职    称

 教授

科研方向

 作物真菌病害与绿色防控

招生专业

 硕士、博士

联系方式

 15610306236；haitao.cui@hotmail.com

个人简介

 崔海涛，男，汉族，山东省菏泽市鄄城人，中共党员，遗传学博士，“闽江学者”。中国植物病理学会理事，中国热带作物学会青年工作委员会委员。2010年10月到2016年12月，德国马普植物育种研究所博士后。2017年2月至2023年8月，福建农林大学海峡联合研究院植物免疫中心副主任，作物遗传育种与综合利用教育部重点实验室副主任。近年来，主持国家自然科学基金面上项目2项，主持福建省自然基金重点项目等省部级项目4项。发表以《Molecular Plant》为代表的科技论文20余篇。

教学背景及工作经历

2023.09-至      今：港澳台论坛\教授

2017.02-2023.08：福建农林大学农学院\教授

2010.10-2016.12：德国马普植物育种研究所\博士后

2009.07-2010.09：北京生命科学研究所\助理研究员

2005.09-2009.06：中科院遗传与发育生物学研究所\博士

2002.09-2005.07：港澳台论坛\硕士

1998.09-2002.07：港澳台论坛\学生

教学工作

 主要承担本科生《农业植物病理学》，硕士研究生《高级实验设计与生物统计》，博士研究生《植物分子病原学及生态管理》等课程的教学。指导硕士、博士研究生获得国家奖学金、省级优秀学位论文等奖励。

研究方向

1.小麦真菌病害致病机制与绿色防控；

2.水稻抗病机制；

3.镰刀真菌致病机制。

科研项目

1.港澳台论坛人才引进启动经费，2023.09-2028.08，150万元，主持；

2.核糖体蛋白介导的翻译调控在水稻免疫中的功能和机理研究，福建省自然基金重点项目，2023J02011，福建省科技厅，30万元，2023.8-2026.8，主持；

3.国家自然科学基金委员会，面上项目，31970281，2020-2023，58万元，主持；

4.国家自然科学基金委员会，面上项目，31770277，2018-2021，60万元，主持；

5.福建省闽江学者奖励计划，2018-2022，200万元，主持；

6.中央引导地方科技发展资金专项（广西），2021ZYZX1037，2022-2024，50万元，合作方负责人。

代表性科研成果

1. Zeng, Y., Zheng, Z., Hessler, G., Zou, K., Leng, J., Bautor, J., Stuttmann, J., Xue, L., Parker, J.E., and Cui, H. (2024). Arabidopsis PHYTOALEXIN DEFICIENT 4 promotes the maturation and nuclear accumulation of immune-related cysteine protease RD19. J Exp Bot 75, 1530-1546. 10.1093/jxb/erad454.

2. Zhong, Z., Zhong, L., Zhu, X., Jiang, Y., Zheng, Y., Lan, T., and Cui, H. (2023). Transcription factor OsSPL10 interacts with OsJAmyb to regulate blast resistance in rice. The Crop Journal. 10.1016/j.cj.2023.10.015

3. Yu, D., Dong, X., Zou, K., Jiang, X.D., Sun, Y.B., Min, Z., Zhang, L.P., Cui, H., and Hu, J.Y. (2023). A hidden mutation in the seventh WD40-repeat of COP1 determines the early flowering trait in a set of Arabidopsis myc mutants. The Plant cell 35, 345-350. 10.1093/plcell/koac319. (共同通讯)

4. Zhao, C., Li, S., Du, C., Gao, H., Yang, D., Fu, G., and Cui, H. (2022). Establishment of a Protoplasts-Based Transient Expression System in Banana (Musa spp.). Agronomy 12, 2648.

5. Parker, J.E., Hessler, G., and Cui, H. (2022). A new biochemistry connecting pathogen detection to induced defense in plants. New Phytol 234, 819-826.

6. Ling, H., Fu, X., Huang, N., Zhong, Z., Su, W., Lin, W., Cui, H., and Que, Y. (2022). A sugarcane smut fungus effector simulates the host endogenous elicitor peptide to suppress plant immunity. New Phytol 233, 919-933. (共同通讯)

7. Yang, D., Li, S., Xiao, Y., Lu, L., Zheng, Z., Tang, D., and Cui, H. (2021). Transcriptome analysis of rice response to blast fungus identified core genes involved in immunity. Plant Cell Environ 44, 3103-3121.

8. Zhao, C., Tang, Y., Wang, J., Zeng, Y., Sun, H., Zheng, Z., Su, R., Schneeberger, K., Parker, J.E., and Cui, H. (2021). A mis-regulated cyclic nucleotide-gated channel mediates cytosolic calcium elevation and activates immunity in Arabidopsis. New Phytol 230, 1078-1094.

