Bridging the genotyping gap: using genotyping by sequencing (GBS) to add high-density SNP markers and new value to traditional bi-parental mapping and breeding populations
Genotyping by sequencing (GBS) is the latest application of next-generation sequencing protocols for the purposes of discovering and genotyping SNPs in a variety of crop species and populations. Unlike other high-density genotyping technologies which have mainly been applied to general interest “ref...
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| Veröffentlicht in: | Theoretical and applied genetics 2013-11, Vol.126 (11), p.2699-2716 |
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| creator | Spindel, Jennifer Wright, Mark Chen, Charles Cobb, Joshua Gage, Joseph Harrington, Sandra Lorieux, Mathias Ahmadi, Nourollah McCouch, Susan |
| description | Genotyping by sequencing (GBS) is the latest application of next-generation sequencing protocols for the purposes of discovering and genotyping SNPs in a variety of crop species and populations. Unlike other high-density genotyping technologies which have mainly been applied to general interest “reference” genomes, the low cost of GBS makes it an attractive means of saturating mapping and breeding populations with a high density of SNP markers. One barrier to the widespread use of GBS has been the difficulty of the bioinformatics analysis as the approach is accompanied by a high number of erroneous SNP calls which are not easily diagnosed or corrected. In this study, we use a 384-plex GBS protocol to add 30,984 markers to an indica (IR64) × japonica (Azucena) mapping population consisting of 176 recombinant inbred lines of rice (Oryza sativa) and we release our imputation and error correction pipeline to address initial GBS data sparsity and error, and streamline the process of adding SNPs to RIL populations. Using the final imputed and corrected dataset of 30,984 markers, we were able to map recombination hot and cold spots and regions of segregation distortion across the genome with a high degree of accuracy, thus identifying regions of the genome containing putative sterility loci. We mapped QTL for leaf width and aluminum tolerance, and were able to identify additional QTL for both phenotypes when using the full set of 30,984 SNPs that were not identified using a subset of only 1,464 SNPs, including a previously unreported QTL for aluminum tolerance located directly within a recombination hotspot on chromosome 1. These results suggest that adding a high density of SNP markers to a mapping or breeding population through GBS has a great value for numerous applications in rice breeding and genetics research. |
| doi_str_mv | 10.1007/s00122-013-2166-x |
| format | Article |
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Using the final imputed and corrected dataset of 30,984 markers, we were able to map recombination hot and cold spots and regions of segregation distortion across the genome with a high degree of accuracy, thus identifying regions of the genome containing putative sterility loci. We mapped QTL for leaf width and aluminum tolerance, and were able to identify additional QTL for both phenotypes when using the full set of 30,984 SNPs that were not identified using a subset of only 1,464 SNPs, including a previously unreported QTL for aluminum tolerance located directly within a recombination hotspot on chromosome 1. 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Unlike other high-density genotyping technologies which have mainly been applied to general interest “reference” genomes, the low cost of GBS makes it an attractive means of saturating mapping and breeding populations with a high density of SNP markers. One barrier to the widespread use of GBS has been the difficulty of the bioinformatics analysis as the approach is accompanied by a high number of erroneous SNP calls which are not easily diagnosed or corrected. In this study, we use a 384-plex GBS protocol to add 30,984 markers to an indica (IR64) × japonica (Azucena) mapping population consisting of 176 recombinant inbred lines of rice (Oryza sativa) and we release our imputation and error correction pipeline to address initial GBS data sparsity and error, and streamline the process of adding SNPs to RIL populations. Using the final imputed and corrected dataset of 30,984 markers, we were able to map recombination hot and cold spots and regions of segregation distortion across the genome with a high degree of accuracy, thus identifying regions of the genome containing putative sterility loci. We mapped QTL for leaf width and aluminum tolerance, and were able to identify additional QTL for both phenotypes when using the full set of 30,984 SNPs that were not identified using a subset of only 1,464 SNPs, including a previously unreported QTL for aluminum tolerance located directly within a recombination hotspot on chromosome 1. These results suggest that adding a high density of SNP markers to a mapping or breeding population through GBS has a great value for numerous applications in rice breeding and genetics research.