玉米冠根性状的遗传解析及其与地上部农艺性状的遗传关系

doi:10.1016/j.jia.2023.04.022

Journal of Integrative Agriculture ›› 2023, Vol. 22 ›› Issue (11): 3394-3407.DOI: 10.1016/j.jia.2023.04.022

玉米冠根性状的遗传解析及其与地上部农艺性状的遗传关系

收稿日期:2022-11-16 接受日期:2023-02-21 出版日期:2023-11-20 发布日期:2023-11-09

Genetic dissection of crown root traits and their relationships with aboveground agronomic traits in maize

SHA Xiao-qian^1*, GUAN Hong-hui^2*, ZHOU Yu-qian^3*, SU Er-hu^4*, GUO Jian², LI Yong-xiang², ZHANG Deng-feng², LIU Xu-yang², HE Guan-hua², LI Yu², WANG Tian-yu², ZOU Hua-wen^1#, LI Chun-hui^2#

¹ College of Agriculture, Yangtze University, Jingzhou 434000, P.R.China
² State Key Laboratory of Crop Gene Resources and Breeding, Institute of Crop Sciences, Chinese Academy of Agricultural Sciences, Beijing 100081, P.R.China
³ Institute of Crops, Gansu Academy of Agricultural Sciences, Lanzhou 730070, P.R.China
⁴ Institute of Maize Research, Inner Mongolia Academy of Agricultural & Animal Husbandry Sciences, Hohhot 010031, P.R.China

Received:2022-11-16 Accepted:2023-02-21 Online:2023-11-20 Published:2023-11-09
About author:SHA Xiao-qian, E-mail: xq18392891030@163.com; #Correspondence ZOU Hua-wen, E-mail: zouhuawen@yangtzeu.edu.cn; LI Chun-hui, E-mail: lichunhui@caas.cn * These authors contributed equally to this study.
Supported by:
This work was supported by grants from the National Natural Science Foundation of China (31971891), the Guangxi Key Research and Development Projects, China (GuikeAB21238004), the Scientific Innovation 2030 Project, China (2022ZD0401703), and the Modern Agro-Industry Technology Research System of Maize, China (CARS-02-03).

摘要/Abstract

摘要：

冠根系统是玉米营养期和生殖期最重要的根系组成部分。然而，玉米冠根性状的遗传基础及其与地上部农艺性状的关系尚不清楚。本研究以531个玉米优良自交系为研究对象，在不同的田间环境下，对其冠根相关性状和地上部农艺性状进行表型分析。结果表明，根系性状与开花时间、株型结构、籽粒产量等地上部农艺性状呈显著正相关。通过全基因组关联分析（GWAS）结合重测序，共鉴定出115关联位点和22个高置信候选基因。其中冠根与花期和植株构型有46个QTL共定位，因此大约三分之一的冠根性状遗传变异可能要归因于开花时间和植株结构。此外，115个冠根位点中有103个（89.6%）位于已知的驯化和改良选择范围内，这表明冠根在玉米驯化和改良过程中可能经历了间接选择。此外，Zm00001d036901是一个高置信候选基因，其表达可能与玉米冠根的表型变异有关，Zm00001d036901在玉米驯化改良过程中是受选择的。本研究促进了我们对根系结构遗传基础的理解，并为改进玉米根系结构提供了基因组学资源。

Abstract: The crown root system is the most important root component in maize at both the vegetative and reproductive stages. However, the genetic basis of maize crown root traits (CRT) is still unclear, and the relationship between CRT and aboveground agronomic traits in maize is poorly understood. In this study, an association panel including 531 elite maize inbred lines was planted to phenotype the CRT and aboveground agronomic traits in different field environments. We found that root traits were significantly and positively correlated with most aboveground agronomic traits, including flowering time, plant architecture and grain yield. Using a genome-wide association study (GWAS) coupled with resequencing, a total of 115 associated loci and 22 high-confidence candidate genes were identified for CRT. Approximately one-third of the genetic variation in crown root was co-located with 46 QTLs derived from flowering and plant architecture. Furthermore, 103 (89.6%) of 115 crown root loci were located within known domestication- and/or improvement-selective sweeps, suggesting that crown roots might experience indirect selection in maize during domestication and improvement. Furthermore, the expression of Zm00001d036901, a high-confidence candidate gene, may contribute to the phenotypic variation in maize crown roots, and Zm00001d036901 was selected during the domestication and improvement of maize. This study promotes our understanding of the genetic basis of root architecture and provides resources for genomics-enabled improvements in maize root architecture.

