森林培育学科-曹一博
姓 名:曹一博
通信地址:北京市海淀区清华东路35号星空官网·中国区集团/注册/登陆✦,
邮政编码:100083
邮 箱:caoyibo@bjfu.edu.cn
一、教育背景
2014.9-2020.1 中国农业大学,生物学院,植物学,博士
2010.9-2013.7 星空官网·中国区集团/注册/登陆✦,,林学院,森林培育学科,硕士
2006.9-2010.7 中国农业大学,农学院,果树学,学士
二、工作经历
2020.9-2022.12 星空官网·中国区集团/注册/登陆✦,,林学院,森林培育学科,讲师
2023.1 至今 星空官网·中国区集团/注册/登陆✦,,林学院,森林培育学科,副教授
三、研究方向
经济林抗逆分子机理、经济林果实发育调控机制
四、研究项目
[1]. VcHKT1;1介导蓝莓响应盐胁迫的分子机制研究(国家自然科学基金青年项目,No. 32101555),2022.01-2024.12,30万元,主持
[2]. REA1介导ROS稳态调控拟南芥适应盐胁迫的分子机制(中国博士后科学基金第14批站中特别资助,No. 2021T140060),2021.6-2023.8,18万元,主持
[3]. REA1介导ROS稳态调控拟南芥适应盐胁迫的分子机制(中国博士后科学基金第68批面上资助,No. 2020M680403),2020.11-2022.9,8万元,主持
[4]. 转录因子VcMYB108介导ABA信号响应蓝莓干旱胁迫的机制研究(星空官网·中国区集团/注册/登陆✦,中央高校基本科研业务费专项资金项目,No. 2021ZY01),2021.06-2022.12,12万元,主持
五、近五年发表论文
[1]. Cao, Y., Zhang, M., Liang, X., Li, F., Shi, Y., Yang, X., and Jiang, C*. (2020). Natural variation of an EF-hand Ca2+-binding-protein coding gene confers saline-alkaline tolerance in maize. Nat Commun. 11, 186.
[2]. Cao, Y., Liang, X., Yin, P., Zhang, M., and Jiang, C*. (2019). A domestication-associated reduction in K+-preferring HKT transporter activity underlies maize shoot K+ accumulation and salt tolerance. New Phytol. 222, 301-317.
[3]. Cao, Y#*., Zhou, X#., Song, H., Zhang, M., and Jiang, C*. (2023). Advances in deciphering salt tolerance mechanism in maize. Crop J. 11, 1001-1010.
[4]. Cao, Y., Wang, Y., and Jiang, C*. (2021). Recent advancement of molecular understanding for combating salinity stress in maize. Molecular Breeding in wheat, maize and sorghum, Chapter14, 247-266.
[5]. Cao, Y., Song, H., and Zhang, L*. (2022). New insight into plant saline-alkali tolerance mechanisms and application to breeding. Int J Mol Sci. 23.
[6]. Wang, Y#., Cao, Y#., Liang, X., Zhuang, J., Wang, X., Qin, F., and Jiang, C*. (2022). A dirigent family protein confers variation of Casparian strip thickness and salt tolerance in maize. Nature Commun. 13, 2222.
[7]. Yang, Z#., Cao, Y#., Shi, Y#., Qin, F*., Jiang, C*., and Yang, S*. (2023). Genetic and molecular exploration of maize enviromental stress resilience: Towards sustainable agriculture. Mol Plant. doi.org/10.1016/j.molp.2023.07.005.
[8]. Zhang, M#., Cao, Y#., Wang, Z#., Wang, Z.Q#., Shi, J., Liang, X., Song, W., Chen, Q., Lai, J., and Jiang, C. (2018). A retrotransposon in an HKT1 family sodium transporter causes variation of leaf Na+ exclusion and salt tolerance in maize. New Phytol. 217, 1161-1176.
[9]. Song, H#., Cao, Y#*., Zhao, X., and Zhang, L*. (2023). Na+-preferential ion transporter HKT1;1 mediates salt tolerance in blueberry. Plant Physiol. 00, 1-19.
[10]. Cui, X#., Cao, Y#., Zhang, H., and Zhang, L*. (2023). A Picea wilsonii NAC transcription factor, PwNAC1, interacts with RNA-binding protein PwRBP1 and synergistically enhances drought and salt tolerance of transgenic Arabidopsis. Environ Exp Bot. 206, 105174.
[11]. Wang, A#., Wang, L#., Liu, K., Liang, K., Yang, S., Cao, Y*., and Zhang, L*. (2022). Comparative transcriptome profiling reveals the defense pathways and mechanisms in the leaves and roots of blueberry to drought stress. Fruit Res. 2, 18.
[12]. Yu, M#., Liu, J#., Hu, J., Zhou, J., Zhang, M., Cao, Y*., and Zhang, L*. (2022). Picea wilsonii transcription factor PwNAC38 promotes drought and salt tolerance in transgenic Arabidopsis and apple calli. Forests. 13, 1304.
[13]. Qin, X#., Hu, J#., Xu, G., Song, H., Zhang, L*., and Cao, Y*. (2023). Development of a high-efficient genetic transformation system and characterization of VcCHS transgenic blueberry callus. Plants. 12, 2905.
[14]. Zhang, M., Liang, X., Wang, L., Cao, Y., Song, W., Shi, J., Lai, J., and Jiang, C. (2019). A HAK family Na+ transporter confers natural variation of salt tolerance in maize. Nat Plants. 5, 1297-1308.
[15]. Steinhorst, L., He, G., Moore, L.K., Schultke, S., Schmitz-Thom, I., Cao, Y., Hashimoto, K., Andres, Z., Piepenburg, K., Ragel, P., et al. (2022). A Ca2+-sensor switch for tolerance to elevated salt stress in Arabidopsis. Dev Cell. 57, 2081-2094 e2087.
[16]. Wang, A., Liang, K., Yang, S., Cao, Y., Wang, L., Zhang, M., Zhou, J., and Zhang, L. (2021). Genome-wide analysis of MYB transcription factors of Vaccinium corymbosum and their positive responses to drought stress. BMC Genomics, 22, 565.
[17]. Guo, Y#., Song, H#., Zhao, Y., Qin, X., Cao, Y., and Zhang, L*. (2021). Switch from symplasmic to aspoplasmic phloem unloading in Xanthoceras sorbifolia fruit and sucrose influx XsSWEET10 as a key candidate for sugar transport. Plant Science, 313, 111089.
[18]. Ye, Z#., Du, B#., Zhou, J., Cao, Y., and Zhang, L*. (2023). Camellia oleifera CoSWEET10 is crucial for seed development and drought resistance by mediating sugar transport in transgenic Arabidopsis. Plants. 2023, 12, 2818.
[19]. Zhou, J., Du, B., Chen, Y., Cao, Y., Yu, M., and Zhang, L*. (2022). Integrative physiological and transcriptomic analysis reveals the transition mechanism of sugar phloem unloading route in Camellia oleifera fruit. Int J Mol Sci. 2310.3390/ijms23094590.
[20]. 刘奎, 李兴芬, 杨沛欣, 仲昭晨, 曹一博*, 张凌云*. (2023). 青杄转录共激活因子 PwMBF1c的功能研究与验证. 生物技术通报, 39: 205-216.
[21]. 姜佩弦#, 张凯#, 王艺桥, 张鸣, 曹一博*, 蒋才富*. (2022). 玉米耐盐分子机制研究进展. 植物遗传资源学报, 23: 49-60.