茶叶所-王新超导师介绍
王新超
研究员
硕,博士生导师
男
茶叶所
茶学
,农艺与种业
茶树种质资源与育种,园艺科学
xcw75@tricaas.com
博士招生专业
1
茶学
2022
1
学术型博士
茶树种质资源和育种
招生信息
1
茶学
2022
1
学术型硕士
茶树种质资源和育种
安徽霍邱人。农学博士,研究员,入选国家、浙江省和中国农科院特殊人才支持计划。
1997年毕业于安徽农业大学农学系,获农学学士学位; 2003年和2011年分别毕业于中国农业科学院研究生院茶学专业,获农学硕士和博士学位。2003年进入中国农业科学院茶叶研究所工作,2015-2016年赴澳大利亚La Trobe University 农业生物中心 Jim Whelan 院士实验室进行访学研究。
现任中国农业科学院茶叶研究所副所长,国家茶树改良中心主任,农业农村部特种经济动植物生物学与遗传育种重点实验室主任,中国农业科学院茶树遗传育种创新团队首席科学家,博(硕)士生导师。
主要研究方向:围绕茶树优特异和抗性品种选育这一主要方向,开展茶树重要性状(抗寒、抗病、芽休眠、花芽分化等)遗传调控机理、茶树功能基因发掘以及茶树分子设计育种技术研究。
先后主持完成国家基金面上项目等省部级以上课题多项,作为主要研究骨干参加过近40个国家级和省部级项目的研究工作。现正主持国家自然科学基金区域创新联合基金重点项目、国家重点研发计划项目子课题、浙江省农业(茶树)新品种选育重大专项、国家茶叶产业技术体系绿茶品种改良岗位等,作为主要研究骨干参与国家自然科学基金多个等项目的研究工作。以第一完成人育成国家登记茶树新品种8个,获得植物新品权3件,主要完成人登记新品种25个,植物品种权3件。获国家发明专利6项,在Nature communications、Plant Physiology、Horticultural Research、中国农业科学等国内外刊物发表科技论文150余篇,其中以第一作者或通讯作者在Nature communications等刊物发表SCI论文50余篇,联合主编英文专著1部,参编著作6部。
担任中国茶叶学会常务理事、中国茶叶学会学术工作委员会主任委员、中国农业科学院茶叶研究所学术委员会委员,广东省茶树资源创新利用重点实验室学术委员会委员和Horticulturae、茶叶科学、中国茶叶、茶叶学报、茶叶、茶叶通讯等期刊编委,Tree Physiology的 Reviewer Board Member。还担任New Phytologist、Plant Journal、Plant Biotechnology Journal、Horticultural Research、JAFC等多家国内外期刊的审稿专家。
获得中国农业科学院科技成果二等奖3项(排名第11、第3、第3)和中国农科院2020年度十大科研进展1项,获第三届中国茶叶学会青年科技奖(2013)、第四届全国优秀茶叶科技工作者(2018)、浙江省“万名好党员” (2016)和多次获得中国农业科学院和茶叶所“优秀共产党员”等荣誉。
实验室已培养出站院优秀博士后3人,在站3人,常年招收博士后人员。
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科研项目
主持在研项目:
1. 国家自然科学基金区域创新联合基金重点项目:浙江绿茶主栽品种响应“倒春寒”的分子调控机制,2023-2026(主持)
2. 国家现代农业产业技术体系:绿茶品种改良岗位,2022-2025(主持)
3. 浙江省农业新品种选育重大科技专项-茶树,2021-2025(主持)
4. 茶树遗传育种创新团队,2021-2025(主持)
5. 全国茶树育种联合攻关项目,2023-2027(主持)
6. 国家重点研发计划课题:茶树优质多抗新种质创制与应用,2024-2027(主持)
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研究成果
近五年主要研究成果:
一、育成品种
1. 中茶601, GPD茶树(2020)330024,第一完成人
2. 中茶602,GPD茶树(2020)330025,第一完成人
3. 中茶603,GPD茶树(2020)330026,第一完成人
4. 中茶604,GPD茶树(2021)330017,第一完成人
5. 中茶606,GPD茶树(2021)330019,第一完成人
6. 中黄4号,GPD茶树(2022)330028,第一完成人
7. 中茶308,GPD茶树(2022)330049,第一完成人
8. 中茶紫芽2号,GPD茶树(2022)330061,第一完成人
9. 中黄1号,GPD茶树(2019)330033,第三完成人
10. 中黄2号,GPD茶树(2019)330034,第三完成人
11. 中茶605,GPD茶树(2021)330018,第二完成人
二、2016年以来发表的代表性论文(#:共同第一作者,*通讯作者)
1. Wang L, Cao H, Chen C, Yue C, Hao X, Yang Y*, Wang X*. Complementary transcriptome andproteome analyses of a chlorophyll-deficient tea plant cultivar revealsmultiple metabolic pathway changes. Journal of Proteomics, 2016, 130: 160-169.
