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Trait Overview
Trait | fiber uniformity |
Trait Category | quality trait |
Abbreviation | FU |
Definition | The ratio between the mean length and the upper half mean length of the fibers expressed as a percentage. |
Descriptors | [view all 4] |
QTLs | [view all 526] |
Dataset | Type |
TP-BC3F2-2005 | QTL |
NCGC germplasm evaluation, AZ01 | phenotype |
NCGC germplasm evaluation, AZ02 | phenotype |
NCGC germplasm evaluation, CS07 | phenotype |
NCGC germplasm evaluation, CS08 | phenotype |
NCGC germplasm evaluation, CS09 | phenotype |
NCGC germplasm evaluation, CS10 | phenotype |
NCGC germplasm evaluation, CS11 | phenotype |
NCGC germplasm evaluation, T01 | phenotype |
NCGC germplasm evaluation, T02 | phenotype |
NCGC germplasm evaluation, T03 | phenotype |
NCGC germplasm evaluation, T04 | phenotype |
NCGC germplasm evaluation, T05 | phenotype |
NCGC germplasm evaluation, T06 | phenotype |
NCGC germplasm evaluation, T07 | phenotype |
NCGC germplasm evaluation, T08 | phenotype |
NCGC germplasm evaluation, T09 | phenotype |
NCGC germplasm evaluation, T14 | phenotype |
NCGC germplasm evaluation, T89 | phenotype |
NCGC germplasm evaluation, T91 | phenotype |
NCGC germplasm evaluation, T92 | phenotype |
NCGC germplasm evaluation, T94 | phenotype |
NCGC germplasm evaluation, T95 | phenotype |
NCGC germplasm evaluation, T96 | phenotype |
NCGC germplasm evaluation, T97 | phenotype |
NCGC germplasm evaluation, T98 | phenotype |
NCGC germplasm evaluation, WS07GH | phenotype |
NCGC germplasm evaluation, WS93GH | phenotype |
NCGC germplasm evaluation, GH06 | phenotype |
NCGC germplasm evaluation, GH07 | phenotype |
NCGC germplasm evaluation, GH08 | phenotype |
NCGC germplasm evaluation, GH10 | phenotype |
NCGC germplasm evaluation, GH11 | phenotype |
NCGC germplasm evaluation, GH12 | phenotype |
NCGC germplasm evaluation, GH | phenotype |
Uzbekistan Germplasm Evaluation | phenotype |
ILTM-F2:3-2014 | QTL |
TTT-CSIL-2016 | QTL |
GG-F2-2013 | QTL |
GG-RIL-2015 | QTL |
GG-RIL-2016 | QTL |
GVG-RIL-2016 | QTL |
GG-RIL-2016 fiber traits | phenotype |
GVG-RIL-2016 fiber traits | phenotype |
CN-F2:3-2018 | QTL |
0S-RIL-2016 | QTL |
DJiM-RIL-2015 | QTL |
SG-BIL-2013 | QTL |
CG-RIL-2018 | QTL |
CY-RIL-2015 | QTL |
Y7-RIL-2015 | QTL |
HSM-RIL-2016 | QTL |
CY-RIL-2017 | QTL |
PA-F2-2017 | QTL |
YAM-RIL-2018 | QTL |
MAGIC-19831-2018 | QTL |
HM-IF2-2018 | QTL |
9s-F2-2019 | QTL |
GG-RIL-2017 | QTL |
GG-RIL-2017 fiber traits | phenotype |
SB-F2-2019 | QTL |
HEAU 202 variety Agronomic Traits | phenotype |
RBTN 2002 | phenotype |
RBTN 2003 | phenotype |
RBTN 2004 | phenotype |
RBTN 2005 | phenotype |
RBTN 2006 | phenotype |
RBTN 2007 | phenotype |
RBTN 2008 | phenotype |
RBTN 2009 | phenotype |
RBTN 2010 | phenotype |
RBTN 2011 | phenotype |
RBTN 2012 | phenotype |
RBTN 2013 | phenotype |
RBTN 2014 | phenotype |
RBTN 2015 | phenotype |
RBTN 2016 | phenotype |
RBTN 2017 | phenotype |
RBTN 2018 | phenotype |
RBTN 2019 | phenotype |
RBTN 2020 | phenotype |
RBTN 2021 | phenotype |
DS-RIL-2022 | QTL |
RBTN 2022 | phenotype |
Year | Publication |
