[1]贾修齐,薛超,龚志云.水稻粒型调控机制及相关基因在育种中应用研究进展[J].江苏农业科学,2021,49(12):29-38.
 Ja Xiuqi,et al.Research progress on regulation mechanism of rice grain type and application of its related genes in breeding[J].Jiangsu Agricultural Sciences,2021,49(12):29-38.
点击复制

水稻粒型调控机制及相关基因在育种中应用研究进展()

《江苏农业科学》[ISSN:1002-1302/CN:32-1214/S]

卷:
第49卷
期数:
2021年第12期
页码:
29-38
栏目:
专论与综述
出版日期:
2021-06-20

文章信息/Info

Title:
Research progress on regulation mechanism of rice grain type and application of its related genes in breeding
作者:
贾修齐薛超龚志云
江苏省作物遗传生理重点实验室/植物功能基因组学教育部重点实验室/江苏省作物基因组学和分子育种重点实验室/
扬州大学农学院,江苏扬州 225009
Author(s):
Ja Xiuqiet al
关键词:
水稻粒型调控途径QTL育种应用
Keywords:
-
分类号:
S511.03
DOI:
-
文献标志码:
A
摘要:
粒型是影响稻米产量和的品质的重要数量性状之一。其遗传调控网络包括信号通路、泛素-蛋白酶体通路、丝裂原活化蛋白激酶(MAPK)信号通路、G蛋白信号通路及转录因子等多个调控通路。目前已经定位到的与粒型相关数量性状位点(QTL)有600多个,并克隆了70多个基因,这些基因间相互作用并于其他调控通路共同构成了水稻粒型调控网络。笔者对粒型调控网络和相关基因进行了总结和梳理并阐明其在育种上的应用前景,以期为水稻高产育种提供有利的理论和材料基础。
Abstract:
-

参考文献/References:

