jeevan K. A., Vik, Jon Olav, Vigeland, Magnus D., Caler, Lis, Grimholt, Unni, Jentoft, Sissel, Vage, Dag Inge, de Jong, Pieter, Moen, Thomas, Baranski, Matthew, Palti, Yniv, Smith, Douglas R., Yorke, James A., Nederbragt, Alexander J., Tooming-Klunderud, Ave, Jakobsen, Kjetill S., Jiang, Xuanting, Fan, Dingding, Liberles, David A., Vidal, Rodrigo, Iturra, Patricia, Jones, Steven J. M., Jonassen, Inge, Maass, Alejandro, Omholt, Stig W., and Davidson, William S.

Abstract

The whole-genome duplication 80 million years ago of the common ancestor of salmonids (salmonid-specific fourth vertebrate whole-genome duplication, Ss4R) provides unique opportunities to learn about the evolutionary fate of a duplicated vertebrate genome in 70 extant lineages. Here we present a high-quality genome assembly for Atlantic salmon (Salmo salar), and show that large genomic reorganizations, coinciding with bursts of transposon-mediated repeat expansions, were crucial for the post-Ss4R rediploidization process. Comparisons of duplicate gene expression patterns across a wide range of tissues with orthologous genes from a pre-Ss4R outgroup unexpectedly demonstrate far more instances of neofunctionalization than subfunctionalization. Surprisingly, we find that genes that were retained as duplicates after the teleost-specific whole-genome duplication 320 million years ago were not more likely to be retained after the Ss4R, and that the duplicate retention was not influenced to a great extent by the nature of the predicted protein interactions of the gene products. Finally, we demonstrate that the Atlantic salmon assembly can serve as a reference sequence for the study of other salmonids for a range of purposes.

Published

2016