2022 | Gowda SA, Katageri IS, Patil RS, Kumar PS, Tiwari GJ, Jena SN, Sawant SV. 63 K and 50 K SNP array based high-density genetic mapping and QTL analysis for productivity and fiber quality traits in cotton. Euphytica. 2022; 218(7):93. |
2020 | Wang F, Zhang J, Chen Y, Zhang C, Gong J, Song Z, Zhou J, Wang J, Zhao C, Jiao M, Liu A, Du Z, Yuan Y, Fan S, Zhang J. Identification of candidate genes for key fibre‐related QTLs and derivation of favourable alleles in Gossypium hirsutum recombinant inbred lines with G. barbadense introgressions. Plant biotechnology journal. 2020; 18(3):707-720. |
2019 | Deng X, Gong J, Liu A, Shi Y, Gong W, Ge Q, Li J, Shang H, Wu Y, Yuan Y. QTL mapping for fiber quality and yield-related traits across multiple generations in segregating population of CCRI 70. Journal of Cotton Research. 2019 Sep 4; 2:13. |
2018 | Diouf L, Magwanga RO, Gong W, He S, Pan Z, Jia YH, Kirungu JN, Du X. QTL Mapping of Fiber Quality and Yield-Related Traits in an Intra-Specific Upland Cotton Using Genotype by Sequencing (GBS). International journal of molecular sciences. 2018 Feb 01; 19(2). |
2018 | Huang C, Shen C, Wen T, Gao B, Zhu , Li X, Ahmed MM, Li D, Lin Z. SSR-based association mapping of fiber quality in upland cotton using an eight-way MAGIC population. Molecular genetics and genomics : MGG. 2018 Feb 01. |
2018 | Jia X, Wang H, Pang C, Ma Q, Su J, Wei H, Song M, Fan S, Yu S. QTL delineation for five fiber quality traits based on an intra-specific Gossypium hirsutum L. recombinant inbred line population. Molecular genetics and genomics : MGG. 2018 Feb 08. |
2018 | Tan Z, Zhang Z, Sun X, Li Q, Sun Y, Yang P, Wang W, Liu X, Chen C, Liu D, Teng Z, Guo K, Zhang J, Liu D, Zhang Z. Genetic Map Construction and Fiber Quality QTL Mapping Using the CottonSNP80K Array in Upland Cotton. Frontiers in plant science. 2018; 9:225. |
2018 | Li C, Yu H, Li C, Zhao T, Dong Y, Deng X, Hu J, Zhang Y, Zhang F, Daud MK, Chen J, Zhu S. QTL Mapping and Heterosis Analysis for Fiber Quality Traits Across Multiple Genetic Populations and Environments in Upland Cotton. Frontiers in plant science. 2018; 9:1364. |
2017 | Huang C, Nie X, Shen C, You C, Li W, Zhao W, Zhang X, Lin Z. Population structure and genetic basis of the agronomic traits of upland cotton in China revealed by a genome-wide association study using high-density SNPs. Plant Biotechnol J. 2017 Nov;15(11):1374-1386. |
2017 | Wang, B, Draye, X, Zhuang, Z, Zhang, Z, Liu, M, Lubbers, EL, Jones D, May OL, Paterson AH, Chee PW. QTL analysis of cotton fiber length in advanced backcross populations derived from a cross between Gossypium hirsutum and G. mustelinum. Theor Appl Genet. 2017 Mar 27; 130:1297–1308. |
2017 | Ma L, Zhao Y, Wang Y, Shang L, Hua J. QTLs Analysis and Validation for Fiber Quality Traits Using Maternal Backcross Population in Upland Cotton. Frontiers in plant science. 2017; 8:2168. |
2016 | Shang L, Wang Y, Wang X, Liu F, Abduweli A, Cai S, Li Y, Ma L, Wang K, Hua J. Genetic Analysis and Stable QTL Detection on Fiber Quality Traits Using Two Recombinant Inbred Line Populations and Their Backcross Progeny in Upland Cotton. G3 (Bethesda, Md.). 2016 Jun 24. |
2016 | Zhang SW, Zhu XF, Feng LC, Gao X, Yang B, Zhang TZ, Zhou BL. Mapping of fiber quality QTLs reveals useful variation and footprints of cotton domestication using introgression lines. Scientific reports. 2016; 6:31954. |
