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Genetic Analysis of Chromosomal Loci Affecting the Content of Insoluble Glutenin in Common Wheat

Huaibing Jin Zhaojun Wang Da Li Peipei Wu Zhengying Dong Chaowu Rong Xin Liu Huanju Qin Huili Li Daowen Wang Kunpu Zhang

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文章导航 > Journal of Genetics and Genomics  > 2015 >  42(9): 495-505
Huaibing Jin, Zhaojun Wang, Da Li, Peipei Wu, Zhengying Dong, Chaowu Rong, Xin Liu, Huanju Qin, Huili Li, Daowen Wang, Kunpu Zhang. Genetic Analysis of Chromosomal Loci Affecting the Content of Insoluble Glutenin in Common Wheat[J]. Journal of Genetics and Genomics, 2015, 42(9): 495-505. doi: 10.1016/j.jgg.2015.04.010
Citation: Huaibing Jin, Zhaojun Wang, Da Li, Peipei Wu, Zhengying Dong, Chaowu Rong, Xin Liu, Huanju Qin, Huili Li, Daowen Wang, Kunpu Zhang. Genetic Analysis of Chromosomal Loci Affecting the Content of Insoluble Glutenin in Common Wheat[J]. Journal of Genetics and Genomics, 2015, 42(9): 495-505. doi: 10.1016/j.jgg.2015.04.010
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doi: 10.1016/j.jgg.2015.04.010
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Genetic Analysis of Chromosomal Loci Affecting the Content of Insoluble Glutenin in Common Wheat

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    The State Key Laboratory of Plant Cell and Chromosome Engineering, Institute of Genetics and Developmental Biology, Chinese Academy of Sciences, Beijing 100101, China

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    University of Chinese Academy of Sciences, Beijing 100049, China

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    Zhaoxian Institute of Agricultural Sciences, Zhaoxian 051530, China

