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个人简历
教育经历
2011年9月-2017年6月,硕、博士,中国农业大学农学与生物技术学院
2007年9月-2011年6月,学士,南京农业大学农学院
2007年9月-2011年6月,学士,南京农业大学农学院
工作经历
2023年7月-至今,北京大学生命科学学院,助理研究员
2022年5月-2023年7月,项目科学家,美国加州大学河滨分校
2019年11月-2022年4月,博士后,美国加州大学河滨分校
2018年4月-2019年10月,博士后,深圳大学生命与海洋科学学院
2022年5月-2023年7月,项目科学家,美国加州大学河滨分校
2019年11月-2022年4月,博士后,美国加州大学河滨分校
2018年4月-2019年10月,博士后,深圳大学生命与海洋科学学院
荣誉奖励
1.国家自然科学基金(青年基金),31900446,miR399及其靶基因参与玉米开花期调控网络的机制研究,2020/01-2022/12, 26万,主持。
2.中国博士后科学基金特别资助(站中), 2019T120753,玉米NAD-capped RNA的鉴定和非生物胁迫下表达变异研究, 2019/12-2021/12, 18万元,主持。
3.中国博士后基金,011581,miR399介导玉米开花期调控网络的解析和机制研究,2018/12-2020/12, 8万元,主持。
4.国家自然科学基金(应用研究项目),玉米氮效率遗传结构的系统解析,2013/01-2016/12, 80万,参与。
2.中国博士后科学基金特别资助(站中), 2019T120753,玉米NAD-capped RNA的鉴定和非生物胁迫下表达变异研究, 2019/12-2021/12, 18万元,主持。
3.中国博士后基金,011581,miR399介导玉米开花期调控网络的解析和机制研究,2018/12-2020/12, 8万元,主持。
4.国家自然科学基金(应用研究项目),玉米氮效率遗传结构的系统解析,2013/01-2016/12, 80万,参与。
杂志任职
无
评审任职
无
会议发言与组织
1.2023年8月,中国兰州,植物细胞生物学大会
2.2021年1月,美国圣地亚哥,植物&动物基因组大会
3.2018年6月,中国宁波,第十届全国核糖核酸(RNA)学术讨论会
4.2018年4月,中国青岛,第三届玉米生物学会议
5.2017年4月,中国安徽,第二届玉米生物学会议 (海报展示)
6.2016年8月,中国北京,第七届国际作物学会议 (海报展示)
7.2015年3月,美国芝加哥,第57届国际玉米遗传学大会 (大会报告)
8.2014年3月,中国北京,第56届国际玉米遗传学大会 (海报展示)
2.2021年1月,美国圣地亚哥,植物&动物基因组大会
3.2018年6月,中国宁波,第十届全国核糖核酸(RNA)学术讨论会
4.2018年4月,中国青岛,第三届玉米生物学会议
5.2017年4月,中国安徽,第二届玉米生物学会议 (海报展示)
6.2016年8月,中国北京,第七届国际作物学会议 (海报展示)
7.2015年3月,美国芝加哥,第57届国际玉米遗传学大会 (大会报告)
8.2014年3月,中国北京,第56届国际玉米遗传学大会 (海报展示)
杂志编辑
无
书籍编撰
无
教材编撰
无
科研领域描述
主要以细菌、拟南芥为研究对象,结合遗传学、生物化学、分子生物学、生物信息学等手段,进行非典型帽子修饰RNA的加帽、脱帽机制及其生物学功能研究。
代表性论文
1.Xufeng Wang*, Dan Yuan*, et al., (2023) INDETERMINATE1 autonomously regulates phosphate homeostasis upstream of the miR399-ZmPHO2 signaling module in maize. Plant Cell
2.Xufeng Wang*, Qiuyue Chen*, Yaoyao Wu*, et al. (2018) Genome-wide analysis of transcriptional variability in a large maize-teosinte population. Molecular Plant
3.Haijiao Dong*, Xufeng Wang*, et al., (2022) NAD+-capped RNAs are widespread in rice (Oryza sativa) and spatiotemporally modulated during development. Science China of Life Science (SCLS)
4.Dingyi Xu*, Xufeng Wang* et al., (2018) Directional selection on standing genetic variation at Glossy15 underlies the evolution of the vegetative transition in maize. Molecular Plant
5.Guanghui Xu*, Xufeng Wang*, et al., (2017) Complex genetic architecture underlies maize tassel domestication. New Phytologist
6.Yameng Liang*, Qiang Liu*, Xufeng Wang *, et al. (2019) ZmMADS69 functions as a flowering activator through the ZmRap2.7-ZCN8 regulatory module and contributes to maize flowering time adaptation. New Phytologist
7.Runlai Hang, Ye Xu, Xufeng Wang, et al. (2023) Arabidopsis HOT3/eIF5B1 constrains rRNA RNAi by facilitating 18S rRNA maturation. Proceedings of the National Academy of Sciences (PNAS)
8.Qi Xie, Xufeng Wang, et al., (2021) Distinct Evolutionary Profiles and Functions of microRNA156 and microRNA529 in Land Plants. International Journal of Molecular Sciences