2. Wang L, Wang Y, Cao H, Hao X, Zeng J, Yang Y*, Wang X*. Transcriptome analysis of ananthracnose-resistant tea plant cultivar reveals genes associated withresistance to Colletotrichumcamelliae. PLoSONE, 2016, 11(2): e0148535.
3. Qian W, Yue C, Wang Y, Cao H, Li N, Wang L, Hao X, Wang X*, Xiao B*, Yang Y*. Identification of theinvertase gene family (INVs) in tea plant and their expression analysis underabiotic stress. PlantCell Reports, 2016, 35:2269–2283.
4. Wang Y C, Qian W J, Li N N, Hao X Y, Wang L, XiaoB*, Wang X C*,Yang Y J*. Metabolicchanges of caffeine in teaplant (Camelliasinensis (L.) O.Kuntze) as defense response to Colletotrichum fructicola. Journal ofAgricultural and Food Chemistry, 2016, 64 (35): 6685–6693.
5. Wang Y C, Hao X Y, Wang L, Xiao B, Wang X C*, Yang Y J*. Diverse Colletotrichumspecies cause anthracnose of tea plants (Camellia sinensis (L.) O. Kuntze) inChina. Scientific Reports, 2016, 6:35287.
6. Hao X, Li L, Hu Y, Zhou C, WangX, Wang L, Zeng J, Yang Y. Transcriptomic analysis of the effects of three differentlight treatments on the biosynthesis of characteristic compounds in the teaplant by RNA-Seq. TreeGenetics & Genomes, 2016, 12: 118.
7. Li N, Qian W, Wang L, Cao H, Hao X, Yang Y*, Wang X*. Isolation and expression featuresof hexose kinase genes under various abiotic stresses in the tea plant (Camellia sinensis). Journal of PlantPhysiology, 2017, 209: 95-104.
8. Wang L#, Cao H#, Qian W, Yao L, Hao X, Li N, Yang Y*, Wang X*. Identification of a novel bZIP transcriptionfactor in Camelliasinensis as a negative regulator of freezing tolerance in transgenicArabidopsis. Annalsof Botany, 2017, 119(7): 1195-1209.
9. Hao X, Yang Y, Yue C, Wang L, Horvath D P*, Wang X*. Comprehensive transcriptome analysesreveal differential gene expression profiles of Camellia sinensis axillary budsat para-, endo-, ecodormancy and bud flush stages. Frontiers in Plant Science, 2017, 8:553.
10. Yue C, Cao H, Hao X, Zeng J, Qian W, Guo Y, Ye N, Yang Y*, Wang X*.Differential expression of gibberellin- and abscisic acid-related genes impliestheir roles in the bud activity-dormancy transition of tea plant. Plant CellReports, 2018, 37(3):425-441.
11. Fu J, Wang X,Mao T, Chen H, Chen F, Yang Y. Identification and functional analysis of germin-likeprotein gene family in tea plant (Camelliasinensis).ScientiaHorticulturae, 2018, 234: 166-175.
12. Wang L, Yao L, Hao X, Li N, Qian W, Yue C, Ding C, Zeng J, Yang Y*, Wang X*. Tea plantSWEET transporters: expression profiling, sugar transport, and the involvementof CsSWEET16 in modifying cold tolerance in Arabidopsis. Plant MolecularBiology, 2018, 96(6):577-592
13. Wang Y#, Hao X#, Lu Q, Wang L, Qian W, Li N, DingC, Wang X*, Yang Y*. Transcriptional analysisand histochemistry reveal that hypersensitive cell death and H2O2 have crucialroles in the resistance of tea plant (Camellia sinensis (L.) O.Kuntze) toanthracnose. HorticultureResearch, 2018, 5: 18
14. Hao X, Tang H, Wang B, Yue C, Wang L, Zeng J, Yang Y*, Wang X*. Integrative transcriptional andmetabolic analyses provide insights into cold spell response mechanisms inyoung shoots of the tea plant. Tree Physiology, 2018, 38(11):1655–1671.
