Mapping quantitative trait loci for lint yield and fiber quality across environments in a Gossypium hirsutum × Gossypium barbadense backcross inbred line population

Yu, Jie-Ae; Zhang, Ke; Li, Shuaiyang; Yu, Shuang; Zhai, Huan-Chen; Wu, Man; Li, Xingli; Fan, Shuli; Song, Meizhen; Yang, Daigang; Li, Yunhai; Zhang, Jinfa

doi:10.1007/s00122-012-1980-x

Cited by 151 publications

(148 citation statements)

References 42 publications

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“…These difficulties have been reported in similar studies with other interspecific populations (Lacape et al 2010(Lacape et al , 2013Marathi et al 2012;Yu et al 2013;Zhu et al 2011). …”

Section: Plant Materialssupporting

confidence: 76%

“…Regardless of these difficulties, such segregating populations were used to map cotton yield and quality QTLs, and comparable data were obtained for traits across the multiple environment locations in other studies (Lacape et al 2013;Yu et al 2013). RIL populations are usually extended beyond F 6 -F 9 generations which have provided better genetic uniformity of trait response (homozygous alleles), reducing the external or environmental effects as compared to early generations on such traits as fiber yield that may not be highly precise due to the limited information in this area.…”

Section: Discussionmentioning

confidence: 99%

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Mapping genomic loci for cotton plant architecture, yield components, and fiber properties in an interspecific (Gossypium hirsutum L. × G. barbadense L.) RIL population

Ulloa²,

Hoffman

et al. 2014

Mol Genet Genomics

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A quantitative trait locus (QTL) mapping was conducted to better understand the genetic control of plant architecture (PA), yield components (YC), and fiber properties (FP) in the two cultivated tetraploid species of cotton (Gossypium hirsutum L. and G. barbadense L.). One hundred and fifty-nine genomic regions were identified on a saturated genetic map of more than 2,500 SSR and SNP markers, constructed with an interspecific recombinant inbred line (RIL) population derived from the genetic standards of the respective cotton species (G. hirsutum acc. TM-1 × G. barbadense acc. 3-79). Using the single nonparametric and MQM QTL model mapping procedures, we detected 428 putative loci in the 159 genomic regions that confer 24 cotton traits in three diverse production environments [College Station F&B Road (FB), TX; Brazos Bottom (BB), TX; and Shafter (SH), CA]. These putative QTL loci included 25 loci for PA, 60 for YC, and 343 for FP, of which 3, 12, and 60, respectively, were strongly associated with the traits (LOD score ≥ 3.0). Approximately 17.7 % of the PA putative QTL, 32.9 % of the YC QTL, and 48.3 % of the FP QTL had trait associations under multiple environments. The At subgenome (chromosomes 1-13) contributed 72.7 % of loci for PA, 46.2 % for YC, and 50.4 % for FP while the Dt subgenome (chromosomes 14-26) contributed 27.3 % of loci for PA, 53.8 % for YC, and 49.6 % for FP. The data obtained from this study augment prior evidence of QTL clusters or gene islands for specific traits or biological functions existing in several non-homoeologous cotton chromosomes. DNA markers identified in the 159 genomic regions will facilitate further dissection of genetic factors underlying these important traits and marker-assisted selection in cotton.

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“…These difficulties have been reported in similar studies with other interspecific populations (Lacape et al 2010(Lacape et al , 2013Marathi et al 2012;Yu et al 2013;Zhu et al 2011). …”

Section: Plant Materialssupporting

confidence: 76%

Section: Discussionmentioning

confidence: 99%

Mapping genomic loci for cotton plant architecture, yield components, and fiber properties in an interspecific (Gossypium hirsutum L. × G. barbadense L.) RIL population

Ulloa²,

Hoffman

et al. 2014

Mol Genet Genomics

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“…DP5690 impressively elongate up to 30 mm in 4 weeks of development with fastest elongation around 8 days post anthesis (DPA), the Li 1 fiber cells only extend about 3 mm when fully mature (Gilbert et al 2013). The single dominant gene that confers this qualitative short fiber phenotype has previously been mapped to a region of chromosome 22 that has also been repeatedly identified in studies of quantitative cotton fiber traits, including quantitative trail loci (QTLs) for fiber length, fiber uniformity and yield of seed cotton Fang et al 2014;Jiang et al 1998;Karaca et al 2002;Rong et al 2005;Yu et al 2013). Despite many approaches including identification of differentially expressed proteins and transcripts, the number of candidate genes for the Li 1 mutation remains very high (Ding et al 2014;Gilbert et al 2013;Liu et al 2012;Zhao et al 2009).…”

Section: Introductionmentioning

confidence: 99%

Mapping-by-sequencing of Ligon-lintless-1 (Li 1 ) reveals a cluster of neighboring genes with correlated expression in developing fibers of Upland cotton (Gossypium hirsutum L.)

