学术论文
1. Wei X, Liu S, Sun C, Xie G*, Wang L* (2021). Convergence and Divergence: Signal Perception and Transduction Mechanisms of Cold Stress in Arabidopsis and Rice. Plants 10(9):1864. 2. Wei X, Zhou H, Xie D, Li J, Yang M, Chang T, Wang D, Hu L, Xie G, Wang J, Wang L (2021). Genome-Wide Association Study in Rice Revealed a Novel Gene in Determining Plant Height and Stem Development, by Encoding a WRKY Transcription Factor. Int J Mol Sci. 22(15):8192. 3. Yang J, Ji L, Liu S, Jing P, Hu J, Jin D, Wang L*, Xie G* (2021). The CaM1-associated CCaMK-MKK1/6 cascade positively affects the lateral root growth through auxin signaling under salt stress in rice. J Exp Bot. 72(18):6611-6627. 4. Wu F, Luo X, Wang L, Wei Y, Li J, Xie H, Zhang J*, Xie G* (2021). Genome-Wide Association Study Reveals the QTLs for Seed Storability in World Rice Core Collections. Plants. 10(4):812. 5. Muhammad A, Li J, Hu W, Yu J, Khan SU, Khan MHU, Xie G, Wang J, Wang L* (2021). Uncovering genomic regions controlling plant architectural traits in hexaploid wheat using different GWAS models. Sci Rep. 11(1):6767. 6. Jing P, Kong D, Ji L, Kong L, Wang Y, Peng L, Xie G* (2021). OsClo5 functions as a transcriptional co-repressor by interacting with OsDi19-5 to negatively affect salt stress tolerance in rice seedlings. Plant J. 105(3):800-815. 7. Muhammad A, Hu W, Li Z, Li J, Xie G, Wang J, Wang L* (2020). Appraising the Genetic Architecture of Kernel Traits in Hexaploid Wheat Using GWAS. Int J Mol Sci. 21(16):5649. 8. Yang J, Liu S, Ji L, Tang X, Zhu Y, Xie G* (2020). Identification of novel OsCML16 target proteins and differential expression analysis under abiotic stresses in rice. J Plant Physiol. 249:153165. 9. Li J, Li X, Khatab AA, Xie G* (2020). Phylogeny, structural diversity and genome-wide expression analysis of fibrillin family genes in rice. Phytochemistry 175:112377. 10. Zhang R, Hu H, Wang Y, Hu Z, Ren S, Li J, He B, Wang Y, Xia T, Chen P, Xie G, Peng L* (2020). A novel rice fragile culm 24 mutant encodes a UDP-glucose epimerase that affects cell wall properties and photosynthesis. J Exp Bot. 71(10):2956-2969. 11. Meng L, Zhang Q, Yang J, Xie G, Liu JH* (2020). PtrCDPK10 of Poncirus trifoliata functions in dehydration and drought tolerance by reducing ROS accumulation via phosphorylating PtrAPX. Plant Sci. 291:110320. 12. Li J, Yang J, Zhu B, Xie G* (2019). Overexpressing OsFBN1 enhances plastoglobule formation, reduces grain-filling percent and jasmonate levels under heat stress in rice. Plant Sci. 285:230-238. 