Welcome to Acta Agronomica Sinica,

Acta Agron Sin ›› 2015, Vol. 41 ›› Issue (07): 1007-1016.doi: 10.3724/SP.J.1006.2015.01007

• CROP GENETICS & BREEDING·GERMPLASM RESOURCES·MOLECULAR GENETICS • Previous Articles     Next Articles

Genetic Dissection of Grain Chalkiness in Indica Mini-core Germplasm Using Genome-wide Association Method

QIU Xian-Jin1,2,YUAN Zhi-Hua1,CHEN Kai4,DU Bin1,HE Wen-Jing1,YANG Long-Wei1,2,XU Jian-Long3,4,*,XING Dan-Ying1,2,*,LÜ Wen-Kai1   

  1. 1 College of Agriculture, Yangtze University, Jingzhou434025, China; 2 Hubei Collaborative Innovation Center for Grain Industry / Engineering Research Center of Ecology and Agricultural Use of Wetland, Ministry of Education, Jingzhou 434025, China; 3 Institute of Crop Science, Chinese Academy of Agricultural Sciences, Beijing 100081, China; 4 Institute of Agricultural Genomics at Shenzhen, Chinese Academy of Agricultural Sciences, Shenzhen 518120, China
  • Received:2015-01-14 Revised:2015-04-02 Online:2015-07-12 Published:2015-05-04

RichHTML

PDF

1786

Cited

2

Abstract:

In order to dissect the genetic bases and mine novel alleles of grain chalkiness in indica, we conducted an experiment with  genome-wide association analysis using phenotypic data collected from multiple locations (Sanya of Hainan, Shenzhen of Guangdong, Hangzhou of Zhejiang, and Jingzhou of Hubei) and 6704 re-sequenced SNP markers distributed in whole genome for 272 indica mini-core germplasm collected worldwide. All accessions were classified into three subpopulations based on SNP data. Total of 42 and 44 loci were detected as significant associations with percentage of grains with chalkiness (PGWC) and degree of endosperm chalkiness (DEC), respectively, which distributed all over the 12 chromosomes. Twenty one and nineteen loci were stably expressed for PGWC and DEC in multiple locations, respectively, and 12 simultaneously affected the two traits. Eleven of the said loci were co-located in the same or near regions harboring the quality genes cloned previously. Of them, the region of 3.3–5.3 Mb on chromosome 5 was significantly associated with PGWC at all four locations, having the largest phenotypic contribution detected in Hangzhou location, and the carrier variety with the best favorable allele was IRGC121689; the another region of 17.5–22.7 Mb on chromosome 12 was significantly associated with DEC at Sanya and Hangzhou, having the largest phenotypic contribution detected in Sanya, and the carrier variety with the best favorable allele was IRGC122285. These loci and germplasms are important potential genes and variety resources that can be used in molecular breeding for rice appearance quality.

Key words: Rice, Chalkiness, Association mapping analysis, SNP marker, Linkage disequilibrium

[1]周少川, 李宏, 王家生, 黄道强, 谢振文, 卢德成. 华南籼稻早造稻米蒸煮、外观和碾米品质与食味品质的相关性研究. 作物学报, 2002, 28: 397–400



Zhou S C, Li H, Wang J S, Huang D Q, Xie Z S, Lu D C. Correlation among eating quality and cooking, apparent and milling qualities of south-China indica rice in the early-cropping season. Acta Agron Sin, 2002, 28: 397–400 (in Chinese with English abstract)



[2]江良荣, 李义珍, 王侯聪, 黄育民. 稻米外观品质的研究进展与分子改良策略. 分子植物育种, 2003, 1: 243–255



Jiang L R, Li Y Z, Wang H C, Huang Y M. Research progress on appearance quality of rice grain and strategies for its molecular improvement. Mol Plant Breed, 2003, 1: 243–255 (in Chinese with English abstract)



[3]徐富贤, 熊洪, 朱永川, 张林, 万先齐, 刘茂, 杨大金. 杂交中稻整精米率的影响因子及其间接鉴定方法研究. 西南农业学报, 2013, 26: 1–6