15. Li N#, Yue C#, Cao H, Qian W, Hao X, Wang Y, Wang L, Ding C, Wang X*, Yang Y*.Transcriptome sequencing dissection of the mechanisms underlying differentialcold sensitivity in young and mature leaves of the tea plant (Camellia sinensis). Journal of Plant Physiology,2018, 224-225: 144-155
16. Hao X, Wang B, Wang L, Zeng J, Yang Y*, WangX*. Comprehensive transcriptome analysis reveals common and specific geneexpression profile changes in tea plant leaves under cold acclimation and rapidcold stress conditions. ScientiaHorticulturae, 2018, 240: 354-368
17. Ding C, Sophia N, Wang Y, Li N, Wang L, Hao X, Zeng J, Wang X*, Yang Y*. Genome-wide identification andcharacterization of ALTERNATIVE OXIDASE genes and their response under abioticstresses in Camelliasinensis (L.) O. Kuntze. Planta, 2018, 248(5): 1231-1247
18. Hao X*, Zhang W, Zhao F, Liu Y, Qian W, Wang Y, Wang L, Zeng J, Yang Y*, Wang X*.Discovery of plant viruses from tea plant (Camellia sinensis(L.) O. Kuntze) by metagenomicsequencing. Frontiersin Microbiology, 2018, 9:2175
19. QianW, Xaio B, Wang L, Hao X, Yue C, Cao H, Wang Y, Li N, Yu Y, Zeng J, Yang Y*, Wang X*. CsINV5, atea vacuolar invertase gene enhances cold tolerance in transgenic Arabidopsis. BMC Plant Biology,2018, 18: 228
20. Lu Q, Wang Y, Li N, Ni D*, Yang Y *, Wang X*. Differences in the characteristics andpathogenicity of Colletotrichumcamelliae and C.fructicola isolated from the tea plant (Camellia sinensis (L.) O. Kuntze). Frontiers inMicrobiology, 2018, 9:3060
21. Wang L, Yao L, Hao X, Li N, Wang Y, Ding C, Lei L, Qian W, Zeng J, Yang Y*, Wang X*.Transcriptional and physiological analyses reveal the association of ROSmetabolism with cold tolerance in tea plant. Environmental and Experimental Botany, 2019, 160:45-58
22. Hao X, Tang H, Wang B, Wang L, Cao H, Wang Y, Zeng J, Fang S, Chu J, Yang Y*, Wang X*. Gene characterizationand expression analysis reveal the importance of auxin signaling in buddormancy regulation in tea plant. Journal of Plant Growth Regulation,2019, 38:225-240
23. Yue C, Cao H, Lin H, Hu J, Ye Y, Li J, Hao Z, Hao X, Sun Y, Yang Y*, Wang X*.Expression patterns of alpha‑amylase and beta‑amylase genes provide insightsinto the molecular mechanisms underlying the responses of tea plants (Camellia sinensis)to stress and postharvest processing treatments. Planta, 2019, 250:281-298
24. Ding C, Lei L, Yao L, Wang L, Hao X, Li N, Wang Y, Yin P, Guo G*, Yang Y*, Wang X*.The involvements of calcium-dependent protein kinases and catechins in teaplant [Camelliasinensis (L.) O. Kuntze] cold responses. Plant Physiology and Biochemistry, 2019, 143:190-202
25. Fu J, Liu G, Yang M, WangX, Chen X, Chen F, Yang Y. Isolation and functional analysis of squalenesynthase gene in tea plant Camelliasinensis. PlantPhysiology and Biochemistry, 2019, 142: 53-58
26. Li N N, Lu J L, Li Q S, Zheng X Q, Wang X C, Wang L, Wang Y C, Ding C Q, Liang YR*, Yang Y J*. Dissection of chemical composition and associated geneexpression in the pigment- deficient tea cultivar ‘Xiaoxueya’ reveals an albinophenotype and metabolite formation. Frontiers in Plant Science, 2019, 10:1543.
