Abstract
Developing chromosome segments substitution lines (CSSLs) is an effective method for broadening the cotton germplasm resource, and improving the fiber quality and yield traits. In this study, the 1054 F2 individual plants and 116 F2:3 lineages were generated from the two parents of MBI9749 and MBI9915 selected from BC5F3:5 lines which originated from hybridization of CCRI36 and Hai1, and advanced backcrossing and repeated selfing. Genotypes of the parents and F2 population were analyzed. The results showed that 19 segments were introgressed for MBI9749 and 12 segments were introgressed for MBI9915, distributing on 17 linkage groups. The average background recovery rate to the recurrent parent CCRI36 was 96.70% for the two parents. An average of 16.46 segments was introgressed in F2 population. The average recovery rate of 1054 individual plants was 96.85%, and the mean length of sea island introgression segments was 157.18 cM, accounting for 3.15% of detection length. QTL mapping analysis detected 22 QTLs associated with fiber quality and yield traits in the F2 and F2:3 populations. These QTLs distributed on seven chromosomes, and the phenotypic variation was explained ranging from 1.20 to 14.61%. Four stable QTLs were detected in F2 and F2:3 populations, simultaneously. We found that eight QTLs were in agreement with the previous research. Six QTL-clusters were identified for fiber quality and yield traits, in which five QTL-clusters were on chromosome20. The results indicated that most of QTL-clusters always improve the fiber quality and have negative additive effect for yield related traits. This study demonstrated that CSSLs provide basis for fine mapping of the fiber quality and yield traits in future, and could be efficiently used for pyramiding favourable alleles to develop the new germplasms for breeding by molecular marker-assisted selection.
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References
Cai HW, Morishima H (2002) QTL clusters reflect character associations in wild and cultivated rice. Theor Appl Genet 104:1217–1228
Cao ZB, Zhu XF, Chen H et al (2015) Fine mapping of clustered quantitative trait loci for fiber quality on chromosome 7 using a Gossypium barbadense introgressed line. Mol Breed 35(11):1–13
Chen ZJ, Scheffler BE, Dennis E et al (2007) Toward sequencing cotton (Gossypium) genomes. Plant Physiol 145(4):1303–1310
Eshed Y, Zamir D (1994) A genomic library of Lycopersicon pennellii in L. esculentum: a tool for fine mapping of genes. Euphytica 79(3):175–179
Fonceka D, Tossim HA, Rivallan R et al (2012) Construction of chromosome segment substitution lines in peanut (Arachis hypogaea L.) using a wild synthetic and QTL mapping for plant morphology. PLoS ONE 7(11):e48642
Fu Y, Yuan DD, Hu WJ et al (2013) Development of Gossypium barbadense chromosome 18 segment substitution lines in the genetic standard line TM-1 of Gossypium hirsutum and mapping of QTLs related to agronomic traits. Acta Agron Sin 39(1):21–28
Guo W, Cai C, Wang C et al (2007) A microsatellite-based, gene-rich linkage map reveals genome structure, function and evolution in Gossypium. Genetics 176(1):527–541
He R (2014) The evaluation and identifying QTL of chromosome segment substitution lines (BC5F3, BC5F3:4, BC5F3:5) in CCRI36 background of Gossypium hirsutum L. Dissertation, Southwest University
He R, Shi Y, Zhang J et al (2014) QTL mapping for plant height using chromosome segment substitution lines in upland cotton. Acta Agron Sin 40(3):457–465
He Q, Yang H, Xiang S et al (2015) Fine mapping of the genetic locus L1, conferring black pods using a chromosome segment substitution line population of soybean. Plant Breed 134(4):437–445
Islam MS, Zeng L, Thyssen GN et al (2016a) Mapping by sequencing in cotton (Gossypium hirsutum) line MD52ne identified candidate genes for fiber strength and its related quality attributes. Theor Appl Genet 129(6):1071–1086
Islam MS, Fang DD, Thyssen GN et al (2016b) Comparative fiber property and transcriptome analyses reveal key genes potentially related to high fiber strength in cotton (Gossypium hirsutum L.) line MD52ne. BMC Plant Biol 16(1):36
Lan MJ, Yang ZM, Shi YZ et al (2011) Assessment of substitution lines and identification of QTL related to fiber yield and quality traits in BC4F2 and BC4F3 population from Gossypium hirsutum × Gossypium barbadense. Sci Agric Sin 44:3086–3097
Li L (2008) Molecular marker study on cotton fiber quality, yield and resistance to Verticillium wilt using advanced backcross recombinational lines between upland cotton (G. hirsutum L.) and island cotton (G. barbadense L.). Dissertation, Chinese Academy of Agriculture Sciences