Key words: maize , root , aboveground agronomic traits , GWAS , candidate genes

SHA Xiao-qian, GUAN Hong-hui, ZHOU Yu-qian, SU Er-hu, GUO Jian, LI Yong-xiang, ZHANG Deng-feng, LIU Xu-yang, HE Guan-hua, LI Yu, WANG Tian-yu, ZOU Hua-wen, LI Chun-hui. 玉米冠根性状的遗传解析及其与地上部农艺性状的遗传关系[J]. Journal of Integrative Agriculture, 2023, 22(11): 3394-3407.

SHA Xiao-qian, GUAN Hong-hui, ZHOU Yu-qian, SU Er-hu, GUO Jian, LI Yong-xiang, ZHANG Deng-feng, LIU Xu-yang, HE Guan-hua, LI Yu, WANG Tian-yu, ZOU Hua-wen, LI Chun-hui. Genetic dissection of crown root traits and their relationships with aboveground agronomic traits in maize[J]. Journal of Integrative Agriculture, 2023, 22(11): 3394-3407.

参考文献

Arain S, Meer M, Sajjad M, Yasmin H. 2021. Light contributes to salt resistance through GAI protein regulation in Arabidopsis thaliana. Plant Physiology and Biochemistry, 159, 1–11.

Asefa M, Worthy S J, Cao M, Song X, Lozano Y M, Yang J. 2022. Above- and below-ground plant traits are not consistent in response to drought and competition treatments. Annals of Botany, 130, 939–950.

Baez R R, Buckley Y, Yu H, Chen Z L, Gallavotti A, Nemhauser J L, Moss B L. 2020. A synthetic approach allows rapid characterization of the maize nuclear auxin response circuit. Plant Physiology, 182, 1713–1722.

Bjerkan K N, Grini P E. 2013. The Arabidopsis DDB1 interacting protein WDR55 is required for vegetative development. Plant Signaling & Behavior, 8, e25347.

Bomblies K, Doebley J F. 2006. Pleiotropic effects of the duplicate maize FLORICAULA/LEAFY genes zfl1 and zfl2 on traits under selection during maize domestication. Genetics, 172, 519–531.

Brown P J, Upadyayula N, Mahone G S, Tian F, Bradbury P J, Myles S, Holland J B, Flint-Garcia S, McMullen M D, Buckler E S, Rocheford T R. 2011. Distinct genetic architectures for male and female inflorescence traits of maize. PLoS Genetics, 7, e1002383.

Burton A L, Johnson J M, Foerster J M, Foerster J M, Hirsch C N, Buell C R, Hanlon M T, Kaeppler S M, Brown K M, Lynch J P. 2014. QTL mapping and phenotypic variation for root architectural traits in maize (Zea mays L.). Theoretical and Applied Genetics, 127, 2293–2311.

Cai H G, Chen F J, Mi G H, Zhang F S, Maurer H P, Liu W X, Reif J C, Yuan L X. 2012. Mapping QTLs for root system architecture of maize (Zea mays L.) in the field at different developmental stages. Theoretical and Applied Genetics, 125, 1313–1324.

Chen L, Li Y X, Li C H, Shi Y S, Song Y C, Zhang D F, Wang H Y, Li Y, Wang T Y. 2020. The retromer protein ZmVPS29 regulates maize kernel morphology likely through an auxin-dependent process(es). Plant Biotechnology Journal, 18, 1004–1014.

Chen M, Liu H, Kong J, Yang Y, Zhang N, Li R, Yue J, Huang J, Li C, Cheung A Y, Tao L Z. 2011. RopGEF7 regulates PLETHORA-dependent maintenance of the root stem cell niche in Arabidopsis. Plant Cell, 23, 2880–2894.