27. Wang Y, Xiong F, Lu Q, Hao X, Zheng M, Wang L, Li N, Ding C, Wang X*, Yang Y*.Diversity of Pestalotiopsis-likespecies causing gray blight disease of tea plants (Camellia sinensis) in China, including two novel Pestalotiopsis species,and analysis of their pathogenicity. Plant Disease, 2019, 103(10):2548-2558
28. Hao X, Zhang W, Liu Y, Zhang H, Ren H, Chen Y, Wang L, Zeng J, Yang Y*, Wang X*. Palegreen mutant analyses reveal the importance of CsGLKs in chloroplastdevelopmental regulation and their effects on flavonoid biosynthesis in teaplant. PlantPhysiology and Biochemistry, 2020, 146: 392-402.
29. Wang Y#, Lu Q#, Xiong F, Hao X, Wang L, Zheng M, Li N, Ding C, Wang X*, Yang Y*.Genome-wide identification, characterization, and expression analysis ofnucleotide-binding leucine-rich repeats gene family under environmental stressesin tea (Camelliasinensis). Genomics,2020, 112: 1351-1362
30. Liu Y#, Hao X#, Lu Q, Zhang W, Zhang H, Wang L, Yang Y*, Xiao B*, Wang X*.Genome-wide identification and expression analysis of flowering-related genesreveal putative floral induction and differentiation mechanisms in tea plant (Camellia sinensis). Genomics, 2020,112: 2318-2326
31. Yao L, Hao X, Cao H, Ding C, Yang Y*, Wang L*, Wang X. ABA‑dependent bZIP transcription factor,CsbZIP18, from Camellia sinensis negatively regulates freezing toleranceinArabidopsis. PlantCell Reports, 2020: 39:553-565
32. XiongF#, Wang Y#, Lu Q, Hao X, Fang W, Yang Y, Zhu X*, Wang X*. Lifestyle characteristics andgeneexpression analysis of Colletotrichum camelliae isolated from tea plant [Camelliasinensis (L.)O. Kuntze] based on transcriptome. Biomolecules, 2020, 10:782
33. WangL, Feng X, Yao L, Ding C, Lei L, Hao X, Li N, Zeng J, Yang Y*, Wang X*.Characterization of CBL–CIPK signaling complexes and their involvement in coldresponse in tea plant. PlantPhysiology and Biochemistry, 2020, 154: 195-203.
34. YaoL, Ding C, Hao X, Zeng J, Yang Y, Wang X*, Wang L*. CsSWEET1a and CsSWEET17mediate growth and freezing tolerance by promoting sugar transport across theplasma membrane. Plant and Cell Physiology, 2020, 61(9):1669-1682.
35. Lu,Q, Wang, Y, Xiong, F, Hao X, Zhang X, Li N, Wang L, Zeng J, Yang Y*,Wang X*.Integrated transcriptomic and metabolomic analyses reveal the effects ofcallose deposition and multihormone signal transduction pathways on the tea plant-Colletotrichumcamelliae interaction. Sci Rep, 2020 10:12858
36. Wang X#, Feng H#,Chang Y#, MaC#, Wang L#, Hao X#, Li A, Cheng H, Wang L,Cui P, Jin J, Wang X,Wei K, Ai C, Zhao S, Wu Z, Li Y, Liu B, Wang G D*, Chen L*, Ruan J*, Yang Y*.Population sequencing enhances understanding of tea plant evolution. Nature Communications,2020, 11:4447
37. YiChangyu, WangXinchao, Chen Qian, Callahan Daminen L, Fournier-Level Alexandre, WhelanJames, Jost Ricarda. Diverse phosphate and auxin transport loci distinguishphosphate tolerant from sensitive Arabidopsis accessions. Plant Physiology, 2021, 187(4):2656–2673
38. ChenYao, Li Yuteng, Ren Hengze, Zhou Jianrong, Wang Lu, Yang Yajun*, Hao Xinyuan*, Wang Xinchao. Genome-wideidentification and expression profiling reveal the diverse role of Methyl-CpG-bindingdomain proteins in tea plant Camelliasinensis. BeveragePlant Research 2021, 1: 10
