作物科学所-毛新国导师介绍
毛新国
副研究员
硕士生导师
男
作物科学所
★作物种质资源学
05作物种质资源创新与利用
maoxinguo@caas.cn
科研项目
近5年主持或参加省部级以上科研项目情况(限10项):
(1)国家自然科学基金国际(地区)合作与交流项目,人工合成小麦及其衍生系抗旱耐热基因发掘与利用(32061143040),2021.1-2025.12,236万元,主持
(2)国家自然科学基金面上项目,小麦TaSnRK2s在茎秆可溶性糖代谢中的作用解析及优异等位基因发掘(31571660),2016.1-2019.12,70.98万元,主持
(3)中国-匈牙利政府间科技合作项目,小麦根系构型与水分利用效率(2017-7-2),2017.1-2018.12,2万元,主持
(4)国家重点研发计划,小麦种质资源精准鉴定与创新利用课题(2016YFD0100102),小麦地方品种导入系创制与种质资源耐旱性鉴定子课题(2016YFD0100102-1-3),2016.7-2020.12,110万元,子课题主持
(5)国家重点研发计划,小麦生产系统对气候变化的响应机制及其适应性栽培途径(2017YFD0300200)项目,气候因子及互作影响小麦产量形成的机制子课题(2017YFD0300202-1),2017.7-2020.12,120万元,子课题主持
(6)国家自然科学基金国际(地区)合作与交流项目,发掘利用抗旱耐热性状及其等位基因改良中国小麦(3141101092),2015.1-2019.12,220万元,参加
(7)转基因生物新品种培育重大专项,动植物转基因材料育种价值评估项目,植物抗逆转基因材料育种价值评估子课题(2016ZX08010005),2016.1-2020.12,50万元,参加
(8)农业农村部作物种质资源保护与利用专项,主要作物抗病虫、抗逆和品质性状鉴定评价课题(2018NWB036-12),小麦种质抗旱性鉴定评价子课题(2018NWB036-12-3),2018.1-2018.12,6.4万元,参加
(9)农业农村部作物种质资源保护与利用专项,主要作物抗病虫、抗逆和品质性状鉴定评价课题(2019NWB036-12),小麦种质抗旱性鉴定评价课题(2019NWB036-12-3),2019.1-2019.12,5.8万元,参加
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研究成果
近5年获省部级以上奖励情况:
(1)小麦抗旱节水种质资源创制和利用,神农中华农业科技奖科技进步二等奖,排名第7(7/15),2019年12月
(2)旱作农业创新团队,神农中华农业科技奖优秀创新团队奖,排名第13(13/20),2017年11月
近5年重要论文、专著及专利情况(限10项):
近5年累计发表论文34篇,其中SCI论文25篇;参编专著1部,参译专著1部;获得国家发明专利10项,其中第一发明人4项;选育国审小麦新品种1个,获植物新品种保护权1项。以下是与项目相关的部分研究成果:
1. 发表论文 (注:#,并列第一作者;*,通讯作者)
(1) Wang J, Li L, Li C, Yang X, Xue Y, Zhu Z, Mao X*, Jing R* (2021) A transposon in the vacuolar sorting receptor gene TaVSR1-B promoter region is associated with wheat root depth at booting stage. Plant Biotechnology Journal 19:1456-1467.
(2) Li C, Li L, Reynolds MP, Wang J, Chang X, Mao X*, Jing R* (2021) Recognizing the hidden half in wheat: root system attributes associated with drought tolerance. Journal of Experimental Botany 72:5117-5133.
(3) Li Y., Zhang Y., Li C., Chen X., Yang L., Zhang J., Wang J., Li L., Reynolds P. M., Jing R., Mao X. *, Wang C*. (2021) Transcription factor TaWRKY51 is a positive regulator in root architecture and grain yield contributing traits. Frontiers in Plant Science 12:734614.
(4) Li Q, Li B, Wang J, Chang X, Mao X*, Jing R* (2021) TaPUB15, a U-Box E3 ubiquitin ligase gene from wheat, enhances salt tolerance in rice. Food and Energy Security 10. DOI: 10.1002/fes3.250
(5) Wang J, Li C, Li L, Reynolds M, Mao X*, Jing R* (2021) Exploitation of drought tolerance-related genes for crop improvement. International journal of molecular sciences 22, 10265.