Xu F X, Xiong H, Zhu Y C, Zhang L, Wan X Q, Liu M, Yang D Q. Study on effect factors and indirect evolution method for percentage oh head milled rice of hybrid mid-season rice. Southwest China J Agric Sci, 26: 1–6 (in Chinese with English abstract)



[4]中华人民共和国国家标准. 优质稻谷GB/T17891-1999. 北京: 中国标准出版社, 1999. pp 6–12



National Standard of the People’ Republic of China. Beijing: Standards Press of China, 1999. pp 6–12 (in Chinese)



[5]Wan X Y, Wan J M, Weng J, Liang L, Bi J C, Wang C M, Zhao H Q. Stability of QTLs for rice grain dimension and endosperm chalkiness characteristics across eight environments. Theor Appl Genet, 2005, 110: 1334–1346



[6]He P, L i S, Qian Q, Ma Y Q, Li J Z, Wang W M, Chen Y, Zhu L H. Genetic analysis of rice grain quality. Theor Appl Genet, 1999, 98: 502–508



[7]Tan Y, Li J, Li X J, Yu S B, Xu C G, Zhang Q F. Genetic bases of appearance quality of rice grains in Shanyou63, an elite rice hybrid. Theor Appl Genet, 2000, 101: 823–829



[8]周立军, 江玲, 刘喜, 陈红, 陈亮明, 刘世家, 万建民. 水稻千粒重和垩白粒率的QTL及其互作分析. 作物学报, 2009, 35: 255–261



Zhou L J, Jiang L, Liu X, Chen H, Chen L M, Liu S J, Wan J M. QTL mapping and interaction analysis for 1000-grain weight and percentage of grains with chalkiness in rice. Acta Agron Sin, 2009, 35: 255–261 (in Chinese with English abstract)



[9]Qin Y, Kin S, Sohn J. Genetic analysis and QTL mapping for grain chalkiness characteristics of brown rice (Oryza sativa L.). Genes Genomics, 2009, 31: 155–164



[10]Guo T, Liu X L, Wan X Y, Weng J F, Liu S J, Liu X, Chen F M, Li J J, Su N, Wu F Q, Cheng Z J, Guo X P, Lei C L, Wang J L, Jiang L, Wan J M. Identification of a stable quantitative trait locus for percentage grains with white chalkiness in rice (Oryza sativa). J Integr Plant Biol, 2011, 53: 598–607



[11]Liu X, Wang Y, Wang S W. QTL analysis of percentage of grains with chalkiness in Japonica rice (Oryza sativa). Genet Mol Res, 2012, 11(1): 717–724



[12]Zhou L J, Chen L M, Jiang L, Zhang W W, Liu L L, Liu X, Zhao Z Q, Liu S J, Zhang L J, Wang J K, Wan J M. Fine mapping of the grain chalkiness QTL qPGWC-7 in rice(Oryza sativa L.). Theor Appl Genet, 2009, 118: 581–590



[13]Song X J, Huang W, Shi M, Zhu M Z, Lin H X. A QTL for rice grain width and weight encodes a previously unknown RING-type E3 ubiquitin ligase. Nat Genet, 2006, 39: 623–630



[14]Li Y B, Fan C C, Xing Y Z, Yun P, Luo L J, Yan B, Peng B, Xie W B, Wang G W, Li X H, Xu C G, He Y Q. Chalk5 encodes a vacuolar H+-translocating pyrophosphatase influencing grain chalkiness in rice. Nat Genet, 2014, 46: 398–404



[15]Kang H G, Park S H, Matsuoka M, An G. White-core endosperm floury sndosperm-4 in rice is generated by knockout mutations in the C4-type pyruvate orthophosphate dikinase gene (OsPPDKB). Plant J, 2005, 42: 901–911



[16]Fujita N, Yoshida M, Kondo T, Saito K, Utsumi Y, Tokunaga T, Nishi A, Satoh H, Park JH, Jane JL, Miyao A, Hirochika H, Nakamura Y. Characterization of SSIIIa-deficient mutants of rice: the function of SSIIIa and pleiotropic effects by SSIIIa deficiency in the endosperm. Plant Physiol, 2007, 144: 2009–2023



