博士、研究员、硕士生导师
主要成果:
1.主持国家自然科学基金1项,国际合作基金项目1项,转基因专项子课题2项,基本业务费3项。作为研究骨干,参加国家863、973、转基因专项、国际合作、院协同创新等项目10余项。2017年入选中国农业科学院“科研英才培育工程”院级人选,主持中国农业科学院创新工程的院级人才计划项目。
2.参与创制了容量为10万份水稻T-DNA标签突变体库,成为国际上具有重要影响的水稻功能基因组学研究平台。利用这个平台,发表科研论文30篇以上,其中SCI论文18篇(第一作者或通讯作者14篇),影响因子累积90分以上;获发明专利授权13项; 培养研究生3人,协助指导博士研究生5人。
授权发明专利 :
1一种植物抗逆蛋白MASTER及其编码基因的应用(授权ZL 200810118022.2)
2一种果聚糖酶及其编码基因与应用(授权ZL200910246719.2)
3植物耐旱相关蛋白DSM1及其编码基因和应用(授权ZL201310712134.1)
4来源于苔藓植物的抗旱蛋白PpLEA3-25及其编码基因与应用(授权ZL201410001281.2 )
5植物抗逆性相关蛋白PpLEA3-23及其编码基因与应用(授权ZL 201210499263.2)
6苔藓植物耐逆蛋白PpLEA3-17及其编码基因与应用(授权ZL 201010599624.1)
7植物耐逆性相关蛋白PpLEA3-21及其编码基因与应用(授权ZL 201210499844.6)
8控制水稻花期的蛋白OSEF1及其编码基因与应用(授权ZL 201410645279.9)
9OsGSL5蛋白在控制植物育性中的应用(授权ZL 201410478783)
10植物耐逆性相关蛋白及其编码基因与应用(授权ZL2012101070407)
11一种与植物抗逆性相关蛋白TaWrky48及其编码基因与应用(授权ZL 201510490829.9)
12一种与植物抗逆性相关蛋白Prp1及其编码基因与应用(授权ZL 201510741973.5)
13一种与水稻光合作用相关WSP1蛋白及其相关生物材料与应用(授权ZL 201510741235.0)
社会兼职:
2017年任Frontier in Genetics 编委,教育部学位中心论文评阅人,中国农业科技导报编委。
联系方式:010-82106132,zhangzhiguo@caaas.cn
主要履历及经历:
1999年获安徽农业大学学士学位;
2003年获安徽农业大学硕士学位;
2006年获中国农业科学院生物技术研究所博士学位;
2006年7月至2009年12月,中国农业科学院生物技术研究所,任助理研究员。
2010年1月至2017年12月,中国农业科学院生物技术研究所,任副研究员。
2017年入选中国农业科学院“科研英才培育工程”院级人选。
2018年1月至今,中国农业科学院生物技术研究所,研究员、博士生导师。
研究领域:
主要从事作物高光效的生物学基础解析及高光效核心材料创制。
发表论文:
[1].Qin G, Nguyen HM, Luu SN, Wang Y, Zhang Z*.Construction of introgression lines of Oryza rufipogon and evaluation of important agronomic traits. Theoretical and Applied Genetics. 2019,132(2):543-553.(*Corresponding Author)
[2].Sun J, Luu NS, Chen Z, Chen B, Cui X, Wu J, Zhang Z*, Lu T*. Generation and characterization of a foxtail millet (Setaria italica) mutant library. Frontiers in Plant Science.2019, 10: 369.(*Corresponding Author)
[3].Cui X, Wang Y, Wu J, Han X, Gu X, Lu T*, Zhang Z*. The RNA editing factor DUA1 is crucial to chloroplast development at low temperature in rice. New Phytologist.2019, 221(2): 834-849.(*Corresponding Author)
[4].Cui X*, Zhang Z*, Wang Y, Wu J, Han X, Gu X, Lu T. TWI1 regulates cell-to-cell movement of OSH15 to control leaf cell fate. New Phytologist. 2019, 221(1): 326-340. (*Co-first Author)
[5].Feng D, Wang Y, Lu T, Zhang Z*, Han X*. Proteomics analysis reveals marker proteins for minor vein initiation in rice leaf. Funct Integr Genomics.2018, 18(5): 581-591.(*Corresponding Author)
[6].Feng D, Wang Y, Lu T, Zhang Z*, Han X*. Proteomics analysis reveals a dynamic diurnal pattern of photosynthesis-related pathways in maize leaves. PLoS One. 2017, 12(7): e180670.