(6) Zhuang M, Li C, Wang J, Mao X, Li L, Yin J, Du Y, Wang X, Jing R (2021) Wheat SHORT ROOT LENGTH 1 gene TaSRL1 regulates root length in an auxin-dependent pathway. Journal of experimental botany. doi.org/10.1093/jxb/erab357
(7) Li L, Peng Z, Mao X, Wang J, Li C, Chang X, Jing R (2021) Genetic insights into natural variation underlying salt tolerance in wheat. Journal of Experimental Botany 72:1135-1150.
(8) ADDIN EN.REFLIST Du Y, Li C, Mao X, Wang J, Li L, Yang J, Zhuang M, Sun D, Jing R (2021) TaERF73 is associated with root depth, thousand-grain weight and plant height in wheat over a range of environmental conditions. Food and Energy Security. DOI: 10.1002/fes3.325
(9) Miao L, Li Y, Zhang H, Zhang H, Liu X, Wang J, Chang X, Mao X*, Jing R* (2021) TaSnRK2.4 is a vital regulator in control of thousand-kernel weight and response to abiotic stress in wheat. Journal of Integrative Agriculture 20:46-54.
(10) Ur Rehman S, Ali Sher M, Saddique MAB, Ali Z, Khan MA, Mao X, Irshad A, Sajjad M, Ikram RM, Naeem M, Jing R (2021) Development and exploitation of KASP assays for genes underpinning drought tolerance among wheat cultivars from Pakistan. Frontiers in Genetics 12:684702.
(11) Huang J-f, Li L, Mao X-g, Wang J-y, Liu H-m, Li C-n, Jing R-l (2020) dCAPS markers developed for nitrate transporter genes TaNRT2L12s associating with 1000-grain weight in wheat. Journal of Integrative Agriculture 19:1543-1553.
(12) Li L, Mao N, Wang J, Chang X, Reynolds M, Jing R (2019) Genetic dissection of drought and heat-responsive agronomic traits in wheat. Plant Cell and Environment 42:2540-2553.
(13) Li L, Peng Z, Mao X, Wang J, Chang X, Reynolds M, Jing R (2019) Genome-wide association study reveals genomic regions controlling root and shoot traits at late growth stages in wheat. Annals of Botany 124:993-1006.
(14) Wang J, Mao X, Wang R, Li A, Zhao G, Zhao J, Jing R* (2019) Identification of wheat stress-responding genes and T alpha PR-1-1 function by screening a cDNA yeast library prepared following abiotic stress. Scientific Reports 9,141.
(15) Mao X*, Li Y, Rehman SU, Miao L, Zhang Y, Chen X, Yu C, Wang J, Li C, Jing R* (2020) The Sucrose non-fermenting 1-related protein kinase 2 (SnRK2) genes are multifaceted players in plant growth, development and response to environmental stimuli. Plant and Cell Physiology 61:225-242.
(16) Wang J, Wang R, Mao X, Zhang J, Liu Y, Xie Q, Yang X, Chang X, Li C, Zhang X, Jing R (2020) RING finger ubiquitin E3 ligase gene TaSDIR1-4A contributes to determination of grain size in common wheat. Journal of Experimental Botany 71:5377-5388.
(17) Liu D, Li B, Feng G, Mao X, Li A, Chang X, Jing R (2019) TaPP2AbB"-gamma, a wheat regulatory subunit of PP2A enhanced abiotic stress tolerance. Plant Growth Regulation 89:345-355.
(18) Mao X, Yang D, Jing R (2017) Improving drought and heat tolerance in wheat. In: Langridge P (ed) Achieving Sustainable Cultivation of Wheat, Vol 1: Breeding, Quality Traits, Pests and Diseases, vol 5. Burleigh Dodds Series in Agricultural Science. pp 113-151. doi:10.19103/as.2016.0004.08
(19) Rehman SU, Wang J, Chang X, Zhang X, Mao X*, Jing R* (2019) A wheat protein kinase gene TaSnRK2.9-5A associated with yield contributing traits. Theoretical and Applied Genetics 132:907-919.