[1]Wang A H,Garcia D,Zhang H,et al. The VQ motif protein IKU1 regulates endosperm growth and seed size in Arabidopsis[J]. The Plant Journal,2010,63(4):670-679.
[2]Xing Y Z,Zhang Q F. Genetic and molecular bases of rice yield[J]. Annual Review of Plant Biology,2010,61(1):421-442.
[3]吕勇. 水稻产量相关性状的QTL定位与分析[D]. 泰安:山东农业大学,2017:52-53.
[4]陈曦. 多群体定位水稻粒形数量性状位点[D]. 南宁:广西大学,2020:6-8.
[5]Wang S K,Wu K,Yuan Q B,et al. Control of grain size,shape and quality by OsSPL16 in rice[J]. Nature Genetics,2012,44(8):950-954.
[6]Wu W G,Liu X Y,Wang M H,et al. A single-nucleotide polymorphism causes smaller grain size and loss of seed shattering during African rice domestication[J]. Nature Plants,2017,3(6):17064.
[7]Zhu Y J,Sun Z C,Niu X J,et al. Dissection of three quantitative trait loci for grain size on the long arm of chromosome 10 in rice (Oryza sativa L.)[J]. PeerJ,2019,7:e6966.
[8]Qi L,Ding Y B,Zheng X M,et al. Fine mapping and identification of a novel locus qGL12.2 control grain length in wild rice (Oryza rufipogon Griff.)[J]. Theoretical and Applied Genetics,2018,131(7):1497-1508.
[9]Li Y B,Fan C C,Xing Y Z,et al. Natural variation in GS5 plays an important role in regulating grain size and yield in rice[J]. Nature Genetics,2011,43(12):1266-1269.
[10]Wang D W,Sun W Q,Yuan Z Y,et al. Identification of a novel QTL and candidate gene associated with grain size using chromosome segment substitution lines in rice[J]. Scientific Reports,2021,11(1):189.
[11]Shomura A,Izawa T,Ebana K,et al. Deletion in a gene associated with grain size increased yields during rice domestication[J]. Nature Genetics,2008,40(8):1023-1028.
[12]Weng J F,Gu S H,Wan X Y,et al. Isolation and initial characterization of GW5,a major QTL associated with rice grain width and weight[J]. Cell Research,2008,18(12):1199-1209.
[13]Fu X,Xu J,Zhou M Y,et al. Enhanced expression of QTL qLL9/DEP1 facilitates the improvement of leaf morphology and grain yield in rice[J]. International Journal of Molecular Sciences,2019,20(4):866.
[14]尉鑫,曾智锋,杨维丰,等. 水稻粒形遗传调控研究进展[J]. 安徽农业科学,2019,47(5):21-28.
[15]康艺维,陈玉宇,张迎信. 水稻粒型基因克隆研究进展及育种应用展望[J]. 中国水稻科学,2020,34(6):479-490.
[16]Song X J,Huang W,Shi M,et al. A QTL for rice grain width and weight encodes a previously unknown RING-type E3 ubiquitin ligase[J]. Nature Genetics,2007,39(5):623-630.
[17]Shomura A,Izawa T,Ebana K,et al. Deletion in a gene associated with grain size increased yields during rice domestication[J]. Nature Genetics,2008,40(8):1023-1028.
[18]Liu J F,Chen J,Zheng X M,et al. GW5 acts in the brassinosteroid signalling pathway to regulate grain width and weight in rice[J]. Nature Plants,2017,3(5):17043.
[19]Ruan B P,Shang L G,Zhang B,et al. Natural variation in the promoter of TGW2 determines grain width and weight in rice[J]. The New Phytologist,2020,227(2):629-640.
[20]Fan C C,Xing Y Z,Mao H L,et al. GS3,a major QTL for grain length and weight and minor QTL for grain width and thickness in rice,encodes a putative transmembrane protein[J]. Theoretical and Applied Genetics,2006,112(6):1164-1171.
[21]Mao H L,Sun S Y,Yao J L,et al. Linking differential domain functions of the GS3 protein to natural variation of grain size in rice[J]. Proceedings of the National Academy of Sciences of the United States of America,2010,107(45):19579-19584.
[22]Zhang X J,Wang J F,Huang J,et al. Rare allele of OsPPKL1 associated with grain length causes extra-large grain and a significant yield increase in rice[J]. Proceedings of the National Academy of Sciences of the United States of America,2012,109(52):21534-21539.
[23]Qi P,Lin Y S,Song X J,et al. The novel quantitative trait locus GL3.1 controls rice grain size and yield by regulating Cyclin-T1;3[J]. Cell Research,2012,22(12):1666-1680.
[24]Hu Z J,He H H,Zhang S Y,et al. A kelch motif-containing serine/threonine protein phosphatase determines the large grain QTL trait in rice[J]. Journal of Integrative Plant Biology,2012,54(12):979-990.
