教育背景 1992/09-1997/06 博士 佛罗里达大学（美国） 植物分子遗传学 1984/09-1987/06 硕士 兰州大学 植物生理学 1980/09-1984/06 学士 兰州大学 植物生理学 工作经历 2022/01- 至 今 山东大学特聘教授、泰山学者II期 2018/05-2020/12 山东大学（青岛）副校长、生命科学学院院长、山东大学特聘教授 2013/05-2022/01 山东大学生命科学学院院长、山东大学特聘教授、泰山学者 2011/01-2013/12 香港中文大学深圳研究院 研究员 2007/12-2013/12 香港中文大学植物分子与农业技术研究所 研究副教授 2001/03-2007/12 佛罗里达大学癌症与遗传研究所 研究助理教授 1997/07-2001/02 佛罗里达大学植物分子与细胞生物学 博士后 1992/08-1997/06 佛罗里达大学园艺科学系 研究助理 1987/06-1992/08 兰州大学生物系 讲师

课题组主要以玉米为模式植物研究种子发育的分子遗传调控机制。种子发育与粮食作物的产量和品质密切相关，解析种子发育的分子遗传调控机制既是植物学的一个根本问题，也是农业生产高产优质育种的重要基础。种子发育过程涉及复杂的遗传调控网络，突变体是解析遗传网络组成元件的主要遗传材料。我们利用Mutator转座子分离了大量的玉米种子发育突变体，开发了针对性的基因克隆技术，通过基因克隆和遗传学、分子生物学和细胞生物学分析，查明这些基因的分子功能，解析调控种子发育的分子机制和调控网络，为分子育种提供理论基础。目前为止，实验室克隆了40多个玉米籽粒发育关键基因，通过功能解析，揭示了调控种子发育的重要途径并创新了相关的基础理论， 如确立了植物激素ABA是通过间接途径合成；发现了一个前所未知的阿魏酰蔗糖循环途径；该循环介导单子叶植物中细胞壁木聚糖阿魏酰化；初步解析了细胞器RNA编辑和内含子剪接的机制，为后续研究奠定了基础。其中，关于ABA合成途径的研究成果被编入美国《Plant Physiology》(Taiz & Zaiger ed.) 大学教材，并被翻译成中文等语言。实验室参与构建的UniformMu突变体库供全球科学家使用，成为玉米遗传学研究最重要的资源。

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Multiple factors interact in the editing of the PPR-E+ targeted sites in maize mitochondria and plastids. Plant Commun. 5: 100836. 6. Liu X.Y., Jiang, R.C., Ma, B., Wang, Y., Yang, Y.Z., Xu, C., Sun, F., Tan, B.C.* (2024). Maize requires Embryo defective27 for embryogenesis and seedling development. Plant Physiology 195: 430-445. 7. Ma, B.#, Liu, H.#, Xiu, Z., Yang, H.H., Wang, H., Wang, Y., Tan, B.C.* (2024). Defective kernel 58 encodes an Rrp15p domain-containing protein essential to ribosome biogenesis and seed development in maize. New Phytologist 241: 1662-1675. 8. Yang Y.Z., Ding, S., Liu., X.Y., Xu, C., Sun, F., Tan, B.C.* (2023). The DEAD-box RNA helicase ZmRH48 is required for the splicing of multiple mitochondrial introns, mitochondrial complex biosynthesis, and seed development in maize. JIPB 65: 2456-2468. 9. Zu, X., Luo, L., Wang, Z., Gong, J., Yang, C., Deng, X., Song, X., Wang, Y., Xu, C., Qiao X., Chen, C., Tan, B.C., Cao, X.* (2023). 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Li C., Shen Y., Meeley R., McCarty D.R., Tan, B.C.* (2015). Embryo defective 14 encodes a plastid-targeted cGTPase essential for embryogenesis in maize. Plant J. 84: 785-799. 34. Sun F., Wang X., Bonnard G., Shen Y., Xiu Z., Li, X., Gao, D., Zhang, Z., Tan B.C.* (2015). Empty pericarp 7 encodes a mitochondrial E-subgroup pentatricopeptide repeat protein that is required for ccmFN editing, mitochondrial function and seed development in maize. Plant J. 84: 283-295. 35. Chen Y., Hou M., Liu L., Wu S., Shen Y., Ishiyama K., Kobayashi M., McCarty D.R., Tan B.C.* (2014). The maize DWARF 1 encodes a Gibberellin 3-oxidase and is dual-localized to the nucleus and cytosol. Plant Physiology 166: 2028-2039. 36. Li X.J., Zhang Y.F., Hou M.M., Sun F., Shen Y., Xiu Z.H., Wang X.M., Chen Z.L., Sun S.S.M., Small I., Tan B.C.* (2014). Small kernel 1 encodes a pentatricopeptide repeat protein required for mitochondrial nad7 transcript editing and seed development in maize and rice. 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