Uncovering the Genetic Architecture of Seed Weight and Size in Intermediate Wheatgrass through Linkage and Association Mapping
Intermediate wheatgrass [IWG; (Host) Barkworth & D.R. Dewey subsp. ] is being developed as a new perennial grain crop that has a large allohexaploid genome similar to that of wheat ( L.). Breeding for increased seed weight is one of the primary goals for improving grain yield of IWG. As a new c...
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Wiley
2017-11-01
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| Series: | The Plant Genome |
| Online Access: | https://dl.sciencesocieties.org/publications/tpg/articles/10/3/plantgenome2017.03.0022 |
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doaj-b15914cffc9449c2b175e5478c1205ad2020-11-25T03:16:23ZengWileyThe Plant Genome1940-33722017-11-0110310.3835/plantgenome2017.03.0022Uncovering the Genetic Architecture of Seed Weight and Size in Intermediate Wheatgrass through Linkage and Association MappingXiaofei ZhangSteven R. LarsonLiangliang GaoSoon Li TehLee R. DeHaanMax FraserAhmad SallamTraci KantarskiKatherine FrelsJesse PolandDonald WyseJames A. AndersonIntermediate wheatgrass [IWG; (Host) Barkworth & D.R. Dewey subsp. ] is being developed as a new perennial grain crop that has a large allohexaploid genome similar to that of wheat ( L.). Breeding for increased seed weight is one of the primary goals for improving grain yield of IWG. As a new crop, however, the genetic architecture of seed weight and size has not been characterized, and selective breeding of IWG may be more intricate than wheat because of its self-incompatible mating system and perennial growth habit. Here, seed weight, seed area size, seed width, and seed length were evaluated across multiple years, in a heterogeneous breeding population comprised of 1126 genets and two clonally replicated biparental populations comprised of 172 and 265 genets. Among 10,171 DNA markers discovered using genotyping-by-sequencing (GBS) in the breeding population, 4731 markers were present in a consensus genetic map previously constructed using seven full-sib populations. Thirty-three quantitative trait loci (QTL) associated with seed weight and size were identified using association mapping (AM), of which 23 were verified using linkage mapping in the biparental populations. About 37.6% of seed weight variation in the breeding population was explained by 15 QTL, 12 of which also contributed to either seed length or seed width. When performing either phenotypic selection or genomic selection for seed weight, we observed the frequency of favorable QTL alleles were increased to >46%. Thus, by combining AM and genomic selection, we can effectively select the favorable QTL alleles for seed weight and size in IWG breeding populations.https://dl.sciencesocieties.org/publications/tpg/articles/10/3/plantgenome2017.03.0022 |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Xiaofei Zhang Steven R. Larson Liangliang Gao Soon Li Teh Lee R. DeHaan Max Fraser Ahmad Sallam Traci Kantarski Katherine Frels Jesse Poland Donald Wyse James A. Anderson |
| spellingShingle |
Xiaofei Zhang Steven R. Larson Liangliang Gao Soon Li Teh Lee R. DeHaan Max Fraser Ahmad Sallam Traci Kantarski Katherine Frels Jesse Poland Donald Wyse James A. Anderson Uncovering the Genetic Architecture of Seed Weight and Size in Intermediate Wheatgrass through Linkage and Association Mapping The Plant Genome |
| author_facet |
Xiaofei Zhang Steven R. Larson Liangliang Gao Soon Li Teh Lee R. DeHaan Max Fraser Ahmad Sallam Traci Kantarski Katherine Frels Jesse Poland Donald Wyse James A. Anderson |
| author_sort |
Xiaofei Zhang |
| title |
Uncovering the Genetic Architecture of Seed Weight and Size in Intermediate Wheatgrass through Linkage and Association Mapping |
| title_short |
Uncovering the Genetic Architecture of Seed Weight and Size in Intermediate Wheatgrass through Linkage and Association Mapping |
| title_full |
Uncovering the Genetic Architecture of Seed Weight and Size in Intermediate Wheatgrass through Linkage and Association Mapping |
| title_fullStr |
Uncovering the Genetic Architecture of Seed Weight and Size in Intermediate Wheatgrass through Linkage and Association Mapping |
| title_full_unstemmed |
Uncovering the Genetic Architecture of Seed Weight and Size in Intermediate Wheatgrass through Linkage and Association Mapping |
| title_sort |
uncovering the genetic architecture of seed weight and size in intermediate wheatgrass through linkage and association mapping |
| publisher |
Wiley |
| series |
The Plant Genome |
| issn |
1940-3372 |
| publishDate |
2017-11-01 |
| description |
Intermediate wheatgrass [IWG; (Host) Barkworth & D.R. Dewey subsp. ] is being developed as a new perennial grain crop that has a large allohexaploid genome similar to that of wheat ( L.). Breeding for increased seed weight is one of the primary goals for improving grain yield of IWG. As a new crop, however, the genetic architecture of seed weight and size has not been characterized, and selective breeding of IWG may be more intricate than wheat because of its self-incompatible mating system and perennial growth habit. Here, seed weight, seed area size, seed width, and seed length were evaluated across multiple years, in a heterogeneous breeding population comprised of 1126 genets and two clonally replicated biparental populations comprised of 172 and 265 genets. Among 10,171 DNA markers discovered using genotyping-by-sequencing (GBS) in the breeding population, 4731 markers were present in a consensus genetic map previously constructed using seven full-sib populations. Thirty-three quantitative trait loci (QTL) associated with seed weight and size were identified using association mapping (AM), of which 23 were verified using linkage mapping in the biparental populations. About 37.6% of seed weight variation in the breeding population was explained by 15 QTL, 12 of which also contributed to either seed length or seed width. When performing either phenotypic selection or genomic selection for seed weight, we observed the frequency of favorable QTL alleles were increased to >46%. Thus, by combining AM and genomic selection, we can effectively select the favorable QTL alleles for seed weight and size in IWG breeding populations. |
| url |
https://dl.sciencesocieties.org/publications/tpg/articles/10/3/plantgenome2017.03.0022 |
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