1984年3月出生于湖南永州，湖南大学隆平农学院执行院长、生物学院教授，教育部CJ学者特聘教授。获湖南省自然科学一等奖（序1）、卫志明青年创新奖等奖励。湖南师范大学获生物技术学士学位（2007年）、理学博士学位（2013年，导师：陈良碧、栾升教授）。加州大学伯克利分校大数据分析方向访问学者（合作导师Devin Coleman-Derr）。开展分子与智算融合的作物基础研究，揭示作物适应土壤病虫害等环境因子的系列分子机理。相关研究成果发表在Nature Plants、Development Cell、Plant Cell和Molecular Plant等本领域权威期刊。成果多次被主要发达国家院士Luis Herrera-Estrella等评价为“first”“breaking new ground”“great story”。曾任湖南大学人力资源处处长兼人才工程办公室主任与党委教师工作部部长、教育部“CJ学者奖励计划”青年学者（2017）、中国科协“青年托举人才”计划（2016）；培养学生中有10余人任浙江大学、西北农林科技大学等高校教授、副教授。

联系方式：feng_yu@hnu.edu.cn

2025.03 - 至今，隆平农学院执行院长

2022.01 - 2025.03，湖南大学人力资源处处长兼人才工程办公室主任

2021.11 - 2022.1，湖南大学人力资源处副处长兼人才工程办公室副主任（主持工作）

2019.12 - 2020.12，湖南大学发展规划办公室（重点建设办公室）副主任（挂职）

2019.04 - 2021.11，湖南大学生物学院副院长

2018.04 - 2019.03，湖南大学生物学院院长助理

2016.04 - 2018.03，湖南大学生物学院生命科学支部书记

2019 -至今，教授，湖南大学生物学院

2017 - 2018，研究员，湖南大学生物学院

2013 - 2017，副教授，湖南大学生物学院

2017 - 2018，加州大学伯克利分校 生物信息与大数据，访问学者，合作导师：Devin Coleman-Derr

2008 - 2013，湖南师范大学 硕博连读生，导师：陈良碧,栾升教授

2003 - 2007，湖南师范大学 生物技术专业 本科

[1]国家自然科学基金面上项目，32370757、受体激酶FER驱动根部穿透土壤的机制、2024/01-2027/01、50万元、在研、主持。

[2]国家重点研发子任务，2023YFD1401100、稻田新除草化合物的构效关系研究、2024/01-2027/01、300万元、在研、主持。

[3]省科技攻关项目，2023ZJ1080、水稻多组学大数据智能育种关键技术研究与验证、2024/01-2027/01、800万元、在研、主持。

[4]国家自然科学基金面上项目，32070769、受体激酶FER调控蛋白质合成的机制、2021/01-2024/12、58万元、在研、主持。

[5]国家自然科学基金面上项目，31871396、一个核质穿梭蛋白在FERONIA信号网络中的功能、2019/01-2022/12、69万元、在研、主持。

[6]国家自然科学基金面上项目，31571444、受体蛋白激酶FERONIA响应RALF多肽信号的机制、2016/01-2019/12、77.8万元、结题、主持。

[7]国家自然科学基金青年项目，31400232、磷酸酶ABI2在受体蛋白激酶FERONIA调控脱落酸与逆境响应中的分子机制研究、2015/01-2017/12、24万元、结题、主持。

[8]中国科协“青年人才托举计划”,YESS20160001, FERONIA信号网络在植物与微生物互作中的作用研究、2016/01-2018/12、45万、结题、主持。

[9]湖南省自然科学基金青年项目，2015JJ3048、受体蛋白激酶FERONIA在乙烯合成中的功能分析、2015/01-2017/12、5万元、结题、主持。

[10]湖南省优秀博士论文项目，受体蛋白激酶FERONIA在RALF与ABA交叉会话中的作用、2015/01-2016/12、2万元、结题、主持。

[11]湖南大学教改项目，基于《微生物与人类健康》的MOOC教学研究、2015/01-2017/12、0.5万元、结题、主持。

发表论文：

[1]Yu F#, Shi J#, Zhou J#, Gu J, Chen Q, Li J, Cheng W, Mao D, Tian L, Buchanan BB*, Li L, Chen L, Li D*, Luan S* (2010) ANK6, a mitochondrial ankyrin repeat protein, is required for male-female gamete recognition in Arabidopsis thaliana. Proceedings of the National Academy of Sciences of the United States of America 107: 22332-22337.