13. Huang J, Xia T, Li G, Li X, Li Y, Wang Y, Wang Y, Chen Y, Xie G, Bai FW, Peng L*, Wang L* (2019). Overproduction of native endo-β-1, 4-glucanases leads to largely enhanced biomass saccharification and bioethanol production by specific modification of cellulose features in transgenic rice. Biotechnol Biofuels, 12:11 14. Yang J, Ji L, Zhu B, Yuan X, Jin D, Xie G* (2018). OsCML16 interacts with a novel CC-NBS-LRR protein OsPi304 in the Ca2+/Mg2+ dependent and independent manner in rice. Biochem Biophys Res Commun. 504(1): 346-351 15. Li F#, Xie G#, Huang J, Zhang R, Li Y, Zhang M, Wang Y, Li A, Li X, Xia T, Qu C, Hu F, Ragauskas AJ, Peng L* (2017). OsCESA9 conserved-site mutation leads to largely enhanced plant lodging resistance and biomass enzymatic saccharification by reducing cellulose DP and crystallinity in rice. Plant Biotechnol J 15(9):1093-110 16. Zahoor, Sun D, Li Y, Wang J, Tu Y, Wang Y, Hu Z, Zhou S, Wang L, Xie G, Huang J, Alam A, Peng L* (2017). Biomass saccharification is largely enhanced by altering wall polymer features and reducing silicon accumulation in rice cultivars harvested from nitrogen fertilizer supply. Bioresour Technol. 243:957-965 17. Li X, Guo K, Zhu X, Chen P, Li Y, Xie G, Wang L, Wang Y, Persson S, Peng L* (2017). Domestication of rice has reduced the occurrence of transposable elements within gene coding regions. BMC Genomics 18(1):55 18. 今井亮三*,謝国生(2016). MAPKシグナル経路のレドックス制御がイネの低温耐性を高める.化学と生物 54(9): 617-619 19. Zhang M, Wei F, Guo K, Hu Z, Li Y, Xie G, Wang Y, Cai X, Peng L*, Wang L* (2016). A Novel FC116/BC10 Mutation Distinctively Causes Alteration in the Expression of the Genes for Cell Wall Polymer Synthesis in Rice. Front Plant Sci. 7:1366 20. Jing P, Zou J, Kong L, Hu S, Wang B, Yang J, Xie G* (2016). OsCCD1, a novel small calcium-binding protein with one EF-hand motif, positively regulates osmotic and salt tolerance in rice. Plant Science 247:104–114 21. Li F, Zhang M, Guo K, Hu Z, Zhang R, Feng Y, Yi X, Zou W, Wang L, Wu C, Tian J, Lu T, Xie G*, Peng L* (2015). High-level hemicellulosic arabinose predominately affects lignocellulose crystallinity for genetically enhancing both plant lodging resistance and biomass enzymatic digestibility in rice mutants. Plant Biotechnol J 13(4):514-25 22. Guo K, Zou W, Feng Y, Zhang M, Zhang J, Tu F, Xie G, Wang L, Wang Y, Klie S, Persson S, Peng L* (2014). An integrated genomic and metabolomic framework for cell wall biology in rice. BMC Genomics 15:596 23. Xie G*, Sasaki K, Imai R, Xie D (2014). A redox-sensitive cysteine residue regulates the kinase activities of OsMPK3 and OsMPK6 in vitro. Plant science 227:69-75 24. Wu Z, Zhang M, Wang L, Tu Y, Zhang J, Xie G, Zou W, Li F, Guo K, Li Q, Gao C, Peng L* (2013). Biomass digestibility is predominantly affected by three factors of wall polymer features distinctive in wheat accessions and rice