Your search keyword '"Bed'hom, Bertrand"' showing total 55 results

1. A frame-shift mutation in COMTD1 is associated with impaired pheomelanin pigmentation in chicken

Author

Bi, Huijuan, Tranell, Jonas, Harper, Dawn C., Lin, Weifeng, Li, Jingyi, Hellström, Anders R., Larsson, Mårten, Rubin, Carl-Johan, Wang, Chao, Sayyab, Shumaila, Kerje, Susanne, Bed'hom, Bertrand, Gourichon, David, Ito, Shosuke, Wakamatsu, Kazumasa, Tixier-Boichard, Michele, Marks, Michael S., Globisch, Daniel, Andersson, Leif, Bi, Huijuan, Tranell, Jonas, Harper, Dawn C., Lin, Weifeng, Li, Jingyi, Hellström, Anders R., Larsson, Mårten, Rubin, Carl-Johan, Wang, Chao, Sayyab, Shumaila, Kerje, Susanne, Bed'hom, Bertrand, Gourichon, David, Ito, Shosuke, Wakamatsu, Kazumasa, Tixier-Boichard, Michele, Marks, Michael S., Globisch, Daniel, and Andersson, Leif

Abstract

The biochemical pathway regulating the synthesis of yellow/red pheomelanin is less well characterized than the synthesis of black/brown eumelanin. Inhibitor of gold (IG phenotype) is a plumage colour variant in chicken that provides an opportunity to further explore this pathway since the recessive allele (IG) at this locus is associated with a defect in the production of pheomelanin. IG/IG homozygotes display a marked dilution of red pheomelanin pigmentation, whilst black pigmentation (eumelanin) is only slightly affected. Here we show that a 2-base pair insertion (frame-shift mutation) in the 5th exon of the Catechol-O-methyltransferase containing domain 1 gene (COMTD1), expected to cause a complete or partial loss-of-function of the COMTD1 enzyme, shows complete concordance with the IG phenotype within and across breeds. We show that the COMTD1 protein is localized to mitochondria in pigment cells. Knockout of Comtd1 in a mouse melanocytic cell line results in a reduction in pheomelanin metabolites and significant alterations in metabolites of glutamate/glutathione, riboflavin, and the tricarboxylic acid cycle. Furthermore, COMTD1 overexpression enhanced cellular proliferation following chemical-induced transfection, a potential inducer of oxidative stress. These observations suggest that COMTD1 plays a protective role for melanocytes against oxidative stress and that this supports their ability to produce pheomelanin., De två första författarna delar förstaförfattarskapet.

Published

2023

2. Improved Basic Cytogenetics Challenges Holocentricity of Butterfly Chromosomes

Author

Dutrillaux, Bernard, Dutrillaux, Anne-marie, Mcclure, Mélanie, Gèze, Marc, Elias, Marianne, Bed’hom, Bertrand, Dutrillaux, Bernard, Dutrillaux, Anne-marie, Mcclure, Mélanie, Gèze, Marc, Elias, Marianne, and Bed’hom, Bertrand

Abstract

Mitotic chromosomes of butterflies, which look like dots or short filaments in most published data, are generally considered to lack localised centromeres and thus to be holokinetic. This particularity, observed in a number of other invertebrates, is associated with meiotic particularities known as “inverted meiosis,” in which the first division is equational, i.e., centromere splitting-up and segregation of sister chromatids instead of homologous chromosomes. However, the accurate analysis of butterfly chromosomes is difficult because (1) their size is very small, equivalent to 2 bands of a mammalian metaphase chromosome, and (2) they lack satellite DNA/heterochromatin in putative centromere regions and therefore marked primary constrictions. Our improved conditions for basic chromosome preparations, here applied to 6 butterfly species belonging to families Nymphalidae and Pieridae challenges the holocentricity of their chromosomes: in spite of the absence of primary constrictions, sister chromatids are recurrently held together at definite positions during mitotic metaphase, which makes possible to establish karyotypes composed of acrocentric and submetacentric chromosomes. The total number of chromosomes per karyotype is roughly inversely proportional to that of non-acrocentric chromosomes, which suggests the occurrence of frequent robertsonian-like fusions or fissions during evolution. Furthermore, the behaviour and morphological changes of chromosomes along the various phases of meiosis do not seem to differ much from those of canonical meiosis. In particular, at metaphase II chromosomes clearly have 2 sister chromatids, which refutes that anaphase I was equational. Thus, we propose an alternative mechanism to holocentricity for explaining the large variations in chromosome numbers in butterflies: (1) in the ancestral karyotype, composed of about 62 mostly acrocentric chromosomes, the centromeres, devoid of centromeric heterochromatin/satellite DNA, were locate

Published

2023

3. A frame-shift mutation in COMTD1 is associated with impaired pheomelanin pigmentation in chicken

Author

Bi, Huijuan, Tranell, Jonas, Harper, Dawn C., Lin, Weifeng, Li, Jingyi, Hellström, Anders R., Larsson, Mårten, Rubin, Carl-Johan, Wang, Chao, Sayyab, Shumaila, Kerje, Susanne, Bed'hom, Bertrand, Gourichon, David, Ito, Shosuke, Wakamatsu, Kazumasa, Tixier-Boichard, Michele, Marks, Michael S., Globisch, Daniel, Andersson, Leif, Bi, Huijuan, Tranell, Jonas, Harper, Dawn C., Lin, Weifeng, Li, Jingyi, Hellström, Anders R., Larsson, Mårten, Rubin, Carl-Johan, Wang, Chao, Sayyab, Shumaila, Kerje, Susanne, Bed'hom, Bertrand, Gourichon, David, Ito, Shosuke, Wakamatsu, Kazumasa, Tixier-Boichard, Michele, Marks, Michael S., Globisch, Daniel, and Andersson, Leif

Abstract

The biochemical pathway regulating the synthesis of yellow/red pheomelanin is less well characterized than the synthesis of black/brown eumelanin. Inhibitor of gold (IG phenotype) is a plumage colour variant in chicken that provides an opportunity to further explore this pathway since the recessive allele (IG) at this locus is associated with a defect in the production of pheomelanin. IG/IG homozygotes display a marked dilution of red pheomelanin pigmentation, whilst black pigmentation (eumelanin) is only slightly affected. Here we show that a 2-base pair insertion (frame-shift mutation) in the 5th exon of the Catechol-O-methyltransferase containing domain 1 gene (COMTD1), expected to cause a complete or partial loss-of-function of the COMTD1 enzyme, shows complete concordance with the IG phenotype within and across breeds. We show that the COMTD1 protein is localized to mitochondria in pigment cells. Knockout of Comtd1 in a mouse melanocytic cell line results in a reduction in pheomelanin metabolites and significant alterations in metabolites of glutamate/glutathione, riboflavin, and the tricarboxylic acid cycle. Furthermore, COMTD1 overexpression enhanced cellular proliferation following chemical-induced transfection, a potential inducer of oxidative stress. These observations suggest that COMTD1 plays a protective role for melanocytes against oxidative stress and that this supports their ability to produce pheomelanin., De två första författarna delar förstaförfattarskapet.

Published

2023

4. A frame-shift mutation in COMTD1 is associated with impaired pheomelanin pigmentation in chicken

Author

Bi, Huijuan, Tranell, Jonas, Harper, Dawn C., Lin, Weifeng, Li, Jingyi, Hellström, Anders R., Larsson, Mårten, Rubin, Carl-Johan, Wang, Chao, Sayyab, Shumaila, Kerje, Susanne, Bed'hom, Bertrand, Gourichon, David, Ito, Shosuke, Wakamatsu, Kazumasa, Tixier-Boichard, Michele, Marks, Michael S., Globisch, Daniel, Andersson, Leif, Bi, Huijuan, Tranell, Jonas, Harper, Dawn C., Lin, Weifeng, Li, Jingyi, Hellström, Anders R., Larsson, Mårten, Rubin, Carl-Johan, Wang, Chao, Sayyab, Shumaila, Kerje, Susanne, Bed'hom, Bertrand, Gourichon, David, Ito, Shosuke, Wakamatsu, Kazumasa, Tixier-Boichard, Michele, Marks, Michael S., Globisch, Daniel, and Andersson, Leif

Abstract

The biochemical pathway regulating the synthesis of yellow/red pheomelanin is less well characterized than the synthesis of black/brown eumelanin. Inhibitor of gold (IG phenotype) is a plumage colour variant in chicken that provides an opportunity to further explore this pathway since the recessive allele (IG) at this locus is associated with a defect in the production of pheomelanin. IG/IG homozygotes display a marked dilution of red pheomelanin pigmentation, whilst black pigmentation (eumelanin) is only slightly affected. Here we show that a 2-base pair insertion (frame-shift mutation) in the 5th exon of the Catechol-O-methyltransferase containing domain 1 gene (COMTD1), expected to cause a complete or partial loss-of-function of the COMTD1 enzyme, shows complete concordance with the IG phenotype within and across breeds. We show that the COMTD1 protein is localized to mitochondria in pigment cells. Knockout of Comtd1 in a mouse melanocytic cell line results in a reduction in pheomelanin metabolites and significant alterations in metabolites of glutamate/glutathione, riboflavin, and the tricarboxylic acid cycle. Furthermore, COMTD1 overexpression enhanced cellular proliferation following chemical-induced transfection, a potential inducer of oxidative stress. These observations suggest that COMTD1 plays a protective role for melanocytes against oxidative stress and that this supports their ability to produce pheomelanin., De två första författarna delar förstaförfattarskapet.

Published

2023

5. A frame-shift mutation in COMTD1 is associated with impaired pheomelanin pigmentation in chicken

Author

Bi, Huijuan, Tranell, Jonas, Harper, Dawn C., Lin, Weifeng, Li, Jingyi, Hellström, Anders R., Larsson, Mårten, Rubin, Carl-Johan, Wang, Chao, Sayyab, Shumaila, Kerje, Susanne, Bed'hom, Bertrand, Gourichon, David, Ito, Shosuke, Wakamatsu, Kazumasa, Tixier-Boichard, Michele, Marks, Michael S., Globisch, Daniel, Andersson, Leif, Bi, Huijuan, Tranell, Jonas, Harper, Dawn C., Lin, Weifeng, Li, Jingyi, Hellström, Anders R., Larsson, Mårten, Rubin, Carl-Johan, Wang, Chao, Sayyab, Shumaila, Kerje, Susanne, Bed'hom, Bertrand, Gourichon, David, Ito, Shosuke, Wakamatsu, Kazumasa, Tixier-Boichard, Michele, Marks, Michael S., Globisch, Daniel, and Andersson, Leif

Abstract

The biochemical pathway regulating the synthesis of yellow/red pheomelanin is less well characterized than the synthesis of black/brown eumelanin. Inhibitor of gold (IG phenotype) is a plumage colour variant in chicken that provides an opportunity to further explore this pathway since the recessive allele (IG) at this locus is associated with a defect in the production of pheomelanin. IG/IG homozygotes display a marked dilution of red pheomelanin pigmentation, whilst black pigmentation (eumelanin) is only slightly affected. Here we show that a 2-base pair insertion (frame-shift mutation) in the 5th exon of the Catechol-O-methyltransferase containing domain 1 gene (COMTD1), expected to cause a complete or partial loss-of-function of the COMTD1 enzyme, shows complete concordance with the IG phenotype within and across breeds. We show that the COMTD1 protein is localized to mitochondria in pigment cells. Knockout of Comtd1 in a mouse melanocytic cell line results in a reduction in pheomelanin metabolites and significant alterations in metabolites of glutamate/glutathione, riboflavin, and the tricarboxylic acid cycle. Furthermore, COMTD1 overexpression enhanced cellular proliferation following chemical-induced transfection, a potential inducer of oxidative stress. These observations suggest that COMTD1 plays a protective role for melanocytes against oxidative stress and that this supports their ability to produce pheomelanin., De två första författarna delar förstaförfattarskapet.

Published

2023

6. Improved Basic Cytogenetics Challenges Holocentricity of Butterfly Chromosomes

Author

Dutrillaux, Bernard, Dutrillaux, Anne-marie, Mcclure, Mélanie, Gèze, Marc, Elias, Marianne, Bed’hom, Bertrand, Dutrillaux, Bernard, Dutrillaux, Anne-marie, Mcclure, Mélanie, Gèze, Marc, Elias, Marianne, and Bed’hom, Bertrand

Abstract

Mitotic chromosomes of butterflies, which look like dots or short filaments in most published data, are generally considered to lack localised centromeres and thus to be holokinetic. This particularity, observed in a number of other invertebrates, is associated with meiotic particularities known as “inverted meiosis,” in which the first division is equational, i.e., centromere splitting-up and segregation of sister chromatids instead of homologous chromosomes. However, the accurate analysis of butterfly chromosomes is difficult because (1) their size is very small, equivalent to 2 bands of a mammalian metaphase chromosome, and (2) they lack satellite DNA/heterochromatin in putative centromere regions and therefore marked primary constrictions. Our improved conditions for basic chromosome preparations, here applied to 6 butterfly species belonging to families Nymphalidae and Pieridae challenges the holocentricity of their chromosomes: in spite of the absence of primary constrictions, sister chromatids are recurrently held together at definite positions during mitotic metaphase, which makes possible to establish karyotypes composed of acrocentric and submetacentric chromosomes. The total number of chromosomes per karyotype is roughly inversely proportional to that of non-acrocentric chromosomes, which suggests the occurrence of frequent robertsonian-like fusions or fissions during evolution. Furthermore, the behaviour and morphological changes of chromosomes along the various phases of meiosis do not seem to differ much from those of canonical meiosis. In particular, at metaphase II chromosomes clearly have 2 sister chromatids, which refutes that anaphase I was equational. Thus, we propose an alternative mechanism to holocentricity for explaining the large variations in chromosome numbers in butterflies: (1) in the ancestral karyotype, composed of about 62 mostly acrocentric chromosomes, the centromeres, devoid of centromeric heterochromatin/satellite DNA, were locate