Chen W K, Chen L, Zhang X, Yang N, Guo J H, Wang M, Ji S H, Zhao X Y, Yin P F, Cai L C, Xu J, Zhang L L, Han Y J, Xiao Y N, Xu G, Wang Y B, Wang S H, Wu S, Yang F, Jackson D, et al. 2022. Convergent selection of a WD40 protein that enhances grain yield in maize and rice. Science, 375, eabg7985.

Colombi T, Kirchgessner N, Le Marié C A, York L M, Lynch J P, Hund A. 2015. Next generation shovelomics: set up a tent and REST. Plant and Soil, 388, 1–20.

Dutilleul C, Ribeiro I, Blanc N, Nezames C D, Deng X W, Zglobicki P, Barrera A M P, Atehortua L, Courtois M, Labas V, Giglioli-Guivarch N, Ducos E. 2016. ASG2 is a farnesylated DWD protein that acts as ABA negative regulator in Arabidopsis. Plant Cell and Environment, 39, 185–198.

FAO (Food and Agriculture Organization) of the United Nations Agriculture Databases. 2019. [2019-08-15]. http://www.fao.org/statistics/databases/en/

Feng X J, Jia L, Cai Y T, Guan H R, Zheng D, Zhang W X, Xiong H, Zhou H M, Wen Y, Hu Y, Zhang X M, Wang Q J, Wu F K, Xu J, Lu Y L. 2022. ABA-inducible DEEPER ROOTING 1

improves adaptation of maize to water deficiency. Plant Biotechnology Journal, 20, 2077–2088.

Fernández-Marco M, Desvoyes B, Manzano C, Liberman L M, Benfey P N, del Pozo J C, Gutierrez C. 2017. Control of Arabidopsis lateral root primordium boundaries by MYB36. New Phytologist, 213, 105–112.

Gao Y Z, Lynch J P. 2016. Reduced crown root number improves water acquisition under water deficit stress in maize (Zea mays L.). Journal of Experimental Botany, 67, 4545–4557.

Gu D D, Mei X P, Yu T T, Sun N N, Xu D, Liu C X, Cai Y L. 2017. QTL identification for brace-root traits of maize in different generations and environments. Crop Science, 57, 13–21.

Hochholdinger F, Woll K, Sauer M, Dembinsky D. 2004. Genetic dissection of root formation in maize (Zea mays) reveals root-type specific developmental programmes. Annals of Botany, 93, 359–368.

Hofmann J, Hess P H, Szakasits D, Blochl A, Wieczorek K, Daxbock-Horvath S, Bohlmann H, van Bel A J E, Grundler F M W. 2009. Diversity and activity of sugar transporters in nematode-induced root syncytia. Journal of Experimental Botany, 60, 3085–3095.

Hufford M B, Xu X, Van Heerwaardan J, Pyhajarvi T, Chia J M, Cartwright R A, Elshire R J, Glaubitz J C, Guill K E, Kaeppler S M, Lai J, Morrell P L, Shannon L M, Song C, Springer N M, Swanson-Wagner R A, Tiffin P, Wang J, Zhang G Y, Doebley J, et al. 2012. Comparative population genomics of maize domestication and improvement. Nature Genetics, 44, 808–811.

Inoue T, Kondo Y, Naramoto S, Nakano A, Ueda T. 2013. RAB5 activation is required for multiple steps in Arabidopsis thaliana root development. Plant and Cell Physiology, 54, 1648–1659.

Ju C L, Zhang W, Liu Y, Gao Y F, Wang X F, Yan J B, Yang X H, Li J S. 2018. Genetic analysis of seedling root traits reveals the association of root trait with other agronomic traits in maize. BMC Plant Biology, 18, 171.

Kang H M, Sul J H, Service S K, Zaitlen N A, Kong S Y, Freimer N B, Sabatti C, Eskin E. 2010. Variance component model to account for sample structure in genome-wide association studies. Nature Genetics, 42, 348–354.