(20) Wang J, Wang R, Mao X, Li L, Chang X, Zhang X, Jing R (2019) TaARF4 genes are linked to root growth and plant height in wheat. Annals of Botany 124:903-915.
(21) Miao L, Mao X#, Wang J, Liu Z, Zhang B, Li W, Chang X, Reynolds M, Wang Z, Jing R (2017) Elite haplotypes of a protein kinase gene TaSnRK2.3 associated with important agronomic traits in common wheat. Frontiers in Plant Science 8:368.
(22) Wang J, Li R, Mao X, Jing R (2017) Functional analysis and marker development of TaCRT-D gene in common wheat (Triticum aestivum L.). Frontiers in Plant Science 8:1557.
(23) Xu Q, Mao X, Wang Y, Wang J, Xi Y, Jing R (2018) A wheat gene TaSAP17-D encoding an AN1/AN1 zinc finger protein improves salt stress tolerance in transgenic Arabidopsis. Journal of Integrative Agriculture 17:507-516.
(24) Li L, Mao X, Wang J, Chang X, Liu Y, Jing R (2018) Drought tolerance evaluation of wheat germplasm resources. Acta Agronomica Sinica 44:988-999.
(25) Yue A, Li A, Mao X, Chang X, Li R, Jing R (2017) Single-nucleotide polymorphisms, mapping and association analysis of 1-FFT-A1 gene in wheat. Journal of Integrative Agriculture 16:789-799.
(26) Zhang B, Xu W, Liu X, Mao X, Li A, Wang J, Chang X, Zhang X, Jing R (2017) Functional conservation and divergence among homoeologs of TaSPL20 and TaSPL21, two SBP-Box genes governing yield-related traits in hexaploid wheat. Plant Physiology 174:1177-1191.
(27) Zhang H*, Jing R*, Mao X* (2017) Functional characterization of TaSnRK2.8 promoter in response to abiotic stresses by deletion analysis in transgenic Arabidopsis. Frontiers in Plant Science 8:1198.
(28) Zhang H, Li W, Mao X, Jing R, Jia H (2016) Differential Activation of the Wheat SnRK2 Family by Abiotic Stresses. Frontiers in Plant Science 7:420.
(29) Li B, Li Q, Mao X, Li A, Wang J, Chang X, Hao C, Zhang X, Jing R (2016) Two Novel AP2/EREBP Transcription Factor Genes TaPARG Have Pleiotropic Functions on Plant Architecture and Yield-Related Traits in Common Wheat. Frontiers in Plant Science 7.
(30) Li B, Liu D, Li Q, Mao X, Li A, Wang J, Chang X, Jing R (2016) Overexpression of wheat gene TaMOR improves root system architecture and grain yield in Oryza sativa. Journal of Experimental Botany 67:4155-4167.
