History of the progressive development of genetic marker systems for common buckwheat

Genotyping is an essential procedure for identifying agronomically useful genes and analyzing population structure. Various types of genetic marker systems have been developed in common buckwheat (Fagopyrum esculentum Moench). In the 1980s, morphological and allozyme markers were used to construct l...

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Published inBreeding Science Vol. 70; no. 1; pp. 13 - 18
Main Author Yasui, Yasuo
Format Journal Article
LanguageEnglish
Published Japan Japanese Society of Breeding 01.01.2020
Japan Science and Technology Agency
Subjects
AFLP
Agronomy
allozyme
Biomarkers
Breeding
Buckwheat
common buckwheat
Cultivation
Deoxyribonucleic acid
DNA
Fagopyrum esculentum
GBS
Gene mapping
Gene sequencing
Genetic analysis
genetic marker
Genetic markers
Genetics
Genomes
Genotyping
Grain cultivation
Invited Review
Mapping
Next-generation sequencing
Polymerase chain reaction
Population genetics
Population structure
Population studies
RAPD
SSR
Technology assessment
common buckwheat
SSR
RAPD
allozyme
AFLP
GBS
genetic marker
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Abstract Genotyping is an essential procedure for identifying agronomically useful genes and analyzing population structure. Various types of genetic marker systems have been developed in common buckwheat (Fagopyrum esculentum Moench). In the 1980s, morphological and allozyme markers were used to construct linkage maps. Until the early 2000s, allozyme markers were widely used in population genetics studies. Such studies demonstrated that cultivated common buckwheat likely originated in the Sanjiang area of China. In the late 1990s and early 2000s, advances in PCR technology led to the development of various DNA marker systems for use in linkage mapping. However, PCR-based markers did not completely cover the genome, making genetic analysis of buckwheat challenging. The subsequent development of next generation sequencing, a game-changing technology, has allowed genome-wide analysis to be performed for many species. Indeed, 8,884 markers spanning 756 loci were recently mapped onto eight linkage groups of common buckwheat; these markers were successfully used for genomic selection to increase yield. Furthermore, draft genome sequences are now available in the Buckwheat Genome DataBase (BGDB). In this review, I summarize advances in the breeding and genetic analysis of common buckwheat based on contemporary genetic marker systems.
AbstractList Genotyping is an essential procedure for identifying agronomically useful genes and analyzing population structure. Various types of genetic marker systems have been developed in common buckwheat (Fagopyrum esculentum Moench). In the 1980s, morphological and allozyme markers were used to construct linkage maps. Until the early 2000s, allozyme markers were widely used in population genetics studies. Such studies demonstrated that cultivated common buckwheat likely originated in the Sanjiang area of China. In the late 1990s and early 2000s, advances in PCR technology led to the development of various DNA marker systems for use in linkage mapping. However, PCR-based markers did not completely cover the genome, making genetic analysis of buckwheat challenging. The subsequent development of next generation sequencing, a game-changing technology, has allowed genome-wide analysis to be performed for many species. Indeed, 8,884 markers spanning 756 loci were recently mapped onto eight linkage groups of common buckwheat; these markers were successfully used for genomic selection to increase yield. Furthermore, draft genome sequences are now available in the Buckwheat Genome DataBase (BGDB). In this review, I summarize advances in the breeding and genetic analysis of common buckwheat based on contemporary genetic marker systems.
Genotyping is an essential procedure for identifying agronomically useful genes and analyzing population structure. Various types of genetic marker systems have been developed in common buckwheat ( Fagopyrum esculentum Moench). In the 1980s, morphological and allozyme markers were used to construct linkage maps. Until the early 2000s, allozyme markers were widely used in population genetics studies. Such studies demonstrated that cultivated common buckwheat likely originated in the Sanjiang area of China. In the late 1990s and early 2000s, advances in PCR technology led to the development of various DNA marker systems for use in linkage mapping. However, PCR-based markers did not completely cover the genome, making genetic analysis of buckwheat challenging. The subsequent development of next generation sequencing, a game-changing technology, has allowed genome-wide analysis to be performed for many species. Indeed, 8,884 markers spanning 756 loci were recently mapped onto eight linkage groups of common buckwheat; these markers were successfully used for genomic selection to increase yield. Furthermore, draft genome sequences are now available in the B uckwheat G enome D ata B ase (BGDB). In this review, I summarize advances in the breeding and genetic analysis of common buckwheat based on contemporary genetic marker systems.
Genotyping is an essential procedure for identifying agronomically useful genes and analyzing population structure. Various types of genetic marker systems have been developed in common buckwheat ( Moench). In the 1980s, morphological and allozyme markers were used to construct linkage maps. Until the early 2000s, allozyme markers were widely used in population genetics studies. Such studies demonstrated that cultivated common buckwheat likely originated in the Sanjiang area of China. In the late 1990s and early 2000s, advances in PCR technology led to the development of various DNA marker systems for use in linkage mapping. However, PCR-based markers did not completely cover the genome, making genetic analysis of buckwheat challenging. The subsequent development of next generation sequencing, a game-changing technology, has allowed genome-wide analysis to be performed for many species. Indeed, 8,884 markers spanning 756 loci were recently mapped onto eight linkage groups of common buckwheat; these markers were successfully used for genomic selection to increase yield. Furthermore, draft genome sequences are now available in the Buckwheat Genome DataBase (BGDB). In this review, I summarize advances in the breeding and genetic analysis of common buckwheat based on contemporary genetic marker systems.
Author Yasui, Yasuo
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Issue 1
Keywords common buckwheat
SSR
RAPD
allozyme
AFLP
GBS
genetic marker
Language English
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SubjectTerms AFLP
Agronomy
allozyme
Biomarkers
Breeding
Buckwheat
common buckwheat
Cultivation
Deoxyribonucleic acid
DNA
Fagopyrum esculentum
GBS
Gene mapping
Gene sequencing
Genetic analysis
genetic marker
Genetic markers
Genetics
Genomes
Genotyping
Grain cultivation
Invited Review
Mapping
Next-generation sequencing
Polymerase chain reaction
Population genetics
Population structure
Population studies
RAPD
SSR
Technology assessment
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Title History of the progressive development of genetic marker systems for common buckwheat
URI https://www.jstage.jst.go.jp/article/jsbbs/70/1/70_19075/_article/-char/en
https://www.ncbi.nlm.nih.gov/pubmed/32351300
https://www.proquest.com/docview/2383080844
https://search.proquest.com/docview/2396858824
https://pubmed.ncbi.nlm.nih.gov/PMC7180146
Volume 70
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ispartofPNX Breeding Science, 2020, Vol.70(1), pp.13-18
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