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    Abstract: In common wheat, insoluble glutenin (IG) is an important fraction of flour glutenin macropolymers, and insoluble glutenin content (IGC) is positively associated with key end-use quality parameters. Here, we present a genetic analysis of the chromosomal loci affecting IGC with the data collected from 90 common wheat varieties cultivated in four environments. Statistical analysis showed that IGC was controlled mainly genetically and influenced by the environment. Among the major genetic components known to affect end-use quality, 1BL/1RS translocation had a significantly negative effect on IGC across all four environments. As to the different alleles of Glu-A1, -B1 and -D1 loci, Glu-A1a, Glu-B1b and Glu-D1d exhibited relatively strong positive effects on IGC in all environments. To identify new loci affecting IGC, association mapping with 1355 DArT markers was conducted. A total of 133 markers were found associated with IGC in two or more environments (P < 0.05), ten of which consistently affected IGC in all four environments. The phenotypic variance explained by the ten markers varied from 4.66% to 8.03%, and their elite alleles performed significantly better than the inferior counterparts in enhancing IGC. Among the ten markers,wPt-3743 and wPt-733835 reflected the action of Glu-D1, and wPt-664972 probably indicated the effect of Glu-A1. The other seven markers, forming three clusters on 2AL, 3BL or 7BL chromosome arms, represented newly identified genetic determinants of IGC. Our work provided novel insights into the genetic control of IGC, which may facilitate wheat end-use quality improvement through molecular breeding in the future.
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    • 参考文献(62)
  • [1] Bangur, R., Batey, I., McKenzie, E. et al. Dependence of extensograph parameters on wheat protein composition measured by SE-HPLC J. Cereal Sci., 25 (1997),pp. 237-241
    [2] Békés, F. New aspects in quality related wheat research: I. Challenges and achievements Cereal Res. Commun., 40 (2012),pp. 159-184
    [3] Békés, F. New aspects in quality related wheat research: II. New methodologies for better quality wheat Cereal Res. Commun., 40 (2012),pp. 307-333
    [4] Bogard, M., Allard, V., Brancourt-Hulmel, M. et al. Deviation from the grain protein concentration-grain yield negative relationship is highly correlated to post-anthesis N uptake in winter wheat J. Exp. Bot., 61 (2010),pp. 4303-4312
    [5] Bogard, M., Allard, V., Martre, P. et al. Identifying wheat genomic regions for improving grain protein concentration independently of grain yield using multiple inter-related populations Mol. Breed., 31 (2013),pp. 587-599
    [6] Bordes, J., Ravel, C., Le Gouis, J. et al. Use of a global wheat core collection for association analysis of flour and dough quality traits J. Cereal Sci., 54 (2011),pp. 137-147
    [7] Branlard, G., Dardevet, M., Saccomano, R. et al. Genetic diversity of wheat storage proteins and bread wheat quality Euphytica, 119 (2001),pp. 59-67
    [8] Breseghello, F., Sorrekks, M.E. Genetics, 172 (2006),pp. 1165-1177
    [9] Chai, J.F., Liu, X., Jia, J.Z. Homoeologous cloning of ω-secalin gene family in a wheat 1BL/1RS translocation Cell Res., 15 (2005),pp. 658-664
    [10] Conti, V., Roncallo, P.F., Beaufort, V. et al. Mapping of main and epistatic effect QTLs associated to grain protein and gluten strength using a RIL population of durum wheat J. Appl. Genet., 52 (2011),pp. 287-298
    [11] Couviour, F.L., Faure, S., Poupard, B. et al. Analysis of genetic structure in a panel of elite wheat varieties and relevance for association mapping Theor. Appl. Genet., 123 (2011),pp. 715-727
    [12] D'Ovidio, R., Masci, S. The low-molecular-weight glutenin subunits of wheat gluten J. Cereal Sci., 39 (2004),pp. 321-339
    [13] Delcour, J.A., Joye, I.J., Pareyt, B. et al. Wheat gluten functionality as a quality determinant in cereal-based food products Annu. Rev. Food Sci. Technol., 3 (2012),pp. 469-492
    [14] Dong, L.L., Zhang, X.F., Liu, D.C. et al. New insights into the organization, recombination, expression and functional mechanism of low molecular weight glutenin subunit genes in bread wheat PLoS One, 5 (2010),p. e13548
    [15] El-Feki, W.M., Byrne, P.F., Reid, S.D. et al. Quantitative trait locus mapping for end-use quality traits in hard winter wheat under contrasting soil moisture levels Crop Sci., 53 (2013),pp. 1953-1967
    [16] Gobaa, S., Bancel, E., Kleijer, G. et al. Effect of the 1BL.1RS translocation on the wheat endosperm, as revealed by proteomic analysis Proteomics, 7 (2007),pp. 4349-4357
    [17] Goel, S., Rathore, M., Grewal, S. et al. Agric. Res., 1 (2015),pp. 1-13
    [18] Graybosch, R.A. Uneasy unions: quality effects of rye chromatin transfers to wheat J. Cereal Sci., 33 (2001),pp. 3-16
    [19] Gupta, R.B., Khan, K., Macritchie, F. Biochemical basis of flour properties in bread wheats. I. Effects of variation in the quantity and size distribution of polymeric protein J. Cereal Sci., 18 (1993),pp. 23-41
    [20] He, Z., Bonjean, A.
    [21] He, Z.H., Liu, L., Xia, X.C. et al. Composition of HMW and LMW glutenin subunits and their effects on dough properties, pan bread, and noodle quality of Chinese bread wheats Cereal Chem., 82 (2005),pp. 345-350
    [22] Howell, T., Hale, I., Jankuloski, L. et al. Mapping a region within 1RS.1BL translocation in common wheat affecting the grain yield and canopy water status Theor. Appl. Genet., 127 (2014),pp. 2695-2709
    [23] Howitt, C.A., Gale, K.R., Juhász, A.
    [24] Hu, X.Z., Wei, Y.M., Wang, C. et al. Quantitative assessment of protein fractions of Chinese wheat flours and their contribution to white salted noodle quality Food Res. Int., 40 (2007),pp. 1-6
    [25] Huang, X.Q., Cloutier, S., Lycar, L. et al. Theor. Appl. Genet., 113 (2006),pp. 753-766
    [26] Hurni, S., Brunner, S., Stirnweis, D. et al. Plant J., 79 (2014),pp. 904-913