Li YL, Zhou RH, Wang J et al (2012) Novel and favourable QTL allele clusters for end-use quality revealed by introgression lines derived from synthetic wheat. Mol Breed 29:627–643
Li BT, Shi YZ, Gong WK et al (2016) Genetic effects and heterosis of yield and yield component traits based on Gossypium barbadense chromosome segment substitution lines in two Gossypium hirsutum backgrounds. PLoS ONE 11(6):e0157978
Liang Y (2010) Construction of chromosome segment substitution lines and primary QTL mapping in early-maturing upland cotton. Dissertation, Chinese Academy of Agricultural Sciences
Ma LJ, Shi YZ, Lan MJ et al (2013) Evaluation of chromosome segment substitution lines related to fiber yield and quality traits from Gossypium hirsutum × Gossypium barbadense. Cotton Sci 25(6):486–495
Malik W, Ashraf J, Iqbal M et al (2014) Molecular markers and cotton genetic improvement: current status and future prospects. Sci World J. https://doi.org/10.1155/2014/607091
Manangkil OE, Vu HTT, Mori N et al (2013) Mapping of quantitative trait loci controlling seedling vigor in rice (Oryza sativa L.) under submergence. Euphytica 192(1):63–75
Marc L, Danny L, John J et al (2010) Meta-analysis of cotton fiber quality QTLs across diverse environments in a Gossypium hirsutum × G. barbadense RIL population. BMC Plant Biol 10(1):1–24
Nie XH, Tu JL, Wang B et al (2015) A BIL population derived from G. hirsutum and G. barbadense provides a resource for cotton genetics and breeding. PLoS ONE 10(10):e0141064
Ning ZY, Chen H, Mei HX et al (2014) Molecular tagging of QTLs for fiber quality and yield in the upland cotton cultivar Acala-Prema. Euphytica 195(1):143–156
Paterson AH, Brubaker C, Wendel JF (1993) A rapid method for extraction of cotton (Gossypium spp.) genomic DNA suitable for RFLP or PCR analysis. Plant Mol Biol Rep 11(2):122–127
Pillen K, Zacharias A, Leon J (2003) Advanced backcross QTL analysis in barley (Hordeum vulgare L.). Theor Appl Genet 107(2):340–352
Said JI, Lin Z, Zhang X et al (2013) A comprehensive meta QTL analysis for fiber quality, yield, yield related and morphological traits, drought tolerance, and disease resistance in tetraploid cotton. BMC Genomics 14(1):776
Shen XL, Guo WZ, Lu QX et al (2007) Genetic mapping of quantitative trait loci for fiber quality and yield trait by RIL approach in upland cotton. Euphytica 155(3):371–380
Shi YZ, Li WT, Li AG (2015) Constructing a high-density linkage map for Gossypium hirsutum × G. barbadense and identifying QTLs for lint percentage. J Integr Plant Biol 57(5):450–467
Song WW (2016) Genetic effect of the introgressed segments in the introgression line from Gossypium hirsutum × Gossypium barbadense. Dissertation, Chinese Academy of Agricultural Sciences
Sun Q, Cai YF, Xie YF et al (2010) Gene expression profiling during gland morphogenesis of a mutant and a glandless upland cotton. Mol Biol Rep 37(7):3319–3325
Tang S, Teng Z, Zhai T et al (2015) Construction of genetic map and QTL analysis of fiber quality traits for upland cotton (Gossypium hirsutum L.). Euphytica 201(2):195–213
Tomson MJ, Tai TH, Mcclung AM et al (2003) Mapping quantitative trait loci for yield, yield components and morphological traits in an advanced backcross population between Oryza fufipogon and the Oryza sativa cultivar Jefferson. Theor Appl Genet 107(3):479–493
Ulloa M, Meredith WR (2000) Genetic linkage map and QTL analysis of agronomic and fiber quality traits in an intraspecific population. J Cotton Sci 4(3):161–170
Van Berloo R (2008) GGT 2.0: versatile software for visualization and analysis of genetic data. J Hered 99(2):232–236
Voorrips RE (2002) MapChart: software for the graphical presentation of linkage maps and QTLs. J Hered 93(1):77–78
Wang J, Wan X, Crossa J et al (2006) QTL mapping of grain length in rice (Oryza sativa L.) using chromosome segment substitution lines. Genet Res 88(2):93–104
Wang FR, Gong YC, Zhang CY et al (2011) Genetic effects of introgression genomic components from Sea Island cotton (Gossypium barbadense L.) on fiber related traits in upland cotton (G. hirsutum L.). Euphytica 181(1):41–53
Wang P, Zhu Y, Song X et al (2012a) Inheritance of long staple fiber quality traits of Gossypium barbadense in G. hirsutum background using CSILs. Theor Appl Genet 124(8):1415–1428
Wang W, He Q, Yang H et al (2012b) Development of a chromosome segment substitution line population with wild soybean (Glycine soja Sieb. et Zucc.) as donor parent. Euphytica 189(2):293–307
Wang FR, Xu ZZ, Sun R et al (2013) Genetic dissection of the introgressive genomic components from Gossypium barbadense L. that contribute to improved fiber quality in Gossypium hirsutum L. Mol Breed (2013) 32:547–562
Wang H, Huang C, Guo H et al (2015) QTL mapping for fiber and yield traits in upland cotton under multiple environments. PLoS ONE 10(6):e0130742.