Thyssen

Fang

Turley³

et al. 2015

Theor Appl Genet

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Mapping-by-sequencing and SNP marker analysis were used to fine map the Ligon-lintless-1 ( Li 1 ) short fiber mutation in tetraploid cotton to a 255-kb region that contains 16 annotated proteins. The Ligon-lintless-1 (Li 1 ) mutant of cotton (Gossypium hirsutum L.) has been studied as a model for cotton fiber development since its identification in 1929; however, the causative mutation has not been identified yet. Here we report the fine genetic mapping of the mutation to a 255-kb region that contains only 16 annotated genes in the reference Gossypium raimondii genome. We took advantage of the incompletely dominant dwarf vegetative phenotype to identify 100 mutants (Li 1 /Li 1 ) and 100 wild-type (li 1 /li 1 ) homozygotes from a mapping population of 2567 F2 plants, which we bulked and deep sequenced. Since only homozygotes were sequenced, we were able to use a high stringency in SNP calling to rapidly narrow down the region harboring the Li 1 locus, and designed subgenome-specific SNP markers to test the population. We characterized the expression of all sixteen genes in the region by RNA sequencing of elongating fibers and by RT-qPCR at seven time points spanning fiber development. One of the most highly expressed genes found in this interval in wild-type fiber cells is 40-fold under-expressed at the day of anthesis (DOA) in the mutant fiber cells. This gene is a major facilitator superfamily protein, part of the large family of proteins that includes auxin and sugar transporters. Interestingly, nearly all genes in this region were most highly expressed at DOA and showed a high degree of co-expression. Further characterization is required to determine if transport of hormones or carbohydrates is involved in both the dwarf and lintless phenotypes of Li 1 plants.

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“…With the advancements in molecular marker technology, marker-assisted selection (MAS) combined with conventional backcrossing has become an effective technique for introducing multiple traits. One example of this approach is the construction of genetic maps for cotton genomes, using SSR markers (e.g., Ulloa and Meredith 2000;Lacape et al 2003;Mei et al 2004;Nguyen et al 2004;Han et al 2004;Lin et al 2005;Yu et al2007;Guo et al 2008;Zhang et al 2009Zhang et al , 2012Sun et al 2012;Yu et al 2013;Wang et al 2013a, b). Other molecular marker systems have also provided valuable tools for genetic dissection of complex traits; For example, complementary DNA (cDNA) -amplified fragment length polymorphism (AFLP) has been applied to detect coding sequence polymorphisms of target genes in a segregating population, so that these transcript polymorphisms can be directly used as genetic markers (e.g., Biezen et al 2000;Lister and Dean 1993;Brugmans et al 2002;Liu et al 2009).…”

Section: Introductionmentioning

confidence: 99%

Mapping QTL for cotton fiber quality traits using simple sequence repeat markers, conserved intron-scanning primers, and transcript-derived fragments

et al. 2014

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Cotton is an important fiber crop worldwide. Improved fiber quality is a driving force for cotton genetic studies and breeding. A BC 1 population containing 115 individuals from a cross between Gossypium hirsutum cv. CCRI8 and G. barbadense cv. Pima 90-53 was established, and 519 simple sequence repeat (SSR) markers, two conserved intronscanning primers (CISPs), and transcript-derived fragments (TDFs) amplified from 156 ApoI/TaqI selective primer combinations were used to construct a genetic linkage map. The map included 579 markers distributed on 56 linkage groups. Accounting for 83.4 % of the cotton genome, it covered 4,168.72 cM, with an average distance of 7.19 cM between markers. Lengths of the linkage groups ranged from 1.25 to 255.79 cM, with 2 to 44 markers per group. Of these 56 groups, 43 were assigned to 26 chromosomes, with the remaining 13 unknown. Based on this newly constructed map of tetraploid cotton, we performed quantitative trait loci (QTL) mapping and analysis of fiber quality traits from the BC 1 and its derived BC 1 F 2 lines. A total of 44 fiber quality QTL were detected on 17 chromosomes, explaining 7.72-23.73 % of the phenotypic variation. Pima 90-53 offered 13 QTL alleles with positive additive effects and four with negative additive effects for fiber quality traits. The results from this study may provide useful information for breeders to transfer desirable fiber traits from cotton types, such as the Sea Island strain, to Upland cotton that is primarily cultivated currently.

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Mapping quantitative trait loci for lint yield and fiber quality across environments in a Gossypium hirsutum × Gossypium barbadense backcross inbred line population

Cited by 151 publications

References 42 publications

Mapping genomic loci for cotton plant architecture, yield components, and fiber properties in an interspecific (Gossypium hirsutum L. × G. barbadense L.) RIL population

Mapping genomic loci for cotton plant architecture, yield components, and fiber properties in an interspecific (Gossypium hirsutum L. × G. barbadense L.) RIL population

Mapping-by-sequencing of Ligon-lintless-1 (Li 1 ) reveals a cluster of neighboring genes with correlated expression in developing fibers of Upland cotton (Gossypium hirsutum L.)

Mapping QTL for cotton fiber quality traits using simple sequence repeat markers, conserved intron-scanning primers, and transcript-derived fragments

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