王雷----中国科学院植物分子生理学重点实验室

科研队伍

植物生物钟与发育调控

王雷研究员

1999年，东北师范大学获学士学位；
2002年，吉林农业大学获硕士学位；
2006年，中国科学院植物研究所获博士学位；
2006-2013年，在美国俄亥俄州立大学分子遗传学系从事博士后研究；
2010年3月-2010年9月，在韩国浦项科技大学作研究访问学者；
2013年11月到植物所工作；
现任中国科学院植物分子生理学重点实验室副主任；
在EMBO Journal、PNAS、Nucleic Acids Research、Molecular Plant等期刊发表SCI收录论文30余篇。参与申报国内专利4项，其中已授权3项。参与国际专著编写1部。

联系方式：010-62836175 E-mail：wanglei@ibcas.ac.cn

研究方向
课题组成员

生物钟分子系统(Circadian molecular system)是生物体为了因应地球自转而产生的昼夜环境周期性的变化，从而进化出的协调细胞内基因表达，及代谢网络调控的分子系统。我们课题组以水稻和拟南芥为模式植物，解析植物生物钟分子系统组成以及对植物生长发育的调控机理，主要包括对开花时间调控、细胞生长以及如何协同细胞内代谢网络方面的分子机理研究。研究核心主要是围绕植物生物钟分子系统如何通过对环境信号的整合而实现对输出系统的控制，以期为提高农作物品质与产量提供时间生物学方面的理论依据和遗传资源。课题组主要研究方向为： 1）植物生物钟分子系统的组成解析及关键因子的转录后水平调控； 2）水稻生物钟分子系统的表观遗传控制分子机制； 3）生物钟分子系统对植物发育的调控及相关分子机理。

张媛媛

副研究员
zhangyy@ibcas.ac.cn
010-62836165
左毅

助理研究员
zuoyi@ibcas.ac.cn
010-62836165
李彬

工程师
libin@ibcas.ac.cn
010-62836165
王希岭

博士生
wangxiling@ibcas.ac.cn
010-62836165
郑清波

博士后
qingbozheng@ibcas.ac.cn
010-62836165
何雨晴

博士生
heyuqing@ibcas.ac.cn
010-62836165
于英俊

博士生
xnyingjun3739@163.com
010-62836874
秦玉梅

博士生
1242272529@qq.com
010-62836165
苏晨

博士生
suchen95@hotmail.com
010-62836165
徐航

博士生
xuhang3156@163.com
010-62836165
牛钰凡

硕士生
13474054949@163.com
010-62836165
张家硕

硕士生
jiashuoz@ibcas.ac.cn
010-62836165
冯震

博士生
fengzhen@ibcas.ac.cn
010-62836165
朱纯真

硕士生
zhuchunzhen21@mails.ucas.ac.cn
010-62836165

研究论文

Wang Y^#, Su C^#, Yu YJ^#, He YQ, Wei H, Li N, Li H, Duan J, Li B, Li JG, Davis S, Wang L*. 2022. TIME FOR COFFEE regulates phytochrome A-mediated hypocotyl growth through dawn-phased signaling. Plant Cell, https://doi.org/10.1093/plcell/koac138

Wei H, Xu H, Su C, Wang XL, Wang L*. 2022. Rice CIRCADIAN CLOCK ASSOCIATED1 transcriptionally regulates ABA signaling to confer multiple abiotic stress tolerance. Plant Physiology, https://doi.org/10.1093/plphys/kiac196

Ronald J, Su C, Wang L, Davis SJ*. 2022. Cellular localization of Arabidopsis EARLY FLOWERING3 is responsive to light quality. Plant Physiology, doi: 10.1093/plphys/kiac072

Xu XD*, Yuan L, Yang X, Zhang X, Wang L, Xie QG*. 2022. Circadian clock in plants: Linking timing to fitness. Journal of Integrative Plant Biology, 64(4):792-811

Yan JP, Li SB, Kim YJ, Zeng QN, Radziejwoski A, Wang L, Nomura Y, Nakagami H, Somers DE. 2021. TOC1 clock protein phosphorylation controls complex formation with NF-YB/C to repress hypocotyl growth, The EMBO Journal, e108684. doi: 10.15252/embj.2021108684