Published

2023

7. A frame-shift mutation in COMTD1 is associated with impaired pheomelanin pigmentation in chicken

Author

Bi, Huijuan, Tranell, Jonas, Harper, Dawn C., Lin, Weifeng, Li, Jingyi, Hellström, Anders R., Larsson, Mårten, Rubin, Carl-Johan, Wang, Chao, Sayyab, Shumaila, Kerje, Susanne, Bed'hom, Bertrand, Gourichon, David, Ito, Shosuke, Wakamatsu, Kazumasa, Tixier-Boichard, Michele, Marks, Michael S., Globisch, Daniel, Andersson, Leif, Bi, Huijuan, Tranell, Jonas, Harper, Dawn C., Lin, Weifeng, Li, Jingyi, Hellström, Anders R., Larsson, Mårten, Rubin, Carl-Johan, Wang, Chao, Sayyab, Shumaila, Kerje, Susanne, Bed'hom, Bertrand, Gourichon, David, Ito, Shosuke, Wakamatsu, Kazumasa, Tixier-Boichard, Michele, Marks, Michael S., Globisch, Daniel, and Andersson, Leif

Abstract

The biochemical pathway regulating the synthesis of yellow/red pheomelanin is less well characterized than the synthesis of black/brown eumelanin. Inhibitor of gold (IG phenotype) is a plumage colour variant in chicken that provides an opportunity to further explore this pathway since the recessive allele (IG) at this locus is associated with a defect in the production of pheomelanin. IG/IG homozygotes display a marked dilution of red pheomelanin pigmentation, whilst black pigmentation (eumelanin) is only slightly affected. Here we show that a 2-base pair insertion (frame-shift mutation) in the 5th exon of the Catechol-O-methyltransferase containing domain 1 gene (COMTD1), expected to cause a complete or partial loss-of-function of the COMTD1 enzyme, shows complete concordance with the IG phenotype within and across breeds. We show that the COMTD1 protein is localized to mitochondria in pigment cells. Knockout of Comtd1 in a mouse melanocytic cell line results in a reduction in pheomelanin metabolites and significant alterations in metabolites of glutamate/glutathione, riboflavin, and the tricarboxylic acid cycle. Furthermore, COMTD1 overexpression enhanced cellular proliferation following chemical-induced transfection, a potential inducer of oxidative stress. These observations suggest that COMTD1 plays a protective role for melanocytes against oxidative stress and that this supports their ability to produce pheomelanin., De två första författarna delar förstaförfattarskapet.

Published

2023

8. The European Reference Genome Atlas:piloting a decentralised approach to equitable biodiversity genomics

Author

Mc Cartney, Ann M, Formenti, Giulio, Mouton, Alice, Panis, Diego De, Marins, Luisa S, Leitão, Henrique G, Diedericks, Genevieve, Kirangwa, Joseph, Morselli, Marco, Salces-Ortiz, Judit, Escudero, Nuria, Iannucci, Alessio, Natali, Chiara, Svardal, Hannes, Fernández, Rosa, Pooter, Tim De, Joris, Geert, Strazisar, Mojca, Wood, Jo, Herron, Katie E, Seehausen, Ole, Watts, Phillip C, Shaw, Felix, Davey, Robert P, Minotto, Alice, Fernández, José M, Böhne, Astrid, Alegria, Carla, Alioto, Tyler, Alves, Paulo C, Amorim, Isabel R, Aury, Jean-Marc, Backstrom, Niclas, Baldrian, Petr, Baltrunaite, Laima, Barta, Endre, Bed’Hom, Bertrand, Belser, Caroline, Bergsten, Johannes, Bertrand, Laurie, Bilandžija, Helena, Binzer-Panchal, Mahesh, Bista, Iliana, Blaxter, Mark, Borges, Paulo AV, Dias, Guilherme Borges, Bosse, Mirte, Garg, Shilpa, Madsen, Ole, Stiller, Josefin, Mc Cartney, Ann M, Formenti, Giulio, Mouton, Alice, Panis, Diego De, Marins, Luisa S, Leitão, Henrique G, Diedericks, Genevieve, Kirangwa, Joseph, Morselli, Marco, Salces-Ortiz, Judit, Escudero, Nuria, Iannucci, Alessio, Natali, Chiara, Svardal, Hannes, Fernández, Rosa, Pooter, Tim De, Joris, Geert, Strazisar, Mojca, Wood, Jo, Herron, Katie E, Seehausen, Ole, Watts, Phillip C, Shaw, Felix, Davey, Robert P, Minotto, Alice, Fernández, José M, Böhne, Astrid, Alegria, Carla, Alioto, Tyler, Alves, Paulo C, Amorim, Isabel R, Aury, Jean-Marc, Backstrom, Niclas, Baldrian, Petr, Baltrunaite, Laima, Barta, Endre, Bed’Hom, Bertrand, Belser, Caroline, Bergsten, Johannes, Bertrand, Laurie, Bilandžija, Helena, Binzer-Panchal, Mahesh, Bista, Iliana, Blaxter, Mark, Borges, Paulo AV, Dias, Guilherme Borges, Bosse, Mirte, Garg, Shilpa, Madsen, Ole, and Stiller, Josefin

Abstract

A global genome database of all of Earth’s species diversity could be a treasure trove of scientific discoveries. However, regardless of the major advances in genome sequencing technologies, only a tiny fraction of species have genomic information available. To contribute to a more complete planetary genomic database, scientists and institutions across the world have united under the Earth BioGenome Project (EBP), which plans to sequence and assemble high-quality reference genomes for all 1.5 million recognized eukaryotic species through a stepwise phased approach. As the initiative transitions into Phase II, where 150,000 species are to be sequenced in just four years, worldwide participation in the project will be fundamental to success. As the European node of the EBP, the European Reference Genome Atlas (ERGA) seeks to implement a new decentralised, accessible, equitable and inclusive model for producing high-quality reference genomes, which will inform EBP as it scales. To embark on this mission, ERGA launched a Pilot Project to establish a network across Europe to develop and test the first infrastructure of its kind for the coordinated and distributed reference genome production on 98 European eukaryotic species from sample providers across 33 European countries. Here we outline the process and challenges faced during the development of a pilot infrastructure for the production of reference genome resources, and explore the effectiveness of this approach in terms of high-quality reference genome production, considering also equity and inclusion. The outcomes and lessons learned during this pilot provide a solid foundation for ERGA while offering key learnings to other transnational and national genomic resource projects.Competing Interest StatementThe authors have declared no competing interest.Biodiversity genomicsThe application of genomic methods to research biodiversity.BUSCOA bioinformatic method (Benchmarking Universal Single-Copy Orthologues) used to e

Published

2023

9. The European Reference Genome Atlas:piloting a decentralised approach to equitable biodiversity genomics

Author

Mc Cartney, Ann M, Formenti, Giulio, Mouton, Alice, Panis, Diego De, Marins, Luisa S, Leitão, Henrique G, Diedericks, Genevieve, Kirangwa, Joseph, Morselli, Marco, Salces-Ortiz, Judit, Escudero, Nuria, Iannucci, Alessio, Natali, Chiara, Svardal, Hannes, Fernández, Rosa, Pooter, Tim De, Joris, Geert, Strazisar, Mojca, Wood, Jo, Herron, Katie E, Seehausen, Ole, Watts, Phillip C, Shaw, Felix, Davey, Robert P, Minotto, Alice, Fernández, José M, Böhne, Astrid, Alegria, Carla, Alioto, Tyler, Alves, Paulo C, Amorim, Isabel R, Aury, Jean-Marc, Backstrom, Niclas, Baldrian, Petr, Baltrunaite, Laima, Barta, Endre, Bed’Hom, Bertrand, Belser, Caroline, Bergsten, Johannes, Bertrand, Laurie, Bilandžija, Helena, Binzer-Panchal, Mahesh, Bista, Iliana, Blaxter, Mark, Borges, Paulo AV, Dias, Guilherme Borges, Bosse, Mirte, Garg, Shilpa, Madsen, Ole, Stiller, Josefin, Mc Cartney, Ann M, Formenti, Giulio, Mouton, Alice, Panis, Diego De, Marins, Luisa S, Leitão, Henrique G, Diedericks, Genevieve, Kirangwa, Joseph, Morselli, Marco, Salces-Ortiz, Judit, Escudero, Nuria, Iannucci, Alessio, Natali, Chiara, Svardal, Hannes, Fernández, Rosa, Pooter, Tim De, Joris, Geert, Strazisar, Mojca, Wood, Jo, Herron, Katie E, Seehausen, Ole, Watts, Phillip C, Shaw, Felix, Davey, Robert P, Minotto, Alice, Fernández, José M, Böhne, Astrid, Alegria, Carla, Alioto, Tyler, Alves, Paulo C, Amorim, Isabel R, Aury, Jean-Marc, Backstrom, Niclas, Baldrian, Petr, Baltrunaite, Laima, Barta, Endre, Bed’Hom, Bertrand, Belser, Caroline, Bergsten, Johannes, Bertrand, Laurie, Bilandžija, Helena, Binzer-Panchal, Mahesh, Bista, Iliana, Blaxter, Mark, Borges, Paulo AV, Dias, Guilherme Borges, Bosse, Mirte, Garg, Shilpa, Madsen, Ole, and Stiller, Josefin

Abstract

A global genome database of all of Earth’s species diversity could be a treasure trove of scientific discoveries. However, regardless of the major advances in genome sequencing technologies, only a tiny fraction of species have genomic information available. To contribute to a more complete planetary genomic database, scientists and institutions across the world have united under the Earth BioGenome Project (EBP), which plans to sequence and assemble high-quality reference genomes for all 1.5 million recognized eukaryotic species through a stepwise phased approach. As the initiative transitions into Phase II, where 150,000 species are to be sequenced in just four years, worldwide participation in the project will be fundamental to success. As the European node of the EBP, the European Reference Genome Atlas (ERGA) seeks to implement a new decentralised, accessible, equitable and inclusive model for producing high-quality reference genomes, which will inform EBP as it scales. To embark on this mission, ERGA launched a Pilot Project to establish a network across Europe to develop and test the first infrastructure of its kind for the coordinated and distributed reference genome production on 98 European eukaryotic species from sample providers across 33 European countries. Here we outline the process and challenges faced during the development of a pilot infrastructure for the production of reference genome resources, and explore the effectiveness of this approach in terms of high-quality reference genome production, considering also equity and inclusion. The outcomes and lessons learned during this pilot provide a solid foundation for ERGA while offering key learnings to other transnational and national genomic resource projects.Competing Interest StatementThe authors have declared no competing interest.Biodiversity genomicsThe application of genomic methods to research biodiversity.BUSCOA bioinformatic method (Benchmarking Universal Single-Copy Orthologues) used to e

Published

2023

10. The feather pattern autosomal barring in chicken is strongly associated with segregation at the MC1R locus

Author

Thalmann, Doreen Schwochow, Bornelov, Susanne, Jiang, Tingxin, Li, Jingyi, Gourichon, David, Bed'Hom, Bertrand, Dorshorst, Benjamin J., Chuong, Cheng-Ming, Tixier-Boichard, Michele, Andersson, Leif, Thalmann, Doreen Schwochow, Bornelov, Susanne, Jiang, Tingxin, Li, Jingyi, Gourichon, David, Bed'Hom, Bertrand, Dorshorst, Benjamin J., Chuong, Cheng-Ming, Tixier-Boichard, Michele, and Andersson, Leif

Abstract

Color patterns within individual feathers are common in birds but little is known about the genetic mechanisms causing such patterns. Here, we investigate the genetic basis for autosomal barring in chicken, a horizontal striping pattern on individual feathers. Using an informative backcross, we demonstrate that the MC1R locus is strongly associated with this phenotype. A deletion at SOX10, underlying the dark brown phenotype on its own, affects the manifestation of the barring pattern. The coding variant L133Q in MC1R is the most likely causal mutation for autosomal barring in this pedigree. Furthermore, a genetic screen across six different breeds showing different patterning phenotypes revealed that the most striking shared characteristics among these breeds were that they all carried the MC1R alleles Birchen or brown. Our data suggest that the presence of activating MC1R mutations enhancing pigment synthesis is an important mechanism underlying pigmentation patterns on individual feathers in chicken. We propose that MC1R and its antagonist ASIP play a critical role for determining within-feather pigmentation patterns in birds by acting as activator and inhibitor possibly in a Turing reaction-diffusion model.

Published

2021

11. The feather pattern autosomal barring in chicken is strongly associated with segregation at the MC1R locus

Author

Schwochow, Doreen, Bornelöv, Susanne, Jiang, Tingxing, Li, Jingyi, Gourichon, David, Bed'Hom, Bertrand, Dorshorst, Ben J., Chuong, Cheng-Ming, Tixier-Boichard, Michele, Andersson, Leif, Schwochow, Doreen, Bornelöv, Susanne, Jiang, Tingxing, Li, Jingyi, Gourichon, David, Bed'Hom, Bertrand, Dorshorst, Ben J., Chuong, Cheng-Ming, Tixier-Boichard, Michele, and Andersson, Leif

Abstract

Color patterns within individual feathers are common in birds but little is known about the genetic mechanisms causing such patterns. Here, we investigate the genetic basis for autosomal barring in chicken, a horizontal striping pattern on individual feathers. Using an informative backcross, we demonstrate that the MC1R locus is strongly associated with this phenotype. A deletion at SOX10, underlying the dark brown phenotype on its own, affects the manifestation of the barring pattern. The coding variant L133Q in MC1R is the most likely causal mutation for autosomal barring in this pedigree. Furthermore, a genetic screen across six different breeds showing different patterning phenotypes revealed that the most striking shared characteristics among these breeds were that they all carried the MC1R alleles Birchen or brown. Our data suggest that the presence of activating MC1R mutations enhancing pigment synthesis is an important mechanism underlying pigmentation patterns on individual feathers in chicken. We propose that MC1R and its antagonist ASIP play a critical role for determining within-feather pigmentation patterns in birds by acting as activator and inhibitor possibly in a Turing reaction-diffusion model.