Kengkanna J, Jakaew P, Amawan S, Busener N, Bucksch A, Saengwilai P. 2019. Phenotypic variation of cassava root traits and their responses to drought. Applications in Plant Sciences, 7, e01238.

Ku L X, Sun Z H, Wang C L, Zhang J, Zhao R F, Liu H Y, Tai G Q, Chen Y H. 2012. QTL mapping and epistasis analysis of brace root traits in maize. Molecular Breeding, 30, 697–708.

Kubo M, Udagawa M, Nishikubo N, Horiguchi G, Yamaguchi M, Ito J, Mimura T, Fukuda H, Demura T. 2005. Transcription switches for protoxylem and metaxylem vessel formation. Genes & Development, 19, 1855–1860.

Van Leene J, Blomme J, Kulkarni S R, Cannoot B, De Winne N, Eeckhout D, Persiau G, Van De Slijke E, Vercruysse L, Bossche R V, Heyndrickx K S, Vanneste S, Goossens A, Gevaert K, Vandepoele K, Gonzalez N, Inze D, Jaeger G D. 2016. Functional characterization of the Arabidopsis transcription factor bZIP29 reveals its role in leaf and root development. Journal of Experimental Botany, 67, 5825–5840.

Li C H, Guan H H, Jing X, Li Y Y, Wang B B, Li Y X, Liu X Y, Zhang D F, Liu C, Xie X Q, Zhao H Y, Wang Y B, Liu J B, Zhang P P, Hu G H, Li G L, Li S Y, Sun D Q, Wang X M, Shi Y S, et al. 2022. Genomic insights into historical improvement of heterotic groups during modern hybrid maize breeding. Nature Plants, 8, 750–763.

Li C H, Wang G, Zhao J L, Zhang L Q, Ai L F, Han Y F, Sun D Y, Zhang S W, Sun Y. 2014. The receptor-like kinase SIT1 mediates salt sensitivity by activating MAPK3/6 and regulating ethylene homeostasis in rice. Plant Cell, 26, 2538–2553.

Li P C, Fan Y Y, Yin S Y, Wang Y Y, Wang H M, Xu Y, Yang Z F, Xu C W. 2020. Multi-environment QTL mapping of crown root traits in a maize RIL population. The Crop Journal, 8, 645–654.

Li P C, Zhang Y Y, Yin S Y, Zhu P F, Pan T, Xu Y, Wang J Y, Hao D R, Fang H M, Xu C W, Yang Z F. 2018. QTL-by-environment interaction in the response of maize root and shoot traits to different water regimes. Frontiers in Plant Science, 9, 229.

Li R Y, Zeng Y J, Xu J, Wang Q, Wu F K, Cao M J, Lan H, Liu Y X, Lu Y L. 2015. Genetic variation for maize root architecture in response to drought stress at the seedling stage. Breeding Science, 65, 298–307.

Liang Y M, Liu Q, Wang X F, Huang C, Xu G H, Hey S, Lin H Y, Li C, Xu D Y, Wu L S, Wang C L, Wu W H, Xia J L, Xu H, Lu S J, Lai J S, Song W B, Schnable P S, Tian F. 2019. ZmMADS69 functions as a flowering activator through the ZmRap2.7-ZCN8 regulatory module and contributes to maize flowering time adaptation. New Phytologist, 221, 2335–2347.

Liu Q C, Deng S N, Liu B S, Tao Y F, Ai H Y, Liu J J, Zhang Y Z, Zhao Y, Xu M L. 2020. A helitron-induced RabGDI alpha variant causes quantitative recessive resistance to maize rough dwarf disease. Nature Communications, 11, 495.

Liu R X, Jia H T, Cao X L, Huang J, Li F, Tao Y S, Qiu F Z, Zheng Y L, Zhang Z X. 2012. Fine mapping and candidate gene prediction of a pleiotropic quantitative trait locus for yield-related trait in Zea mays. PLoS ONE, 7, e49836.

Liu T B, Liu Q Y, Yu Z, Wang C L, Mai H F, Liu G L, Li R J, Pang G, Chen D W, Liu H L, Yang J G, Tao L Z. 2022. eIF4E1 regulates Arabidopsis embryo development and root growth by interacting with RopGEF7. Frontiers in Plant Science, 13, 938476.