9.Hailei Zhang*, Huan Zhong*, Xufeng Wang, et al., (2021) Use of NAD tagSeq II to identify growth phase-dependent alterations in E. coli RNA NAD + capping. Proceedings of the National Academy of Sciences (PNAS)
10.Hao Hu, Nora Flynn, Hailei Zhang, Chenjiang You, Runlai Hang, Xufeng Wang, et al., (2021) SPAAC-NAD-seq, a sensitive and accurate method to profile NAD+ -capped transcripts Proceedings of the National Academy of Sciences (PNAS)
11.Xiaoyu Yang, Chenjiang You, Xufeng Wang, et al., (2021) Widespread occurrence of microRNA-mediated target cleavage on membrane-bound polysomes. Genome Biology
12.Juan He, Zengming Jiang, Lei Gao, Chenjiang You, Xuan Ma, Xufeng Wang, et al., (2019) Genome-Wide Transcript and Small RNA Profiling Reveals Transcriptomic Responses to Heat Stress. Plant Physiology
13.Xue Wei, Anderson S., Xufeng Wang, et al. (2019) Hybrid Decay: A Transgenerational Epigenetic Decline in Vigor and Viability Triggered in Backcross Populations of Teosinte with Maize. Genetics
14.Yuhua Fu*, Guangui Xu*, Huafeng Chen, Xufeng Wang, et al. (2019) QTL mapping for leaf morphology traits in a large maize-teosinte population. Molecular Breeding
15.Guanghui Xu*, Jinjin Cao*, Xufeng Wang, et al. (2019) Evolutionary Metabolomics Identifies Substantial Metabolic Divergence between Maize and its Wild Ancestor, Teosinte. Plant Cell
16.Cheng Huang, Huayue Chen, Dingyi Xu, Qiuyue Chen, Yameng Liang, Xufeng Wang, et al. (2018) ZmCCT9 enhances maize adaptation to higher latitudes. Proceedings of the National Academy of Sciences (PNAS)
17.Qiuyue Chen*, Yingjia Hang*, Haijun Liu*, Xufeng Wang, et al. (2018) Genome-wide association analyses reveal the importance of alternative splicing in diversifying gene function and regulating phenotypic variation in maize. Plant Cell
18.Dan Li, Xufeng Wang, et al., (2016) The genetic architecture of leaf number and its genetic relationship to flowering time in maize. New Phytologist
19.Qiuyue Chen, Zhipeng Liu, Baobao Wang, Xufeng Wang, et al., (2015) Transcriptome sequencing reveals the roles of transcription factors in modulating genotype by nitrogen interaction in maize. Plant Cell Reports
2.Xufeng Wang*, Qiuyue Chen*, Yaoyao Wu*, et al. (2018) Genome-wide analysis of transcriptional variability in a large maize-teosinte population. Molecular Plant
3.Haijiao Dong*, Xufeng Wang*, et al., (2022) NAD+-capped RNAs are widespread in rice (Oryza sativa) and spatiotemporally modulated during development. Science China of Life Science (SCLS)
4.Dingyi Xu*, Xufeng Wang* et al., (2018) Directional selection on standing genetic variation at Glossy15 underlies the evolution of the vegetative transition in maize. Molecular Plant
5.Guanghui Xu*, Xufeng Wang*, et al., (2017) Complex genetic architecture underlies maize tassel domestication. New Phytologist