[17]Ryoo N, Yu C, Park C S, Bail M Y, Park IM, Cho M H, Bhoo S H, An G, Hahn T R, Feon J S. Knockout of a starch synthase gene OsSSIIIa/Flo5 causes white-core floury endosperm in rice (Oryza sativa L.). Plant Cell Rep, 2007, 26: 1083–1095



[18]Wang E T, Wang J J, Zhu X D, Hao W, Wang L Y, Li Q, Zhang L X, He W, Lu B R, Lin H X, Ma H, Zhang G Q, He Z H. Control of rice grain-filling and yield by a gene with a potential signature of domestication. Nat Genet, 2008, 40: 1370–1374



[19]Wang E T, Xu X, Zhang L, Zhang H, Lin L, Wang Q, Li Q, Ge S, Lu B R, Wang W, He Z H. Duplication and independent selection of cell-wall invertase genes GIF1 and OsCIN1 during rice evolution and domestication. BMC Evol Biol, 2010, 10: 108



[20]Woo M O, Ham T H, Ji H S, Choi M S, Jiang W Z, Chu S H, Piao R, Chin J H, Kin J A, Park B S, Seo H S, Jwa N S, McCouch S, Koh H J. Inactive of UGPase1 gene causes genic male sterility and endosperm chalkiness in rice (Oryza sativa L.). Plant J, 2008, 54: 190–204



[21]She K C, Kusano H, Koizumi K, Yamakawa H, Hakata M, Imamura T, Fkuda M, Naito N, Tsurumaki Y, Yaeshima M, Tsuge T, Matsumoto K, Kudoh M, Itoh E, Kikuchi S, Kishimoto N, Yazaki J, Ando T, Yano M, Aoyama T, Sasaki T, Satoh H, Shimada H. A novel factor FLOURY ENDOSPERM2 is involved in regulation of rice grain size and starch quality. Plant Cell, 2010, 22: 3280–3294



[22]Wang Y H, Ren Y L, Liu X, Jiang L, Chen L M, Han X H, Jin M N, Liu S J, Liu F, Lü J, Zhou K N, Su N, Bao Y Q, Wan J M. OsRab5a regulates endomembrane organization and storage protein trafficking in rice endosperm cells. Plant J, 2010, 64: 812–824



[23]张学勇, 童依平, 游光霞, 郝晨阳, 盖红梅, 王兰芬, 李滨, 董玉琛, 李振声. 选择牵连效应分析: 发掘重要基因的新思路. 中国农业科学, 2006, 39: 1526–1535



Zhang X Y, Tong Y P, You G X, Hao C Y, Gai H M, Wang L F, Li B, Dong Y C, Li Z S. Hitching effect mapping: a new approach for discovering agronomic important genes. Sci Agric Sin, 2006, 39: 1526–1535 (in Chinese with English abstract)



[24]Huang X H, Wei X H, Sang T, Zhao Q, Feng Q, Zhao T, Li CY, Zhu C R, Lu T T, Zhang Z W, Li M, Fan D L, Guo Y L, Wang A H, Wang L, Deng L W, Li W J, Lu Y Q, Weng Q J, Liu K Y, Huang T, Zhou T Y, Jing Y F, Li W, Lin Z, Bulker E S, Qian Q, Zhang Q F, Li J Y, Han B.Genome-wide association studies of 14 agronomic traits in rice landraces. Nat Genet, 2010, 43: 961–967



[25]Huang X H, Zhao Y, Wei X H, Li C Y, Wang A H, Zhao Q, Li W J, Guo Y L, Deng L W, Zhu C R, Fan D L, Weng Q J, Liu K Y, Zhou T Y, Jing Y F, Si L Z, Dong G J, Huang T, Lu T T, Feng Q, Qian Q, Li J Y, Han B.Genome-wide association study of flowering time and grain yield traits in a worldwide collection of rice germplasm. Nat Genet, 2012, 44: 32–39



[26]Zhao K Y, Tung C W, Eizenga G C, Wright M H, Ali M L, Price A H, Norton G J, Islam M R, Reynolds A, Mezey J, McClung A M, Bustamante C D, McCouch S R. Genome-wide association mapping reveals a rich genetic architecture of complex traits in Oryza sativa. Nat Commun, 2011, 2: 467