[2]Yu F, Qian L, Nibau C, Duan Q, Kita D, Levasseur K, Li X, Lu C, Li H, Hou C, Li L, Buchanan BB*, Chen L*, Cheung AY, Li D*, Luan S* (2012) FERONIA receptor kinase pathway suppresses abscisic acid signaling in Arabidopsis by activating ABI2 phosphatase. Proceedings of the National Academy of Sciences of the United States of America 109: 14693-14698.

[3]Yu F, Li J, Huang Y, Liu L, Li D*, Chen L*, Luan S* (2014a) FERONIA receptor kinase controls seed size in Arabidopsis thaliana. Molecular Plant 7: 920-922. ESI highly cited paper.

[4]Yu F#, Tian W#, Luan S* (2014b) From receptor-like kinases to calcium spikes: what are the missing links? Molecular Plant 7: 1501-1504.

[5]Yu D#,Yu F#, Du C, Li X, Zhao X*, Liu X* (2015) RPN1a, a subunit of the 26S proteasome, controls trichome development in Arabidopsis. Plant Physiology and Biochemistry 88: 82-88.

[6]Mao D#,Yu F#*, Li J, Van de Poel B, Tan D, Li J, Liu Y, Li X, Dong M, Chen L*, Li D, Luan S* (2015) FERONIA receptor kinase interacts with S-adenosylmethionine synthetase and suppresses S-adenosylmethionine production and ethylene biosynthesis in Arabidopsis. Plant, Cell and Environment 38: 2566-2574. ESI highly cited paper.

[7]Yang T#, Wang L#, Li C, Liu Y, Zhu S, Qi Y, Liu X, Lin Q*, Luan S,Yu F* (2015) Receptor protein kinase FERONIA controls leaf starch accumulation by interacting with glyceraldehyde-3-phosphate dehydrogenase. Biochemical and Biophysical Research Communications 465: 77-82.

[8]Chen J#,Yu F#*, Liu Y, Du C, Li X, Zhu S, Wang X, Lan W, Rodriguez PL, Liu X, Li D, Chen L, Luan S* (2016) FERONIA interacts with ABI2-type phosphatases to facilitate signaling cross-talk between abscisic acid and RALF peptide in Arabidopsis. Proceedings of the National Academy of Sciences of the United States of America 113: E5519-E5527. ESI highly cited paper.

[9]Yu D#, Li X#, Zhao X#, Du C, Chen J, Li C, Sun M, Wang L, Lin J, Tang D,Yu F*, Liu X* (2016) RPN1a negatively regulates ABA signaling in Arabidopsis. Plant Physiology and Biochemistry 108: 279-285.

[10]Yu F, Luan S* (2016) Peptide signaling in plants: finding partners is the key. Cell Research 26: 755-756.

[11]Du C#, Li X#, Chen J#, Chen W, Li B, Li C, Wang L, Li J, Zhao X, Lin J, Liu X*, Luan S*,Yu F* (2016) Receptor kinase complex transmits RALF peptide signal to inhibit root growth in Arabidopsis. Proceedings of the National Academy of Sciences of the United States of America 113: E8326-E8334. ESI highly cited paper.

[12]Li C#, Wang L#, Cui Y, He L, Qi Y, Zhang J, Lin J, Liao H, Lin Q, Yang T,Yu F*, Liu X* (2016) Two FERONIA-like receptor (FLR) genes are required to maintain architecture, fertility, and seed yield in rice. Molecular Breeding 36: 151.

