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Home > Archive>Volume 24, Issue 6, 2023 >1690-1701. DOI:10.13430/j.cnki.jpgr.20230329002
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Genetic Effects Analysis of qPh-3D, a Major QTL for Plant Height in Common Wheat
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Affiliation:

1.School of Agriculture, Ludong University/ Key Laboratory of Molecular Module-Based Breeding of High Yield and Abiotic Resistant Plants in Universities of Shandong,Yantai 264025;2.Jingbo Agrochemicals Technology Co.,Ltd., Binzhou 256500,Shandong

Fund Project:

Foundation projects: Key R&D Program of Shandong Province (Major Innovation Project) (2022LZG002-2); National Natural Science Foundation of China (32101726, 32072051, 32272119)

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    Abstract:

    qPh-3D is a major quantitative trait locus (QTL) regulating plant height (PH) in wheat. This locus could be repeatedly identified in datasets at 14 different environments in the recombinant inbred line (RIL) population derived from the cross between Kenong 9204 and Jing 411 (denoted as KJ-RILs). qPh-3D was mapped to the chromosomal region of KN3D:515.08-539.08 Mb, and the allele from parent Jing 411 could reduce PH. In this study, we aimed to further characterize the genetic mechanism of PH reduction caused by qPh-3D and clarify its genetic effects on yield-related traits, using the KJ-RILs population containing 187 lines as well as a natural mapping population consisting of 316 breeding varieties (advanced lines). In KJ-RILs, the qPh-3D allele from Jing 411 can significantly reduce PH via reducing all internode lengths without significant effect on spike length (SL), whereas it can reduce kernel yield per plant (KYPP) at certain level. Two markers AX-110160363 and AX-111109273, which closely link with qPh-3D, were used for genotyping in the natural mapping population with the yield-related phenotypic datasets. The qPh-3D allele with decreased PH was found with a positive effect on SL, but a significant negative effect on KYPP. Based on the breeding selection effect analysis at the qPh-3D locus, the qPh-3D allele with decreased PH was present in a higher proportion in wheat varieties released from Beijing and Shanxi in China, but lower in Shandong, Qinghai, Sichuan and the foreign countries. This allele was detected in a lower proportion in earlier varieties, while its presence in modern varieties was detected increasingly. In addition, a closely linked PCR-based InDel marker targeting the qPh-3D locus was developed. Collectively, the findings of this study will provide theoretical guidance for future applications of qPh-3D in molecular breeding programs in wheat.

    Reference
    [1] 胡文静, 李东升, 裔新, 张春梅, 张勇. 小麦穗部性状和株高的QTL定位及育种标记开发和验证. 作物学报, 2022, 48(6): 1346-1356Hu W J, Li D S, Yi X, Zhang C M, Zhang Y. Molecular mapping and validation of quantitative trait loci for spike-related traits and plant height in wheat. Acta Agronomica Sinica, 2022, 48(6): 1346-1356
    [2] 吕广德, 靳雪梅, 郭营, 赵岩, 钱兆国, 吴科, 李斯深. 小麦株高分子遗传学研究进展. 植物遗传资源学报, 2021, 22(3): 571-582Lv G D, Jin X M, Guo Y, Zhao Y, Qian Z G, Wu K, Li S S. Advances in molecular genetics of wheat plant height. Journal of Plant Genetic Resources, 2021, 22(3): 571-582