6.Yameng Liang*, Qiang Liu*, Xufeng Wang *, et al. (2019) ZmMADS69 functions as a flowering activator through the ZmRap2.7-ZCN8 regulatory module and contributes to maize flowering time adaptation. New Phytologist
7.Runlai Hang, Ye Xu, Xufeng Wang, et al. (2023) Arabidopsis HOT3/eIF5B1 constrains rRNA RNAi by facilitating 18S rRNA maturation. Proceedings of the National Academy of Sciences (PNAS)
8.Qi Xie, Xufeng Wang, et al., (2021) Distinct Evolutionary Profiles and Functions of microRNA156 and microRNA529 in Land Plants. International Journal of Molecular Sciences
9.Hailei Zhang*, Huan Zhong*, Xufeng Wang, et al., (2021) Use of NAD tagSeq II to identify growth phase-dependent alterations in E. coli RNA NAD + capping. Proceedings of the National Academy of Sciences (PNAS)
10.Hao Hu, Nora Flynn, Hailei Zhang, Chenjiang You, Runlai Hang, Xufeng Wang, et al., (2021) SPAAC-NAD-seq, a sensitive and accurate method to profile NAD+ -capped transcripts Proceedings of the National Academy of Sciences (PNAS)
11.Xiaoyu Yang, Chenjiang You, Xufeng Wang, et al., (2021) Widespread occurrence of microRNA-mediated target cleavage on membrane-bound polysomes. Genome Biology
12.Juan He, Zengming Jiang, Lei Gao, Chenjiang You, Xuan Ma, Xufeng Wang, et al., (2019) Genome-Wide Transcript and Small RNA Profiling Reveals Transcriptomic Responses to Heat Stress. Plant Physiology
13.Xue Wei, Anderson S., Xufeng Wang, et al. (2019) Hybrid Decay: A Transgenerational Epigenetic Decline in Vigor and Viability Triggered in Backcross Populations of Teosinte with Maize. Genetics
14.Yuhua Fu*, Guangui Xu*, Huafeng Chen, Xufeng Wang, et al. (2019) QTL mapping for leaf morphology traits in a large maize-teosinte population. Molecular Breeding
15.Guanghui Xu*, Jinjin Cao*, Xufeng Wang, et al. (2019) Evolutionary Metabolomics Identifies Substantial Metabolic Divergence between Maize and its Wild Ancestor, Teosinte. Plant Cell
16.Cheng Huang, Huayue Chen, Dingyi Xu, Qiuyue Chen, Yameng Liang, Xufeng Wang, et al. (2018) ZmCCT9 enhances maize adaptation to higher latitudes. Proceedings of the National Academy of Sciences (PNAS)
17.Qiuyue Chen*, Yingjia Hang*, Haijun Liu*, Xufeng Wang, et al. (2018) Genome-wide association analyses reveal the importance of alternative splicing in diversifying gene function and regulating phenotypic variation in maize. Plant Cell
18.Dan Li, Xufeng Wang, et al., (2016) The genetic architecture of leaf number and its genetic relationship to flowering time in maize. New Phytologist
19.Qiuyue Chen, Zhipeng Liu, Baobao Wang, Xufeng Wang, et al., (2015) Transcriptome sequencing reveals the roles of transcription factors in modulating genotype by nitrogen interaction in maize. Plant Cell Reports
执教课程
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