[25]Ishimaru K,Hirotsu N,Madoka Y,et al. Loss of function of the IAA-glucose hydrolase gene TGW6 enhances rice grain weight and increases yield[J]. Nature Genetics,2013,45(6):707-711.
[26]Yu J P,Xiong H Y,Zhu X Y,et al. OsLG3 contributing to rice grain length and yield was mined by Ho-LAMap[J]. BMC Biology,2017,15(1):28.
[27]Xia D,Zhou H,Liu R J,et al. GL3.3,a novel QTL encoding a GSK3/SHAGGY-like kinase,epistatically interacts with GS3 to produce extra-long grains in rice[J]. Molecular plant,2018,11(5):754-756.
[28]Hu Z J,Lu S J,Wang M J,et al. A novel QTL qTGW3 encodes the GSK3/SHAGGY-Like kinase OsGSK5/OsSK41 that interacts with OsARF4 to negatively regulate grain size and weight in rice[J]. Molecular plant,2018,11(5):736-749.
[29]Ying J Z,Ma M,Bai C,et al. TGW3,a major QTL that negatively modulates grain length and weight in rice[J]. Molecular Plant,2018,11(5):750-753.
[30]Wang A,Hou Q Q,Si L Z,et al. The PLATZ transcription factor GL6 affects grain length and number in rice[J]. Plant Physiology,2019,180(4):2077-2090.
[31]Si L Z,Chen J Y,Huang X E,et al. OsSPL13 controls grain size in cultivated rice[J]. Nature Genetics,2016,48(4):447.
[32]Hu J,Wang Y X,Fang Y X,et al. A rare allele of GS2 enhances grain size and grain yield in rice[J]. Molecular Plant,2015,8(10):1455-1465.
[33]Che R H,Tong H N,Shi B,et al. Control of grain size and rice yield by GL2-mediated brassinosteroid responses[J]. Nature Plants,2015,2(1):15195.
[34]Xu F,Fang J,Ou S J,et al. Variations in CYP78A1313 coding region influence grain size and yield in rice[J]. Plant,Cell & Environment,2015,38(4):800-811.
[35]Wang S K,Li S,Liu Q,et al. The OsSPL16-GW77 regulatory module determines grain shape and simultaneously improves rice yield and grain quality[J]. Nature Genetics,2015,47(8):949-954.
[36]Wang Y X,Xiong G S,Hu J,et al. Copy number variation at the GL7 locus contributes to grain size diversity in rice[J]. Nature Genetics,2015,47(8):944.
[37]Song X J,Kuroha T,Ayano M,et al. Rare allele of a previously unidentified histone H4 acetyltransferase enhances grain weight,yield,and plant biomass in rice[J]. Proceedings of the National Academy of Sciences of the United States of America,2015,112(1):76-81.
[38]Zhao D S,Li Q F,Zhang C Q,et al. GS9 acts as a transcriptional activator to regulate rice grain shape and appearance quality[J]. Nature Communications,2018,9(1):1240.
[39]赵冬生. 水稻幼苗白化致死基因AL1和粒形基因GS9的克隆与功能分析[D]. 扬州:扬州大学,2016:19-28.
[40]刘晓青. 玉米百粒重主效QTL qHKW3的精细定位[D]. 武汉:华中农业大学,2018:24-28.
[41]Li N,Li Y H. Signaling pathways of seed size control in plants[J]. Current Opinion in Plant Biology,2016,33:23-32.
[42]Li N,Xu R,Duan P G,et al. Control of grain size in rice[J]. Plant Reproduction,2018,31(3):237-251.
[43]曹维,赵静,禹艳坤,等. 调控植物种子大小的分子机制综述[J]. 江苏农业科学,2020,48(6):1-7.
[44]Cao J S,Li G J,Qu D J,et al. Into the seed:auxin controls Seed development and grain yield[J]. International Journal of Molecular Sciences,2020,21(5):1662.
[45]Na G N,Mu X P,Grabowski P,et al. Enhancing microRNA167A expression in seed decreases the α-linolenic acid content and increases seed size in Camelina sativa[J]. The Plant Journal,2019,98(2):346-358.
[46]Liu L C,Tong H N,Xiao Y H,et al. Activation of Big Grain1 significantly improves grain size by regulating auxin transport in rice[J]. Proceedings of the National Academy of Sciences of the United States of America,2015,112(35):11102-11107.
[47]Liu J,Hua W,Hu Z Y,et al. Natural variation in ARF18 gene simultaneously affects seed weight and silique length in polyploid rapeseed[J]. Proceedings of the National Academy of Sciences of the United States of America,2015,112(37):E5123-E5132.
[48]Hirano K,Yoshida H,Aya K,et al. SMALL ORGAN SIZE 1 and SMALL ORGAN SIZE 2/DWARF AND LOW-TILLERING form a complex to integrate auxin and brassinosteroid signaling in rice[J]. Molecular Plant,2017,10(4):590-604.