[27]Murry M G, Thompson W F. Rapid isolation of high molecular-weight plant DNA. Nucleic Acids Res, 1980, 8: 4321



[28]Huang S W, Li R Q, Zhang Z H, Li L, Gu X F, Fan W, Lucas W J, Wang X W, Xie B Y, Ni P X, Ren Y Y, Zhu H M, Lin K, Jin W W, Fei Z J, Li G C, Staub J, Kilian J, Vossen E A G, Wu Y, Guo J, He J, Jia Z Q, Ren Y, Tian G, Lu Y, Ruan J, Qian W B, Wang M W, Huang Q F, Li B, Xuan Z L, Cao J J, Asan, Wu Z G, Zhang J B, Cai Q L, Bai Y Q, Zaho B W, Han Y H, Li Y, Li X F, Wang S H, Shi Q X, Liu S Q, Cho W K, Kim J Y, Xu Y, Heller-Uszynska K, Miao H, Cheng Z C, Zhang S P, Wu J, Yang Y H, Kang H X, Li M, Liang H Q, Ren X L, Shi Z B, Wen M, Jian M, Yang H L, Zhang G J, Yang Z T, Chen R, Liu S F, Li J W, Ma L J, Liu H, Zhou Y, Zhao J, Fang X F, Li G Q, Fang L, Li Y R, Liu D Y, Zheng H K, Zhang Y, Qin N, Li Z, Yang G H, Yang S, Bolund L, Kristiansen K, Zheng H C, Li S C, Zhang X Q, Yang H M, Wang J, Sun R F, Zhang B X, Jiang S Z, Wang J, Du Y C, Li S G. The genome of the cucumber, Cucumis sativus L. Nat Genet, 2009, 41: 1275–1281



[29]盖钧镒. 试验统计方法. 北京: 中国农业出版社, 2000. pp 157–190



Gai J Y. Experimental Statistics Methods. Beijing: Chinese Agriculture Press, 2000. pp 157–190 (in Chinese)



[30]Liu K, Muse S V. PowerMarker: Intergrated analysis environment for genetic marker data. Bioinformatics, 2005, 21: 2128–2129



[31]Pritchard J K, Stephens M, Donnelly P. Inference of population strcutre using multilocous genotype data. Genetics, 2000, 155: 945–959



[32]Falush D, Stephens M, Pritchard J K. Inference of population structure using multilocus genotype data: linked loci and correlated allele frequencies. Genetics, 2003, 164: 1567–1587



[33]Falush D, Stephens M, Pritchard J. Inference of population strucutre using multilocus genetype data: dominant markers and null alleles. Mol Ecol Notes, 2007, 7: 574–578



[34]Falush D, Stephens M, Pritchard J. Inferring weak population strucutre with the assistance of sample group information. Mol Ecol Resour, 2009, 9: 1322–1332



[35]Bradbury P J, Zhang Z, Kroom D E, Casstevens T M, Ramdoss Y, Buckler E S. TASSEL: software for association mapping of complex traits in diverse samples. Bioinformatics, 2007, 23: 2633–2635



[36]Glaubitz J C, Casstevens T M, Lu F, Harriman J, Elshire R J, Sun Q, Buckler E S. TASSEL-GBS: a high capacity genotyping by sequencing analysis pipeline. PloS ONE, 2014, 9(2): e90346



[37]Evanno G, Rsgnaut S, Gounet J. Decting the number of clusters of individuals using the software STRUCTURE: a similation study. Mol Ecol, 2005, 14: 2611–2620



[38]Zhang W H, Sun P Y, He Q, Shu F, Wang J, Deng H F. Fine mapping of GS2, a dominant gene for big grain rice. Crop J, 2013, 1: 160–165



[39]Fan C C, Xing Y Z, Mao H L, Lu T T, Han B, Xu C G, Li X H, Zhang QF.GS3, a major QTL for grain length and weight and minor QTL for grain width and thickness in rice, encodes a putative transmembrane protein.Theor Appl Genet, 2006, 112: 1164–1171