</description><subject>Adaptation, Physiological - drug effects</subject><subject>Adaptation, Physiological - genetics</subject><subject>Agriculture</subject><subject>Aluminum</subject><subject>Aluminum - toxicity</subject><subject>Bar codes</subject><subject>Biochemistry</subject><subject>Biomedical and Life Sciences</subject><subject>Biotechnology</subject><subject>Breeding</subject><subject>Chromosome Breakage</subject><subject>Chromosome Mapping - methods</subject><subject>Chromosome Segregation - genetics</subject><subject>cultivars</subject><subject>data collection</subject><subject>DNA methylation</subject><subject>DNA sequencing</subject><subject>Enzymes</subject><subject>Genetic Markers</subject><subject>Genetic testing</subject><subject>Genetics</subject><subject>genome</subject><subject>Genomes</subject><subject>Genotype</subject><subject>genotyping</subject><subject>Genotyping Techniques - methods</subject><subject>inbred lines</subject><subject>leaves</subject><subject>Life Sciences</subject><subject>loci</subject><subject>Nucleotide sequencing</subject><subject>Original Paper</subject><subject>Oryza - genetics</subject><subject>Oryza sativa</subject><subject>phenotype</subject><subject>Plant Biochemistry</subject><subject>Plant Breeding/Biotechnology</subject><subject>Plant Genetics and Genomics</subject><subject>Plant Leaves - anatomy & histology</subject><subject>Plant Leaves - drug effects</subject><subject>Polymorphism, Single Nucleotide - genetics</subject><subject>Population genetics</subject><subject>quantitative trait loci</subject><subject>Quantitative Trait Loci - genetics</subject><subject>Recombination, Genetic - genetics</subject><subject>Rice</subject><subject>segregation distortion</subject><subject>Sequence Analysis, DNA - methods</subject><subject>single nucleotide polymorphism</subject><subject>Single nucleotide polymorphisms</subject><issn>0040-5752</issn><issn>1432-2242</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2013</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><sourceid>BENPR</sourceid><recordid>eNp9ksFu1DAURSMEokPhA9iAJTbtIsV-djIJu7aipVIFiKFry4lfMi4ZJ9gOzHwTP1mnUyiDUOWF_exzn3XtmyQvGT1ilM7fekoZQEoZT4Hlebp-lMyY4JACCHiczCgVNM3mGewlz7y_ppRCRvnTZA94yQqawyz5deKMbo1tSVgiadH2YTNMZauGd2T0t8v73WpDPH4f0dZTdXB-sjgkoSdKa7I07TLVaL0JG7L4-JmslPuGzhNlNbH4k_xQ3YgTHZzSJpjeqo5UJh2UQxvieqWG20smQeUQ9VQM_TB2aqL98-RJozqPL-7m_eTq7P3X0w_p5afzi9Pjy7TOgYZ0zkRBudLRoFaaoSqh0bwEwYuyrAqssFSs4iJHrUDUDOoqa4A3RZXlDErG95ODbd_B9dGrD3JlfI1dpyz2o5dMZEUGWclpRN_8g173o4vGJkpkrMhZxu6pVnUojW36-AT11FQe8wyAAxUQqaP_UHFoXJm6t9iYuL8jONwRRCbgOrRq9F5eLL7ssmzL1q733mEjB2fiD20ko3IKk9yGScYwySlMch01r-7MjdUK9R_F7_REALaAj0e2RfeX-we6vt6KGtVL1Trj5dUCKBMxnjynYv4gweYFLfgN6FPmDA</recordid><startdate>20131101</startdate><enddate>20131101</enddate><creator>Spindel, Jennifer</creator><creator>Wright, Mark</creator><creator>Chen, Charles</creator><creator>Cobb, Joshua</creator><creator>Gage, Joseph</creator><creator>Harrington, Sandra</creator><creator>Lorieux, Mathias</creator><creator>Ahmadi, Nourollah</creator><creator>McCouch, Susan</creator><general>Springer-Verlag</general><general>Springer Berlin Heidelberg</general><general>Springer</general><general>Springer Nature B.V</general><scope>FBQ</scope><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>ISR</scope><scope>3V.</scope><scope>7SS</scope><scope>7TK</scope><scope>7X7</scope><scope>7XB</scope><scope>88A</scope><scope>88E</scope><scope>8AO</scope><scope>8FD</scope><scope>8FE</scope><scope>8FH</scope><scope>8FI</scope><scope>8FJ</scope><scope>8FK</scope><scope>ABUWG</scope><scope>AFKRA</scope><scope>AZQEC</scope><scope>BBNVY</scope><scope>BENPR</scope><scope>BHPHI</scope><scope>CCPQU</scope><scope>DWQXO</scope><scope>FR3</scope><scope>FYUFA</scope><scope>GHDGH</scope><scope>GNUQQ</scope><scope>HCIFZ</scope><scope>K9.