2016 | Li C, Dong Y, Zhao T, Li L, Li C, Yu E, Mei L, Daud MK, He Q, Chen J, Zhu S. Genome-Wide SNP Linkage Mapping and QTL Analysis for Fiber Quality and Yield Traits in the Upland Cotton Recombinant Inbred Lines Population. Frontiers in plant science. 2016; 7:1356. |
2016 | Jamshed M, Jia F, Gong J, Palanga KK, Shi Y, Li J, Shang H, Liu A, Chen T, Zhang Z, Cai J, Ge Q, Liu Z, Lu Q, Deng X, Tan Y, Rashid H, Sarfraz Z, Hassan M, Gong W, Yuan Y. Identification of stable quantitative trait loci (QTLs) for fiber quality traits across multiple environments in Gossypium hirsutum recombinant inbred line population. BMC Genomics. 2016; 17:197. |
2015 | Wang H, Huang C, Guo H, Li X, Zhao W, Dai B, Yan Z, Lin Z. QTL Mapping for Fiber and Yield Traits in Upland Cotton under Multiple Environments. PloS one. 2015; 10(6):e0130742. |
2015 | Tang S, Teng Z, Zhai T, Fang X, Liu F, Liu D, Zhang J, Liu D, Wang S, Zhang K, Shao Q. Construction of genetic map and QTL analysis of fiber quality traits for Upland cotton (Gossypium hirsutum L.). Euphytica. 2015 Jan 1;201(2):195-213. |
2015 | Tan Z, Fang X, Tang S, Zhang J, Liu D, Teng Z, Li L, Ni H, Zheng F, Liu D, Zhang T, Paterson AH, Zhang Z. Genetic map and QTL controlling fiber quality traits in upland cotton (Gossypium hirsutum L.). Euphytica. 2015; 203:615–628. |
2013 | Liang Q, Hu C, Hua H, Li Z, Hua J. Construction of a linkage map and QTL mapping for fiber quality traits in upland cotton (Gossypium hirsutum L.). Chinese science bulletin Kexue tongbao.. 2013; 58(26):3233-3243. |
2013 | Yu J, Zhang K, Li S, Yu Y, Zhai H, Wu M, Li X, Fan S, Song M, Yang D, Li Y, Zhang J. Mapping quantitative trait loci for lint yield and fiber quality across environments in a Gossypium hirsutum x Gossypium barbadense backcross inbred line population. Theoretical and Applied Genetics. 2013; 126:275–287. |
2012 | MBR-29-335 |
2009 | MBR-24-49 |
2007 | Rong J, Feltus FA, Waghmare VN, Pierce GJ, Chee PW, Draye X, Saranga Y, Wright RJ, Wilkins TA, May OL, Smith CW, Gannaway JR, Wendel JF, Paterson AH. Meta-analysis of polyploid cotton QTL shows unequal contributions of subgenomes to a complex network of genes and gene clusters implicated in lint fiber development. Genetics. 2007 Aug; 176(4):2577-88 |
2005 | Lacape J, Nguyen T, Courtois B, Belot J, Giband M, Gourlot J, Gawryziak G, Roques S, Hau B. QTL analysis of cotton fiber quality using multiple Gossypium hirsutum x Gossypium barbadense backcross generations. Crop science. 2005; 45(1):123-140 |
2005 | Zhang Z, Xiao Y, Luo M, Li X, Luo X, Hou L, Li D, Pei Y. Construction of a genetic linkage map and QTL analysis of fiber-related traits in upland cotton (Gossypium hirsutum L.). Euphytica : international journal of plant breeding. 2005; 144(1-2):91-99 |
2005 | Chee P, Draye X, Jiang C, Decanini L, Delmonte T, Bredhauer R, Smith C, Paterson A. Molecular dissection of phenotypic variation between Gossypium hirsutum and Gossypium barbadense (cotton) by a backcross-self approach. III. Fiber length. Theoretical and applied genetics. 2005; 111(4):772-781 |
2004 | PCE-27-263 |
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