[49]Aya K,Hobo T,Sato-Izawa K,et al. A novel AP2-type transcription factor,SMALL ORGAN SIZE1,controls organ size downstream of an auxin signaling pathway[J]. Plant & Cell Physiology,2014,55(5):897-912.
[50]Matsuta S,Nishiyama A,Chaya G,et al. Characterization of heterotrimeric G protein γ4 subunit in rice[J]. International Journal of Molecular Sciences,2018,19(11):3596.
[51]Wang L,Xu Y Y,Ma Q B,et al. Heterotrimeric G protein alpha subunit is involved in rice brassinosteroid response[J]. Cell Research,2006,16(12):916-922.
[52]Utsunomiya Y,Samejima C,Takayanagi Y,et al. Suppression of the rice heterotrimeric G protein β-subunit gene,RGB1,causes dwarfism and browning of internodes and lamina joint regions[J]. The Plant Journal,2011,67(5):907-916.
[53]Sun S Y,Wang L,Mao H L,et al. A G-protein pathway determines grain size in rice[J]. Nature Communications,2018,9(1):851.
[54]Zhou Y,Zhu J Y,Li Z Y,et al. Deletion in a quantitative trait gene qPE9-1 associated with panicle erectness improves plant architecture during rice domestication[J]. Genetics,2009,183(1):315-324.
[55]Feng Y,Lu Q,Zhai R R,et al. Genome wide association mapping for grain shape traits in indica rice[J]. Planta,2016,244(4):819-830.
[56]Zhao K,Tung C W,Eizenga G C,et al. Genome-wide association mapping reveals a rich genetic architecture of complex traits in Oryza sativa[J]. Nature Communications,2011,2(1):467.
[57]Mao H L,Sun S Y,Yao J L,et al. Linking differential domain functions of the GS3 protein to natural variation of grain size in rice[J]. Proceedings of the National Academy of Sciences of the United States of America,2010,107(45):19579-19584.
[58]Xu J,Zhang S Q. Mitogen-activated protein kinase cascades in signaling plant growth and development[J]. Trends in Plant Science,2015,20(1):56-64.
[59]Xu R,Duan P G,Yu H Y,et al. Control of grain size and weight by the OsMKKK10-OsMKK4-OsMAPK6 signaling pathway in rice[J]. Molecular Plant,2018,11(6):860-873.
[60]Guo T,Chen K,Dong N Q,et al. GRAIN SIZE AND NUMBER1 negatively regulates the OsMKKK10-OsMKK4-OsMPK6 cascade to coordinate the trade-off between grain number per panicle and grain size in rice[J]. The Plant Cell,2018,30(4):871-888.
[61]Liu S Y,Hua L,Dong S J,et al. OsMAPK6,a mitogen-activated protein kinase,influences rice grain size and biomass production[J]. The Plant Journal,2015,84(4):672-681.
[62]Duan P G,Rao Y C,Zeng D L,et al. SMALL GRAIN 1,which encodes a mitogen-activated protein kinase kinase 4,influences grain size in rice[J]. The Plant Journal,2014,77(4):547-557.
[63]杨维丰,詹鹏麟,林少俊,等. 水稻粒形的遗传研究进展[J]. 华南农业大学学报,2019,40(5):203-210.
[64]谢旺清. MERIT40-Tankyrase1相互作用对纺锤体组装影响的研究[D]. 深圳:深圳大学,2017:29-31.
[65]刘喜,牟昌铃,周春雷,等. 水稻粒型基因克隆和调控机制研究进展[J]. 中国水稻科学,2018,32(1):1-11.
[66]Li N,Xu R,Li Y H. Molecular networks of seed size control in plants[J]. Annual Review of Plant Biology,2019,70(1):435-463.
[67]南玲. UCH-L5对TGFβ-1信号转导通路中Smad2/Smad3蛋白去泛素化和稳定性的研究及对肺纤维化的作用[D]. 长春:吉林大学,2017:39-41.
[68]Huang K,Wang D K,Duan P G,et al. WIDE AND THICK GRAIN 1,which encodes an otubain-like protease with deubiquitination activity,influences grain size and shape in rice[J]. The Plant Journal,2017,91(5):849-860.
[69]Shi C L,Ren Y L,Liu L L,et al. Ubiquitin specific protease 15 has an important role in regulating grain width and size in rice[J]. Plant Physiology,2019,180(1):381-391.
[70]Sun P Y,Zhang W H,Wang Y H,et al. OsGRF4 controls grain shape,panicle length and seed shattering in rice[J]. Journal of Integrative Plant Biology,2016,58(10):836-847.
[71]Li S,Tian Y H,Wu K,et al. Modulating plant growth-metabolism coordination for sustainable agriculture[J]. Nature,2018,560(7720):595-600.
[72]Ji X,Du Y,Li F,et al. The basic helix-loop-helix transcription factor,OsPIL15,regulates grain size via directly targeting a purine permease gene OsPUP7 in rice[J]. Plant Biotechnology Journal,2019,17(8):1527-1537.