Liu X M, An J, Han H J, Kim S H, Lim C O, Yun D J, Chung W S. 2014. ZAT11, a zinc finger transcription factor, is a negative regulator of nickel ion tolerance in Arabidopsis. Plant Cell Reports, 33, 2015–2021.

Lynch J P. 2013. Steep, cheap and deep: An ideotype to optimize water and N acquisition by maize root systems. Annals of Botany, 112, 347–357.

Majer C, Xu C Z, Berendzen K W, Hochholdinger F. 2012. Molecular interactions of rootless concerning crown and seminal roots, a LOB domain protein regulating shoot–borne root initiation in maize (Zea mays L.). Philosophical Transactions of the Royal Society (B: Biological Sciences), 367, 1542–1551.

Mallika C, Waraporn T, Tatsuhito F, Stephen C, Fry J, Ketudat C. 2007. Molecular characterization of β-galactosidases from germinating rice (Oryza sativa). Plant Science, 173, 118–134.

Mi G H, Chen F J, Wu Q P, Lai N W, Yuan L X, Zhang F S. 2010. Ideotype root architecture for efficient nitrogen acquisition by maize in intensive cropping systems. Science China (Life Sciences), 53, 1369–1373.

Moussa A A, Mandozai A, Jin Y K, Qu J, Zhang Q, Zhao H, Anwari G, Khalifa M A S, Lamboro A, Noman M, Bakasso Y, Zhang M, Guan S Y, Wang P W. 2021. Genome-wide association screening and verification of potential genes associated with root architectural traits in maize (Zea mays L.) at multiple seedling stages. BMC Genomics, 22, 558.

Nibau C, Tao L Z, Levasseur K, Wu H M, Cheung A Y. 2013. The Arabidopsis small GTPase AtRAC7/ROP9 is a modulator of auxin and abscisic acid signalling. Journal of Experimental Botany, 64, 3425–3437.

Omori F, Mano Y. 2007. QTL m apping of root angle in F2 populations from maize ‘B73’×teosinte ‘Zea luxurians’. Plant Root, 1, 57–65.

Pace J, Gardner C, Romay C, Ganapathysubramanian B, Lubberstedt T. 2015. Genome-wide association analysis of seedling root development in maize (Zea mays L.). BMC Genomics, 16, 47.

Paez-Garcia A, Motes C M, Scheible W R, Chen R, Blancaflor E B, Monteros M J. 2015. Root traits and phenotyping strategies for plant improvement. Plants (Basel), 4, 334–355.

Ren W, Zhao L F, Liang J X, Wang L F, Chen L M, Li P C, Liu Z G, Li X J, Zhang Z H, Li J P, He K H, Zhao Z, Ail F H, Mi G H, Yan J B, Zhang F S, Chen F J, Yuan L X, Pan Q C. 2022. Genome-wide dissection of changes in maize root system architecture during modern breeding. Nature Plants, 8, 1408–1422.

Ribaut J M, Betran J, Monneveux P, Setter T. 2009. Drought tolerance in maize. In: Bennetzen J L, Hake S C, eds., Handbook of Maize: Its Biology. Springer Publishing, New York, USA. pp. 311–344.

Salvi S, Sponza G, Morgante M, Tomes D, Niu X, Fengler K A, Meeley R, Ananiev E V, Svitashev S, Bruggemann E, Li B, Hainey C F, Radovic S, Zaina G, Rafalski J A, Tingey S V, Miao G H, Phillips R L, Tuberosa R. 2007. Conserved noncoding genomic sequences associated with a flowering-time quantitative trait locus in maize. Proceedings of the National Academy of Sciences of the United States of America, 104, 11376–11381.

Schneider H M, Lor V S N, Hanlon M T, Perkins A, Kaepper S M, Borkar A N, Bhosale R, Zhang X, Rodriguez J, Bucksch A, Bennett M J, Brown K M, Lynch J P. 2022. Root angle in maize influences nitrogen capture and is regulated by calcineurin B-like protein (CBL)-interacting serine/threonine-protein kinase 15 (ZmCIPK15). Plant Cell and Environment, 45, 837–853.