[13]Yu F(2016) Molecular mechanism of cross-talk between abscisic acid and RALF peptide in Arabidopsis. Science Foundation in China 24: 50.

[14]Liao H, Tang R, Zhang X, Luan S*,Yu F* (2017) FERONIA receptor kinase at the crossroads of hormone signaling and stress responses. Plant and Cell Physiology 58: 1143-1150.

[15]Lu C#,Yu F#, Tian L#, Huang X, Tan H, Xie Z, Hao X, Li D*, Luan S*, Chen L* (2017) RPS9M, a mitochondrial ribosomal protein, is essential for central cell maturation and endosperm development in Arabidopsis. Frontiers in Plant Science 8: 2171.

[16]Li C#, Liu X#, Qiang X, Li X, Li X, Zhu S, Wang L, Wang Y, Liao H, Luan S,Yu F* (2018) EBP1 nuclear accumulation negatively feeds back on FERONIA-mediated RALF1 signaling. PLOS Biology 16: e2006340. Weekly cover storyHighlighted by Stegmann M (2018) EBP1: A crucial growth regulator downstream of receptor kinases across kingdoms. PLOS Biology 16: e3000056.

[17]于峰（2019） 类受体激酶——植物环境适应性的调节枢纽.生物技术通报35: 1.

[18]强晓楠，李鑫，陈佳，廖红东，于峰*（2019） 拟南芥RALF多肽家族的功能多样性初步分析.生物技术通报35: 2-10.封面论文

[19]Xu G#, Chen W#, Song L, Chen Q, Zhang H, Liao H, Zhao G, Lin F, Zhou H*,Yu F*. (2019) FERONIA phosphorylates E3 ubiquitin ligase ATL6 to modulate the stability of 14-3-3 proteins in response to the carbon/nitrogen ratio. Journal of Experimental Botany 70: 6375-6388.

[20]Yang Z#, Xing J#*, Wang L#, Liu Y, Qu J, Tan Y, Fu X, Lin Q, Deng H*,Yu F*. (2020) Mutations of two FERONIA-like receptor genes enhance rice blast resistance without growth penalty. Journal of Experimental Botany 71: 2112-2126.

[21]Wang L#, Yang T#, Lin Q*, Wang B, Li X, Luan S,Yu F* (2020) Receptor kinase FERONIA regulates flowering time in Arabidopsis. BMC Plant Biology 20: 26.

[22]Zhu S#, Estévez JM#, Liao H, Zhu Y, Yang T, Li C, Wang Y, Li L, Liu X, Pacheco JM, Guo H,Yu F* (2020) The RALF1-FERONIA complex phosphorylates eIF4E1 to promote protein synthesis and polar root hair growth. Molecular Plant 13: 698-716. Cover story.

[23]Zhu S#, Martínez Pacheco J#, Estevez JM*,Yu F*. (2020) Autocrine regulation of root hair size by the RALF-FERONIA-RSL4 signaling pathway. New Phytologist 227: 45-49.

[24]Chen J, Zhu S, Ming Z, Liu X*,Yu F* (2020) FERONIA cytoplasmic domain: node of varied signal outputs. aBIOTECH 1: 135-146.

[25]Wang L#, Yang T#, Wang B, Lin Q*, Zhu S, Li C, Ma Y, Tang J, Xing J, Li X, Liao H, Staiger D, Hu Z,Yu F* (2020) RALF1-FERONIA complex affects splicing dynamics to modulate stress responses and growth in plants. Science Advances 6: eaaz1622.

[26]Yu M#, Li R#, Cui Y, Chen W, Li B, Zhang X, Bu Y, Cao Y, Xing J, Jewaria PK, Li X, Bhalerao RP,Yu F*, Lin J* (2020) The RALF1-FERONIA interaction modulates endocytosis to mediate control of root growth in Arabidopsis. Development 147: dev189902.

[27]Zhang X#, Yang Z#, Wu D,Yu F* (2020a) RALF-FERONIA signaling: linking plant immune response with cell growth. Plant Communications 1: 100084.

