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

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, ZhuZ, Mao X*, Jing R* (2021) A transposon in thevacuolar sorting receptor gene TaVSR1-B promoter region is associated withwheat root depth at booting stage. Plant Biotechnology Journal 19:1456-1467.

(2)       Li C, Li L, Reynolds MP, Wang J, ChangX, Mao X*, Jing R* (2021) Recognizing the hiddenhalf 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 apositive 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 E3ubiquitin ligase gene from wheat, enhances salt tolerance in rice. Food andEnergy Security 10. DOI: 10.1002/fes3.250

(5)       Wang J, Li C, Li L, Reynolds M, Mao X*, Jing R* (2021) Exploitation of droughttolerance-related genes for crop improvement. International journal ofmolecular sciences 22, 10265.

(6)       Zhuang M, Li C, Wang J, Mao X, Li L, YinJ, Du Y, Wang X, Jing R (2021) Wheat SHORT ROOT LENGTH 1 geneTaSRL1 regulates root length in an auxin-dependent pathway. Journal ofexperimental botany. doi.org/10.1093/jxb/erab357

(7)       Li L, Peng Z, Mao X, Wang J, Li C, ChangX, Jing R(2021) Genetic insights into natural variation underlying salt tolerance inwheat. 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 plantheight in wheat over a range of environmental conditions. Food and EnergySecurity. 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-kernelweight and response to abiotic stress in wheat. Journal of IntegrativeAgriculture 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 droughttolerance among wheat cultivars from Pakistan. Frontiers in Genetics 12:684702.

(11)   Huang J-f, Li L, Mao X-g, Wang J-y, LiuH-m, Li C-n, Jing R-l (2020) dCAPS markers developed fornitrate transporter genes TaNRT2L12s associating with 1000-grain weight inwheat. Journal of Integrative Agriculture 19:1543-1553.

(12)   Li L, Mao N, Wang J, Chang X, ReynoldsM, Jing R(2019) Genetic dissection of drought and heat-responsive agronomic traits inwheat. 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 studyreveals genomic regions controlling root and shoot traits at late growth stagesin 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-respondinggenes and T alpha PR-1-1 function by screening a cDNA yeast library preparedfollowing 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 proteinkinase 2 (SnRK2) genes are multifaceted players in plant growth, developmentand 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) RINGfinger ubiquitin E3 ligase gene TaSDIR1-4A contributes to determination ofgrain size in common wheat. Journal of Experimental Botany 71:5377-5388.

(17)   Liu D, Li B, Feng G, Mao X, Li A, ChangX, Jing R(2019) TaPP2AbB"-gamma, a wheat regulatory subunit of PP2A enhancedabiotic stress tolerance. Plant Growth Regulation 89:345-355.

(18)   MaoX, 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 inAgricultural Science. pp 113-151. doi:10.19103/as.2016.0004.08

(19)   Rehman SU, Wang J, Chang X, Zhang X, MaoX*, Jing R* (2019) A wheat protein kinasegene TaSnRK2.9-5A associated with yield contributing traits. Theoretical andApplied 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 andplant 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 haplotypesof a protein kinase gene TaSnRK2.3 associated with important agronomic traitsin 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 inPlant Science 8:1557.

(23)   Xu Q, Mao X, Wang Y, Wang J, Xi Y, JingR(2018) A wheat gene TaSAP17-D encoding an AN1/AN1 zinc finger protein improvessalt stress tolerance in transgenic Arabidopsis. Journal of IntegrativeAgriculture 17:507-516.

(24)   Li L, Mao X, Wang J, Chang X, Liu Y,Jing R(2018) Drought tolerance evaluation of wheat germplasm resources. ActaAgronomica Sinica 44:988-999.

(25)   Yue A, Li A, Mao X, Chang X, Li R, JingR(2017) Single-nucleotide polymorphisms, mapping and association analysis of1-FFT-A1 gene in wheat. Journal of Integrative Agriculture 16:789-799.

(26)   Zhang B, Xu W, Liu X, Mao X, Li A, WangJ, Chang X, Zhang X, Jing R (2017) Functional conservation and divergenceamong homoeologs of TaSPL20 and TaSPL21, two SBP-Box genes governing yield-relatedtraits in hexaploid wheat. Plant Physiology 174:1177-1191.

(27)   Zhang H*, Jing R*, Mao X* (2017) Functional characterization of TaSnRK2.8 promoterin 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 FactorGenes TaPARG Have Pleiotropic Functions on Plant Architecture and Yield-RelatedTraits 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 improvesroot system architecture and grain yield in Oryza sativa. Journal ofExperimental 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