Published

2021

12. The feather pattern autosomal barring in chicken is strongly associated with segregation at the MC1R locus

Author

Schwochow, Doreen, Bornelöv, Susanne, Jiang, Tingxing, Li, Jingyi, Gourichon, David, Bed'Hom, Bertrand, Dorshorst, Ben J., Chuong, Cheng-Ming, Tixier-Boichard, Michele, Andersson, Leif, Schwochow, Doreen, Bornelöv, Susanne, Jiang, Tingxing, Li, Jingyi, Gourichon, David, Bed'Hom, Bertrand, Dorshorst, Ben J., Chuong, Cheng-Ming, Tixier-Boichard, Michele, and Andersson, Leif

Abstract

Color patterns within individual feathers are common in birds but little is known about the genetic mechanisms causing such patterns. Here, we investigate the genetic basis for autosomal barring in chicken, a horizontal striping pattern on individual feathers. Using an informative backcross, we demonstrate that the MC1R locus is strongly associated with this phenotype. A deletion at SOX10, underlying the dark brown phenotype on its own, affects the manifestation of the barring pattern. The coding variant L133Q in MC1R is the most likely causal mutation for autosomal barring in this pedigree. Furthermore, a genetic screen across six different breeds showing different patterning phenotypes revealed that the most striking shared characteristics among these breeds were that they all carried the MC1R alleles Birchen or brown. Our data suggest that the presence of activating MC1R mutations enhancing pigment synthesis is an important mechanism underlying pigmentation patterns on individual feathers in chicken. We propose that MC1R and its antagonist ASIP play a critical role for determining within-feather pigmentation patterns in birds by acting as activator and inhibitor possibly in a Turing reaction-diffusion model.

Published

2021

13. The feather pattern autosomal barring in chicken is strongly associated with segregation at the MC1R locus

Author

Schwochow, Doreen, Bornelöv, Susanne, Jiang, Tingxing, Li, Jingyi, Gourichon, David, Bed'Hom, Bertrand, Dorshorst, Ben J., Chuong, Cheng-Ming, Tixier-Boichard, Michele, Andersson, Leif, Schwochow, Doreen, Bornelöv, Susanne, Jiang, Tingxing, Li, Jingyi, Gourichon, David, Bed'Hom, Bertrand, Dorshorst, Ben J., Chuong, Cheng-Ming, Tixier-Boichard, Michele, and Andersson, Leif

Abstract

Color patterns within individual feathers are common in birds but little is known about the genetic mechanisms causing such patterns. Here, we investigate the genetic basis for autosomal barring in chicken, a horizontal striping pattern on individual feathers. Using an informative backcross, we demonstrate that the MC1R locus is strongly associated with this phenotype. A deletion at SOX10, underlying the dark brown phenotype on its own, affects the manifestation of the barring pattern. The coding variant L133Q in MC1R is the most likely causal mutation for autosomal barring in this pedigree. Furthermore, a genetic screen across six different breeds showing different patterning phenotypes revealed that the most striking shared characteristics among these breeds were that they all carried the MC1R alleles Birchen or brown. Our data suggest that the presence of activating MC1R mutations enhancing pigment synthesis is an important mechanism underlying pigmentation patterns on individual feathers in chicken. We propose that MC1R and its antagonist ASIP play a critical role for determining within-feather pigmentation patterns in birds by acting as activator and inhibitor possibly in a Turing reaction-diffusion model.

Published

2021

14. The feather pattern autosomal barring in chicken is strongly associated with segregation at the MC1R locus

Author

Schwochow, Doreen, Bornelöv, Susanne, Jiang, Tingxing, Li, Jingyi, Gourichon, David, Bed'Hom, Bertrand, Dorshorst, Ben J., Chuong, Cheng-Ming, Tixier-Boichard, Michele, Andersson, Leif, Schwochow, Doreen, Bornelöv, Susanne, Jiang, Tingxing, Li, Jingyi, Gourichon, David, Bed'Hom, Bertrand, Dorshorst, Ben J., Chuong, Cheng-Ming, Tixier-Boichard, Michele, and Andersson, Leif

Abstract

Color patterns within individual feathers are common in birds but little is known about the genetic mechanisms causing such patterns. Here, we investigate the genetic basis for autosomal barring in chicken, a horizontal striping pattern on individual feathers. Using an informative backcross, we demonstrate that the MC1R locus is strongly associated with this phenotype. A deletion at SOX10, underlying the dark brown phenotype on its own, affects the manifestation of the barring pattern. The coding variant L133Q in MC1R is the most likely causal mutation for autosomal barring in this pedigree. Furthermore, a genetic screen across six different breeds showing different patterning phenotypes revealed that the most striking shared characteristics among these breeds were that they all carried the MC1R alleles Birchen or brown. Our data suggest that the presence of activating MC1R mutations enhancing pigment synthesis is an important mechanism underlying pigmentation patterns on individual feathers in chicken. We propose that MC1R and its antagonist ASIP play a critical role for determining within-feather pigmentation patterns in birds by acting as activator and inhibitor possibly in a Turing reaction-diffusion model.

Published

2021

15. The feather pattern autosomal barring in chicken is strongly associated with segregation at the MC1R locus

Author

Animal and Poultry Sciences, Thalmann, Doreen Schwochow, Bornelov, Susanne, Jiang, Tingxin, Li, Jingyi, Gourichon, David, Bed'Hom, Bertrand, Dorshorst, Benjamin J., Chuong, Cheng-Ming, Tixier-Boichard, Michele, Andersson, Leif, Animal and Poultry Sciences, Thalmann, Doreen Schwochow, Bornelov, Susanne, Jiang, Tingxin, Li, Jingyi, Gourichon, David, Bed'Hom, Bertrand, Dorshorst, Benjamin J., Chuong, Cheng-Ming, Tixier-Boichard, Michele, and Andersson, Leif

Abstract

Color patterns within individual feathers are common in birds but little is known about the genetic mechanisms causing such patterns. Here, we investigate the genetic basis for autosomal barring in chicken, a horizontal striping pattern on individual feathers. Using an informative backcross, we demonstrate that the MC1R locus is strongly associated with this phenotype. A deletion at SOX10, underlying the dark brown phenotype on its own, affects the manifestation of the barring pattern. The coding variant L133Q in MC1R is the most likely causal mutation for autosomal barring in this pedigree. Furthermore, a genetic screen across six different breeds showing different patterning phenotypes revealed that the most striking shared characteristics among these breeds were that they all carried the MC1R alleles Birchen or brown. Our data suggest that the presence of activating MC1R mutations enhancing pigment synthesis is an important mechanism underlying pigmentation patterns on individual feathers in chicken. We propose that MC1R and its antagonist ASIP play a critical role for determining within-feather pigmentation patterns in birds by acting as activator and inhibitor possibly in a Turing reaction-diffusion model.

Published

2021

16. The feather pattern autosomal barring in chicken is strongly associated with segregation at the MC1R locus

Author

Schwochow, Doreen, Bornelöv, Susanne, Jiang, Tingxing, Li, Jingyi, Gourichon, David, Bed'Hom, Bertrand, Dorshorst, Ben J., Chuong, Cheng-Ming, Tixier-Boichard, Michele, Andersson, Leif, Schwochow, Doreen, Bornelöv, Susanne, Jiang, Tingxing, Li, Jingyi, Gourichon, David, Bed'Hom, Bertrand, Dorshorst, Ben J., Chuong, Cheng-Ming, Tixier-Boichard, Michele, and Andersson, Leif

Abstract

Color patterns within individual feathers are common in birds but little is known about the genetic mechanisms causing such patterns. Here, we investigate the genetic basis for autosomal barring in chicken, a horizontal striping pattern on individual feathers. Using an informative backcross, we demonstrate that the MC1R locus is strongly associated with this phenotype. A deletion at SOX10, underlying the dark brown phenotype on its own, affects the manifestation of the barring pattern. The coding variant L133Q in MC1R is the most likely causal mutation for autosomal barring in this pedigree. Furthermore, a genetic screen across six different breeds showing different patterning phenotypes revealed that the most striking shared characteristics among these breeds were that they all carried the MC1R alleles Birchen or brown. Our data suggest that the presence of activating MC1R mutations enhancing pigment synthesis is an important mechanism underlying pigmentation patterns on individual feathers in chicken. We propose that MC1R and its antagonist ASIP play a critical role for determining within-feather pigmentation patterns in birds by acting as activator and inhibitor possibly in a Turing reaction-diffusion model.

Published

2021

17. A missense mutation in TYRP1 causes the chocolate plumage color in chicken and alters melanosome structure

Author

Li, Jingyi, Bed'hom, Bertrand, Marthey, Sylvain, Valade, Mathieu, Dureux, Audrey, Moroldo, Marco, Pechoux, Christine, Coville, Jean-Luc, Gourichon, David, Vieaud, Agathe, Dorshorst, Ben, Andersson, Leif, Tixier-Boichard, Michele, Li, Jingyi, Bed'hom, Bertrand, Marthey, Sylvain, Valade, Mathieu, Dureux, Audrey, Moroldo, Marco, Pechoux, Christine, Coville, Jean-Luc, Gourichon, David, Vieaud, Agathe, Dorshorst, Ben, Andersson, Leif, and Tixier-Boichard, Michele

Abstract

The chocolate plumage color in chickens is due to a sex-linked recessive mutation, choc, which dilutes eumelanin pigmentation. Because TYRP1 is sex-linked in chickens, and TYRP1 mutations determine brown coat color in mammals, TYRP1 appeared as the obvious candidate gene for the choc mutation. By combining gene mapping with gene capture, a complete association was identified between the chocolate phenotype and a missense mutation leading to a His214Asn change in the ZnA zinc-binding domain of the protein. A diagnostic test confirmed complete association by screening 428 non-chocolate chickens of various origins. This is the first TYRP1 mutation described in the chicken. Electron microscopy analysis showed that melanosomes were more numerous in feather follicles of chocolate chickens but exhibited an abnormal structure characterized by a granular content and an irregular shape. A similar altered morphology was observed on melanosomes of another TYRP1 mutant in birds, the roux mutation of the quail.

Published

2019

18. The evolution of Sex-linked barring alleles in chickens involves both regulatory and coding changes in CDKN2A

Author

Thalmann, Doreen Schwochow, Ring, Henrik, Sundström, Elisabeth, Cao, Xiaofang, Larsson, Mårten, Kerje, Susanne, Höglund, Andrey, Fogelholm, Jesper, Wright, Dominic, Jemth, Per, Hallböök, Finn, Bed'Hom, Bertrand, Dorshorst, Ben, Tixier-Boichard, Michele, Andersson, Leif, Thalmann, Doreen Schwochow, Ring, Henrik, Sundström, Elisabeth, Cao, Xiaofang, Larsson, Mårten, Kerje, Susanne, Höglund, Andrey, Fogelholm, Jesper, Wright, Dominic, Jemth, Per, Hallböök, Finn, Bed'Hom, Bertrand, Dorshorst, Ben, Tixier-Boichard, Michele, and Andersson, Leif

Abstract

Sex-linked barring is a fascinating plumage pattern in chickens recently shown to be associated with two non-coding and two missense mutations affecting the ARF transcript at the CDKN2A tumor suppressor locus. It however remained a mystery whether all four mutations are indeed causative and how they contribute to the barring phenotype. Here, we show that Sex-linked barring is genetically heterogeneous, and that the mutations form three functionally different variant alleles. The B0 allele carries only the two non-coding changes and is associated with the most dilute barring pattern, whereas the B1 and B2 alleles carry both the two non-coding changes and one each of the two missense mutations causing the Sex-linked barring and Sex-linked dilution phenotypes, respectively. The data are consistent with evolution of alleles where the non-coding changes occurred first followed by the two missense mutations that resulted in a phenotype more appealing to humans. We show that one or both of the non-coding changes are cis-regulatory mutations causing a higher CDKN2A expression, whereas the missense mutations reduce the ability of ARF to interact with MDM2. Caspase assays for all genotypes revealed no apoptotic events and our results are consistent with a recent study indicating that the loss of melanocyte progenitors in Sex-linked barring in chicken is caused by premature differentiation and not apoptosis. Our results show that CDKN2A is a major locus driving the differentiation of avian melanocytes in a temporal and spatial manner.

Published

2017

19. The evolution of Sex-linked barring alleles in chickens involves both regulatory and coding changes in CDKN2A

Author

Thalmann, Doreen Schwochow, Ring, Henrik, Sundström, Elisabeth, Cao, Xiaofang, Larsson, Mårten, Kerje, Susanne, Höglund, Andrey, Fogelholm, Jesper, Wright, Dominic, Jemth, Per, Hallböök, Finn, Bed'Hom, Bertrand, Dorshorst, Ben, Tixier-Boichard, Michele, Andersson, Leif, Thalmann, Doreen Schwochow, Ring, Henrik, Sundström, Elisabeth, Cao, Xiaofang, Larsson, Mårten, Kerje, Susanne, Höglund, Andrey, Fogelholm, Jesper, Wright, Dominic, Jemth, Per, Hallböök, Finn, Bed'Hom, Bertrand, Dorshorst, Ben, Tixier-Boichard, Michele, and Andersson, Leif

Abstract

Sex-linked barring is a fascinating plumage pattern in chickens recently shown to be associated with two non-coding and two missense mutations affecting the ARF transcript at the CDKN2A tumor suppressor locus. It however remained a mystery whether all four mutations are indeed causative and how they contribute to the barring phenotype. Here, we show that Sex-linked barring is genetically heterogeneous, and that the mutations form three functionally different variant alleles. The B0 allele carries only the two non-coding changes and is associated with the most dilute barring pattern, whereas the B1 and B2 alleles carry both the two non-coding changes and one each of the two missense mutations causing the Sex-linked barring and Sex-linked dilution phenotypes, respectively. The data are consistent with evolution of alleles where the non-coding changes occurred first followed by the two missense mutations that resulted in a phenotype more appealing to humans. We show that one or both of the non-coding changes are cis-regulatory mutations causing a higher CDKN2A expression, whereas the missense mutations reduce the ability of ARF to interact with MDM2. Caspase assays for all genotypes revealed no apoptotic events and our results are consistent with a recent study indicating that the loss of melanocyte progenitors in Sex-linked barring in chicken is caused by premature differentiation and not apoptosis. Our results show that CDKN2A is a major locus driving the differentiation of avian melanocytes in a temporal and spatial manner.