[28]Zhang X#, Peng H#, Zhu S#, Xing J, Li X, Zhu Z, Zheng J, Wang L, Wang B, Chen J, Ming Z, Yao K, Jian J, Luan S, Coleman-Derr D, Liao H*, Peng Y*, Peng D,Yu F* (2020b) Nematode-encoded RALF peptide mimics facilitate parasitism of plants through the FERONIA receptor kinase. Molecular Plant 13: 1434-1454.

[29]Chen H#, Kong Y#, Chen J, Li L, Li X,Yu F*, Ming Z* (2020) Crystal structure of the extracellular domain of the receptor-like kinase TMK3 from Arabidopsis thaliana. Acta Crystallographica Section F, Structural Biology Communications F76: 384-390.

[30]Wang L#, Wang D#, Yang Z#, Jiang S, Qu J, He W, Liu Z, Xing J, Ma Y, Lin Q*,Yu F* (2021) Roles of FERONIA-like receptor genes in regulating grain size and quality in rice. Science China life Sciences 64: 294-310.

[31]Li L#, Li B#, Zhu S, Wang L, Song L, Chen J, Ming Z, Liu X*, Li X*,Yu F* (2021) TMK4 receptor kinase negatively modulates ABA signaling by phosphorylating ABI2 and enhancing its activity. Journal of Integrative Plant Biology 63: 1161-1178.

[32]Zhu S, Fu Q, Xu F, Zheng H,Yu F* (2021) New paradigms in cell adaptation: decades of discoveries on the CrRLK1L receptor kinase signalling network. New Phytologist 232: 1168-1183.

[33]Wu D#, Wang L#, Zhang Y, Bai L*,Yu F* (2021) Emerging roles of pathogen-secreted host mimics in plant disease development. Trends in Parasitology 37: 1082-1095.

[34]He W#, Wang L#, Lin Q*,Yu F* (2021) Rice seed storage proteins: Biosynthetic pathways and the effects of environmental factors. Journal of Integrative Plant Biology 63: 1999-2019.

[35]Tang J#, Wu D#, Li X, Wang L, Xu L, Zhang Y, Xu F, Liu H, Xie Q, Dai S, Coleman-Derr D, Zhu S,Yu F* (2022) Plant immunity suppression via PHR1-RALF-FERONIA shapes the root microbiome to alleviate phosphate starvation. The EMBO Journal 41: e109102.

[36]Song L#, Xu G#, Li T#, Zhou H, Lin Q, Chen J, Wang L, Wu D, Li X, Wang L, Zhu S*,Yu F* (2022) The RALF1-FERONIA complex interacts with and activates TOR signaling in response to low nutrients. Molecular Plant 15: 1120-1136. Cover Story

[37]Liu Z#, Jiang S#, Jiang L, Li W, Tang Y, He W, Wang M, Xing J, Cui Y, Lin Q*,Yu F*, Wang L * (2022) Transcription factor OsSGL is a regulator of starch synthesis and grain quality in rice. Journal of Experimental Botany 73: 3417-3430.

[38]Chen W#, Hu Z#, Yu M, Zhu S, Xing J, Song L, Pu W*,Yu F* (2022) A molecular link between autophagy and circadian rhythm in plants. Journal of Integrative Plant Biology 64: 1044-1058.

[39]Li C#, Chen J#, Li X, Zhang X, Liu Y, Zhu S, Wang L, Zheng H, Luan S, Li J,Yu F* (2022) FERONIA is involved in phototropin 1-mediated blue light phototropic growth in Arabidopsis. Journal of Integrative Plant Biology 64: 1901-1915. Cover Story

[40]Wang B#, Wang S#, Tang Y, Jiang L, He W, Lin Q,Yu F*, Wang L* (2022) Transcriptome-wide characterization of seed aging in rice: identification of specific long-lived mRNAs for seed longevity. Frontiers in Plant Science 13: 857390.