[40]Mao H L, Sun S Y, Yao J L, Wang C R, Yu S B, Xu C G, Li X H, Zhang Q F. Linking differential domain functions of the GS3 protein to natural variation of grain size in rice. Proc Natl Acad Sci USA, 2010, 107: 19579–19584



[41]Wang Z Y, Wu Z L, Xing Y Y, Zheng F G, Guo X L, Zhang W G, Hong M M. Nucleotide sequence of rice waxy gene. Nucleic Acids Res, 1990, 19(19): 5898



[42]Ishimaru K, Hirotsu N, Madoka Y, Murakami N, Hara N, Onodera H, Kashiwagi T, Ujiie K, Shimizu B, Onishi A, Miyagawa H, Katoh E. Loss of function of IAA-glucose hydrolase gene TGW6 enhances rice grain weight and increases yield. Nat Genet, 2014, 45: 707–173



[43]Wang S K, Wu K, Yuan Q B, Liu X Y, Liu Z B, Lin X Y, Zeng R Z, Zhu H T, Dong G J, Qian Q, Zhang G Q, Fu X D. Control of grain size, shape and quality by OsSOL16 in rice. Nat Genet, 2012, 44: 950–954



[44]Jin L, Lu Y, Xiao P, Sun M, Corke H, Bao J S. Genetic diversity and population strucutre of a diverse set of rice germplasm for association mapping. Theor Appl Genet, 2010, 121: 475–487



[45]蔺万煌, 萧浪涛, 彭克勤, 洪亚辉, 邹冬生. 稻米垩白的形成及其调控. 湖南农业大学学报(自然科学版), 2001, 27(3): 234–239



Lin W H, Xiao L T, Peng K Q, Hong K H, Zou D S. Chalkiness formation in rice kernel and its regulation. J Hunan Agric Univ (Nat Sci), 2001, 27(3): 234–239 (in Chinese with English abstract)