Published

2017

20. The evolution of Sex-linked barring alleles in chickens involves both regulatory and coding changes in CDKN2A

Author

Thalmann, Doreen Schwochow, Ring, Henrik, Sundström, Elisabeth, Cao, Xiaofang, Larsson, Mårten, Kerje, Susanne, Höglund, Andrey, Fogelholm, Jesper, Wright, Dominic, Jemth, Per, Hallböök, Finn, Bed'Hom, Bertrand, Dorshorst, Ben, Tixier-Boichard, Michele, Andersson, Leif, Thalmann, Doreen Schwochow, Ring, Henrik, Sundström, Elisabeth, Cao, Xiaofang, Larsson, Mårten, Kerje, Susanne, Höglund, Andrey, Fogelholm, Jesper, Wright, Dominic, Jemth, Per, Hallböök, Finn, Bed'Hom, Bertrand, Dorshorst, Ben, Tixier-Boichard, Michele, and Andersson, Leif

Abstract

Sex-linked barring is a fascinating plumage pattern in chickens recently shown to be associated with two non-coding and two missense mutations affecting the ARF transcript at the CDKN2A tumor suppressor locus. It however remained a mystery whether all four mutations are indeed causative and how they contribute to the barring phenotype. Here, we show that Sex-linked barring is genetically heterogeneous, and that the mutations form three functionally different variant alleles. The B0 allele carries only the two non-coding changes and is associated with the most dilute barring pattern, whereas the B1 and B2 alleles carry both the two non-coding changes and one each of the two missense mutations causing the Sex-linked barring and Sex-linked dilution phenotypes, respectively. The data are consistent with evolution of alleles where the non-coding changes occurred first followed by the two missense mutations that resulted in a phenotype more appealing to humans. We show that one or both of the non-coding changes are cis-regulatory mutations causing a higher CDKN2A expression, whereas the missense mutations reduce the ability of ARF to interact with MDM2. Caspase assays for all genotypes revealed no apoptotic events and our results are consistent with a recent study indicating that the loss of melanocyte progenitors in Sex-linked barring in chicken is caused by premature differentiation and not apoptosis. Our results show that CDKN2A is a major locus driving the differentiation of avian melanocytes in a temporal and spatial manner.

Published

2017

21. The evolution of Sex-linked barring alleles in chickens involves both regulatory and coding changes in CDKN2A

Author

Thalmann, Doreen Schwochow, Ring, Henrik, Sundstrom, Elisabeth, Cao, Xiaofang, Larsson, Marten, Kerje, Susanne, Höglund, Andrey, Fogelholm, Jesper, Wright, Dominic, Jemth, Per, Hallböök, Finn, Bed'Hom, Bertrand, Dorshorst, Benjamin J., Tixier-Boichard, Michele, Andersson, Leif, Thalmann, Doreen Schwochow, Ring, Henrik, Sundstrom, Elisabeth, Cao, Xiaofang, Larsson, Marten, Kerje, Susanne, Höglund, Andrey, Fogelholm, Jesper, Wright, Dominic, Jemth, Per, Hallböök, Finn, Bed'Hom, Bertrand, Dorshorst, Benjamin J., Tixier-Boichard, Michele, and Andersson, Leif

Abstract

Sex-linked barring is a fascinating plumage pattern in chickens recently shown to be associated with two non-coding and two missense mutations affecting the ARF transcript at the CDKN2A tumor suppressor locus. It however remained a mystery whether all four mutations are indeed causative and how they contribute to the barring phenotype. Here, we show that Sex-linked barring is genetically heterogeneous, and that the mutations form three functionally different variant alleles. The B0 allele carries only the two non-coding changes and is associated with the most dilute barring pattern, whereas the B1 and B2 alleles carry both the two non-coding changes and one each of the two missense mutations causing the Sex-linked barring and Sex-linked dilution phenotypes, respectively. The data are consistent with evolution of alleles where the non-coding changes occurred first followed by the two missense mutations that resulted in a phenotype more appealing to humans. We show that one or both of the non-coding changes are cis-regulatory mutations causing a higher CDKN2A expression, whereas the missense mutations reduce the ability of ARF to interact with MDM2. Caspase assays for all genotypes revealed no apoptotic events and our results are consistent with a recent study indicating that the loss of melanocyte progenitors in Sex-linked barring in chicken is caused by premature differentiation and not apoptosis. Our results show that CDKN2A is a major locus driving the differentiation of avian melanocytes in a temporal and spatial manner.

Published

2017

22. The evolution of Sex-linked barring alleles in chickens involves both regulatory and coding changes in CDKN2A

Author

Thalmann, Doreen Schwochow, Ring, Henrik, Sundström, Elisabeth, Cao, Xiaofang, Larsson, Mårten, Kerje, Susanne, Höglund, Andrey, Fogelholm, Jesper, Wright, Dominic, Jemth, Per, Hallböök, Finn, Bed'Hom, Bertrand, Dorshorst, Ben, Tixier-Boichard, Michele, Andersson, Leif, Thalmann, Doreen Schwochow, Ring, Henrik, Sundström, Elisabeth, Cao, Xiaofang, Larsson, Mårten, Kerje, Susanne, Höglund, Andrey, Fogelholm, Jesper, Wright, Dominic, Jemth, Per, Hallböök, Finn, Bed'Hom, Bertrand, Dorshorst, Ben, Tixier-Boichard, Michele, and Andersson, Leif

Abstract

Sex-linked barring is a fascinating plumage pattern in chickens recently shown to be associated with two non-coding and two missense mutations affecting the ARF transcript at the CDKN2A tumor suppressor locus. It however remained a mystery whether all four mutations are indeed causative and how they contribute to the barring phenotype. Here, we show that Sex-linked barring is genetically heterogeneous, and that the mutations form three functionally different variant alleles. The B0 allele carries only the two non-coding changes and is associated with the most dilute barring pattern, whereas the B1 and B2 alleles carry both the two non-coding changes and one each of the two missense mutations causing the Sex-linked barring and Sex-linked dilution phenotypes, respectively. The data are consistent with evolution of alleles where the non-coding changes occurred first followed by the two missense mutations that resulted in a phenotype more appealing to humans. We show that one or both of the non-coding changes are cis-regulatory mutations causing a higher CDKN2A expression, whereas the missense mutations reduce the ability of ARF to interact with MDM2. Caspase assays for all genotypes revealed no apoptotic events and our results are consistent with a recent study indicating that the loss of melanocyte progenitors in Sex-linked barring in chicken is caused by premature differentiation and not apoptosis. Our results show that CDKN2A is a major locus driving the differentiation of avian melanocytes in a temporal and spatial manner.

Published

2017

23. The evolution of Sex-linked barring alleles in chickens involves both regulatory and coding changes in CDKN2A

Author

Animal and Poultry Sciences, Thalmann, Doreen Schwochow, Ring, Henrik, Sundstrom, Elisabeth, Cao, Xiaofang, Larsson, Marten, Kerje, Susanne, Höglund, Andrey, Fogelholm, Jesper, Wright, Dominic, Jemth, Per, Hallböök, Finn, Bed'Hom, Bertrand, Dorshorst, Benjamin J., Tixier-Boichard, Michele, Andersson, Leif, Animal and Poultry Sciences, Thalmann, Doreen Schwochow, Ring, Henrik, Sundstrom, Elisabeth, Cao, Xiaofang, Larsson, Marten, Kerje, Susanne, Höglund, Andrey, Fogelholm, Jesper, Wright, Dominic, Jemth, Per, Hallböök, Finn, Bed'Hom, Bertrand, Dorshorst, Benjamin J., Tixier-Boichard, Michele, and Andersson, Leif

Abstract

Sex-linked barring is a fascinating plumage pattern in chickens recently shown to be associated with two non-coding and two missense mutations affecting the ARF transcript at the CDKN2A tumor suppressor locus. It however remained a mystery whether all four mutations are indeed causative and how they contribute to the barring phenotype. Here, we show that Sex-linked barring is genetically heterogeneous, and that the mutations form three functionally different variant alleles. The B0 allele carries only the two non-coding changes and is associated with the most dilute barring pattern, whereas the B1 and B2 alleles carry both the two non-coding changes and one each of the two missense mutations causing the Sex-linked barring and Sex-linked dilution phenotypes, respectively. The data are consistent with evolution of alleles where the non-coding changes occurred first followed by the two missense mutations that resulted in a phenotype more appealing to humans. We show that one or both of the non-coding changes are cis-regulatory mutations causing a higher CDKN2A expression, whereas the missense mutations reduce the ability of ARF to interact with MDM2. Caspase assays for all genotypes revealed no apoptotic events and our results are consistent with a recent study indicating that the loss of melanocyte progenitors in Sex-linked barring in chicken is caused by premature differentiation and not apoptosis. Our results show that CDKN2A is a major locus driving the differentiation of avian melanocytes in a temporal and spatial manner.

Published

2017

24. The evolution of Sex-linked barring alleles in chickens involves both regulatory and coding changes in CDKN2A

Author

Thalmann, Doreen Schwochow, Ring, Henrik, Sundström, Elisabeth, Cao, Xiaofang, Larsson, Mårten, Kerje, Susanne, Höglund, Andrey, Fogelholm, Jesper, Wright, Dominic, Jemth, Per, Hallböök, Finn, Bed'Hom, Bertrand, Dorshorst, Ben, Tixier-Boichard, Michele, Andersson, Leif, Thalmann, Doreen Schwochow, Ring, Henrik, Sundström, Elisabeth, Cao, Xiaofang, Larsson, Mårten, Kerje, Susanne, Höglund, Andrey, Fogelholm, Jesper, Wright, Dominic, Jemth, Per, Hallböök, Finn, Bed'Hom, Bertrand, Dorshorst, Ben, Tixier-Boichard, Michele, and Andersson, Leif

Abstract

Sex-linked barring is a fascinating plumage pattern in chickens recently shown to be associated with two non-coding and two missense mutations affecting the ARF transcript at the CDKN2A tumor suppressor locus. It however remained a mystery whether all four mutations are indeed causative and how they contribute to the barring phenotype. Here, we show that Sex-linked barring is genetically heterogeneous, and that the mutations form three functionally different variant alleles. The B0 allele carries only the two non-coding changes and is associated with the most dilute barring pattern, whereas the B1 and B2 alleles carry both the two non-coding changes and one each of the two missense mutations causing the Sex-linked barring and Sex-linked dilution phenotypes, respectively. The data are consistent with evolution of alleles where the non-coding changes occurred first followed by the two missense mutations that resulted in a phenotype more appealing to humans. We show that one or both of the non-coding changes are cis-regulatory mutations causing a higher CDKN2A expression, whereas the missense mutations reduce the ability of ARF to interact with MDM2. Caspase assays for all genotypes revealed no apoptotic events and our results are consistent with a recent study indicating that the loss of melanocyte progenitors in Sex-linked barring in chicken is caused by premature differentiation and not apoptosis. Our results show that CDKN2A is a major locus driving the differentiation of avian melanocytes in a temporal and spatial manner.

Published

2017

25. Detection of QTL controlling digestive efficiency and anatomy of the digestive tract in chicken fed a wheat-based diet

Author

Tran, Son-Thanh, Narcy, Agnès, Carré, Bernard, Rideau, Nicole, Gilbert, Hélène, Demeure, Olivier, Bed'Hom, Bertrand, Chantry-Darmon, Céline, Boscher, Marie-Yvonne, Bastianelli, Denis, Sellier, Nadine, Chabault, Marie, Calenge, Fanny, Le Bihan-Duval, Elisabeth, Beaumont, Catherine, Mignon-Grasteau, Sandrine, Tran, Son-Thanh, Narcy, Agnès, Carré, Bernard, Rideau, Nicole, Gilbert, Hélène, Demeure, Olivier, Bed'Hom, Bertrand, Chantry-Darmon, Céline, Boscher, Marie-Yvonne, Bastianelli, Denis, Sellier, Nadine, Chabault, Marie, Calenge, Fanny, Le Bihan-Duval, Elisabeth, Beaumont, Catherine, and Mignon-Grasteau, Sandrine

Abstract

Background: Improving digestive efficiency is a major goal in poultry production, to reduce production costs, make possible the use of alternative feedstuffs and decrease the volume of manure produced. Since measuring digestive efficiency is difficult, identifying molecular markers associated with genes controlling this trait would be a valuable tool for selection. Detection of QTL (quantitative trait loci) was undertaken on 820 meat-type chickens in a F2 cross between D- and D+ lines divergently selected on low or high AMEn (apparent metabolizable energy value of diet corrected to 0 nitrogen balance) measured at three weeks in animals fed a low-quality diet. Birds were measured for 13 traits characterizing digestive efficiency (AMEn, coefficients of digestive utilization of starch, lipids, proteins and dry matter (CDUS, CDUL, CDUP, CDUDM)), anatomy of the digestive tract (relative weights of the proventriculus, gizzard and intestine and proventriculus plus gizzard (RPW, RGW, RIW, RPGW), relative length and density of the intestine (RIL, ID), ratio of proventriculus and gizzard to intestine weight (PG/I); and body weight at 23 days of age. Animals were genotyped for 6000 SNPs (single nucleotide polymorphisms) distributed on 28 autosomes, the Z chromosome and one unassigned linkage group. Results: Nine QTL for digestive efficiency traits, 11 QTL for anatomy-related traits and two QTL for body weight at 23 days of age were detected. On chromosome 20, two significant QTL at the genome level co-localized for CDUS and CDUDM, i.e. two traits that are highly correlated genetically. Moreover, on chromosome 16, chromosome-wide QTL for AMEn, CDUS, CDUDM and CDUP, on chromosomes 23 and 26, chromosome-wide QTL for CDUS, on chromosomes 16 and 26, co-localized QTL for digestive efficiency and the ratio of intestine length to body weight and on chromosome 27 a chromosome-wide QTL for CDUDM were identified. Conclusions: This study identified several regions of the chicken genome in