9. Leng, J., Tu, W., Hou, Y., and Cui, H. (2021). Temperature-Inducible Transgenic EDS1 and PAD4 in Arabidopsis Confer an Enhanced Disease Resistance at Elevated Temperature. Plants 10, 1258.

10. Cui, H., J. Qiu, Y. Zhou, D. D. Bhandari, C. Zhao, J. Bautor and J. E. Parker (2018). Antagonism of Transcription Factor MYC2 by EDS1/PAD4 Complexes Bolsters Salicylic Acid Defense in Arabidopsis Effector-Triggered Immunity. Mol Plant 11(8): 1053-1066.

11. Cui, H., Gobbato, E., Kracher, B., Qiu, J., Bautor, J., and Parker, J.E. (2017). A core function of EDS1 with PAD4 is to protect the salicylic acid defense sector in Arabidopsis immunity. New Phytol 213, 1802-1817.

12. Cui, H., Tsuda, K., and Parker, J.E. (2015). Effector-triggered immunity: from pathogen perception to robust defense. Annual review of plant biology 66, 487-511.

13. Cui, H., Y. Wang, L. Xue, J. Chu, C. Yan, J. Fu, M. Chen, R. W. Innes and J. M. Zhou (2010). Pseudomonas syringae effector protein AvrB perturbs Arabidopsis hormone signaling by activating MAP kinase 4. Cell Host Microbe 7(2): 164-175.

14. Zhang, J., H. Lu, X. Li, Y. Li, H. Cui, C. K. Wen, X. Tang, Z. Su and J. M. Zhou (2010). Effector-triggered and pathogen-associated molecular pattern-triggered immunity differentially contribute to basal resistance to Pseudomonas syringae. Mol Plant Microbe Interact 23(7): 940-948.

15. Cui, H., T. Xiang and J. M. Zhou (2009). Plant immunity: a lesson from pathogenic bacterial effector proteins. Cell Microbiol 11(10): 1453-1461.

16. Shang, Y., X. Li, H. Cui, P. He, R. Thilmony, S. Chintamanani, J. Zwiesler-Vollick, S. Gopalan, X. Tang and J. M. Zhou (2006). RAR1, a central player in plant immunity, is targeted by Pseudomonas syringae effector AvrB. Proc Natl Acad Sci U S A 103(50): 19200-19205.

17. Chen, H., L. Xue, S. Chintamanani, H. Germain, H. Lin, H. Cui, R. Cai, J. Zuo, X. Tang, X. Li, H. Guo and J. M. Zhou (2009). ETHYLENE INSENSITIVE3 and ETHYLENE INSENSITIVE3-LIKE1 repress SALICYLIC ACID INDUCTION DEFICIENT2 expression to negatively regulate plant innate immunity in Arabidopsis. Plant Cell 21(8): 2527-2540.

18. Zhang, J., F. Shao, Y. Li, H. Cui, L. Chen, H. Li, Y. Zou, C. Long, L. Lan, J. Chai, S. Chen, X. Tang and J. M. Zhou (2007). A Pseudomonas syringae effector inactivates MAPKs to suppress PAMP-induced immunity in plants. Cell Host Microbe 1(3): 175-185.

19. Zhuo, T., Wang, X., Chen, Z., Cui, H., Zeng, Y., Chen, Y., Fan, X., Hu, X., and Zou, H. (2020). The Ralstonia solanacearum effector RipI induces a defence reaction by interacting with the bHLH93 transcription factor in Nicotiana benthamiana. Mol Plant Pathol 21, 999-1004.

20. Zhou, Y., Tergemina, E., Cui, H., Forderer, A., Hartwig, B., Velikkakam James, G., Schneeberger, K., and Turck, F. (2017). Ctf4-related protein recruits LHP1-PRC2 to maintain H3K27me3 levels in dividing cells in Arabidopsis thaliana. Proc Natl Acad Sci U S A 114, 4833-4838.

21. Mei, S., Hou, S., Cui, H., Feng, F., and Rong, W. (2016). Characterization of the interaction between Oidium heveae and Arabidopsis thaliana. Mol Plant Pathol 17, 1331-1343.

22. Xue, L., H, Cui., B. Buer, V. Vijayakumar, P. M. Delaux, S. Junkermann and M. Bucher (2015). Network of GRAS Transcription Factors Involved in the Control of Arbuscule Development in Lotus japonicus. Plant Physiol 167(3): 854-871.