[7].Zhang Z, Cui X, Wang Y, Wu J, Gu X, Lu T. The RNA editing factor WSP1 is essential for chloroplast development in rice. Molecular Plant.2017, 10(1): 86-98.
[8].Sun X*, Zhang Z*, Wu J, Cui X, Feng D, Wang K, Xu M, Zhou L, Han X, Gu X, Lu T. The oryza sativa regulator HDR1 associates with the kinase OsK4 to control photoperiodic flowering. PLoS Genetics. 2016, 12(3):e1005927.(*Co-first Author)
[9].Wu J*, Zhang Z*, Zhang Q, Han X, Gu X, Lu T.The molecular cloning and clarification of a photorespiratory mutant, oscdm1, using enhancer trapping. Frontiers in Genetics.2015, 6: 226. (*Co-first Author)
[10].Wu J*, Zhang Z*, Zhang Q, Liu Y, Zhu B, Cao J, Li Z, Han L, Jia J, Zhao G, Sun X.Generation of wheat transcription factor FOX rice lines and systematic screening for salt and osmotic stress tolerance. PLoS One.2015, 10(7): e132314. (*Co-first Author)
[11].Feng D, Wang W, Wu J,Lu T, Zhang Z*. Development and drought tolerance assay of marker-free transgenic rice with OsAPX2 using biolistic particle mediated co-transformation. Crop Journal. 2017, 271-281.( *Corresponding Author)
[12].Zou L*, Zhang Z*, Qi D, Peng M, Lu T. Cytological Mechanisms of Leaf Rolling in Rice.Crop Science. 2014,54 :1-12. (*Co-first Author)
[13].Zhang Z, Zhang Q, Wu J, Zheng X, Zheng S, Sun X, Qiu Q, Lu T. Gene knockout study reveals that cytosolic ascorbate peroxidase 2(OsAPX2) plays a critical role in growth and reproduction in rice under drought, salt and cold stresses. PLoS One.2013, 8(2): e57472.
[14].Wan S*, Wu J*, Zhang Z*, Sun X, Lv Y, Gao C, Ning Y, Ma J, Guo Y, Zhang Q, Zheng X, Zhang C, Ma Z, Lu T.Activation tagging, an efficient tool for functional analysis of the rice genome. Plant Molecular Biology.2009, 69(1-2): 69-80. (*Co-first Author)
[15].Shi X, Sun X, Zhang Z, Feng D, Zhang Q, Han L, Wu J, Lu T. Glucan Synthase-Like 5 (GSL5) plays an essential role in male fertility by regulating callose metabolism during microsporogenesis in rice. Plant and Cell Physiology. 2015, 56(3): 497-509.
[16].Sun L, Zhang Q, Wu J, Zhang L, Jiao X, Zhang S, Zhang Z, Sun D, Lu T, Sun Y. Two rice authentic histidine phosphotransfer proteins, OsAHP1 and OsAHP2, mediate cytokinin signaling and stress responses in rice. Plant Physiology.2014, 165(1): 335-345.
[17].Zou L, Sun X, Zhang Z, Liu P, Wu JX, Tian C, Qiu J, Lu T. Leaf rolling controlled by the homeodomain leucine zipper class IV gene Roc5 in rice. Plant Physiology.2011, 156(3): 1589-1602.
[18].Zhang L, Bai M, Wu J, Zhu J, Wang H, Zhang Z, Wang W, Sun Y, Zhao J, Sun X, Yang H, Xu Y, Kim S, Fujioka S, Lin W, Chong K, Lu T, Wang Z. 2009. Antagonistic HLH/bHLH transcription factors mediate brassinosteroid regulation of cell elongation and plant development in rice and Arabidopsis. Plant Cell.2009, 21(12): 3767-3780.