    [27] Khodadadi, E., Aharizad, S., Sabzi, M. et al. Combining ability analysis of bread quality in wheat Ann. Biol. Res., 3 (2012),pp. 2464-2468
    [28] Lowe, I., Jankuloski, L., Chao, S. et al. Mapping and validation of QTL which confer partial resistance to broadly virulent post-2000 North American races of stripe rust in hexaploid wheat Theor. Appl. Genet., 123 (2011),pp. 143-157
    [29] Marone, D., Laido, G., Gadaleta, A. et al. A high-density consensus map of A and B wheat genomes Theor. Appl. Genet., 125 (2012),pp. 1619-1638
    [30] Nelson, J.C., Andreescu, C., Breseghello, F. et al. Quantitative trait locus analysis of wheat quality traits Euphytica, 149 (2006),pp. 145-159
    [31] Neumann, K., Kobiljski, B., Dencic, R. et al. Mol. Breed., 27 (2011),pp. 37-58
    [32] Ng, P.K.W., Bushuk, W. Statistical relationships between high molecular weight subunits of glutenin and bread making quality of Canadian-grown wheats Cereal Chem., 65 (1988),pp. 408-424
    [33] Nishio, Z., Takata, K., Ito, M. et al. Small-scale bread-quality-test performance heritability in bread wheat: influence of high molecular weight glutenin subunits and the 1BL.1RS translocation Crop Sci., 47 (2007),pp. 1451-1458
    [34] Oury, F.-X., Godin, C. Yield and grain protein concentration in bread wheat: how to use the negative relationship between the two characters to identify favourable genotypes? Euphytica, 157 (2007),pp. 45-57
    [35] Payne, P.I., Lawrence, G.J. Cereal Res. Commun., 11 (1983),pp. 29-35
    [36] Payne, P.I. Genetics of wheat storage protein and the effect of allelic variation on breed making quality Annu. Rev. Plant Physiol., 38 (1987),pp. 141-153
    [37] Peake, A.S., Gilmour, A., Cooper, M. The 1BL/1RS translocation decreases grain yield of spring wheat germplasm in low yield environments of north-eastern Australia Crop Pasture Sci., 62 (2011),pp. 276-288
    [38] Plessis, A., Ravel, C., Bordes, J. et al. Association study of wheat grain protein composition reveals that gliadin and glutenin composition are trans-regulated by different chromosome regions J. Exp. Bot., 64 (2013),pp. 3627-3644
    [39] Pritchard, J.K., Stephens, M., Donnelly, P. Inference of population structure from multilocus genotype data Genetics, 155 (2000),pp. 945-959
    [40] Qi, P.F., Wei, Y.M., Yue, Y.W. et al. Biochemical and molecular characterization of gliadins Mol. Biol., 40 (2006),pp. 713-723
    [41] Reif, J.C., Gowda, M., Maurer, H.P. et al. Association mapping for quality traits in soft winter wheat Theor. Appl. Genet., 122 (2011),pp. 961-970
    [42] Rohlf, F.J.
    [43] Ross, A.S., Bettge, A.D.
    [44] Sapirstein, H.D., Fu, B.X. Intercultivar variation in the quantity of monomeric proteins, soluble and insoluble glutenin, and residue protein in wheat flour and relationships to breadmaking quality Cereal Chem., 75 (1998),pp. 500-507
    [45] Sapirstein, H.D., Johnson, W.J.
    [46] Shewry, P.R., Popineau, Y., Lafiandra, D. et al. The high molecular weight subunits of wheat glutenin and their role in determining wheat processing properties Adv. Food Nutr. Res., 45 (2003),pp. 219-302
    [47] Shewry, P.R., Tatham, A.S., Barro, F. et al. Biotechnology of breadmaking: unraveling and manipulating the multi-protein gluten complex Nat. Biotechnol., 13 (1995),pp. 1185-1190
    [48] Southan, M., MacRitchie, F. Molecular weight distribution of wheat proteins Cereal Chem., 76 (1999),pp. 827-836
    [49] Tarekegne, A., Labuschagne, M.T. Relationship between high molecular weight glutenin subunit composition and gluten quality in ethiopian-grown bread and durum wheat cultivars and lines J. Agron. Crop Sci., 191 (2005),pp. 300-307
    [50] Tsilo, T., Ohm, J.B., Hareland, G. et al. Quantitative trait loci influencing endosperm proteins and end-use quality traits of hard red spring wheat breeding lines Czech J. Genet. Plant Breed., 47 (2011),pp. S190-S195
    [51] Wan, Y., Liu, K.F., Wang, D. et al. Theor. Appl. Genet., 101 (2000),pp. 879-884
    [52] Wang, C., Kovacs, M.I.P. Swelling index of glutenin test. I. Method and comparison with sedimentation, gel-protein, and insoluble glutenin tests Cereal Chem., 79 (2002),pp. 183-189
    [53] Wang, C., Kovacs, M.I.P. Swelling index of glutenin test. II. Application in prediction of dough properties and end-use quality Cereal Chem., 79 (2002),pp. 190-196
    [54] Wenzl, P., Carling, J., Kudrna, D. et al. Diversity Array Technology (DArT) for whole genome profiling of barley Proc. Natl. Acad. Sci. USA, 101 (2004),pp. 9915-9920
    [55] Wieser, H. Chemistry of gluten proteins Food Microbiol., 24 (2007),pp. 115-119
    [56] Wrigley, C.W., Békés, F., Bushuk, W.
    [57] Wrigley, C.W., Asenstorfer, R., Batey, I.L. et al.
    [58] Zhang, L.Y., Liu, D.C., Guo, X.L. et al. Investigation of genetic diversity and population structure of common wheat cultivars in northern China using DArT markers BMC Genet., 12 (2011),p. 42
    [59] Zhang, X.F., Liu, D.C., Zhang, J.H. et al. Novel insight the composition, variation, organization, and expression of the low-molecular-weight glutenin subunit gene family in common wheat J. Exp. Bot., 64 (2013),pp. 2027-2040
    [60] Zhang, K.P., Wang, J.J., Zhang, L.Y. et al. Association analysis of genomic loci important for grain weight control in elite common wheat varieties cultivated with variable water and fertilizer supply PLoS One, 8 (2013),p. e57853
    [61] Zhang, Z.W., Ersoz, E., Lai, C.Q. et al. Mixed linear model approach adapted for genome wide association studies Nat. Genet., 42 (2010),pp. 355-360
    [62] Zhao, C.H., Cui, F., Wang, X.Q. et al. Effect of 1BL/1RS translocation in wheat on agronomic performance and quality characteristics Field Crop Res., 127 (2012),pp. 79-84
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出版历程
  • 收稿日期:  2014-12-22
  • 录用日期:  2015-04-27
  • 修回日期:  2015-04-10
  • 网络出版日期:  2015-07-11
  • 刊出日期:  2015-09-20

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