Published

2014

26. Detection of QTL controlling digestive efficiency and anatomy of the digestive tract in chicken fed a wheat-based diet

Author

Tran, Son-Thanh, Narcy, Agnès, Carré, Bernard, Rideau, Nicole, Gilbert, Hélène, Demeure, Olivier, Bed'Hom, Bertrand, Chantry-Darmon, Céline, Boscher, Marie-Yvonne, Bastianelli, Denis, Sellier, Nadine, Chabault, Marie, Calenge, Fanny, Le Bihan-Duval, Elisabeth, Beaumont, Catherine, Mignon-Grasteau, Sandrine, Tran, Son-Thanh, Narcy, Agnès, Carré, Bernard, Rideau, Nicole, Gilbert, Hélène, Demeure, Olivier, Bed'Hom, Bertrand, Chantry-Darmon, Céline, Boscher, Marie-Yvonne, Bastianelli, Denis, Sellier, Nadine, Chabault, Marie, Calenge, Fanny, Le Bihan-Duval, Elisabeth, Beaumont, Catherine, and Mignon-Grasteau, Sandrine

Abstract

Background: Improving digestive efficiency is a major goal in poultry production, to reduce production costs, make possible the use of alternative feedstuffs and decrease the volume of manure produced. Since measuring digestive efficiency is difficult, identifying molecular markers associated with genes controlling this trait would be a valuable tool for selection. Detection of QTL (quantitative trait loci) was undertaken on 820 meat-type chickens in a F2 cross between D- and D+ lines divergently selected on low or high AMEn (apparent metabolizable energy value of diet corrected to 0 nitrogen balance) measured at three weeks in animals fed a low-quality diet. Birds were measured for 13 traits characterizing digestive efficiency (AMEn, coefficients of digestive utilization of starch, lipids, proteins and dry matter (CDUS, CDUL, CDUP, CDUDM)), anatomy of the digestive tract (relative weights of the proventriculus, gizzard and intestine and proventriculus plus gizzard (RPW, RGW, RIW, RPGW), relative length and density of the intestine (RIL, ID), ratio of proventriculus and gizzard to intestine weight (PG/I); and body weight at 23 days of age. Animals were genotyped for 6000 SNPs (single nucleotide polymorphisms) distributed on 28 autosomes, the Z chromosome and one unassigned linkage group. Results: Nine QTL for digestive efficiency traits, 11 QTL for anatomy-related traits and two QTL for body weight at 23 days of age were detected. On chromosome 20, two significant QTL at the genome level co-localized for CDUS and CDUDM, i.e. two traits that are highly correlated genetically. Moreover, on chromosome 16, chromosome-wide QTL for AMEn, CDUS, CDUDM and CDUP, on chromosomes 23 and 26, chromosome-wide QTL for CDUS, on chromosomes 16 and 26, co-localized QTL for digestive efficiency and the ratio of intestine length to body weight and on chromosome 27 a chromosome-wide QTL for CDUDM were identified. Conclusions: This study identified several regions of the chicken genome in

Published

2014

27. Sonic Hedgehog-Signalling Patterns the Developing Chicken Comb as Revealed by Exploration of the Pea-comb Mutation

Author

Boije, Henrik, Harun-Or-Rashid, Mohammad, Lee, Yu-Jen, Imsland, Freyja, Bruneau, Nicolas, Vieaud, Agathe, Gourichon, David, Tixier-Boichard, Michèle, Bed’hom, Bertrand, Andersson, Leif, Hallböök, Finn, Boije, Henrik, Harun-Or-Rashid, Mohammad, Lee, Yu-Jen, Imsland, Freyja, Bruneau, Nicolas, Vieaud, Agathe, Gourichon, David, Tixier-Boichard, Michèle, Bed’hom, Bertrand, Andersson, Leif, and Hallböök, Finn

Abstract

The genetic basis and mechanisms behind the morphological variation observed throughout the animal kingdom is stillrelatively unknown. In the present work we have focused on the establishment of the chicken comb-morphology byexploring the Pea-comb mutant. The wild-type single-comb is reduced in size and distorted in the Pea-comb mutant. Peacombis formed by a lateral expansion of the central comb anlage into three ridges and is caused by a mutation in SOX5,which induces ectopic expression of the SOX5 transcription factor in mesenchyme under the developing comb. Analysis ofdifferential gene expression identified decreased Sonic hedgehog (SHH) receptor expression in Pea-comb mesenchyme. Byexperimentally blocking SHH with cyclopamine, the wild-type single-comb was transformed into a Pea-comb-likephenotype. The results show that the patterning of the chicken comb is under the control of SHH and suggest that ectopicSOX5 expression in the Pea-comb change the response of mesenchyme to SHH signalling with altered combmorphogenesis as a result. A role for the mesenchyme during comb morphogenesis is further supported by the recentfinding that another comb-mutant (Rose-comb), is caused by ectopic expression of a transcription factor in combmesenchyme. The present study does not only give knowledge about how the chicken comb is formed, it also adds to ourunderstanding how mutations or genetic polymorphisms may contribute to inherited variations in the human face.

Published

2012

28. The Rose-comb Mutation in Chickens Constitutes a Structural Rearrangement Causing Both Altered Comb Morphology and Defective Sperm Motility

Author

Imsland, Freyja, Feng, Chungang, Boije, Henrik, Bed'hom, Bertrand, Fillon, Valerie, Dorshorst, Ben, Rubin, Carl-Johan, Liu, Ranran, Gao, Yu, Gu, Xiaorong, Wang, Yanqiang, Gourichon, David, Zody, Michael C., Zecchin, William, Vieaud, Agathe, Tixier-Boichard, Michele, Hu, Xiaoxiang, Hallböök, Finn, Li, Ning, Andersson, Leif, Imsland, Freyja, Feng, Chungang, Boije, Henrik, Bed'hom, Bertrand, Fillon, Valerie, Dorshorst, Ben, Rubin, Carl-Johan, Liu, Ranran, Gao, Yu, Gu, Xiaorong, Wang, Yanqiang, Gourichon, David, Zody, Michael C., Zecchin, William, Vieaud, Agathe, Tixier-Boichard, Michele, Hu, Xiaoxiang, Hallböök, Finn, Li, Ning, and Andersson, Leif

Abstract

Rose-comb, a classical monogenic trait of chickens, is characterized by a drastically altered comb morphology compared to the single-combed wild-type. Here we show that Rose-comb is caused by a 7.4 Mb inversion on chromosome 7 and that a second Rose-comb allele arose by unequal crossing over between a Rose-comb and wild-type chromosome. The comb phenotype is caused by the relocalization of the MNR2 homeodomain protein gene leading to transient ectopic expression of MNR2 during comb development. We also provide a molecular explanation for the first example of epistatic interaction reported by Bateson and Punnett 104 years ago, namely that walnut-comb is caused by the combined effects of the Rose-comb and Pea-comb alleles. Transient ectopic expression of MNR2 and SOX5 (causing the Pea-comb phenotype) occurs in the same population of mesenchymal cells and with at least partially overlapping expression in individual cells in the comb primordium. Rose-comb has pleiotropic effects, as homozygosity in males has been associated with poor sperm motility. We postulate that this is caused by the disruption of the CCDC108 gene located at one of the inversion breakpoints. CCDC108 is a poorly characterized protein, but it contains a MSP (major sperm protein) domain and is expressed in testis. The study illustrates several characteristic features of the genetic diversity present in domestic animals, including the evolution of alleles by two or more consecutive mutations and the fact that structural changes have contributed to fast phenotypic evolution.

Published

2012

29. Sonic Hedgehog-Signalling Patterns the Developing Chicken Comb as Revealed by Exploration of the Pea-comb Mutation

Author

Boije, Henrik, Harun-Or-Rashid, Mohammad, Lee, Yu-Jen, Imsland, Freyja, Bruneau, Nicolas, Vieaud, Agathe, Gourichon, David, Tixier-Boichard, Michèle, Bed’hom, Bertrand, Andersson, Leif, Hallböök, Finn, Boije, Henrik, Harun-Or-Rashid, Mohammad, Lee, Yu-Jen, Imsland, Freyja, Bruneau, Nicolas, Vieaud, Agathe, Gourichon, David, Tixier-Boichard, Michèle, Bed’hom, Bertrand, Andersson, Leif, and Hallböök, Finn

Abstract

The genetic basis and mechanisms behind the morphological variation observed throughout the animal kingdom is stillrelatively unknown. In the present work we have focused on the establishment of the chicken comb-morphology byexploring the Pea-comb mutant. The wild-type single-comb is reduced in size and distorted in the Pea-comb mutant. Peacombis formed by a lateral expansion of the central comb anlage into three ridges and is caused by a mutation in SOX5,which induces ectopic expression of the SOX5 transcription factor in mesenchyme under the developing comb. Analysis ofdifferential gene expression identified decreased Sonic hedgehog (SHH) receptor expression in Pea-comb mesenchyme. Byexperimentally blocking SHH with cyclopamine, the wild-type single-comb was transformed into a Pea-comb-likephenotype. The results show that the patterning of the chicken comb is under the control of SHH and suggest that ectopicSOX5 expression in the Pea-comb change the response of mesenchyme to SHH signalling with altered combmorphogenesis as a result. A role for the mesenchyme during comb morphogenesis is further supported by the recentfinding that another comb-mutant (Rose-comb), is caused by ectopic expression of a transcription factor in combmesenchyme. The present study does not only give knowledge about how the chicken comb is formed, it also adds to ourunderstanding how mutations or genetic polymorphisms may contribute to inherited variations in the human face.

Published

2012

30. Sonic Hedgehog-Signalling Patterns the Developing Chicken Comb as Revealed by Exploration of the Pea-comb Mutation

Author

Boije, Henrik, Harun-Or-Rashid, Mohammad, Lee, Yu-Jen, Imsland, Freyja, Bruneau, Nicolas, Vieaud, Agathe, Gourichon, David, Tixier-Boichard, Michèle, Bed’hom, Bertrand, Andersson, Leif, Hallböök, Finn, Boije, Henrik, Harun-Or-Rashid, Mohammad, Lee, Yu-Jen, Imsland, Freyja, Bruneau, Nicolas, Vieaud, Agathe, Gourichon, David, Tixier-Boichard, Michèle, Bed’hom, Bertrand, Andersson, Leif, and Hallböök, Finn

Abstract

The genetic basis and mechanisms behind the morphological variation observed throughout the animal kingdom is stillrelatively unknown. In the present work we have focused on the establishment of the chicken comb-morphology byexploring the Pea-comb mutant. The wild-type single-comb is reduced in size and distorted in the Pea-comb mutant. Peacombis formed by a lateral expansion of the central comb anlage into three ridges and is caused by a mutation in SOX5,which induces ectopic expression of the SOX5 transcription factor in mesenchyme under the developing comb. Analysis ofdifferential gene expression identified decreased Sonic hedgehog (SHH) receptor expression in Pea-comb mesenchyme. Byexperimentally blocking SHH with cyclopamine, the wild-type single-comb was transformed into a Pea-comb-likephenotype. The results show that the patterning of the chicken comb is under the control of SHH and suggest that ectopicSOX5 expression in the Pea-comb change the response of mesenchyme to SHH signalling with altered combmorphogenesis as a result. A role for the mesenchyme during comb morphogenesis is further supported by the recentfinding that another comb-mutant (Rose-comb), is caused by ectopic expression of a transcription factor in combmesenchyme. The present study does not only give knowledge about how the chicken comb is formed, it also adds to ourunderstanding how mutations or genetic polymorphisms may contribute to inherited variations in the human face.

Published

2012

31. The Rose-comb Mutation in Chickens Constitutes a Structural Rearrangement Causing Both Altered Comb Morphology and Defective Sperm Motility

Author

Imsland, Freyja, Feng, Chungang, Boije, Henrik, Bed'hom, Bertrand, Fillon, Valerie, Dorshorst, Ben, Rubin, Carl-Johan, Liu, Ranran, Gao, Yu, Gu, Xiaorong, Wang, Yanqiang, Gourichon, David, Zody, Michael C., Zecchin, William, Vieaud, Agathe, Tixier-Boichard, Michele, Hu, Xiaoxiang, Hallböök, Finn, Li, Ning, Andersson, Leif, Imsland, Freyja, Feng, Chungang, Boije, Henrik, Bed'hom, Bertrand, Fillon, Valerie, Dorshorst, Ben, Rubin, Carl-Johan, Liu, Ranran, Gao, Yu, Gu, Xiaorong, Wang, Yanqiang, Gourichon, David, Zody, Michael C., Zecchin, William, Vieaud, Agathe, Tixier-Boichard, Michele, Hu, Xiaoxiang, Hallböök, Finn, Li, Ning, and Andersson, Leif

Abstract

Rose-comb, a classical monogenic trait of chickens, is characterized by a drastically altered comb morphology compared to the single-combed wild-type. Here we show that Rose-comb is caused by a 7.4 Mb inversion on chromosome 7 and that a second Rose-comb allele arose by unequal crossing over between a Rose-comb and wild-type chromosome. The comb phenotype is caused by the relocalization of the MNR2 homeodomain protein gene leading to transient ectopic expression of MNR2 during comb development. We also provide a molecular explanation for the first example of epistatic interaction reported by Bateson and Punnett 104 years ago, namely that walnut-comb is caused by the combined effects of the Rose-comb and Pea-comb alleles. Transient ectopic expression of MNR2 and SOX5 (causing the Pea-comb phenotype) occurs in the same population of mesenchymal cells and with at least partially overlapping expression in individual cells in the comb primordium. Rose-comb has pleiotropic effects, as homozygosity in males has been associated with poor sperm motility. We postulate that this is caused by the disruption of the CCDC108 gene located at one of the inversion breakpoints. CCDC108 is a poorly characterized protein, but it contains a MSP (major sperm protein) domain and is expressed in testis. The study illustrates several characteristic features of the genetic diversity present in domestic animals, including the evolution of alleles by two or more consecutive mutations and the fact that structural changes have contributed to fast phenotypic evolution.

