Your search keyword '"QTL discovery"' showing total 5 results

1. Highly accurate sequence imputation enables precise QTL mapping in Brown Swiss cattle

Author

Mirjam Frischknecht, Hubert Pausch, Beat Bapst, Heidi Signer-Hasler, Christine Flury, Dorian Garrick, Christian Stricker, Ruedi Fries, and Birgit Gredler-Grandl

Subjects

Whole genome sequencing, Imputation, Accuracy, Genome-wide association study, QTL discovery, Milk traits, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Within the last few years a large amount of genomic information has become available in cattle. Densities of genomic information vary from a few thousand variants up to whole genome sequence information. In order to combine genomic information from different sources and infer genotypes for a common set of variants, genotype imputation is required. Results In this study we evaluated the accuracy of imputation from high density chips to whole genome sequence data in Brown Swiss cattle. Using four popular imputation programs (Beagle, FImpute, Impute2, Minimac) and various compositions of reference panels, the accuracy of the imputed sequence variant genotypes was high and differences between the programs and scenarios were small. We imputed sequence variant genotypes for more than 1600 Brown Swiss bulls and performed genome-wide association studies for milk fat percentage at two stages of lactation. We found one and three quantitative trait loci for early and late lactation fat content, respectively. Known causal variants that were imputed from the sequenced reference panel were among the most significantly associated variants of the genome-wide association study. Conclusions Our study demonstrates that whole-genome sequence information can be imputed at high accuracy in cattle populations. Using imputed sequence variant genotypes in genome-wide association studies may facilitate causal variant detection.

Published

2017

2. Genome-wide association studies of fertility and calving traits in Brown Swiss cattle using imputed whole-genome sequences

Author

Mirjam Frischknecht, Beat Bapst, Franz R. Seefried, Heidi Signer-Hasler, Dorian Garrick, Christian Stricker, Intergenomics Consortium, Ruedi Fries, Ingolf Russ, Johann Sölkner, Anna Bieber, Maria G. Strillacci, Birgit Gredler-Grandl, and Christine Flury

Subjects

Whole genome sequencing, Genome-wide association study, QTL discovery, Functional traits, Brown Swiss, Dairy cattle, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background The detection of quantitative trait loci has accelerated with recent developments in genomics. The introduction of genomic selection in combination with sequencing efforts has made a large amount of genotypic data available. Functional traits such as fertility and calving traits have been included in routine genomic estimation of breeding values making large quantities of phenotypic data available for these traits. This data was used to investigate the genetics underlying fertility and calving traits and to identify potentially causative genomic regions and variants. We performed genome-wide association studies for 13 functional traits related to female fertility as well as for direct and maternal calving ease based on imputed whole-genome sequences. Deregressed breeding values from ~1000–5000 bulls per trait were used to test for associations with approximately 10 million imputed sequence SNPs. Results We identified a QTL on BTA17 associated with non-return rate at 56 days and with interval from first to last insemination. We found two significantly associated non-synonymous SNPs within this QTL region. Two more QTL for fertility traits were identified on BTA25 and 29. A single QTL was identified for maternal calving traits on BTA13 whereas three QTL on BTA19, 21 and 25 were identified for direct calving traits. The QTL on BTA19 co-localizes with the reported BH2 haplotype. The QTL on BTA25 is concordant for fertility and calving traits and co-localizes with a QTL previously reported to influence stature and related traits in Brown Swiss dairy cattle. Conclusion The detection of QTL and their causative variants remains challenging. Combining comprehensive phenotypic data with imputed whole genome sequences seems promising. We present a QTL on BTA17 for female fertility in dairy cattle with two significantly associated non-synonymous SNPs, along with five additional QTL for fertility traits and calving traits. For all of these we fine mapped the regions and suggest candidate genes and candidate variants.

Published

2017

3. Highly accurate sequence imputation enables precise QTL mapping in Brown Swiss cattle.

Author

Frischknecht, Mirjam, Pausch, Hubert, Bapst, Beat, Signer-Hasler, Heidi, Flury, Christine, Garrick, Dorian, Stricker, Christian, Fries, Ruedi, and Gredler-Grandl, Birgit

Subjects

*BROWN Swiss cattle, *MULTIPLE imputation (Statistics), *GENOMICS, *GENE expression, *GENETICS, *NUCLEOTIDE sequencing

Abstract

Background: Within the last few years a large amount of genomic information has become available in cattle. Densities of genomic information vary from a few thousand variants up to whole genome sequence information. In order to combine genomic information from different sources and infer genotypes for a common set of variants, genotype imputation is required. Results: In this study we evaluated the accuracy of imputation from high density chips to whole genome sequence data in Brown Swiss cattle. Using four popular imputation programs (Beagle, FImpute, Impute2, Minimac) and various compositions of reference panels, the accuracy of the imputed sequence variant genotypes was high and differences between the programs and scenarios were small. We imputed sequence variant genotypes for more than 1600 Brown Swiss bulls and performed genome-wide association studies for milk fat percentage at two stages of lactation. We found one and three quantitative trait loci for early and late lactation fat content, respectively. Known causal variants that were imputed from the sequenced reference panel were among the most significantly associated variants of the genome-wide association study. Conclusions: Our study demonstrates that whole-genome sequence information can be imputed at high accuracy in cattle populations. Using imputed sequence variant genotypes in genome-wide association studies may facilitate causal variant detection. [ABSTRACT FROM AUTHOR]

Published

2017

4. Genome-wide association studies of fertility and calving traits in Brown Swiss cattle using imputed whole-genome sequences.