</scope><scope>LK8</scope><scope>M0S</scope><scope>M1P</scope><scope>M7P</scope><scope>P64</scope><scope>PQEST</scope><scope>PQQKQ</scope><scope>PQUKI</scope><scope>PRINS</scope><scope>RC3</scope></search><sort><creationdate>20131101</creationdate><title>Bridging the genotyping gap: using genotyping by sequencing (GBS) to add high-density SNP markers and new value to traditional bi-parental mapping and breeding populations</title><author>Spindel, Jennifer ; Wright, Mark ; Chen, Charles ; Cobb, Joshua ; Gage, Joseph ; Harrington, Sandra ; Lorieux, Mathias ; Ahmadi, Nourollah ; McCouch, Susan</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c620t-714803ad806dad1ea92fd39243899b8ebe9a1b346eda24c12cb5f23f8b5612913</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2013</creationdate><topic>Adaptation, Physiological - drug effects</topic><topic>Adaptation, Physiological - genetics</topic><topic>Agriculture</topic><topic>Aluminum</topic><topic>Aluminum - toxicity</topic><topic>Bar codes</topic><topic>Biochemistry</topic><topic>Biomedical and Life Sciences</topic><topic>Biotechnology</topic><topic>Breeding</topic><topic>Chromosome Breakage</topic><topic>Chromosome Mapping - methods</topic><topic>Chromosome Segregation - genetics</topic><topic>cultivars</topic><topic>data collection</topic><topic>DNA methylation</topic><topic>DNA sequencing</topic><topic>Enzymes</topic><topic>Genetic Markers</topic><topic>Genetic testing</topic><topic>Genetics</topic><topic>genome</topic><topic>Genomes</topic><topic>Genotype</topic><topic>genotyping</topic><topic>Genotyping Techniques - methods</topic><topic>inbred lines</topic><topic>leaves</topic><topic>Life Sciences</topic><topic>loci</topic><topic>Nucleotide sequencing</topic><topic>Original Paper</topic><topic>Oryza - genetics</topic><topic>Oryza sativa</topic><topic>phenotype</topic><topic>Plant Biochemistry</topic><topic>Plant Breeding/Biotechnology</topic><topic>Plant Genetics and Genomics</topic><topic>Plant Leaves - 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Unlike other high-density genotyping technologies which have mainly been applied to general interest “reference” genomes, the low cost of GBS makes it an attractive means of saturating mapping and breeding populations with a high density of SNP markers. One barrier to the widespread use of GBS has been the difficulty of the bioinformatics analysis as the approach is accompanied by a high number of erroneous SNP calls which are not easily diagnosed or corrected. In this study, we use a 384-plex GBS protocol to add 30,984 markers to an indica (IR64) × japonica (Azucena) mapping population consisting of 176 recombinant inbred lines of rice (Oryza sativa) and we release our imputation and error correction pipeline to address initial GBS data sparsity and error, and streamline the process of adding SNPs to RIL populations. Using the final imputed and corrected dataset of 30,984 markers, we were able to map recombination hot and cold spots and regions of segregation distortion across the genome with a high degree of accuracy, thus identifying regions of the genome containing putative sterility loci. We mapped QTL for leaf width and aluminum tolerance, and were able to identify additional QTL for both phenotypes when using the full set of 30,984 SNPs that were not identified using a subset of only 1,464 SNPs, including a previously unreported QTL for aluminum tolerance located directly within a recombination hotspot on chromosome 1. These results suggest that adding a high density of SNP markers to a mapping or breeding population through GBS has a great value for numerous applications in rice breeding and genetics research.</abstract><cop>Berlin/Heidelberg</cop><pub>Springer-Verlag</pub><pmid>23918062</pmid><doi>10.1007/s00122-013-2166-x</doi><tpages>18</tpages></addata></record> |
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| ispartof | Theoretical and applied genetics, 2013-11, Vol.126 (11), p.2699-2716 |
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| source | MEDLINE; Springer Journals |
| subjects | Adaptation, Physiological - drug effects Adaptation, Physiological - genetics Agriculture Aluminum Aluminum - toxicity Bar codes Biochemistry Biomedical and Life Sciences Biotechnology Breeding Chromosome Breakage Chromosome Mapping - methods Chromosome Segregation - genetics cultivars data collection DNA methylation DNA sequencing Enzymes Genetic Markers Genetic testing Genetics genome Genomes Genotype genotyping Genotyping Techniques - methods inbred lines leaves Life Sciences loci Nucleotide sequencing Original Paper Oryza - genetics Oryza sativa phenotype Plant Biochemistry Plant Breeding/Biotechnology Plant Genetics and Genomics Plant Leaves - anatomy & histology Plant Leaves - drug effects Polymorphism, Single Nucleotide - genetics Population genetics quantitative trait loci Quantitative Trait Loci - genetics Recombination, Genetic - genetics Rice segregation distortion Sequence Analysis, DNA - methods single nucleotide polymorphism Single nucleotide polymorphisms |
| title | Bridging the genotyping gap: using genotyping by sequencing (GBS) to add high-density SNP markers and new value to traditional bi-parental mapping and breeding populations |
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