3. 获得发明专利
(1) 抗逆相关蛋白及其编码基因与应用(ZL200810226139.0),2011/09
(2) 植物抗逆相关蛋白TaERECTA及其编码基因与应用(ZL200810246712.6),2012/05
(3) 植物抗逆相关蛋白TaSnRK2.3及其编码基因与应用(ZL201110144767.8),2012/11
(4) 植物抗逆相关蛋白TaSnRK2.10及其编码基因与应用(ZL201110333264.5),2013/05
(5) 植物抗逆相关蛋白TaNAC67及其编码基因与应用(ZL20121114593.1),2013/11
(6) 一种植物耐逆相关蛋白TaWRKY35及其编码基因与应用(ZL201610172560.4),2019/11
(7) 一种与小麦千粒重和株高相关的分子标记TaSnRK2.3A及其应用(ZL 201611102374.X),2019/08
(8) 一种与小麦千粒重和茎秆可溶性糖含量相关的分子标记TaSnRK2.3B及其应用(ZL 201611102371.4),2019/08
(9) 一种与小麦千粒重和茎秆可溶性糖含量相关的分子标记TaSnRK2.4A及其应用(ZL 201611102181.4),2019/09
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学校介绍
中国农业科学院研究生院成立于1979年,1981年经国务院批准开始实施硕士、博士学历学位教育,是我国国家级科研机构举办研究生教育的先行院所之一。作为支撑我院研究生教育的中国农业科学院成立于1957年,是农业农村部直属的综合性国家农业科研机构,是全国综合性农业科学研究的最高学术机构,是农业及农业科学技术战略咨询机构,是三农领域国家战略科技力量,担负着全国农业重大基础与应用基础研究、应用研究和高新技术技术研究的任务,致力于解决我国农业及农村经济发展中公益性、基础性、全局性、战略性、前瞻性的重大科学与技术问题。在推动农业科技创新、服务经济社会发展、培养高层次人才、促进国际交流与合作等方面发挥着重要作用。“十三五”期间,共获得国家科学技术奖36项,占全国农业领域获奖总数的26%。其中科技进步一等奖1项,自然科学二等奖2项,技术发明二等奖6项,科技进步二等奖27项;获得省部级奖励229项;发表论文近30000篇,其中SCI论文近15000篇、《NATURE》《SCIENCE》《CELL》等国际顶级学术期刊论文29篇;出版专著近1500部,通过国审品种等近1200个,获得植物新品种权397项,新兽药证书55个等。科研成果与科研实力处于行业领先地位。
中国农科院研究生教育依托中国农业科学院的国家级科研平台基地、先进科研设施设备、重大科研攻关项目、稳定的科研经费保障、前沿交叉学科集群、一流的导师队伍、广泛的国际合作机制、丰富的图书文献等各种重要资源,形成了38个研究所共同参与、“院所结合、两段式培养”这一特色鲜明的科研机构举办研究生教育的创新模式,将中国农业科学院的科研资源优势转化为学科建设、人才培养、特色办学优势,为研究生完成课程教学、开展学术研究、参与课题实践、培养创新能力提供了农业科研国家队特有的广阔舞台。
中国农业科学院深圳农业基因组研究所(以下简称“基因组所”),创建于2014年,是农业农村部,中国农科院和深圳市在科技体制改革的背景下,整合农业基因组学研究力量在深圳成立的新型研究所。
成立以来,基因组所深入贯彻落实习近平总书记“四个面向、两个一流”指示精神,开展科研自主权改革试点工作,被列为中国农科院现代院所改革的“试验田”,建设了由中国农科院与深圳市主管领导任共同理事长的理事会;组建了近800人的研究队伍;形成了以组学技术为核心、辐射农业、食品和生态方向的学科体系,获批“岭南现代农业科学与技术广东省实验室深圳分中心”“农业农村部农业基因数据分析重点实验室”等创新载体;在包括 Science、Nature、Cell 等顶级期刊在内的杂志上发表SCI论文400多篇,以基因组设计育种育成国审、省审新品种30余个,农业基因组学等研究领域占据世界前沿。 2019年、2020年连续两年自然指数排名全国农业类科研院所第一名,多项成果入选“‘十三五’农业科技十大标志性成果”“中国生命科学十大进展”“中国农业科学十大进展”。先后获得“何梁何利基金”奖、“周光召基础科学奖”“深圳经济特区建立40周年创新创业和先进模范人物”“深圳市市长奖”等奖励。基因组所联合深圳市相关部门提出了“深圳国际食品谷”,规划已得到市政府印发,将构建农业食品产学研协作生态,做出科技推动农业食品产业转型升级的先行示范。
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按照国家相关规定,我院全日制与非全日制硕士研究生学费标准均为:8000元/人/年。凡我院各研究所录取的推免生均免收第一年学费,优秀推免生免收基本学制内全部学费。
我院全日制非定向硕士研究生奖助学金体系由奖学金和助学金两部分组成。奖学金包括国家奖学金、学业奖学金(100%覆盖)、研究生院单项奖学金和企业奖学金。助学金包括国家助学金、研究生院助学金、导师助研津贴、“三助”津贴和特困生补助,具体奖助学金政策可登陆中国农业科学院研究生院网站查询。
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