39. WangHuan, Ding Zhaotang, Gou Mengjie, Hu Jianhui, Wang Yu, Wang Lu, WangYuchun, DiTaimei, Zhang Xinfu, Hao Xinyuan, Wang Xinchao, Yang Yajun, Qian Wenjun*.Genome-wide identification, characterization, and expression analysis of teaplant autophagy-related genes(CsARGs)demonstrates that they play diverse roles during development and under abioticstress. BMCGenomics, 22:121
40. Wei Kang, Wang Xinchao, HaoXinyuan, QianYinhong, Li Xin, Xu Liyi, Ruan Li, Wang Yongxin, Zhang Yazhen, BaiPeixian, LiQiang, Aktar Shirin, Hu Xili, Zheng Guoyang, Wang Liubin, LiuBenying, HeWeizhong *, Cheng Hao *, Wang Liyuan *. Development of a genome-wide200K SNP array and its application for high-density genetic mapping and originanalysis of Camellia sinensis. Plant Biotechnology Journal, 2022, 20: 414–416(共同第一作者)
41. CaoQinghai, Lv Wuyun, Jiang Hong, Chen Xueling, Wang Xinchao*, Wang Yuchun*. Genome-wideidentification of glutathioneS-transferase gene family members in tea plant (Camellia sinensis)and their response to environmental stress. International Journal of Biological Macromolecules,2022, 205: 749-760
42. Peng J, LiN, Ding C, Li X, Wu Y, Hao X, Wang Y, Yang Y, Wang X*, WangL*. The interaction of CsWRKY4 andCsOCP3 with CsICE1 regulates CsCBF1/3 and mediates stress response in tea plant(Camelliasinensis). Environmental andExperimental Botany, 2022, 200: 104892
43. Wang Lu, DiTaimei, Peng Jing, Li Yuteng, LiNana, Hao Xinyuan, Ding Changqing, Huang Jianyan, Zeng Jianming, Yang Yajun*, Wang Xinchao*.Comparative metabolomic analysis reveals the involvement of catechins inadaptation mechanism to cold stress in tea plant (Camellia sinensis var.sinensis). Environmentaland Experimental Botany, 2022, 201: 104978
44. He Shan, LiBo, Wang Huan, Liang Shicai, Ding Zhaotang, Wang Yu, Fan Kai, Hu Jianhui, WangXinchao*, Qian Wenjun*. Characterization of invertase inhibitors (InvInhs) intea plant, and their potential roles in participating in growth, developmentand cold response. ScientiaHorticulturae, 2023, 308: 111580
45. Liu Y.,Dreni L., Zhang H., Zhang X., Li N., Zhang K., Di T., Wang L., Yang Y., Hao X.,Wang X*. A tea plant (Camelliasinensis) FLOWERING LOCUS C-like gene, CsFLC1, is correlated to bud dormancy andtriggers early flowering in Arabidopsis.Int. J. Mol. Sci. 2022, 23:15711.
46. Jiang Hong,Cao Qinghai, Wang Xinchao*, Lv Wuyun*, Wang Yuchun*. Pectate lyase genesabundantly expressed during the infection regulate morphological development of Colletotrichum camelliae andCcPEL16 is required for full virulence to tea plants. Msphere,2023,8(1): 10.1128/msphere.00677-22.
47. Ding, Y.;Huang, H.; Cui, H.; Wang, X*.; Zhao, Y*. A non-destructive method foridentification of tea plant cultivars based on deep learning. Forests,2023, 14: 728
48. Di, T.; Wu,Y.; Peng, J.; Wang, J.; Wang, H.;He, M.; Li, N.; Hao, X.; Yang, Y.; Ni, D.; Wang,L., Wang, X. CsCIPK11-regulated metalloprotease CsFtsH5 mediates the coldresponse of tea plants. Int.J. Mol.Sci. 2023, 24, 6288.
49. Huang Jianyan *, Zhao Xiaobo, Bürger Marco,Chory Joanne, Wang Xinchao*. The role ofethylene in plant temperature stress response. Trends in Plant Science, 2023,28(7):808-824.
50. Chen Yao,Tang Junwei, Ren Hengze, Li Yuteng, LiCongcong, Wang Haoqian, Wang Lu, YangYajun, Wang Xinchao, Hao Xinyuan*. Exogenous activation of the ethylenesignaling pathway enhances the freezing tolerance of young tea shoots byregulating the plant’s antioxidant system. Horticulturae 2023, 9,875.