Published

2012

32. The Rose-comb Mutation in Chickens Constitutes a Structural Rearrangement Causing Both Altered Comb Morphology and Defective Sperm Motility

Author

Imsland, Freyja, Feng, Chungang, Boije, Henrik, Bed'hom, Bertrand, Fillon, Valerie, Dorshorst, Ben, Rubin, Carl-Johan, Liu, Ranran, Gao, Yu, Gu, Xiaorong, Wang, Yanqiang, Gourichon, David, Zody, Michael C., Zecchin, William, Vieaud, Agathe, Tixier-Boichard, Michele, Hu, Xiaoxiang, Hallböök, Finn, Li, Ning, Andersson, Leif, Imsland, Freyja, Feng, Chungang, Boije, Henrik, Bed'hom, Bertrand, Fillon, Valerie, Dorshorst, Ben, Rubin, Carl-Johan, Liu, Ranran, Gao, Yu, Gu, Xiaorong, Wang, Yanqiang, Gourichon, David, Zody, Michael C., Zecchin, William, Vieaud, Agathe, Tixier-Boichard, Michele, Hu, Xiaoxiang, Hallböök, Finn, Li, Ning, and Andersson, Leif

Abstract

Rose-comb, a classical monogenic trait of chickens, is characterized by a drastically altered comb morphology compared to the single-combed wild-type. Here we show that Rose-comb is caused by a 7.4 Mb inversion on chromosome 7 and that a second Rose-comb allele arose by unequal crossing over between a Rose-comb and wild-type chromosome. The comb phenotype is caused by the relocalization of the MNR2 homeodomain protein gene leading to transient ectopic expression of MNR2 during comb development. We also provide a molecular explanation for the first example of epistatic interaction reported by Bateson and Punnett 104 years ago, namely that walnut-comb is caused by the combined effects of the Rose-comb and Pea-comb alleles. Transient ectopic expression of MNR2 and SOX5 (causing the Pea-comb phenotype) occurs in the same population of mesenchymal cells and with at least partially overlapping expression in individual cells in the comb primordium. Rose-comb has pleiotropic effects, as homozygosity in males has been associated with poor sperm motility. We postulate that this is caused by the disruption of the CCDC108 gene located at one of the inversion breakpoints. CCDC108 is a poorly characterized protein, but it contains a MSP (major sperm protein) domain and is expressed in testis. The study illustrates several characteristic features of the genetic diversity present in domestic animals, including the evolution of alleles by two or more consecutive mutations and the fact that structural changes have contributed to fast phenotypic evolution.

Published

2012

33. Sonic Hedgehog-Signalling Patterns the Developing Chicken Comb as Revealed by Exploration of the Pea-comb Mutation

Author

Boije, Henrik, Harun-Or-Rashid, Mohammad, Lee, Yu-Jen, Imsland, Freyja, Bruneau, Nicolas, Vieaud, Agathe, Gourichon, David, Tixier-Boichard, Michèle, Bed’hom, Bertrand, Andersson, Leif, Hallböök, Finn, Boije, Henrik, Harun-Or-Rashid, Mohammad, Lee, Yu-Jen, Imsland, Freyja, Bruneau, Nicolas, Vieaud, Agathe, Gourichon, David, Tixier-Boichard, Michèle, Bed’hom, Bertrand, Andersson, Leif, and Hallböök, Finn

Abstract

The genetic basis and mechanisms behind the morphological variation observed throughout the animal kingdom is stillrelatively unknown. In the present work we have focused on the establishment of the chicken comb-morphology byexploring the Pea-comb mutant. The wild-type single-comb is reduced in size and distorted in the Pea-comb mutant. Peacombis formed by a lateral expansion of the central comb anlage into three ridges and is caused by a mutation in SOX5,which induces ectopic expression of the SOX5 transcription factor in mesenchyme under the developing comb. Analysis ofdifferential gene expression identified decreased Sonic hedgehog (SHH) receptor expression in Pea-comb mesenchyme. Byexperimentally blocking SHH with cyclopamine, the wild-type single-comb was transformed into a Pea-comb-likephenotype. The results show that the patterning of the chicken comb is under the control of SHH and suggest that ectopicSOX5 expression in the Pea-comb change the response of mesenchyme to SHH signalling with altered combmorphogenesis as a result. A role for the mesenchyme during comb morphogenesis is further supported by the recentfinding that another comb-mutant (Rose-comb), is caused by ectopic expression of a transcription factor in combmesenchyme. The present study does not only give knowledge about how the chicken comb is formed, it also adds to ourunderstanding how mutations or genetic polymorphisms may contribute to inherited variations in the human face.

Published

2012

34. The Rose-comb Mutation in Chickens Constitutes a Structural Rearrangement Causing Both Altered Comb Morphology and Defective Sperm Motility

Author

Imsland, Freyja, Feng, Chungang, Boije, Henrik, Bed'hom, Bertrand, Fillon, Valerie, Dorshorst, Ben, Rubin, Carl-Johan, Liu, Ranran, Gao, Yu, Gu, Xiaorong, Wang, Yanqiang, Gourichon, David, Zody, Michael C., Zecchin, William, Vieaud, Agathe, Tixier-Boichard, Michele, Hu, Xiaoxiang, Hallböök, Finn, Li, Ning, Andersson, Leif, Imsland, Freyja, Feng, Chungang, Boije, Henrik, Bed'hom, Bertrand, Fillon, Valerie, Dorshorst, Ben, Rubin, Carl-Johan, Liu, Ranran, Gao, Yu, Gu, Xiaorong, Wang, Yanqiang, Gourichon, David, Zody, Michael C., Zecchin, William, Vieaud, Agathe, Tixier-Boichard, Michele, Hu, Xiaoxiang, Hallböök, Finn, Li, Ning, and Andersson, Leif

Abstract

Rose-comb, a classical monogenic trait of chickens, is characterized by a drastically altered comb morphology compared to the single-combed wild-type. Here we show that Rose-comb is caused by a 7.4 Mb inversion on chromosome 7 and that a second Rose-comb allele arose by unequal crossing over between a Rose-comb and wild-type chromosome. The comb phenotype is caused by the relocalization of the MNR2 homeodomain protein gene leading to transient ectopic expression of MNR2 during comb development. We also provide a molecular explanation for the first example of epistatic interaction reported by Bateson and Punnett 104 years ago, namely that walnut-comb is caused by the combined effects of the Rose-comb and Pea-comb alleles. Transient ectopic expression of MNR2 and SOX5 (causing the Pea-comb phenotype) occurs in the same population of mesenchymal cells and with at least partially overlapping expression in individual cells in the comb primordium. Rose-comb has pleiotropic effects, as homozygosity in males has been associated with poor sperm motility. We postulate that this is caused by the disruption of the CCDC108 gene located at one of the inversion breakpoints. CCDC108 is a poorly characterized protein, but it contains a MSP (major sperm protein) domain and is expressed in testis. The study illustrates several characteristic features of the genetic diversity present in domestic animals, including the evolution of alleles by two or more consecutive mutations and the fact that structural changes have contributed to fast phenotypic evolution.

Published

2012

35. Sonic Hedgehog-Signalling Patterns the Developing Chicken Comb as Revealed by Exploration of the Pea-comb Mutation

Author

Boije, Henrik, Harun-Or-Rashid, Mohammad, Lee, Yu-Jen, Imsland, Freyja, Bruneau, Nicolas, Vieaud, Agathe, Gourichon, David, Tixier-Boichard, Michèle, Bed’hom, Bertrand, Andersson, Leif, Hallböök, Finn, Boije, Henrik, Harun-Or-Rashid, Mohammad, Lee, Yu-Jen, Imsland, Freyja, Bruneau, Nicolas, Vieaud, Agathe, Gourichon, David, Tixier-Boichard, Michèle, Bed’hom, Bertrand, Andersson, Leif, and Hallböök, Finn

Abstract

The genetic basis and mechanisms behind the morphological variation observed throughout the animal kingdom is stillrelatively unknown. In the present work we have focused on the establishment of the chicken comb-morphology byexploring the Pea-comb mutant. The wild-type single-comb is reduced in size and distorted in the Pea-comb mutant. Peacombis formed by a lateral expansion of the central comb anlage into three ridges and is caused by a mutation in SOX5,which induces ectopic expression of the SOX5 transcription factor in mesenchyme under the developing comb. Analysis ofdifferential gene expression identified decreased Sonic hedgehog (SHH) receptor expression in Pea-comb mesenchyme. Byexperimentally blocking SHH with cyclopamine, the wild-type single-comb was transformed into a Pea-comb-likephenotype. The results show that the patterning of the chicken comb is under the control of SHH and suggest that ectopicSOX5 expression in the Pea-comb change the response of mesenchyme to SHH signalling with altered combmorphogenesis as a result. A role for the mesenchyme during comb morphogenesis is further supported by the recentfinding that another comb-mutant (Rose-comb), is caused by ectopic expression of a transcription factor in combmesenchyme. The present study does not only give knowledge about how the chicken comb is formed, it also adds to ourunderstanding how mutations or genetic polymorphisms may contribute to inherited variations in the human face.

Published

2012

36. The Rose-comb Mutation in Chickens Constitutes a Structural Rearrangement Causing Both Altered Comb Morphology and Defective Sperm Motility

Author

Imsland, Freyja, Feng, Chungang, Boije, Henrik, Bed'hom, Bertrand, Fillon, Valerie, Dorshorst, Ben, Rubin, Carl-Johan, Liu, Ranran, Gao, Yu, Gu, Xiaorong, Wang, Yanqiang, Gourichon, David, Zody, Michael C., Zecchin, William, Vieaud, Agathe, Tixier-Boichard, Michele, Hu, Xiaoxiang, Hallböök, Finn, Li, Ning, Andersson, Leif, Imsland, Freyja, Feng, Chungang, Boije, Henrik, Bed'hom, Bertrand, Fillon, Valerie, Dorshorst, Ben, Rubin, Carl-Johan, Liu, Ranran, Gao, Yu, Gu, Xiaorong, Wang, Yanqiang, Gourichon, David, Zody, Michael C., Zecchin, William, Vieaud, Agathe, Tixier-Boichard, Michele, Hu, Xiaoxiang, Hallböök, Finn, Li, Ning, and Andersson, Leif

Abstract

Rose-comb, a classical monogenic trait of chickens, is characterized by a drastically altered comb morphology compared to the single-combed wild-type. Here we show that Rose-comb is caused by a 7.4 Mb inversion on chromosome 7 and that a second Rose-comb allele arose by unequal crossing over between a Rose-comb and wild-type chromosome. The comb phenotype is caused by the relocalization of the MNR2 homeodomain protein gene leading to transient ectopic expression of MNR2 during comb development. We also provide a molecular explanation for the first example of epistatic interaction reported by Bateson and Punnett 104 years ago, namely that walnut-comb is caused by the combined effects of the Rose-comb and Pea-comb alleles. Transient ectopic expression of MNR2 and SOX5 (causing the Pea-comb phenotype) occurs in the same population of mesenchymal cells and with at least partially overlapping expression in individual cells in the comb primordium. Rose-comb has pleiotropic effects, as homozygosity in males has been associated with poor sperm motility. We postulate that this is caused by the disruption of the CCDC108 gene located at one of the inversion breakpoints. CCDC108 is a poorly characterized protein, but it contains a MSP (major sperm protein) domain and is expressed in testis. The study illustrates several characteristic features of the genetic diversity present in domestic animals, including the evolution of alleles by two or more consecutive mutations and the fact that structural changes have contributed to fast phenotypic evolution.

Published

2012

37. The Dark brown plumage color in chickens is caused by an 8.3-kb deletion upstream of SOX10

Author

Gunnarsson, Ulrika, Kerje, Susanne, Bed'hom, Bertrand, Sahlqvist, Anna-Stina, Ekwall, Olov, Tixier-Boichard, Michele, Kämpe, Olle, Andersson, Leif, Gunnarsson, Ulrika, Kerje, Susanne, Bed'hom, Bertrand, Sahlqvist, Anna-Stina, Ekwall, Olov, Tixier-Boichard, Michele, Kämpe, Olle, and Andersson, Leif

Abstract

The Dark brown (DB) mutation in chickens reduces expression of black eumelanin and enhances expression of red pheomelanin, but only in certain parts of the plumage. Here, we present genetic evidence that an 8.3-kb deletion upstream of the SOX10 transcription start site is the causal mutation underlying the DB phenotype. The SOX10 transcription factor has a well-established role in melanocyte biology and is essential for melanocyte migration and survival. Previous studies have demonstrated that the mouse homolog of a highly conserved element within the deleted region is a SOX10 enhancer. The mechanism of action of this mutation remains to be established, but one possible scenario is that the deletion leads to reduced SOX10 expression which in turn down-regulates expression of key enzymes in pigment synthesis such as tyrosinase. Lower tyrosinase activity leads to a shift toward a more pheomelanistic (reddish) plumage color, which is the characteristic feature of the DB phenotype.

Published

2011

38. Sex-linked barring in chickens is controlled by the CDKN2A/B tumour suppressor locus

Author

Hellström, Anders R., Sundström, Elisabeth, Gunnarsson, Ulrika, Bed'hom, Bertrand, Tixier-Boichard, Michele, Honaker, Christa F., Sahlqvist, Anna-Stina, Jensen, Per, Kämpe, Olle, Siegel, Paul B., Kerje, Susanne, Andersson, Leif, Hellström, Anders R., Sundström, Elisabeth, Gunnarsson, Ulrika, Bed'hom, Bertrand, Tixier-Boichard, Michele, Honaker, Christa F., Sahlqvist, Anna-Stina, Jensen, Per, Kämpe, Olle, Siegel, Paul B., Kerje, Susanne, and Andersson, Leif

Abstract

Sex-linked barring, a common plumage colour found in chickens, is characterized by black and white barred feathers. Previous studies have indicated that the white bands are caused by an absence of melanocytes in the feather follicle during the growth of this region. Here we show that Sex-linked barring is controlled by the CDKN2A/B locus, which encodes the INK4b and ARF transcripts. We identified two non-coding mutations in CDKN2A that showed near complete association with the phenotype. Also identified were two missense mutations at highly conserved sites, V9D and R10C, and every bird tested with a confirmed Sex-linked barring phenotype carried one of these missense mutations. Further work is required to determine if one of these or a combined effect of two or more CDKN2A mutations is causing Sex-linked barring. This novel finding provides the first evidence that the tumour suppressor locus CDKN2A/B can affect pigmentation phenotypes and sheds new light on the functional significance of this gene.