    [3] Duvick D N. Feeding the ten billion: Plants and population growth. Crop Science, 1999, 39(5): 1522-1523
    [4] 周阳, 何中虎, 陈新民, 王德森, 张勇, 张改生. 30余年来北部冬麦区小麦品种产量改良遗传进展. 作物学报, 2007, 33(9): 1530-1535Zhou Y, He Z H, Chen X M, Wang D S, Zhang Y, Zhang G S. Genetic gain of wheat breeding for yield in northern winter wheat zone over 30 years. Acta Agronomica Sinica, 2007,33 (9): 1530-1535
    [5] Pearce S, Saville R, Vaughan S P, Chandler P M, Wilhelmet E P. Molecular characterization of Rht-1 dwarfing genes in hexaploid wheat. Plant Physiology, 2011, 157: 1820-1831
    [6] Chen Z Y, Cheng X J, Chai L L, Wang Z H, Bian R L, Li J, Zhao A J, Xin M M, Guo W L, Hu Z R, Peng H R, Yao Y Y, Sun Q X, Ni Z F. Dissection of genetic factors underlying grain size and fine mapping of QTgw.cau-7D in common wheat (Triticum aestivum L.). Theoretical and Applied Genetics, 2020, 133: 149-162
    [7] Chai L L, Chen Z Y, Bian R L, Zhai H J, Cheng X J, Peng H R, Yao Y Y, Hu Z R, Xin M M, Guo W L, Sun Q X, Zhao A J, Ni Z F. Dissection of two quantitative trait loci with pleiotropic effects on plant height and spike length linked in coupling phase on the short arm of chromosome 2D of common wheat (Triticum aestivum L.). Theoretical and Applied Genetics, 2019, 132: 1815-1831
    [8] Cui F, Li J, Ding A M, Zhao C H, Wang L, Wang X Q, Li S S, Bao Y G, Li X F, Feng D S, Kong L R, Wang H G. Conditional QTL mapping for plant height with respect to the length of the spike and internode in two mapping populations of wheat. Theoretical and Applied Genetics, 2011, 122: 1517-1536
    [9] Qin R, Ma T H, Cao M S, Liu X J, Zhou X H, Hu G M, Zhong W, Sun X H, Xiao J G, Dong J J, Kong W C, Zhao C H, Wu Y Z, Sun H, Ji J, Cui F. QTL detection for internode component index in wheat using a RIL mapping population. Plant Molecular Biology Reporter, 2022, DOI: 10.1007/s11105-022-01359-1
    [10] 李杏普, 兰素缺, 张京慧, 冯延茹, 刘书娥, 张业伦, Gale M D, Worland T J. Rht8、Rht10和Rht12矮秆基因对产量构成因子的影响. 华北农学报, 2009, 24(S2): 72-75Li X P, Lan S Q, Zhang J H, Feng Y R, Liu S E, Zhang Y L, Gale M D, Worland T J. Effects of Rht8, Rht10 and Rht12 dwarf genes on yield components. Acta Agriclturae Boreali-sinica, 2009, 24(S2): 72-75
    [11] Yan J K, Zhang S Q. Effects of dwarfing genes on water use efficiency of bread wheat. Frontiers of Agricultural Science and Engineering, 2017, 4: 126-134
    [12] Mo Y, Vanzetti L S, Hale L, Spagnolo E J, Guidobaldi F, Ai-Oboudo J, Odle N, Pearce S, Helguera M, Dubcovsky J. Identification and characterization of Rht25, a locus on chromosome arm 6AS affecting wheat plant height, heading time, and spike development. Theoretical and Applied Genetics, 2018, 131: 2021-2035
    [13] Fick G N, Qualset C O. Seedling emergence, coleoptile length, and plant height relationships in crosses of dwarf and standard-height wheats. Euphytica, 1976, 25: 679-684
    [14] Singh A, Knox R E, DePauw R M, Singh A K, Cuthbert R D, Kumar S, Campbell H L. Genetic mapping of common bunt resistance and plant height QTL in wheat. Theoretical and Applied Genetics, 2016, 129: 243-256
    [15] 胡文静, 高德荣, 陆成彬, 梁秀梅, 石宜宗, 程顺和. 小麦穗部性状和株高的QTL定位及T6VS 6AL易位效应分析. 麦类作物学报, 2019, 39(5): 505-512Hu W J, Gao D R, Lu C B, Liang X M, Shi Y Z, Cheng S H. QTL mapping for spike traits and plant height in wheat (Triticum aestivum L.) and analysis of the effect of T6VS 6AL translocation. Journal of Triticeae Crops, 2019, 39(5): 505-512
