王成树----中国科学院分子植物科学卓越创新中心/中国科学院上海植物生理生态研究所

个人信息

博士生导师
研究员
2012年获得“国家杰出青年基金”
Email: wangcs@cemps.ac.cn
个人网页: http://sippe.ac.cn/wangcs/

研究方向

昆虫分子病理及真菌分子生物学

研究单元

中国科学院昆虫发育与进化生物学重点实验室

王成树

个人简介

1989.9–1993.7 安徽农业大学植保系, 学士；
1993.9–1996.7 安徽农业大学林学系, 硕士；
1998.9–2001.7 中国农业大学微生物系, 博士；
1999.8–2000.9 英国University of Wales Swansea，访问学者；
2001.7-2003.12 英国University of Wales Swansea，博士后研究；
2004.1-2006.8 美国University of Maryland，博士后研究；
2006.9- 应聘为中国科学院上海植物生理生态研究所课题组长，研究员

研究工作

以真菌—昆虫互作为模型，研究：
1. 昆虫病理真菌的基因组进化学与种群遗传学；
2. 真菌—昆虫互作的蛋白效应机制；
3. 真菌—昆虫互作的化学生物学；
4. 真菌分子遗传与菌种退化的分子机理。

主要成果

1. 昆虫真菌基因组进化研究：揭示了昆虫真菌致病性进化的多起源性及协同进化特征，阐明了寄主不同的绿僵菌由专性菌经中间过渡物种向广谱菌方向进化的现象；
2. 真菌—昆虫互作的化学生物学研究：揭示了绿僵菌合成破坏素、白僵菌合成卵胞霉素的分子机理及其对于真菌杀虫毒力贡献的分子机理；首次发现蛹虫草能够合成喷司他丁，并由同一基因簇介导的虫草素与喷司他丁伴随生物合成机理；
3. 昆虫真菌致病机理研究：揭示了白僵菌或绿僵菌中LysM效应蛋白、细胞自噬相关基因、磷脂代谢及不同转录因子对于昆虫真菌细胞分化及致病毒力影响的分子机理等。

发表论文
相关新闻

1. Shang JM, Tang GR, Yang J, Lu MT, Wang C-Z, and Wang CS* (2023). Sensing of a spore surface protein by a Drosophila chemosensory protein induces behavioral defense against fungal parasitic infections. Current Biology 33(2): 276-286.

2. Hong S, Sun YL, Chen HM, Wang CS*. 2023. Suppression of the insect cuticular microbiomes by a fungal defensin to facilitate parasite infection. ISME Journal, 17(1): 1-11.

3. Sun YL#, Chen B#, Li XL, Yin Y, Wang CS*. 2022. Orchestrated biosynthesis of the secondary metabolite cocktails enables the producing fungus to combat diverse bacteria. mBio,13(5): e0180022.

4. Luo FF#, Tang GR#, Hong S, Gong T, Xin X-F, Wang CS.* 2022. Promotion of Arabidopsis immune responses by a rhizosphere fungus via supply of pipecolic acid to plants and selective augment of phytoalexins. Science China Life Sciences, 10.1007/s11427-022-2238-8

5. Sun YL, Hong S, Chen HM, Yin Y, Wang CS*. 2022. Production of helvolic acid in Metarhizium contributes to fungal infection of insects by bacteriostatic inhibition of the host cuticular microbiomes. Microbiology Spectrum, 10(5), e0262022.

6. Hong S, Sun Y, Sun D, Wang CS*. 2022. Microbiome assembly on Drosophila body surfaces benefits the flies to combat fungal infections. iScience, 25(6): 104408.

7. Li B, Song SX, Wei XF, Tang GR, Wang CS*. 2022. Activation of microlipophagy during early infection of insect hosts by Metarhizium robertsii. Autophagy, 18(3): 608-623.

8. Chen B#, Sun YL#, Li, SQ, Yin Y, and Wang, CS*. 2021. Inductive production of the iron-chelating 2-pyridones benefits the producing fungus to compete for diverse niches. mBio 12(6): e0327921.

9. Mei LJ#, Wang XW#, Yin Y, Tang GR, Wang CS*. 2021. Conservative production of galactosaminogalactan in Metarhizium is responsible for appressorium mucilage production and topical infection of insect hosts. PLoS Pathogens, 17(6): e1009656. [Cover story]

10. Shang JM#, Shang YF#, Tang GR, Wang CS*. 2021. Identification of a key G-protein coupled receptor in mediating appressorium formation and fungal virulence against insects. Science China Life Science, 64 (3): 466-477.

11. Mei LJ, Chen MJ, Shang YF, Tang GR, Tao Y, Zeng L, Huang B, Li ZZ, Zhan S*, Wang CS*. 2020. Population genomics and evolution of a fungal pathogen after releasing exotic strains to control insect pests for 20 years. ISME J, 14(6): 1422-1434.

12. Luo FF, Hong S, Chen B, Yin Y, Tang GR, Hu FL, Zhang HZ, Wang CS*. 2020. Unveiling of swainsonine biosynthesis via a multi-branched pathway in fungi. ACS Chemical Biology, 15(9): 2476-2484.