Shang Q, Zhang D, Li R, Wang K, Cheng Z, Zhou Z, Hao Z, Pan J, Li X, Shi L. 2020. Mapping quantitative trait loci associated with stem-related traits in maize (Zea mays L.). Plant Molecular Biology, 104, 583–595.

Shen Y, Gilbert G S, Li W B, Fang M, Lu H P, Yu S X. 2019. Linking aboveground traits to root traits and local environment: Implications of the plant economics spectrum. Frontiers in Plant Science, 10, 1412.

Song W B, Wang B B, Hauck A L, Dong X M, Li J P, Lai J S. 2016. Genetic dissection of maize seedling root system architecture traits using an ultra-high density bin-map and a recombinant inbred line population. Journal of Integrative Plant Biology, 58, 266–279.

Strobl S M, Kischka D, Heilmann I, Mouille G, Schneider S. 2018. The tonoplastic inositol transporter INT1 from Arabidopsis thaliana impacts cell elongation in a sucrose-dependent way. Frontiers in Plant Science, 9, 1657.

Sunohara H, Kawai T, Shimizu-Sato S, Sato Y, Sato K, Kitano H. 2009. A dominant mutation of TWISTED DWARF 1 encoding an alpha-tubulin protein causes severe dwarfism and right helical growth in rice. Genes & Genetic Systems, 84, 209–218.

Tai H H, Lu X, Opitz N, Marcon C, Paschold A, Lithio A, Nettleton D, Hochholdinger F. 2016. Transcriptomic and anatomical complexity of primary, seminal, and crown roots highlight root type-specific functional diversity in maize (Zea mays L.). Journal of Experimental Botany, 67, 1123–1135.

Tian J G, Wang C L, Xia J L, Wu L S, Xu G H, Wu W H, Dan L, Qin W C, Han X, Chen Q Y, Jin W W, Tian F. 2019. Teosinte ligule allele narrows plant architecture and enhances high-density maize yields. Science, 365, 658–664.

Trachsel S, Kaeppler S M, Brown K M, Lynch J P. 2013. Maize root growth angles become steeper under low N conditions. Field Crops Research, 140, 18–31.

Vaid N, Macovei A, Tuteja N. 2013. Knights in action: Lectin receptor-like kinases in plant development and stress responses. Molecular Plant, 6, 1405–1418.

Vaid N, Pandey P K, Tuteja N. 2012. Genome-wide analysis of lectin receptor-like kinase family from Arabidopsis and rice. Plant Molecular Biology, 80, 365–388.

Wang B B, Lin Z C, Li X, Zhao Y P, Zhao B B, Wu G X, Ma X J, Wang H, Xie Y R, Li Q Q, Song G S, Kong D X, Zheng Z G, Wei H B, Shen R X, Wu H, Chen C X, Meng Z D, Wang T Y, Li Y, et al. 2020. Genome-wide selection and genetic improvement during modern maize breeding. Nature Genetics, 52, 565–571.

Wang F, Coe R A, Karki S, Wanchana S, Thakur V, Henry A, Lin H C, Huang J L, Peng S B, Quick W P. 2016. Overexpression of OsSAP16 regulates photosynthesis and the expression of a broad range of stress response genes in rice (Oryza sativa L.). PLoS ONE, 11, e0157244.

Wang H M, Tang X, Yang X Y, Fan Y Y, Xu Y, Li P C, Xu C W, Yang Z F. 2021. Exploiting natural variation in crown root traits via genome-wide association studies in maize. BMC Plant Biology, 21, 346.

Wang H M, Wei J, Li P C, Wang Y Y, Ge Z Z, Qian J Y, Fan Y Y, Ni J R, Xu Y, Yang Z F, Xu C W. 2019. Integrating GWAS and gene expression analysis identifies candidate genes for root morphology traits in maize at the seedling stage. Genes, 10, 773.

