1. 植物激素的转运机制。

植物激素是植物体内产生的一些微量的、能够移动和具有信号功能的小分子。其中，生长素影响植物生长发育的多个方面，包括禾本科作物的分蘖与穗子大小以及各种果实的大小等；脱落酸ABA是植物逆境响应激素，调控植物的抗逆性和衰老等过程。植物激素的最大特点是可以在一个部位合成，在另外一个部位发挥作用。大家最为熟知的激素转运是PIN所介导的生长素的极性运输。除了PIN以外，还有哪些转运蛋白家族也参与了对生长素的转运？ABA的转运机制又是如何？我们以模式植物拟南芥和番茄为材料，鉴定植物激素尤其是生长素和ABA的转运蛋白，解析其在不同组织、细胞以及细胞器之间的分子转运机制。

 

2. 挖掘番茄抗逆新基因，培育番茄抗逆新品种，改善番茄风味。

我国是世界上最大的番茄生产国。番茄未来发展的方向是番茄风味的改善和提高。番茄是中度盐敏感作物，适度的盐碱或者干旱可以改善番茄的风味和品质。我们利用正向遗传学方法构建番茄全基因组突变体库，挖掘番茄抗盐抗干旱等抗逆基因，为培育番茄抗逆新品种和改善番茄风味提供重要基因资源。

博士后和客座研究生招聘信息：

本实验室常年招收博士后和客座研究生，欢迎对植物激素的转运和植物抗逆研究感兴趣、并立志为改善番茄风味提高番茄品质做贡献的青年申请。

热烈欢迎各大高校和各院系所同学报考本实验室硕士、博士。

071007-遗传学

植物激素的转运，植物抗逆研究，番茄风味品质的改善

2009-09--2015-07   中国科学院大学遗传与发育生物学研究所   博士
2006-09--2009-07   深圳大学   硕士
2002-09--2006-07   聊城大学   学士

   

2022-09~现在, 中国科学院大学, 副教授
2015-08~2022-08,以色列特拉维夫大学, 博士后

   

（1） PBC以色列杰出博士后, 一等奖, 国家级, 2016
（2） 山东省高校省级优秀毕业生, 特等奖, 省级, 2006

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