    [16] Liu G, Jia L J, Lu L H, Qin D D, Zhang J P, Guan P F, Ni Z F, Yao Y Y, Sun Q X, Peng H R. Mapping QTLs of yield-related traits using RIL population derived from common wheat and Tibetan semi-wild wheat. Theoretical and Applied Genetics, 2014, 127: 2415-2432
    [17] B?rner A, Schumann E, Fürste A, C?ster H, Leithold B, R?der S, Weber E. Mapping of quantitative trait loci determining agronomic important characters in hexaploid wheat (Triticum aestivum L.). Theoretical and Applied Genetics, 2002, 105: 921-936
    [18] Sadeque A, Turner M A. QTL analysis of plant height in hexaploid wheat doubled haploid population. Thai Journal of Agricultural Science, 2010, 43: 91-96
    [19] Luo Q L, Zheng Q, Hu P, Liu L Q, Yang G T, Li H W, Li B, Li Z S. Mapping QTL for agronomic traits under two levels of salt stress in a new constructed RIL wheat population. Theoretical and Applied Genetics, 2021, 134: 171-189
    [20] Shi S K, Azam F I, Li H H, Chang X P, Li B, Jing R L. Mapping QTL for stay-green and agronomic traits in wheat under diverse water regimes. Euphytica, 2017, 213(11): 246
    [21] Hai L, Guo H J, Wagner C, Xiao S H, Friedt W. Genomic regions for yield and yield parameters in Chinese winter wheat (Triticum aestivum L.) genotypes tested under varying environments correspond to QTL in widely different wheat materials. Plant Science, 2008, 175(3): 226-232
    [22] McCartney C A, Somers D J, Humphreys D G, Lukow O, Ames N, Noll J, Cloutier S, McCallum B D. Mapping quantitative trait loci controlling agronomic traits in the spring wheat cross RL4452 × 'AC Domain'. Genome, 2005, 48(5): 870-883
    [23] 马天航, 蔡益彪, 熊永星, 徐勤青, 周晓涵, 孔文超, 李晶雪, 程蕊, 李诗慧, 曹明苏, 王晨阳, 赵春华, 秦冉, 孙晗, 吴永振, 崔法. 小麦不育小穗数QTL-qSsnps-5D遗传及育种选择效应解析. 植物遗传资源学报, 2022, 23(3): 811-822Ma T H, Cai Y B, Xiong Y X, Xu Q Q, Zhou X H, Kong W C, Li J X, Cheng R, Li S H, Cao M S, Wang C Y, Zhao C H, Qin R, Sun H, Wu Y Z, Cui F. Analysis of inheritance and breeding selection effect of QTL-qSsnps-5D for sterile spikelets in wheat. Journal of Plant Genetic Resources, 2022, 23(3): 811-822
    [24] Wu X H, Wang Z H, Chang X P, Jing R L. Genetic dissection of the developmental behaviours of plant height in wheat under diverse water regimes. Journal of Experimental Botany, 2010, 61(11): 2923-2937
    [25] 刘朦朦, 张萌娜, 张倩倩, 刘锡建, 郭宇航, 孙靳惠, 武亚瑞, 王素容, 吴永振, 孙晗, 崔法, 赵春华. 小麦旗叶宽主效QTL QFlw-5B遗传效应解析. 麦类作物学报, 2019, 39(12): 1399-1405Liu M M, Zhang M N, Zhang Q Q, Liu X J, Guo Y H, Sun J H, Wu Y R, Wang S R, Wu Y Z, Sun H, Cui F, Zhao C H. Genetic analysis of a major stable QTL QFlw-5B for wheat flag leaf width. Journal of Triticeae Crops, 2019, 39(12): 1399-1405
    [26] 崔俊鹏, 赵慧, 张倩倩, 宫娜, 刘朦朦, 张萌娜, 侯玉竹, 刘成, 李林志, 周芳婷, 吴永振, 孙晗, 赵春华, 崔法. 小麦穗粒数主效QTL-qKnps-4A遗传效应解析. 分子植物育种, 2019, 17(11): 3632-3640Cui J P, Zhao H, Zhang Q Q, Gong N, Liu M M, Zhang M N, Hou Y Z, Liu C, Li L Z, Zhou F T, Wu Y Z, Sun H, Zhao C H, Cui F. Genetic effects analysis of major QTL-qKnps-4A for kernel per spike in common wheat. Molecular Plant Breeding, 2019, 17(11): 3632-3640