Author

Frischknecht, Mirjam, Bapst, Beat, Seefried, Franz R., Signer-Hasler, Heidi, Garrick, Dorian, Stricker, Christian, Consortium, Intergenomics, Fries, Ruedi, Russ, Ingolf, Sölkner, Johann, Bieber, Anna, Strillacci, Maria G., Gredler-Grandl, Birgit, and Flury, Christine

Subjects

*GENOMES, *BROWN Swiss cattle, *CATTLE fertility, *CATTLE parturition, *DAIRY cattle

Abstract

Background: The detection of quantitative trait loci has accelerated with recent developments in genomics. The introduction of genomic selection in combination with sequencing efforts has made a large amount of genotypic data available. Functional traits such as fertility and calving traits have been included in routine genomic estimation of breeding values making large quantities of phenotypic data available for these traits. This data was used to investigate the genetics underlying fertility and calving traits and to identify potentially causative genomic regions and variants. We performed genome-wide association studies for 13 functional traits related to female fertility as well as for direct and maternal calving ease based on imputed whole-genome sequences. Deregressed breeding values from ~1000-5000 bulls per trait were used to test for associations with approximately 10 million imputed sequence SNPs. Results: We identified a QTL on BTA17 associated with non-return rate at 56 days and with interval from first to last insemination. We found two significantly associated non-synonymous SNPs within this QTL region. Two more QTL for fertility traits were identified on BTA25 and 29. A single QTL was identified for maternal calving traits on BTA13 whereas three QTL on BTA19, 21 and 25 were identified for direct calving traits. The QTL on BTA19 co-localizes with the reported BH2 haplotype. The QTL on BTA25 is concordant for fertility and calving traits and co-localizes with a QTL previously reported to influence stature and related traits in Brown Swiss dairy cattle. Conclusion: The detection of QTL and their causative variants remains challenging. Combining comprehensive phenotypic data with imputed whole genome sequences seems promising. We present a QTL on BTA17 for female fertility in dairy cattle with two significantly associated non-synonymous SNPs, along with five additional QTL for fertility traits and calving traits. For all of these we fine mapped the regions and suggest candidate genes and candidate variants. [ABSTRACT FROM AUTHOR]

Published

2017

5. Highly accurate sequence imputation enables precise QTL mapping in Brown Swiss cattle

Author

Dorian J. Garrick, Ruedi Fries, Heidi Signer-Hasler, Mirjam Frischknecht, Beat Bapst, Christian Stricker, Hubert Pausch, Birgit Gredler-Grandl, and Christine Flury

Subjects

0301 basic medicine, Genome-wide association study, Genotyping Techniques, lcsh:QH426-470, lcsh:Biotechnology, Quantitative Trait Loci, Milk traits, Genomics, Computational biology, Quantitative trait locus, Biology, Genome, Polymorphism, Single Nucleotide, Whole genome sequencing, Imputation, Accuracy, QTL discovery, Brown Swiss, Dairy cattle, 03 medical and health sciences, lcsh:TP248.13-248.65, Genetics, Animals, Genetic association, Chromosome Mapping, Sequence Analysis, DNA, lcsh:Genetics, 030104 developmental biology, Cattle, Imputation (genetics), Biotechnology, Research Article

Abstract

BACKGROUND: Within the last few years a large amount of genomic information has become available in cattle. Densities of genomic information vary from a few thousand variants up to whole genome sequence information. In order to combine genomic information from different sources and infer genotypes for a common set of variants, genotype imputation is required. RESULTS: In this study we evaluated the accuracy of imputation from high density chips to whole genome sequence data in Brown Swiss cattle. Using four popular imputation programs (Beagle, FImpute, Impute2, Minimac) and various compositions of reference panels, the accuracy of the imputed sequence variant genotypes was high and differences between the programs and scenarios were small. We imputed sequence variant genotypes for more than 1600 Brown Swiss bulls and performed genome-wide association studies for milk fat percentage at two stages of lactation. We found one and three quantitative trait loci for early and late lactation fat content, respectively. Known causal variants that were imputed from the sequenced reference panel were among the most significantly associated variants of the genome-wide association study. CONCLUSIONS: Our study demonstrates that whole-genome sequence information can be imputed at high accuracy in cattle populations. Using imputed sequence variant genotypes in genome-wide association studies may facilitate causal variant detection., BMC Genomics, 18, ISSN:1471-2164

Published

2017