Wang FR, Zhang CY, Liu GD et al (2016) Phenotypic variation analysis and QTL mapping for cotton (Gossypium hirsutum L.) fiber quality grown in different cotton-producing regions. Euphytica 211(2):169–183
Wei X, Wang B, Peng Q et al (2015) Heterotic loci for various morphological traits of maize detected using a single segment substitution lines test-cross population. Mol Breed 35(3):1–13
Wu MQ, Zhang XL, Nie YC et al (2003) Localization of QTLs for yield and fiber quality traits of tetraploid cotton cultivar. Acta Genet Sin 30(5):443–452
Xu P, Zhu J, Zhang XG et al (2012) Molecular mapping and identification of QTLs for fiber micronaire on chromosome 7 from Gossypium klotzschianum. Acta Agron Sin 38(3):447–453
Yang ZM, Li JZ, Li AG et al (2009) Developing chromosome segment substitution lines (CSSLs) in cotton (Gossypium) using advanced backcross and MAS. Mol Plant Breed 7:233–241
Yang Y, Guo M, Li R et al (2015) Identification of quantitative trait loci responsible for rice grain protein content using chromosome segment substitution lines and fine mapping of qPC-1, in rice (Oryza sativa L.). Mol Breed 35(6):1–9
Yu ZW, Yu SX, Wang W et al (2007) High-density linkage map of cultivated allotetraploid cotton based on SSR, TRAP, SRAP and AFLP markers. J Integr Plant Biol 49(5):716–724
Yu J, Kohel RJ, Smith CW (2010) The construction of a tetraploid cotton genome wide comprehensive reference map. Genomics 95(4):230–240
Yu J, Zhang K, Li S et al (2013a) Mapping quantitative trait loci for lint yield and fiber quality across environments in a Gossypium hirsutum × Gossypium barbadense backcross inbred line population. Theor Appl Genet 126(1):275–287
Yu JW, Yu SX, Gore M et al (2013b) Identification of quantitative trait loci across interspecific F2, F2:3 and testcross populations for agronomic and fiber traits in tetraploid cotton. Euphytica 191(3):375–389
Yu JZ, Ulloa M, Hoffman SM et al (2014) Mapping genomic loci for cotton plant architecture, yield components, and fiber properties in an interspecific (Gossypium hirsutum L. × G. barbadense L.) RIL population. Mol Genet Genomics 289(6):1347–1367
Zeng L, Meredith WR (2011) Relationship between SSR-based genetic distance and cotton F hybrid performance for lint yield and fiber properties. Crop Sci 51(6):2362
Zhai HC, Gong WK, Tan YN et al (2016) Identification of chromosome segment substitution lines of Gossypium barbadense introgressed in G. hirsutum and quantitative trait locus mapping for fiber quality and yield traits. PLoS ONE 11(9):e0159101
Zhang J (2012) The evaluation and identifying QTL of fiber yield and quality traits of chromosome segment substitution lines (BC5F3, BC5F3:4, BC5F3:5) in upland cotton. Dissertation, Chinese Academy of Agricultural Sciences
Zhang J, Guo WZ, Zhang TZ (2002) Molecular linkage map of allotetraploid cotton (Gossypium hirsutum L. × Gossypium barbadense L.) with a haploid population. Theor Appl Genet 105:1166–1174
Zhang ZS, Hu MC, Zhang J et al (2009) Construction of a comprehensive PCR-based marker linkage map and QTL mapping for fiber quality traits in upland cotton (Gossypium hirsutum L.). Mol Breed 24(1):49–61
Zhang ZS, Rong JK, Vijay N et al (2011) QTL alleles for improved fiber quality from a wild Hawaiian cotton, Gossypium tomentosum. Theor Appl Genet 123(7):1075–1088
Zhang JF, Dan YZ, Liang Y et al (2012) Evaluation of yield and fiber quality traits of chromosome segment substitution lines population (BC5F3 and BC5F3:4) in cotton. J Plant Genet Resour 13(5):773–781
Zhao L, Yu YD, Cai CP et al (2012) Toward allotetraploid cotton genome assembly: integration of a high-density molecular genetic linkage map with DNA sequence information. BMC Genomics 13(1):539
Zhou G, Zhu Q, Yang G et al (2014) qEL7.2 is a pleiotropic QTL for kernel number per row, ear length and ear weight in maize 5 (Zea mays L.). Euphytica 203(2):429–436
Acknowledgements
This work was funded by the National Natural Science Foundation of China (31101188), the National Key R&D Program for Crop Breeding (2016YFD0100300), the National Agricultural Science and Technology Innovation Project for CAAS and the Project of Director (161016201733).
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Guo, L., Shi, Y., Gong, J. et al. Genetic analysis of the fiber quality and yield traits in G. hirsutum background using chromosome segments substitution lines (CSSLs) from Gossypium barbadense. Euphytica 214, 82 (2018). https://doi.org/10.1007/s10681-018-2158-7
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DOI: https://doi.org/10.1007/s10681-018-2158-7