13. Yin Y, Chen B, Song SX, Li B, Yang XQ, Wang CS*. 2020. Production of diverse beauveriolide analogs in closely related fungi: a rare case of fungal chemodiversity. mSphere, 5(5):e00667-20.

14. Huang A, Lu M, Ling E, Li P*, Wang CS*. 2020. A M35 family metalloprotease is required for fungal virulence against insects by inactivating host prophenoloxidases and beyond. Virulence, 11:222-237.

15. Huang W, Hong S, Tang GR, Lu YZ, Wang CS*. 2019. Unveiling the function and regulation control of the DUF3129 family proteins in fungal infection of hosts. Philosophical Transactions of the Royal Society B: Biological Sciences, 374(1767): 20180321. Yang XQ, Feng P, Yin Y, Bushley K, Spatafora JW, Wang CS*. 2018. Cyclosporine biosynthesis in Tolypocladium inflatum benefits fungal adaptation to the environment. mBio, 9(5):e01211-18.

16. Wang CS*, Wang SB. 2017. Insect pathogenic fungi: genomics, molecular interactions, and genetic improvements. Annual Review of Entomology, 62: 73-90.

17. Xia YL, Luo FF, Shang YF, Chen PL, Lu YZ, Wang CS*. 2017. Fungal cordycepin biosynthesis is coupled with the production of the safeguard molecule pentostatin. Cell Chemical Biology, 24: 1479-1489.

18. Cen K, Li B, Lu YZ, Zhang SW, Wang CS*. 2017. Divergent LysM effectors contribute to the virulence of Beauveria bassiana by evasion of insect immune defenses. PLoS Pathogens, 13(9): e1006004.

19. Shang YF, Xiao GH, Zheng P, Cen K, Zhan S, Wang CS*. 2016. Divergent and convergent evolution of fungal pathogenicity. Genome Biology and Evolution, 8(5): 1374-1387.

20. Feng P, Shang YF, Cen K, Wang CS*. 2015. Fungal biosynthesis of the bibenzoquinoe oosporein to evade insect immunity. Proceedings of the National Academy of Sciences USA, 112(36): 11365-11370.

21. Shang YF, Feng P, Wang CS*. 2015. Fungi that infect insects: altering host behavior and beyond. PLoS Pathogens, 11(8): e1005037.

22. Hu X, Xiao GH, Zheng P, Shang YF, Su Y, Zhang XY, Liu XZ, Zhan S, St. Leger RJ, Wang CS*. 2014. Trajectory and genomic determinants of fungal-pathogen speciation and host adaptation. Proceedings of the National Academy of Sciences USA, 111(47): 16796-16801.

23. Li L, Hu X, Xia YL, Xiao GH, Zheng P, Wang CS.* 2014. Linkage of oxidative stress and mitochondrial dysfunctions to spontaneous culture degeneration in Aspergillus nidulans. Molecular & Cellular Proteomics, 13(2): 449-461.

24. Duan ZB, Chen YX, Huang W, Shang YF, Chen PL, Wang CS*. 2013. Linkage of autophagy to fungal development, lipid storage and virulence in Metarhizium robertsii. Autophagy, 9(4): 538-549.

25. Hu X, Zhang YJ, Xiao GH, Zheng P, Xia YL, Zhang XY, St Leger RJ, Liu XZ, Wang CS*. 2013. Genome survey uncovers the secrets of sex and lifestyle in caterpillar fungus. Chinese Science Bulletin, 58(23): 2846-2854. (cover story)

26. Wang B, Kang QJ, Lu YZ, Bai LQ, Wang CS*. 2012. Unveiling the biosynthetic puzzle of destruxins in Metarhizium species. Proceedings of the National Academy of Sciences USA, 109(4): 1287-1292.

27. Wang SY, Zhao G-P. Liu XZ, St. Leger RJ, Wang CS*. 2011. Genome sequence of the insect pathogenic fungus Cordyceps militaris, a valued traditional Chinese medicine. Genome Biology, 12(11): R116.

28. Gao Q, Jin K, Ying S-H, Zhang YJ, Xiao GH, Shang YF, Duan ZB, Hu X, Xie XQ, Zhou G, Peng GX, Luo ZB, Huang W, Wang B, Fang WG, Wang SB, Zhong Y, Ma L-J, St. Leger RJ, Zhao G-P, Pei Y, Feng M-G*, Xia YX*, Wang CS*. 2011. Genome sequencing and comparative transcriptomics of the model entomopathogenic fungi Metarhizium anisopliae and M. acridum. PLoS Genetics, 7(1): e1001264.

29. Wang CS*, St Leger RJ*. 2007. A scorpion neurotoxin increases the potency of a fungal insecticide. Nature Biotechnology 25(12):1455-1456.

30. Wang CS, St Leger RJ*. 2006. A collagenous protective coat enables Metarhizium anisopliae to evade insect immune responses. Proceedings of the National Academy of Sciences USA 103(17): 6647-6652.