[73]Yin L L,Xue H W. The MADS29 transcription factor regulates the degradation of the nucellus and the nucellar projection during rice seed development[J]. The Plant Cell,2012,24(3):1049-1065.
[74]Xu J J,Zhang X F,Xue H W. Rice aleurone layer specific OsNF-YB1 regulates grain filling and endosperm development by interacting with an ERF transcription factor[J]. Journal of Experimental Botany,2016,67(22):6399-6411.
[75]葛慧雯. OsRhoGAP2基因过表达改变水稻粒形的分子机制研究[D]. 新乡:河南师范大学,2018:41-43.
[76]Liu Q,Han R,Wu K,et al. G-protein βγ subunits determine grain size through interaction with MADS-domain transcription factors in rice[J]. Nature Communications,2018,9(1):852.
[77]王静宇,陈晓慧,赖钟雄. 植物表观遗传修饰的分子机制及其生物学功能[J]. 热带作物学报,2020,41(10):2099-2112.
[78]Zhang Y C,Yu Y,Wang C Y,et al. Overexpression of microRNA OsmiR397 improves rice yield by increasing grain size and promoting panicle branching[J]. Nature Biotechnology,2013,31(9):848-852.
[79]Duan P,Ni S,Wang J,et al. Regulation of OsGRF4 by OsmiR396 controls grain size and yield in rice[J]. Nature Plants,2015,2(1):15203.
[80]Zhang J P,Yu Y,Feng Y Z,et al. MiR408 regulates grain yield and photosynthesis via a phytocyanin protein[J]. Plant Physiology,2017,175(3):1175-1185.
[81]Sui P,Shi J,Gao X,et al. H3K36 methylation is involved in promoting rice flowering[J]. Molecular Plant,2013,6(3):975-977.
[82]张昌泉,赵冬生,李钱峰,等. 稻米品质性状基因的克隆与功能研究进展[J]. 中国农业科学,2016,49(22):4265-4283.
[83]Lyu J,Wang D R,Duan P G,et al. Control of grain size and weight by the GSK2-LARGE1/OML4 pathway in rice[J]. The Plant Cell,2020,32(6):1905-1918.
[84]Yan S,Zou G H,Li S J,et al. Seed size is determined by the combinations of the genes controlling different seed characteristics in rice[J]. Theoretical and Applied Genetics,2011,123(7):1173-1181.
[85]Li J,Chu H W,Zhang Y H,et al. The rice HGW gene encodes a ubiquitin-associated (UBA) domain protein that regulates heading date and grain weight[J]. PLoS One,2012,7(3):e34231.
[86]余海平. 水稻颖壳缺陷基因DG11和粒型基因GR55的克隆与功能分析[D]. 沈阳:沈阳农业大学,2018:68-71.
[87]Hu Z,Lu S J,Wang M J,et al. A novel QTL qTGW3 encodes the GSK3/SHAGGY-Like kinase OsGSK5/OsSK41 that interacts with OsARF4 to negatively regulate grain size and weight in rice[J]. Molecular Plant,2018,11(5):736-749.
[88]张剑霞. 利用分子标记辅助选择转移野生稻增产QTL和聚合水稻优良基因[D]. 武汉:华中农业大学,2009:25-27.
[89]杨梯丰,曾瑞珍,朱海涛,等. 水稻粒长基因GS3在聚合育种中的效应[J]. 分子植物育种,2010,8(1):59-66.
[90]Zeng D L,Tian Z X,Rao Y C,et al. Rational design of high-yield and superior-quality rice[J]. Nature Plants,2017,3(4):17031.
[91]姚祝平,程远,万红建,等. CRISPR/Cas9基因编辑技术在植物基因工程育种中的应用[J]. 分子植物育种,2017,15(7):2647-2655.
[92]Zong Y,Song Q N,Li C,et al. Efficient C-to-T base editing in plants using a fusion of nCas9 and human APOBEC3A[J]. Nature Biotechnology,2018,36(10):950-953.
[93]Anzalone A V,Randolph P B,Davis J R,et al. Search-and-replace genome editing without double-strand breaks or donor DNA[J]. Nature,2019,576(7785):149-157.
[94]Mieulet D,Jolivet S,Rivard M,et al. Turning rice meiosis into mitosis[J]. Cell Research,2016,26(11):1242-1254.
[95]Sun D W,Cen H Y,Weng H Y,et al. Using hyperspectral analysis as a potential high throughput phenotyping tool in GWAS for protein content of rice quality[J]. Plant Methods,2019,15(3):54.
[96]Korte A,Farlow A. The advantages and limitations of trait analysis with GWAS:a review[J]. Plant Methods,2013,9(1):29.
[97]Wang H R,Xu X,Vieira F G,et al. The power of inbreeding:NGS-Based GWAS of rice reveals convergent evolution during rice domestication[J]. Molecular Plant,2016,9(7):975-985.
[98]周玲,熊威,胡俏强,等. 基于温带和热带玉米群体全基因组选择和杂种优势候选位点的鉴定[J]. 江苏农业科学,2021,49(4):19-26.
[99]Michelmore R W,Paran I,Kesseli R V. Identification of markers linked to disease-resistance genes by bulked segregant analysis:a rapid method to detect markers in specific genomic regions by using segregating populations[J]. Proceedings of the National Academy of Sciences of the United States of America,1991,88(21):9828-9832.
[100]宫李辉,高振宇,马伯军,等. 水稻粒形遗传的研究进展[J]. 植物学报,2011,46(6):597-605.