Published

2010

39. Whole genome resequencing reveals loci under selection during chicken domestication

Author

Rubin, Carl-Johan, Zody, Michael C., Eriksson, Jonas, Meadows, Jennifer, Sherwood, Ellen, Webster, Matthew T., Jiang, Lin, Ingman, Max, Sharpe, Ted, Besnier, Francois, Ka, Sojeong, Hallböök, Finn, Carlborg, Örjan, Bed'hom, Bertrand, Tixier-Boichard, Michèle, Jensen, Per, Siegel, Paul, Lindblad-Toh, Kerstin, Andersson, Leif, Rubin, Carl-Johan, Zody, Michael C., Eriksson, Jonas, Meadows, Jennifer, Sherwood, Ellen, Webster, Matthew T., Jiang, Lin, Ingman, Max, Sharpe, Ted, Besnier, Francois, Ka, Sojeong, Hallböök, Finn, Carlborg, Örjan, Bed'hom, Bertrand, Tixier-Boichard, Michèle, Jensen, Per, Siegel, Paul, Lindblad-Toh, Kerstin, and Andersson, Leif

Abstract

Domestic animals are excellent models for genetic studies of phenotypic evolution. They have evolved genetic adaptations to a new environment, the farm, and have been subjected to strong human-driven selection leading to remarkable phenotypic changes in morphology, physiology and behaviour. Identifying the genetic changes underlying these developments provides new insight into general mechanisms by which genetic variation shapes phenotypic diversity. Here we describe the use of massively parallel sequencing to identify selective sweeps of favourable alleles and candidate mutations that have had a prominent role in the domestication of chickens (Gallus gallus domesticus) and their subsequent specialization into broiler (meat-producing) and layer (egg-producing) chickens. We have generated 44.5-fold coverage of the chicken genome using pools of genomic DNA representing eight different populations of domestic chickens as well as red jungle fowl (Gallus gallus), the major wild ancestor. We report more than 7,000,000 single nucleotide polymorphisms, almost 1,300 deletions and a number of putative selective sweeps. One of the most striking selective sweeps found in all domestic chickens occurred at the locus for thyroid stimulating hormone receptor (TSHR), which has a pivotal role in metabolic regulation and photoperiod control of reproduction in vertebrates. Several of the selective sweeps detected in broilers overlapped genes associated with growth, appetite and metabolic regulation. We found little evidence that selection for loss-of-function mutations had a prominent role in chicken domestication, but we detected two deletions in coding sequences that we suggest are functionally important. This study has direct application to animal breeding and enhances the importance of the domestic chicken as a model organism for biomedical research.

Published

2010

40. Whole-genome resequencing reveals loci under selection during chicken domestication

Author

Rubin, Carl-Johan, Zody, Michael C., Meadows, Jennifer R. S., Sherwood, Ellen, Webster, Matthew, Jiang, Lin, Ingman, Max, Sharpe, Ted, Ka, Sojeong, Hallböök, Finn, Besnier, Francois, Carlborg, Örjan, Bed'hom, Bertrand, Jensen, Per, Siegel, Paul, Lindblad-Toh, Kerstin, Andersson, Leif, Rubin, Carl-Johan, Zody, Michael C., Meadows, Jennifer R. S., Sherwood, Ellen, Webster, Matthew, Jiang, Lin, Ingman, Max, Sharpe, Ted, Ka, Sojeong, Hallböök, Finn, Besnier, Francois, Carlborg, Örjan, Bed'hom, Bertrand, Jensen, Per, Siegel, Paul, Lindblad-Toh, Kerstin, and Andersson, Leif

Abstract

Domestic animals are excellent models for genetic studies of phenotypic evolution(1-3). They have evolved genetic adaptations to a new environment, the farm, and have been subjected to strong human-driven selection leading to remarkable phenotypic changes in morphology, physiology and behaviour. Identifying the genetic changes underlying these developments provides new insight into general mechanisms by which genetic variation shapes phenotypic diversity. Here we describe the use of massively parallel sequencing to identify selective sweeps of favourable alleles and candidate mutations that have had a prominent role in the domestication of chickens (Gallus gallus domesticus) and their subsequent specialization into broiler (meat-producing) and layer (egg-producing) chickens. We have generated 44.5-fold coverage of the chicken genome using pools of genomic DNA representing eight different populations of domestic chickens as well as red jungle fowl (Gallus gallus), the major wild ancestor(4). We report more than 7,000,000 single nucleotide polymorphisms, almost 1,300 deletions and a number of putative selective sweeps. One of the most striking selective sweeps found in all domestic chickens occurred at the locus for thyroid stimulating hormone receptor (TSHR), which has a pivotal role in metabolic regulation and photoperiod control of reproduction in vertebrates. Several of the selective sweeps detected in broilers overlapped genes associated with growth, appetite and metabolic regulation. We found little evidence that selection for loss-of-function mutations had a prominent role in chicken domestication, but we detected two deletions in coding sequences that we suggest are functionally important. This study has direct application to animal breeding and enhances the importance of the domestic chicken as a model organism for biomedical research.

Published

2010

41. Whole-genome resequencing reveals loci under selection during chicken domestication

Author

Rubin, Carl-Johan, Zody, Michael C., Meadows, Jennifer R. S., Sherwood, Ellen, Webster, Matthew, Jiang, Lin, Ingman, Max, Sharpe, Ted, Ka, Sojeong, Hallböök, Finn, Besnier, Francois, Carlborg, Örjan, Bed'hom, Bertrand, Jensen, Per, Siegel, Paul, Lindblad-Toh, Kerstin, Andersson, Leif, Rubin, Carl-Johan, Zody, Michael C., Meadows, Jennifer R. S., Sherwood, Ellen, Webster, Matthew, Jiang, Lin, Ingman, Max, Sharpe, Ted, Ka, Sojeong, Hallböök, Finn, Besnier, Francois, Carlborg, Örjan, Bed'hom, Bertrand, Jensen, Per, Siegel, Paul, Lindblad-Toh, Kerstin, and Andersson, Leif

Abstract

Domestic animals are excellent models for genetic studies of phenotypic evolution(1-3). They have evolved genetic adaptations to a new environment, the farm, and have been subjected to strong human-driven selection leading to remarkable phenotypic changes in morphology, physiology and behaviour. Identifying the genetic changes underlying these developments provides new insight into general mechanisms by which genetic variation shapes phenotypic diversity. Here we describe the use of massively parallel sequencing to identify selective sweeps of favourable alleles and candidate mutations that have had a prominent role in the domestication of chickens (Gallus gallus domesticus) and their subsequent specialization into broiler (meat-producing) and layer (egg-producing) chickens. We have generated 44.5-fold coverage of the chicken genome using pools of genomic DNA representing eight different populations of domestic chickens as well as red jungle fowl (Gallus gallus), the major wild ancestor(4). We report more than 7,000,000 single nucleotide polymorphisms, almost 1,300 deletions and a number of putative selective sweeps. One of the most striking selective sweeps found in all domestic chickens occurred at the locus for thyroid stimulating hormone receptor (TSHR), which has a pivotal role in metabolic regulation and photoperiod control of reproduction in vertebrates. Several of the selective sweeps detected in broilers overlapped genes associated with growth, appetite and metabolic regulation. We found little evidence that selection for loss-of-function mutations had a prominent role in chicken domestication, but we detected two deletions in coding sequences that we suggest are functionally important. This study has direct application to animal breeding and enhances the importance of the domestic chicken as a model organism for biomedical research.

Published

2010

42. Vietnamese chickens: a gate towards Asian genetic diversity

Author

Berthouly, Cécile, Rognon, Xavier, Nhu Van Thu, Gély, Marie, Vu Chi Cuong, Tixier-Boichard, Michèle, Bed'Hom, Bertrand, Bruneau, N., Verrier, Etienne, Maillard, Jean-Charles, Michaux, J.R., Berthouly, Cécile, Rognon, Xavier, Nhu Van Thu, Gély, Marie, Vu Chi Cuong, Tixier-Boichard, Michèle, Bed'Hom, Bertrand, Bruneau, N., Verrier, Etienne, Maillard, Jean-Charles, and Michaux, J.R.

Abstract

Background: Chickens represent an important animal genetic resource and the conservation of local breeds is an issue for the preservation of this resource. The genetic diversity of a breed is mainly evaluated through its nuclear diversity. However, nuclear genetic diversity does not provide the same information as mitochondrial genetic diversity. For the species Gallus gallus, at least 8 maternal lineages have been identified. While breeds distributed westward from the Indian subcontinent usually share haplotypes from 1 to 2 haplogroups, Southeast Asian breeds exhibit all the haplogroups. The Vietnamese Ha Giang (HG) chicken has been shown to exhibit a very high nuclear diversity but also important rates of admixture with wild relatives. Its geographical position, within one of the chicken domestication centres ranging from Thailand to the Chinese Yunnan province, increases the probability of observing a very high genetic diversity for maternal lineages, and in a way, improving our understanding of the chicken domestication process. Results: A total of 106 sequences from Vietnamese HG chickens were first compared to the sequences of published Chinese breeds. The 25 haplotypes observed in the Vietnamese HG population belonged to six previously published haplogroups which are: A, B, C, D, F and G. On average, breeds from the Chinese Yunnan province carried haplotypes from 4.3 haplogroups. For the HG population, haplogroup diversity is found at both the province and the village level (0.69). The AMOVA results show that genetic diversity occurred within the breeds rather than between breeds or provinces. Regarding the global structure of the mtDNA diversity per population, a characteristic of the HG population was the occurrence of similar pattern distribution as compared to G. gallus spadiceus. However, there was no geographical evidence of gene flow between wild and domestic populations as observed when microsatellites were used. Conclusions: In contrast to other chic

Published

2010

43. Revealing fine scale subpopulation structure in the Vietnamese H'mong cattle breed for conservation purposes

Author

Berthouly, Cécile, Maillard, Jean-Charles, Pham Doan Lan, Nhu Van Thu, Bed'Hom, Bertrand, Leroy, G., Hoang Thanh, Hai, Laloë, Denis, Bruneau, N., Vu Chi Cuong, Nguyen Dang Vang, Verrier, Etienne, Rognon, Xavier, Berthouly, Cécile, Maillard, Jean-Charles, Pham Doan Lan, Nhu Van Thu, Bed'Hom, Bertrand, Leroy, G., Hoang Thanh, Hai, Laloë, Denis, Bruneau, N., Vu Chi Cuong, Nguyen Dang Vang, Verrier, Etienne, and Rognon, Xavier

Abstract

Background: During the last decades, there has been an acceleration of the loss of domestic animal biodiversity. For conservation purposes, the genetic diversity of the H'Mong cattle, an indigenous local breed was studied. Singlenucleotide polymorphisms (SNP) of the SRY gene and mtDNA D-Loop sequence were analysed to clarify the origin of the breed. The genetic diversity was assessed through genetic data with twenty-five FAO microsatellites, and morphometric data with five body measurements from 408 animals sampled from eight districts of the Ha Giang province. Results: The SRY genes were all of the zebu type. Among the 27 mtDNA haplotypes, 12 haplotypes were of the taurine type and the remaining 15 of the zebu type. This indicates female taurine introgression in the zebu H'Mong. The observed and expected heterozygosity ranged from 0.616 to 0.673 and from 0.681 to 0.729 respectively according to district, with low genetic differentiation (FST = 0.0076). Multivariate analysis on morphometric and genetic data shows a separation of districts into two groups following a south-west/north-east cline and admixture analysis confirmed the two clusters, but no differentiation of taurine introgression between clusters was observed. A possible admixture with the Yellow cattle breed from a neighbouring province was suggested through genetic data and householder interviews. Conclusions: In this study we demonstrate the interest of fine-scale sampling for the study of genetic structure of local breeds. Such a study allows avoiding erroneous conservation policies and on the contrary, proposes measures for conserving and limiting crossbreeding between the H'Mong and the Yellow cattle breeds.

Published

2010

44. Whole-genome resequencing reveals loci under selection during chicken domestication

Author

Rubin, Carl-Johan, Zody, Michael C., Meadows, Jennifer R. S., Sherwood, Ellen, Webster, Matthew, Jiang, Lin, Ingman, Max, Sharpe, Ted, Ka, Sojeong, Hallböök, Finn, Besnier, Francois, Carlborg, Örjan, Bed'hom, Bertrand, Jensen, Per, Siegel, Paul, Lindblad-Toh, Kerstin, Andersson, Leif, Rubin, Carl-Johan, Zody, Michael C., Meadows, Jennifer R. S., Sherwood, Ellen, Webster, Matthew, Jiang, Lin, Ingman, Max, Sharpe, Ted, Ka, Sojeong, Hallböök, Finn, Besnier, Francois, Carlborg, Örjan, Bed'hom, Bertrand, Jensen, Per, Siegel, Paul, Lindblad-Toh, Kerstin, and Andersson, Leif

Abstract

Domestic animals are excellent models for genetic studies of phenotypic evolution(1-3). They have evolved genetic adaptations to a new environment, the farm, and have been subjected to strong human-driven selection leading to remarkable phenotypic changes in morphology, physiology and behaviour. Identifying the genetic changes underlying these developments provides new insight into general mechanisms by which genetic variation shapes phenotypic diversity. Here we describe the use of massively parallel sequencing to identify selective sweeps of favourable alleles and candidate mutations that have had a prominent role in the domestication of chickens (Gallus gallus domesticus) and their subsequent specialization into broiler (meat-producing) and layer (egg-producing) chickens. We have generated 44.5-fold coverage of the chicken genome using pools of genomic DNA representing eight different populations of domestic chickens as well as red jungle fowl (Gallus gallus), the major wild ancestor(4). We report more than 7,000,000 single nucleotide polymorphisms, almost 1,300 deletions and a number of putative selective sweeps. One of the most striking selective sweeps found in all domestic chickens occurred at the locus for thyroid stimulating hormone receptor (TSHR), which has a pivotal role in metabolic regulation and photoperiod control of reproduction in vertebrates. Several of the selective sweeps detected in broilers overlapped genes associated with growth, appetite and metabolic regulation. We found little evidence that selection for loss-of-function mutations had a prominent role in chicken domestication, but we detected two deletions in coding sequences that we suggest are functionally important. This study has direct application to animal breeding and enhances the importance of the domestic chicken as a model organism for biomedical research.