Wang XL^#, He YQ^#, Wei H, Wang L*. 2021. A clock regulatory module is required for salt tolerance and control of heading date in rice. Plant Cell & Environment, 44: 3283-3301

Yuan L^#, Yu YJ^#, Liu MM, Song Y, Li HM, Sun JQ, Wang Q, Xie QG*, Wang L*, Xu XD*. 2021. BBX19 fine-tunes the circadian rhythm by interacting with PSEUDO-RESPONSE REGULATOR proteins to facilitate their repressive effect on morning-phased clock genes. Plant Cell, 33: 2602-2617

Zhang YY, Li N, Wang L*. 2021. Phytochrome interacting factor proteins regulate cytokinesis in Arabidopsis. Cell Reports, 35: 109095

Li N, Bo C, Zhang YY*, Wang L*. 2021.PHYTOCHROME INTERACTING FACTORS PIF4 and PIF5 promote heat stress induced leaf senescence in Arabidopsis. Journal of Experimental Botany, 72: 4577-4589

Tian WW^#, Wang RY^#, Bo CP, Yu YJ, Zhang YY, Shin G, Kim W, Wang L*. 2021. SDC mediates DNA methylation-controlled clock pace by interacting with ZTL in Arabidopsis. Nucleic Acids Research, 49:3764-3780

Su C, Wang Y, Yu YJ, He YQ, Wang L*. 2021. Coordinative regulation of plants growth and development by light and circadian clock. aBIOTECH, 2: 179-189

Wang Y, Lu Z, Wang L*. 2021. Uncover the nuclear proteomic landscape with enriched nuclei followed by label-free quantitative mass spectrometry. Methods in Molecular Biology, 2297:115-124

Wei H, Wang XL, He YQ, Xu H, Wang L*. 2021. Clock component OsPRR73 positively regulates rice salt tolerance by modulating OsHKT2;1-mediated sodium homeostasis. The EMBO Journal, 40: e105086

Wei H, Wang XL, Xu H, Wang L*.2020. Molecular basis of heading date control in rice. aBIOTECH, 1:219-232

Li N^#, Zhang YY^#, He YQ, Wang Y, Wang L*. 2020. Pseudo Response Regulators regulate photoperiodic hypocotyl growth by repressing PIF4/5 transcription. Plant Physiology, 183(2): 686-699 [下载]

Wang Y, He YQ, Su C, Zentella R, Sun TP, Wang L*. 2020. Nuclear localized O-fucosyltransferase SPY facilitates PRR5 proteolysis to fine-tune the pace of Arabidopsis circadian clock. Molecular Plant, 3: 446-458 [下载]

Wang Y^#, Qin YM^#, Li B, Zhang YY, Wang L*. 2020. Attenuated TOR signaling lengthens circadian period in Arabidopsis. Plant Signaling & Behavior, 2:e1710935 [下载]

Kim TS, Wang L, Kim YJ, Somers DE*. 2020. Compensatory mutations in GI and ZTL may modulate temperature compensation in the circadian clock. Plant Physiology, 2: 1130-1141 [下载]

Zhang YY, Bo CP, Wang L*. 2019. Novel crosstalks between circadian clock and jasmonic acid pathway finely coordinate the tradeoff among plant growth, senescence and defense. International Journal of Molecular Sciences, 20: 5254 [下载]

Li B^#, Wang Y^#, Zhang YY, Tian WW, Chong K, Jang JC, Wang L*. 2019. PRR5, 7 and 9 positively modulate TOR signaling-mediated root cell proliferation by repressing TANDEM ZINC FINGER 1 in Arabidopsis. Nucleic Acids Research, 10: 5001-5015 [下载]

Wang Y, Zhang YY, Wang L*. 2018. Cross regulatory network between circadian clock and leaf senescence is emerging in higher plants. Frontiers in Plant Science, 9: 700 [下载]

Zhang YY, Wang Y, Wei H, Li N, Tian WW, Chong K, Wang L*. 2018. Circadian evening complex represses Jasmonate-induced leaf senescence in Arabidopsis. Molecular Plant, 11: 326-337 [下载]

Cha JY, Kim J, Kim TS, Zeng QN, Wang L, Lee SY, Kim WY, Somers DE*. 2017. GIGANTEA acts as a co-chaperone with HSP90 to facilitate maturation of the client protein ZEITLUPE in the Arabidopsis circadian clock. Nature Communications, 8: 3 [下载]