相似文献/References:

[1]马旭俊,刘春娟,吕世博,等.绿色荧光蛋白基因在水稻遗传转化中的应用[J].江苏农业科学,2013,41(04):35.
[2]李岳峰,居立海,张来运,等.水分胁迫下丛枝菌根对水稻/绿豆间作系统 作物生长和氮磷吸收的影响[J].江苏农业科学,2013,41(04):58.
[3]崔月峰,孙国才,王桂艳,等.不同施氮水平和前氮后移措施对水稻产量 及氮素利用率的影响[J].江苏农业科学,2013,41(04):66.
[4]张其蓉,宋发菊,田进山,等.长江中下游稻区水稻区域试验品种抗稻瘟病鉴定与评价[J].江苏农业科学,2013,41(04):92.
[5]王麒,张小明,卞景阳,等.不同插秧密度对黑龙江省第二积温带水稻产量及产量构成的影响[J].江苏农业科学,2013,41(05):60.
 Wang Qi,et al.Effect of different transplanting density on yield and yield component of rice in second temperature zone of Heilongjiang Province[J].Jiangsu Agricultural Sciences,2013,41(12):60.
[6]张国良,张森林,丁秀文,等.基质厚度和含水量对水稻育秧的影响[J].江苏农业科学,2013,41(05):62.
 Zhang Guoliang,et al.Effects of substrate thickness and water content on growth of rice seedlings[J].Jiangsu Agricultural Sciences,2013,41(12):62.
[7]赵忠宝,朱清海.稻-蟹-鳅生态系统的能值分析[J].江苏农业科学,2013,41(05):349.
 Zhao Zhongbao,et al.Emergy analysis of paddy-crab-loach ecosystem[J].Jiangsu Agricultural Sciences,2013,41(12):349.
[8]杨红福,姚克兵,束兆林,等.甲氧基丙烯酸酯类杀菌剂对水稻恶苗病的田间药效[J].江苏农业科学,2014,42(12):166.
 Yang Hongfu,et al.Field efficacy of strobilurin fungicides against rice bakanae disease[J].Jiangsu Agricultural Sciences,2014,42(12):166.
[9]唐成,陈露,安敏敏,等.稻瘟病诱导水稻幼苗叶片氧化还原系统的特征谱变化[J].江苏农业科学,2014,42(12):141.
 Tang Cheng,et al.Characteristic spectral changes of redox homeostasis system in rice seedling leaves induced by rice blast[J].Jiangsu Agricultural Sciences,2014,42(12):141.
[10]万云龙.优质水稻—春甘蓝轮作高效栽培模式[J].江苏农业科学,2014,42(12):90.
 Wan Yunlong.Efficient cultivation mode of high quality rice-spring cabbage rotation[J].Jiangsu Agricultural Sciences,2014,42(12):90.
[11]谢婷婷,张令瑄,郭伟伟,等.水稻粒型与粒质量的QTL分析[J].江苏农业科学,2016,44(06):99.
 Xie Tingting,et al.QTL analysis of grain traits and grain weight of rice[J].Jiangsu Agricultural Sciences,2016,44(12):99.
[12]冯海洋,刘康伟,代强,等.水稻粒型调控研究进展[J].江苏农业科学,2025,53(21):10.
 Feng Haiyang,et al.Research progress on grain shape regulation of rice[J].Jiangsu Agricultural Sciences,2025,53(12):10.

备注/Memo

备注/Memo:
收稿日期:2021-03-21
基金项目:国家自然科学基金(编号:31871232);中国博士后科学基金(编号:2019M651981)。
作者简介:贾修齐(1995—),男,陕西澄城人,硕士,主要从事水稻遗传育种研究。E-mail:731150785@qq.com。
通信作者:龚志云,博士,教授,主要从事水稻基因组学研究。E-mail:zygong@yzu.edu.cn。
更新日期/Last Update: 2021-06-20