[46]Li Y B, Fan C C, Xing Y Z, Jiang Y H, Luo L J, Sun L, Shao D, Xu C G, Li X H, Xiao J H, He Y Q, Zhang Q F. Natural variation in GS5 plays an important role in regulating grain size and yield in rice. Nat Genet, 2011, 43:1266–1269
[1] TIAN Tian, CHEN Li-Juan, HE Hua-Qin. Identification of rice blast resistance candidate genes based on integrating Meta-QTL and RNA-seq analysis [J]. Acta Agronomica Sinica, 2022, 48(6): 1372-1388.
[2] ZHENG Chong-Ke, ZHOU Guan-Hua, NIU Shu-Lin, HE Ya-Nan, SUN wei, XIE Xian-Zhi. Phenotypic characterization and gene mapping of an early senescence leaf H5(esl-H5) mutant in rice (Oryza sativa L.) [J]. Acta Agronomica Sinica, 2022, 48(6): 1389-1400.
[3] ZHOU Wen-Qi, QIANG Xiao-Xia, WANG Sen, JIANG Jing-Wen, WEI Wan-Rong. Mechanism of drought and salt tolerance of OsLPL2/PIR gene in rice [J]. Acta Agronomica Sinica, 2022, 48(6): 1401-1415.
[4] ZHENG Xiao-Long, ZHOU Jing-Qing, BAI Yang, SHAO Ya-Fang, ZHANG Lin-Ping, HU Pei-Song, WEI Xiang-Jin. Difference and molecular mechanism of soluble sugar metabolism and quality of different rice panicle in japonica rice [J]. Acta Agronomica Sinica, 2022, 48(6): 1425-1436.
[5] YAN Jia-Qian, GU Yi-Biao, XUE Zhang-Yi, ZHOU Tian-Yang, GE Qian-Qian, ZHANG Hao, LIU Li-Jun, WANG Zhi-Qin, GU Jun-Fei, YANG Jian-Chang, ZHOU Zhen-Ling, XU Da-Yong. Different responses of rice cultivars to salt stress and the underlying mechanisms [J]. Acta Agronomica Sinica, 2022, 48(6): 1463-1475.
[6] YANG Jian-Chang, LI Chao-Qing, JIANG Yi. Contents and compositions of amino acids in rice grains and their regulation: a review [J]. Acta Agronomica Sinica, 2022, 48(5): 1037-1050.
[7] DENG Zhao, JIANG Nan, FU Chen-Jian, YAN Tian-Zhe, FU Xing-Xue, HU Xiao-Chun, QIN Peng, LIU Shan-Shan, WANG Kai, YANG Yuan-Zhu. Analysis of blast resistance genes in Longliangyou and Jingliangyou hybrid rice varieties [J]. Acta Agronomica Sinica, 2022, 48(5): 1071-1080.
[8] YANG De-Wei, WANG Xun, ZHENG Xing-Xing, XIANG Xin-Quan, CUI Hai-Tao, LI Sheng-Ping, TANG Ding-Zhong. Functional studies of rice blast resistance related gene OsSAMS1 [J]. Acta Agronomica Sinica, 2022, 48(5): 1119-1128.
[9] ZHU Zheng, WANG Tian-Xing-Zi, CHEN Yue, LIU Yu-Qing, YAN Gao-Wei, XU Shan, MA Jin-Jiao, DOU Shi-Juan, LI Li-Yun, LIU Guo-Zhen. Rice transcription factor WRKY68 plays a positive role in Xa21-mediated resistance to Xanthomonas oryzae pv. oryzae [J]. Acta Agronomica Sinica, 2022, 48(5): 1129-1140.
[10] WANG Xiao-Lei, LI Wei-Xing, OU-YANG Lin-Juan, XU Jie, CHEN Xiao-Rong, BIAN Jian-Min, HU Li-Fang, PENG Xiao-Song, HE Xiao-Peng, FU Jun-Ru, ZHOU Da-Hu, HE Hao-Hua, SUN Xiao-Tang, ZHU Chang-Lan. QTL mapping for plant architecture in rice based on chromosome segment substitution lines [J]. Acta Agronomica Sinica, 2022, 48(5): 1141-1151.
[11] WANG Ze, ZHOU Qin-Yang, LIU Cong, MU Yue, GUO Wei, DING Yan-Feng, NINOMIYA Seishi. Estimation and evaluation of paddy rice canopy characteristics based on images from UAV and ground camera [J]. Acta Agronomica Sinica, 2022, 48(5): 1248-1261.
[12] KE Jian, CHEN Ting-Ting, WU Zhou, ZHU Tie-Zhong, SUN Jie, HE Hai-Bing, YOU Cui-Cui, ZHU De-Quan, WU Li-Quan. Suitable varieties and high-yielding population characteristics of late season rice in the northern margin area of double-cropping rice along the Yangtze River [J]. Acta Agronomica Sinica, 2022, 48(4): 1005-1016.
[13] CHEN Yue, SUN Ming-Zhe, JIA Bo-Wei, LENG Yue, SUN Xiao-Li. Research progress regarding the function and mechanism of rice AP2/ERF transcription factor in stress response [J]. Acta Agronomica Sinica, 2022, 48(4): 781-790.
[14] WANG Lyu, CUI Yue-Zhen, WU Yu-Hong, HAO Xing-Shun, ZHANG Chun-Hui, WANG Jun-Yi, LIU Yi-Xin, LI Xiao-Gang, QIN Yu-Hang. Effects of rice stalks mulching combined with green manure (Astragalus smicus L.) incorporated into soil and reducing nitrogen fertilizer rate on rice yield and soil fertility [J]. Acta Agronomica Sinica, 2022, 48(4): 952-961.
[15] QIN Qin, TAO You-Feng, HUANG Bang-Chao, LI Hui, GAO Yun-Tian, ZHONG Xiao-Yuan, ZHOU Zhong-Lin, ZHU Li, LEI Xiao-Long, FENG Sheng-Qiang, WANG Xu, REN Wan-Jun. Characteristics of panicle stem growth and flowering period of the parents of hybrid rice in machine-transplanted seed production [J]. Acta Agronomica Sinica, 2022, 48(4): 988-1004.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
Add: No.12 Zhongguancun South Street, Beijing 100081,China Email:xbzw@chinajournal.net.cn
Supported by Beijing Magtech Co.Ltd