51. Ding Changqing, Hao Xinyuan, Wang Lu, Li Nana,Huang Jianyan, Zeng Jianming, YangYajun*, Xinchao Wang*. iTRAQ-based quantitative proteomic analysis of tea plant(Camellia sinensis (L.) O. Kuntze) during cold acclimation and de-acclimationprocedures. BeveragePlant Research,2023, 3:16.
52. Lv W, Xu Y,Jiang H, Cao Q, Wang X*, Wang Y*. An NBS-LRR-encoding gene CsRPM1 confersresistance to the fungus Colletotrichum camelliae in tea plant. Beverage PlantResearch, 2023, 3:13.
53. Zhang Kexin, Feng Xia, Liu Ying, Yang Yajun, Hao Xinyuan, Li Dongliang, Wang Xinchao*,Wang Lu*. Integrative transcriptome and whole-genome bisulfitesequencing analyses of a temperature-sensitive albino tea plant cultivar. Physiologia Plantarum,2023,175(6):e14064
54. Lu Lu, Wang Lu, Liu Ru-Yi, Zhang Ying-Bin, Zheng Xin-Qiang, Lu Jian-Liang, Wang Xin-Chao *,Ye Jian-Hui *. An efficient artificial intelligence algorithm for predictingthe sensory quality of green and black teas based on the key chemical indices. Food Chemistry,2024,441:138341
55. Lv Wuyun,Cao Qinghai, Jiang Hong, Ren Henze, Wang Xinchao*, Wang Yuchun*. A tauclass glutathione S-transferase in tea plant, CsGSTU45, facilitates tea plantsusceptibility to Colletotrichum camelliae infection mediated by jasmonatesignaling pathway. Plant J,2024,117(5):1356-1376
56. Di Taimei, Wu Yedie, Feng Xia, He Mingming, Lei Lei, Wang Jie, Li Nana, Hao Xinyuan, James Whelan, Wang Xinchao*, Wang Lu*. CIPK11 phosphorylates GSTU23 to promote cold tolerance in Camellia sinensis. Plant, Cell & Environment,2024,47(12):4786-4799
57. Wang Lu, DiTaimei, LiNana, Peng Jing, Wu Yedie, He Mingming, Hao Xinyuan, Huang Jianyan,Ding Changqing, Yang Yajun, WangXinchao* Transcriptomicanalysis of hub genes regulating albinism in light- and temperature-sensitivealbino tea cultivars‘Zhonghuang 1’ and ‘Zhonghuang 2’. Plant Molecular Biology,2024,114:44
58. Ding Kai, Lv Wuyun, Ren Henze, Xiong Fei, Zhang Yuting,Zhang Junhong, Tong ZaiKang*, Wang Xinchao*, Wang Yuchun*.Small world but bigdifference: Phyllosphere fungal composition, function, assembly and networkdriven by secondary metabolites in tea plant (Camellia sinensis). Plant and Soil,2024,502:725-743
59. Wang Yanli,Tong Wei, Li Fangdong, SamarinaLidia, Li Penghui, Yang Tianyuan, ZhangZhaoliang, Yi Lianghui, Zhai Fei, WangXinchao*, Xia Enhua*. LUX ARRHYTHMO links CBF pathway and jasmonic acid metabolism to regulate cold tolerance of tea plants. Plant Physiology,2024, 196(2):961-978
60. Zheng Qinghua, Guo Lina, Huang Jianyan, Hao Xinyuan, LiXiaoman, Li Na-na, Wang Yueqi, Zhang Kexin, Wang Xinchao, Wang Lu*, Zeng Jianming*. Comparative transcriptomicsprovides novel insights into the mechanisms of selenium accumulation andtransportation in tea cultivars (Camellia sinensis (L.) O. Kuntze). Frontiersin Plant Science, 2023,14:1268537.
61. Tang Junwei, Chen Yao, Huang Chao, Li Congcong,Feng Yue, Wang Haoqian, Ding Changqing, Li Na-na, Wang Lu, Zeng Jianming, YangYajun, Hao Xinyuan*, Xinchao Wang.Uncovering the complex regulatory network of spring bud sprouting in teaplants: insights from metabolic, hormonal, and oxidative stress pathways.Frontiers in Plant Science, 2023, 14:1263606.