Wang L, Chong K*. 2016. The essential role of cytokin in signaling in root apical meristem formation during somatic embryogenesis. Frontiers in Plant Science, 6: 1196-1200 [下载]

Jia YB, Tian HY, Li HJ, Yu QQ, Wang L, Friml J, Ding ZJ*. 2015. The Arabidopsis thaliana elongator complex subunit 2 epigenetically affects root development. Journal of Experimental Botany, 4631-4642 [下载]

Choudhary M, Nomura Y, Wang L, Nakagami H, Somers DE*. 2015. Quantitative circadian phosphoproteomic analysis of Arabidopsis reveals extensive clock control of key components in physiological, metabolic, and signaling pathways. Molecular & Cellular Proteomics, 14: 2243-2260 [下载]

Kim Y, Lim J, Yeom M, Kim H, Kim J, Wang L, Somers D, Nam H*. 2013. ELF4 regulates GIGANTEA chromatin access through subnuclear sequestration. Cell Reports, 3: 671-677 [下载]

Wang L, Kim J, Somers D*. 2013. Transcriptional corepressor TOPLESS comlexes with pseudoresponse regulator proteins and histone deacetylase to regulate circadian transcription. Proc. Natl. Acad. Sci. USA, 110: 761-766 [下载]

Zhang C, Xu YY, Guo SY, Zhu JY, Huan Q, Liu HH, Wang L, Luo GZ, Wang XJ, Chong K*. 2012. Dynamics of brassinosteroid response modulated by negative regulator LIC in rice. PLoS Genetics, 8: e1002686 [下载]

Wang L, Chong K*. 2010. Auxin brassinosteroids and G protein signaling. In Integrated G protein Signaling in Plants. Series of Signaling and Communication in Plants. page: 135-154 (Book chapter). [下载]

Wang L, Fujiwara S and Somers D*. 2010. PRR5 regulates phosphorylation, nuclear import and subnuclear localization of TOC1 in the Arabidopsis circadian clock. The EMBO Journal, 29: 1903-1915 [下载]

Li D, Wang L, Wang M, Xu Y, Luo W, Liu Y, Xu Z, Li J, Chong K*. 2009. Engineering OsBAK1 gene as a molecular tool to improve rice architecture for high yield. Plant Biotechnology Journal, 7: 791–806 [下载]

Wang L, Xu Y, Zhang C Ma QB, Kim J, Xu ZH, Chong K*. 2008. OsLIC, a novel CCCH-type zinc finger protein with transcription activation, mediates rice architecture via brassinosteroids signaling. PLoS ONE. 3: e3521 [下载]

Fujiwara S^#, Wang L^#, Han L, Suh SS, Salomé P, McClung R, Somers D*. 2008. Post-translational regulation of the Arabidopsis circadian clock through selective proteolysis and phosphorylation of pseudo-response regulator proteins. Journal of Biological Chemistry, 283: 23073-23083. (cover story). [下载]

Wang L, Xu YY, Li J, Powell R, Xu ZH, Chong K*. 2007. Transgenic rice plants ectopically expressing AtBAK1 are semi-dwarfed and hypersensitive to 24-epibrassinolide. Journal of Plant Physiology, 164: 655-664 [下载]

Liu KM, Wang L, Xu YY, Chen N, Ma QB, Li F, Chong K*. 2007. Overexpression of OsCOIN, a putative cold inducible zinc finger protein, increased tolerance to chilling, salt and drought, and enhanced proline level in rice. Planta, 226: 1007-1016 [下载]

Wang L, Xu YY, Ma QB, Li D, Xu ZH, Chong K*. 2006. Heterotrimeric G protein alpha subunit is involved in rice brassinosteroid response. Cell Research, 16: 916-922 [下载]

Wang ZY*, Wang QM, Chong K, Wang FR, Wang L, Bai MY, Jia CG. 2006. The brassinosteroid signal transduction pathway. Cell Research, 16: 427-434 [下载]

张媛媛

左毅

李彬

王希岭

郑清波

何雨晴

于英俊

秦玉梅

苏晨

徐航

牛钰凡

张家硕

冯震

朱纯真