Wang X F, He F F, Ma X X, Mao C Z, Hodgman C, Lu C G, Wu P. 2011. OsCAND1 is required for crown root emergence in rice. Molecular Plant, 4, 289–299.

Wang Y J, Deng D X, Bian Y L, Lv Y P, Xie Q. 2010. Genome-wide analysis of primary auxin-responsive Aux/IAA gene family in maize (Zea mays L.). Molecular Biology Reports, 37, 3991–4001.

Woll K, Borsuk L A, Stransky H, Nettleton D, Schnable P S, Hochholdinger F. 2005. Isolation, characterization, and pericycle-specific transcriptome analyses of the novel maize lateral and seminal root initiation mutant rum1. Plant Physiology, 139, 1255–1267.

Wu B, Ren W, Zhao L F, Li Q, Sun J Z, Chen F J, Pan Q C. 2022. Genome-wide association study of root system architecture in maize. Genes, 13, 181.

Wu Z C, Ren H Y, Mcgrath S P, Wu P, Zhao F J. 2011. Investigating the contribution of the phosphate transport pathway to arsenic accumulation in rice. Plant Physiology, 157, 498–508.

Xia R, Wang J G, Liu C Y, Wang Y, Wang Y Q, Zhai J X, Liu J, Hong X H, Cao X F, Zhu J K, Gong Z H. 2006. ROR1/RPA2A, a putative replication protein A2, functions in epigenetic gene silencing and in regulation of meristem development in Arabidopsis. Plant Cell, 18, 85–103.

Yang X Y, Wang B C, Farris B, Clark G, Roux S J. 2015. Modulation of root skewing in Arabidopsis by apyrases and extracellular ATP. Plant and Cell Physiology, 56, 2197–2206.

Yazdanbakhsh N, Fisahn J. 2011. Mutations in leaf starch metabolism modulate the diurnal root growth profiles of Arabidopsis thaliana. Plant Signaling & Behavior, 6, 995–998.

Yu X L, Wang H Y, Leung D W M, He Z D, Zhang J J, Peng X X, Liu E E. 2019. Overexpression of OsIAAGLU reveals a role for IAA-glucose conjugation in modulating rice plant architecture. Plant Cell Reports, 38, 731–739.

Zeng T R, Meng Z D, Yue R Q, Lu S P, Li W L, Li W C, Meng H, Sun Q. 2022. Genome wide association analysis for yield related traits in maize. BMC Plant Biology, 22, 449.

Zhang C, Dong S S, Xu J Y, He W M, Yang T L. 2019. PopLDdecay: A fast and effective tool for linkage disequilibrium decay analysis based on variant call format files. Bioinformatics, 35, 1786–1788.

Zhang Y X, Paschold A, Marcon C, Liu S Z, Tai H H, Nestler J, Yeh C T, Opitz N, Lanz C, Schnable P S, Hochholdinger F. 2014. The Aux/IAA gene rum1 involved in seminal and lateral root formation controls vascular patterning in maize (Zea mays L.) primary roots. Journal of Experimental Botany, 65, 4919–4930.

Zhang Z H, Zhang X, Lin Z L, Wang J, Xu M L, Lai J S, Yu J M, Lin Z W. 2018. The genetic architecture of nodal root number in maize. Plant Journal, 93, 1032–1044.

Zhong R Q, Lee C H, Ye Z H. 2010. Evolutionary conservation of the transcriptional network regulating secondary cell wall biosynthesis. Trends in Plant Science, 15, 625–632.

Zhou J L, Zhong R Q, Ye Z H. 2014. Arabidopsis NAC domain proteins, VND1 to VND5, are transcriptional regulators of secondary wall biosynthesis in vessels. PLoS ONE, 9, e105726.

Zhu J M, Kaeppler S M, Lynch J P. 2005. Topsoil foraging and phosphorus acquisition efficiency in maize (Zea mays). Functional Plant Biology, 32, 749–762.

玉米冠根性状的遗传解析及其与地上部农艺性状的遗传关系

Genetic dissection of crown root traits and their relationships with aboveground agronomic traits in maize

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 0

编辑推荐

Metrics