    [27] 张倩倩, 闫学梅, 刘锡建, 张萌娜, 刘朦朦, 周芳婷, 吴永振, 孙晗, 赵春华, 崔法. 小麦穗粒数主效QTL-qKnps-2A遗传效应解析. 分子植物育种, 2020, 18(15): 5003-5009Zhang Q Q, Yan X M, Liu X J, Zhang M N, Liu M M, Zhou F T, Wu Y Z, Sun H, Zhao C H, Cui F. Genetic analysis of qKnps-2A: A major stable QTL for kernel number per spike in common wheat. Molecular Plant Breeding, 2020, 18(15): 5003-5009
    [28] Cui F, Fan X L, Zhao C H, Chen M, Ji J, Zhang W, Li J M. A novel genetic map of wheat: Utility for mapping QTL for yield under different nitrogen treatments. BMC Genetics, 2014, 15(1): 57
    [29] Fan X L, Cui F, Ji J, Zhang W, Zhang X Q, Liu J J, Meng D Y, Tong Y P, Wang Y P, Wang T, Li J M. Dissection of pleiotropic QTL regions controlling wheat spike characteristics under different nitrogen treatments using traditional and conditional QTL mapping. Frontiers in Plant Science, 2019, 10: 187
    [30] Cui F, Zhang N, Fan X L, Zhang W, Zhao C H, Yang L J, Pan R Q, Chen M, Han J, Zhao X Q, Ji J, Tong Y P, Zhang H X, Jia J Z, Zhao G Y, Li J M. Utilization of a Wheat660K SNP array-derived high-density genetic map for high-resolution mapping of a major QTL for kernel number. Scientific Reports, 2017, 7(1): 3788
    [31] Shi X L, Cui F, Han X Y, He Y W, Zhao L, Zhang N, Zhang H, Zhu H D, Liu Z X, Ma B, Zheng S S, Zhang W, Liu J J, Fan X L, Si Y Q, Tian S Q, Niu J Q, Wu H L, Liu X M, Chen Z, Meng D Y, Wang X Y, Song L Q, Sun L J, Han J, Zhao H, Ji J, Wang Z G, He X Y, Li R L, Chi X B, Liang C Z, Niu B F, Xiao J, Li J M, Ling H Q. Comparative genomic and transcriptomic analyses uncover the molecular basis of high nitrogen-use efficiency in the wheat cultivar Kenong 9204. Molecular Plant, 2022, 15(9): 1440-1456
    [32] 朱志翔. 遗传分析软件QGAStation2.0和GMDR-GPU的开发. 杭州: 浙江大学, 2012Zhu Z X. Development of the genetic analysis softwares QGAStation 2.0 and GMDR-GPU. Hangzhou: Zhejiang University, 2012
    [33] Zhang N, Fan X L, Cui F, Zhao C H, Zhang W, Zhao X Q, Yang L J, Pan R Q, Chen M, Han J, Ji J, Liu D C, Zhao Z W, Tong Y P, Zhang A M, Wang T, Li J M. Characterization of the temporal and spatial expression of wheat (Triticum aestivum L.) plant height at the QTL level and their influence on yield related traits. Theoretical and Applied Genetics, 2017, 130(6): 1235-1252
    [34] Snape J W, Law C N,Worland A J. Whole chromosome analysis of height in wheat. Heredity, 1977, 38: 25-36
    [35] Li J H, Xie L N, Tian X L, Liu S Y, Xu D G, Jin H, Song J, Dong Y, Zhao D H, Li G Y, Li Y L, Zhang Y, Zhang Y, Xia X C, He Z H, Cao S H. TaNAC100 acts as an integrator of seed protein and starch synthesis exerting pleiotropic effects on agronomic traits in wheat. The Plant Journal, 2021, 108: 829-840
    [36] Tian X L, Wen W E, Xie L, Fu L P, Xu D G, Fu C, Wang D S, Chen X M, Xia X C, Chen Q J, He Z H, Cao S H. Molecular mapping of reduced plant height gene Rht24 in bread wheat. Frontiers in Plant Science, 2017, 8: 1379
    [37] Zhang K P, Wang J J, Qin H J, Wei Z Y, Hang L B, Zhang P W, Reynolds M, Wang D W. Assessment of the individual and combined effects of Rht8 and Ppd-D1a on plant height, time to heading and yield traits in common wheat. The Crop Journal, 2019, 7(6): 845-856
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History
  • Received:March 29,2023
  • Revised:May 31,2023
  • Online: October 31,2023
  • Published: October 31,2023
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