mutants. Biotechnol Biofuels 6(1):183 25. Xie G, Yang B, Xu Z, Li F, Guo K, Zhang M, Wang L, Zou W, Wang Y, Peng L* (2013). Global identification of multiple OsGH9 family members and their involvement in cellulose crystallinity modification in rice. PloS one 8(1):e50171 26. Xie G, Kato H, Imai R* (2012). Biochemical identification of the OsMKK6-OsMPK3 signaling pathway for chilling stress tolerance in rice. The Biochemical J 443(1):95-102 27. Xie G, Peng L* (2011). Genetic engineering of energy crops: a strategy for biofuel production in China. Journal of integrative plant biology 53(2):143-150 28. Xie G, Kato H, Sasaki K, Imai R* (2009). A cold-induced thioredoxin h of rice, OsTrx23, negatively regulates kinase activities of OsMPK3 and OsMPK6 in vitro. FEBS letters 583(17): 734-2738 29. 吴方喜,罗曦,魏毅东,郑燕梅,林强,谢国生,谢华安,张建福*(2020).世界水稻核心种质的耐储藏特性鉴定[J].福建稻麦科技,2021,39(01):1-5 30. 武茹,王姣梅,夏胜明,凌霄霞,谢国生*(2020).长江中下游地区杂交中稻再生稻品种适应性的综合评价与筛选. 欧洲杯买球完全官网学报(03):19-27 31. 朱晓博,张贵粉,王友梅,Staffan Persson,谢国生,王令强*(2018).T载体介导的基于attL核心区LR反应的简化快速Gateway克隆系统(英文)[J].中国生物化学与分子生物学报34(03):341-350 32. 吉凌霄,朱伯华,李佳佳,岳安琪,谢国生*(2017).植物载脂蛋白家族结构与功能研究进展[J].植物生理学报53(11):1929-1937 33. 蔡鑫,曹仕明,赵飚,谢德颖,杨俊,谢国生*(2015).不同栽培模式对鄂西南烤烟香型及质量风格的影响因子分析[J].西南农业学报28(03):1317-1321 34. 易晓燕,李丰成,郭凯,张冉,李旭凯,王友梅,彭良才,谢国生*(2015).水稻半纤维素支链合酶基因GT61家族的结构特征和组织表达分析[J].中国农业大学学报20(01):19-28 35. 邹娟子,胡诗琦,王碧莹,景沛,杨俊,谢国生*(2014).植物钙结合蛋白与钙离子结合鉴定技术的研究进展[J]. 植物科学学报06:661-670 36. 曹仕明,蔡鑫,伍义成,曹勤华,谢德颖,张黎明,杨俊,谢国生*(2014).不同栽培模式对恩施山地特色烤烟生长和干物质积累的影响[J].中国农学通报01:185-192 37. 周慧梅,谢德颖,李佳佳,谢国生*(2014).一个特异水稻原纤蛋白FBN11的生物信息学和基因表达特性分析[J]. 植物遗传资源学报03:655-661 38. 周慧梅,谢德颖,邹娟子,李佳佳,谢国生*(2014).植物质体Fibrillin蛋白家族的起源、结构和功能[J]. 中国农业科技导报04:41-49 39. 冯永清,邹维华,李丰成,张晶,张会,谢国生,涂媛苑,路铁刚,彭良才* (2013).特异水稻脆茎突变体生物学特性及生物质降解效率的研究[J].中国农业科技导报03:77-83 40. 张言芳,周慧梅,蔡克桐,朱安婷,谢国生* (2013).无机盐混合试剂与γ-PGA复合处理对早稻苗期耐冷性的引发和分子效应分析[J].农业环境科学学报12:2323-2330 41. 庞贞武,谢国生*,郭税,蔡克桐(2010).铝胁迫下水稻幼苗根尖表面pH和有机酸的动态变化[J]. 中国生态农业学报04:831-835 42. 朱安婷,蒋友武,谢国生,陈守文* (2010).外源聚γ-谷氨酸对水稻幼苗耐旱性和渗透调节的影响[J]. 核农学报06:1269-1273+1279 43. 庞贞武,师瑞红,谢国生*,刘铁梅,柯文峰,蔡明历(2009). 铝、硒、硅和磷复合处理对水稻幼苗生长的影响[J].应用生态学报06:1375-1382 44. 谢国生*,师瑞红,庞贞武,蔡克桐(2009).铝胁迫下水稻幼苗根系的生理特性[J].应用生态学报07:1698-1704
教材与著作 1. Xie G & Peng L*. Chapter 1 Genetic engineering for bioenergy crops towards high biofuel production. Sustainable biomass production. pp.1-16. Taylors & Francis books, Inc.2014,04 2. Xie D & Xie G*. Chapter 11 Cold stress signaling and tolerance in rice. Molecular approaches in plant abiotic stresses. pp.181-192. CRC Press 2013, 12 3. 刘铁梅,谢国生 主编。农业系统分析与模拟。北京:科学出版社,2010, 02 4. 谢国生 参编。第10章 聚γ-PGA疫苗的生物功能与实践。植物免疫与植物疫苗-研究与实践。北京:科学出版社,2008,04 5. 谢国生,李合生 主译。植物逆境生物化学及分子生物学。中国农业出版社,2004,07 6. 谢国生 参编。第3章 作物的遗传改良。农学概论(普通高等教育“十二五”国家级规划教材)。北京:科学出版社,2018,06 |