62. Wu Yedie,Di Taimei, Wu Zhijing, Peng Jing, Wang Jie, Zhang Kexin, He Mingming, Li Nana,Hao Xinyuan, Fang Wanping, Wang Xinchao,Wang Lu*. CsLHY positively regulates cold tolerance by activating CsSWEET17 intea plants. Plant Physiology and Biochemistry,2024,207:108341
63. Zhang Yongheng; Wang Jie; Xiao Yezi; Wu Yedie; Li Nana; Ding Changqing; Hao Xinyuan; Yu Youben; Wang Lu; Wang, Xinchao. CsWRKY12 interacts with CsVQ4L to promote the accumulation of galloylated catechins in tender leaves of tea plants. Plant Journal,2024, 120(6): 2861-2873
64. Ye Lili, Xue Huaqian, Li Nana, Ye Meng, Huang Jianyan, Wang Xinchao, Wu Juan*, Ding Changqing*. Genome-wide identification and expression analysis of pseudo-response regulators (PRRs) in the tea plant Camellia sinensis (L.) O. Kuntze. Horticulturae,2024,10(12):1294
65. Tu Yiyi, Wang Yuchun, Jiang Hong, Ren Hengze, Wang Xinchao*, Lv Wuyun*. A loop-mediated isothermal amplification assay for the rapid detection of Didymella segeticola causing tea leaf spot. Journal of Fungi, 2024, 10(7): 467
66. Li Nana, He Weizhong, Ye Yufan, He Mingming, Di Taimei, Hao Xinyuan, Ding Changqing, YangYajun, Wang Lu *, WangXinchao *. Integrated metabolomics and proteomics analyses reveal theregulatory mechanism underlying the yellow leaf phenotype of the tea plantcultivar ‘Zhonghuang 2’. Horticultural Plant Journal, 2025,11(1):417-430
67. Hao Xinyuan#, Tang Junwei#, Chen Yao#, Huang Chao, Zhang Weifu, Liu Ying, Yue Chuan, Wang Lu, Ding Changqing, Dai Wenhao, Yang Yajun, Horvath David*, Wang Xinchao*. CsCBF1/CsZHD9-CsMADS27, a critical gene module controlling dormancy and bud break in tea plants. Plant Journal,2025, 121(1): e17165
68. Di Taimei, Wu Yedie, Wang Jie, He Mingming, Huang Jianyan, Li Nana, Hao Xinyuan, Ding Changqing, Zeng Jianming, Yang Yajun, Wang Xinchao *, Wang Lu *. CsCIPK20 improves tea plant cold tolerance by modulating AsA synthesis through attenuation of CsCSN5-CsVTC1 interaction. Plant, Cell & Environment,2025, 48:3337-3351
69. Wang Yujie; Zheng Yiqian; Wang Lu; Ye Yufan; Shen Xinbo; Hao Xinyuan; Ding Changqing; Yang Yajun; Wang Xinchao, Li Nana*. Hexokinase gene CsHXK4 positively regulates cold resistance in tea plants (Camellia sinensis). Plant Physiology and Biochemistry, 2025,221:109603
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71. Zhu Jinping, Li Xiaoman, Huang Jianyan, Wang Lu, Zheng Qinghua, Li Hanjia, Chen Yao, Tang Junwei, Hao Xinyuan, Wang Xinchao, Huang Youyi*, Zeng Jianming*. Transcriptomics and plant hormone analysis reveal the mechanism of branching angle formation in tea plants (Camellia Sinensis). International Journal of Molecular Sciences,2025,26: 604
72. Shan Ruiyang, Zhang Yongheng, You Xiaomei, Kong Xiangrui, Zhang Yazhen, Li Xinlei, Wang Lu, Wang Xinchao*, Chen Changsong*. Revealing the molecular regulatory mechanism of flavonoid accumulation in tender leaves of tea plants by transcriptomic and metabolomic analyses. Plants, 2025, 14: 625
74. Zhang Yongheng, Shan Ruiyang, Ding Changqing, You Xiaomei, Zheng Shiqin, Chen Zhihui, Li Xinlei, Kong Xiangrui, Zhang Yazhen, Lin Zhenghe, Wang Xinchao *, Chen Changsong *. Identification of key aroma components responsive for jasmine-like aroma in ‘Chungui’ cultivar oolong tea processing. Industrial Crops & Products, 2025, 233:121376
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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:10000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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