Published

2010

45. Revealing fine scale subpopulation structure in the Vietnamese H'mong cattle breed for conservation purposes

Author

Berthouly, Cécile, Maillard, Jean-Charles, Pham Doan Lan, Nhu Van Thu, Bed'Hom, Bertrand, Leroy, G., Hoang Thanh, Hai, Laloë, Denis, Bruneau, N., Vu Chi Cuong, Nguyen Dang Vang, Verrier, Etienne, Rognon, Xavier, Berthouly, Cécile, Maillard, Jean-Charles, Pham Doan Lan, Nhu Van Thu, Bed'Hom, Bertrand, Leroy, G., Hoang Thanh, Hai, Laloë, Denis, Bruneau, N., Vu Chi Cuong, Nguyen Dang Vang, Verrier, Etienne, and Rognon, Xavier

Abstract

Background: During the last decades, there has been an acceleration of the loss of domestic animal biodiversity. For conservation purposes, the genetic diversity of the H'Mong cattle, an indigenous local breed was studied. Singlenucleotide polymorphisms (SNP) of the SRY gene and mtDNA D-Loop sequence were analysed to clarify the origin of the breed. The genetic diversity was assessed through genetic data with twenty-five FAO microsatellites, and morphometric data with five body measurements from 408 animals sampled from eight districts of the Ha Giang province. Results: The SRY genes were all of the zebu type. Among the 27 mtDNA haplotypes, 12 haplotypes were of the taurine type and the remaining 15 of the zebu type. This indicates female taurine introgression in the zebu H'Mong. The observed and expected heterozygosity ranged from 0.616 to 0.673 and from 0.681 to 0.729 respectively according to district, with low genetic differentiation (FST = 0.0076). Multivariate analysis on morphometric and genetic data shows a separation of districts into two groups following a south-west/north-east cline and admixture analysis confirmed the two clusters, but no differentiation of taurine introgression between clusters was observed. A possible admixture with the Yellow cattle breed from a neighbouring province was suggested through genetic data and householder interviews. Conclusions: In this study we demonstrate the interest of fine-scale sampling for the study of genetic structure of local breeds. Such a study allows avoiding erroneous conservation policies and on the contrary, proposes measures for conserving and limiting crossbreeding between the H'Mong and the Yellow cattle breeds.

Published

2010

46. Vietnamese chickens: a gate towards Asian genetic diversity

Author

Berthouly, Cécile, Rognon, Xavier, Nhu Van Thu, Gély, Marie, Vu Chi Cuong, Tixier-Boichard, Michèle, Bed'Hom, Bertrand, Bruneau, N., Verrier, Etienne, Maillard, Jean-Charles, Michaux, J.R., Berthouly, Cécile, Rognon, Xavier, Nhu Van Thu, Gély, Marie, Vu Chi Cuong, Tixier-Boichard, Michèle, Bed'Hom, Bertrand, Bruneau, N., Verrier, Etienne, Maillard, Jean-Charles, and Michaux, J.R.

Abstract

Background: Chickens represent an important animal genetic resource and the conservation of local breeds is an issue for the preservation of this resource. The genetic diversity of a breed is mainly evaluated through its nuclear diversity. However, nuclear genetic diversity does not provide the same information as mitochondrial genetic diversity. For the species Gallus gallus, at least 8 maternal lineages have been identified. While breeds distributed westward from the Indian subcontinent usually share haplotypes from 1 to 2 haplogroups, Southeast Asian breeds exhibit all the haplogroups. The Vietnamese Ha Giang (HG) chicken has been shown to exhibit a very high nuclear diversity but also important rates of admixture with wild relatives. Its geographical position, within one of the chicken domestication centres ranging from Thailand to the Chinese Yunnan province, increases the probability of observing a very high genetic diversity for maternal lineages, and in a way, improving our understanding of the chicken domestication process. Results: A total of 106 sequences from Vietnamese HG chickens were first compared to the sequences of published Chinese breeds. The 25 haplotypes observed in the Vietnamese HG population belonged to six previously published haplogroups which are: A, B, C, D, F and G. On average, breeds from the Chinese Yunnan province carried haplotypes from 4.3 haplogroups. For the HG population, haplogroup diversity is found at both the province and the village level (0.69). The AMOVA results show that genetic diversity occurred within the breeds rather than between breeds or provinces. Regarding the global structure of the mtDNA diversity per population, a characteristic of the HG population was the occurrence of similar pattern distribution as compared to G. gallus spadiceus. However, there was no geographical evidence of gene flow between wild and domestic populations as observed when microsatellites were used. Conclusions: In contrast to other chic

Published

2010

47. Whole-genome resequencing reveals loci under selection during chicken domestication

Author

Rubin, Carl-Johan, Zody, Michael C., Meadows, Jennifer R. S., Sherwood, Ellen, Webster, Matthew, Jiang, Lin, Ingman, Max, Sharpe, Ted, Ka, Sojeong, Hallböök, Finn, Besnier, Francois, Carlborg, Örjan, Bed'hom, Bertrand, Jensen, Per, Siegel, Paul, Lindblad-Toh, Kerstin, Andersson, Leif, Rubin, Carl-Johan, Zody, Michael C., Meadows, Jennifer R. S., Sherwood, Ellen, Webster, Matthew, Jiang, Lin, Ingman, Max, Sharpe, Ted, Ka, Sojeong, Hallböök, Finn, Besnier, Francois, Carlborg, Örjan, Bed'hom, Bertrand, Jensen, Per, Siegel, Paul, Lindblad-Toh, Kerstin, and Andersson, Leif

Abstract

Domestic animals are excellent models for genetic studies of phenotypic evolution(1-3). They have evolved genetic adaptations to a new environment, the farm, and have been subjected to strong human-driven selection leading to remarkable phenotypic changes in morphology, physiology and behaviour. Identifying the genetic changes underlying these developments provides new insight into general mechanisms by which genetic variation shapes phenotypic diversity. Here we describe the use of massively parallel sequencing to identify selective sweeps of favourable alleles and candidate mutations that have had a prominent role in the domestication of chickens (Gallus gallus domesticus) and their subsequent specialization into broiler (meat-producing) and layer (egg-producing) chickens. We have generated 44.5-fold coverage of the chicken genome using pools of genomic DNA representing eight different populations of domestic chickens as well as red jungle fowl (Gallus gallus), the major wild ancestor(4). We report more than 7,000,000 single nucleotide polymorphisms, almost 1,300 deletions and a number of putative selective sweeps. One of the most striking selective sweeps found in all domestic chickens occurred at the locus for thyroid stimulating hormone receptor (TSHR), which has a pivotal role in metabolic regulation and photoperiod control of reproduction in vertebrates. Several of the selective sweeps detected in broilers overlapped genes associated with growth, appetite and metabolic regulation. We found little evidence that selection for loss-of-function mutations had a prominent role in chicken domestication, but we detected two deletions in coding sequences that we suggest are functionally important. This study has direct application to animal breeding and enhances the importance of the domestic chicken as a model organism for biomedical research.

Published

2010

48. Whole-genome resequencing reveals loci under selection during chicken domestication

Author

Rubin, Carl-Johan, Zody, Michael C., Meadows, Jennifer R. S., Sherwood, Ellen, Webster, Matthew, Jiang, Lin, Ingman, Max, Sharpe, Ted, Ka, Sojeong, Hallböök, Finn, Besnier, Francois, Carlborg, Örjan, Bed'hom, Bertrand, Jensen, Per, Siegel, Paul, Lindblad-Toh, Kerstin, Andersson, Leif, Rubin, Carl-Johan, Zody, Michael C., Meadows, Jennifer R. S., Sherwood, Ellen, Webster, Matthew, Jiang, Lin, Ingman, Max, Sharpe, Ted, Ka, Sojeong, Hallböök, Finn, Besnier, Francois, Carlborg, Örjan, Bed'hom, Bertrand, Jensen, Per, Siegel, Paul, Lindblad-Toh, Kerstin, and Andersson, Leif

Abstract

Domestic animals are excellent models for genetic studies of phenotypic evolution(1-3). They have evolved genetic adaptations to a new environment, the farm, and have been subjected to strong human-driven selection leading to remarkable phenotypic changes in morphology, physiology and behaviour. Identifying the genetic changes underlying these developments provides new insight into general mechanisms by which genetic variation shapes phenotypic diversity. Here we describe the use of massively parallel sequencing to identify selective sweeps of favourable alleles and candidate mutations that have had a prominent role in the domestication of chickens (Gallus gallus domesticus) and their subsequent specialization into broiler (meat-producing) and layer (egg-producing) chickens. We have generated 44.5-fold coverage of the chicken genome using pools of genomic DNA representing eight different populations of domestic chickens as well as red jungle fowl (Gallus gallus), the major wild ancestor(4). We report more than 7,000,000 single nucleotide polymorphisms, almost 1,300 deletions and a number of putative selective sweeps. One of the most striking selective sweeps found in all domestic chickens occurred at the locus for thyroid stimulating hormone receptor (TSHR), which has a pivotal role in metabolic regulation and photoperiod control of reproduction in vertebrates. Several of the selective sweeps detected in broilers overlapped genes associated with growth, appetite and metabolic regulation. We found little evidence that selection for loss-of-function mutations had a prominent role in chicken domestication, but we detected two deletions in coding sequences that we suggest are functionally important. This study has direct application to animal breeding and enhances the importance of the domestic chicken as a model organism for biomedical research.

Published

2010

49. Copy number variation in intron 1 of SOX5 causes the Pea-comb phenotype in chickens

Author

Wright, Dominic, Boije, Henrik, Meadows, Jennifer, Bed'hom, Bertrand, Gourichon, David, Vieaud, Agathe, Tixier-Boichard, Michèle, Rubin, Carl-Johan, Imsland, Freyja, Hallböök, Finn, Andersson, Leif, Wright, Dominic, Boije, Henrik, Meadows, Jennifer, Bed'hom, Bertrand, Gourichon, David, Vieaud, Agathe, Tixier-Boichard, Michèle, Rubin, Carl-Johan, Imsland, Freyja, Hallböök, Finn, and Andersson, Leif

Abstract

Pea-comb is a dominant mutation in chickens that drastically reduces the size of the comb and wattles. It is an adaptive trait in cold climates as it reduces heat loss and makes the chicken less susceptible to frost lesions. Here we report that Pea-comb is caused by a massive amplification of a duplicated sequence located near evolutionary conserved non-coding sequences in intron 1 of the gene encoding the SOX5 transcription factor. This must be the causative mutation since all other polymorphisms associated with the Pea-comb allele were excluded by genetic analysis. SOX5 controls cell fate and differentiation and is essential for skeletal development, chondrocyte differentiation, and extracellular matrix production. Immunostaining in early embryos demonstrated that Pea-comb is associated with ectopic expression of SOX5 in mesenchymal cells located just beneath the surface ectoderm where the comb and wattles will subsequently develop. The results imply that the duplication expansion interferes with the regulation of SOX5 expression during the differentiation of cells crucial for the development of comb and wattles. The study provides novel insight into the nature of mutations that contribute to phenotypic evolution and is the first description of a spontaneous and fully viable mutation in this developmentally important gene.

Published

2009

50. Genetic analysis of local Vietnamese chickens provides evidence of gene flow from wild to domestic populations

Author

Berthouly, Cécile, Leroy, G., Nhu Van Thu, Hoang Thanh, Hai, Bed'Hom, Bertrand, Trong Nguyen, Binh, Vu Chi Cuong, Monicat, François, Tixier-Boichard, Michèle, Verrier, Etienne, Maillard, Jean-Charles, Rognon, Xavier, Berthouly, Cécile, Leroy, G., Nhu Van Thu, Hoang Thanh, Hai, Bed'Hom, Bertrand, Trong Nguyen, Binh, Vu Chi Cuong, Monicat, François, Tixier-Boichard, Michèle, Verrier, Etienne, Maillard, Jean-Charles, and Rognon, Xavier

Abstract

Background: Previous studies suggested that multiple domestication events in South and South-East Asia (Yunnan and surrounding areas) and India have led to the genesis of modern domestic chickens. Ha Giang province is a northern Vietnamese region, where local chickens, such as the H'mong breed, and wild junglefowl coexist. The assumption was made that hybridisation between wild junglefowl and Ha Giang chickens may have occurred and led to the high genetic diversity previously observed. The objectives of this study were i) to clarify the genetic structure of the chicken population within the Ha Giang province and ii) to give evidence of admixture with G. gallus. A large survey of the molecular polymorphism for 18 microsatellite markers was conducted on 1082 chickens from 30 communes of the Ha Giang province (HG chickens). This dataset was combined with a previous dataset of Asian breeds, commercial lines and samples of Red junglefowl from Thailand and Vietnam (Ha Noï). Measurements of genetic diversity were estimated both within-population and between populations, and a step-by-step Bayesian approach was performed on the global data set. Results: The highest value for expected heterozygosity (> 0.60) was found in HG chickens and in the wild junglefowl populations from Thailand. HG chickens exhibited the highest allelic richness (mean A = 2.9). No significant genetic subdivisions of the chicken population within the Ha Giang province were found. As compared to other breeds, HG chickens clustered with wild populations. Furthermore, the neighbornet tree and the Bayesian clustering analysis showed that chickens from 4 communes were closely related to the wild ones and showed an admixture pattern. Conclusion: In the absence of any population structuring within the province, the H'mong chicken, identified from its black phenotype, shared a common gene pool with other chickens from the Ha Giang population. The large number of alleles shared exclusively between Ha Giang c

Published

2009