[41]李迎宾，于峰* (2022)揭开“植物细胞感知胞外酸碱性”之谜.科学通报67: 4039-4040.

[42]Liu HB#, Li X#, Cai J, Jiang LL, Zhang X, Wu D, Wang L, Yang A, Guo C, Chen J*, Pu W*,Yu F* (2023) A screening of inhibitors targeting the receptor kinase FERONIA reveals small molecules that enhance plant root immunity. Plant Biotechnology Journal 21: 63-77.

[43]Chen W#, Zhou H#, Xu F, Yu M, Coego A, Rodriguez L, Lu Y, Xie Q, Fu Q, Chen J, Xu G, Wu D, Li X, Li X; Jaillais Y, Rodriguez PL, Zhu S,Yu F* (2023) CAR modulates plasma membrane nano-organization and immune signaling downstream of RALF1-FERONIA signaling pathway. New Phytologist 237: 2148-2162.

[44]Sui J#, Xiao X#, Yang J, Fan Y, Zhu S, Zhu J, Zhou B,Yu F*, Tang C* (2023) The rubber tree RALF peptide hormone and its receptor protein kinase FER implicates in rubber production. Plant Science 326: 111510.

[45]Wang L#, Xu F#,Yu F* (2023) Two environmental signal-driven RNA metabolic processes: alternative splicing and translation. Plant, Cell and Environment 46: 718-732.

[46]Pacheco JM#, Song L#, Kuběnová L, Ovečka M, Berdion Gabarain V, Peralta JM, Lehuedé TU, Ibeas MA, Ricardi MM, Zhu S, Shen Y, Schepetilnikov M, Ryabova LA, Alvarez JM, Gutierrez RA, Grossmann G, Šamaj J,Yu F*, Estevez JM* (2023) Cell surface receptor kinase FERONIA linked to nutrient sensor TORC signaling controls root hair growth at low temperature linked to low nitrate in Arabidopsis thaliana. New Phytologist 238:169-185.

[47]Kong Y#, Chen J#, Jiang L, Chen H, Shen Y, Wang L, Yan Y, Zhou H, Zheng H,Yu F*, Ming Z* (2023) Structural and biochemical basis of Arabidopsis FERONIA receptor kinase-mediated early signaling initiation. Plant Communications 4:100559.

[48]Cai J#, Jiang Y#, Ritchie ES, Macho AP*,Yu F*, Wu D* (2023) Manipulation of plant metabolism by pathogen effectors: more than just food. FEMS Microbiology Reviews 47: 1-16.

[49]Zhao K#, Wang L#, Qiu D#, Cao Z, Wang K, Li Z, Wang X, Wang J, Ma Q, Cao D, Qi Y, Zhao K, Gong F, Li Z, Ren R, Ma X, Zhang X,Yu F*, Yin D* (2023) PSW1, an LRR receptor kinase, regulates pod size in peanut. Plant Biotechnology Journal 21: 2113-2124.

[50]Li Y#, Gao J#, Wang Y, Cai J, Wu D, Wang L, Pu W*,Yu F*, Zhu S* (2023) The functions of a 5' tRNA-Ala-derived fragment in gene expression. Plant Physiology 193: 1126-1141.

[51]Xu F,Yu F* (2023) Sensing and regulation of plant extracellular pH. Trends in Plant Science 28: 1422-1437.

[52]Zhu S#, Li Y#, Wu Y, Shen Y, Wang Y, Yan Y, Chen W, Fu Q, Wang Y, Yu X,Yu F* (2023) The FERONIA-YUELAO module participates in translational control by modulating the abundance of tRNA fragments in Arabidopsis. Developmental Cell. 58: 2930-2946.e9.

[53]Liu H, Sun H, Du L, Jiang L, Zhang L, Qi Y, Cai J,Yu F* (2024) Rice receptor kinase FLR7 regulates rhizosphere oxygen levels and enriches the dominant Anaeromyxobacter that improves submergence tolerance in rice. The ISME Journal. 18: wrae006.

[54]Xu F#, Chen J#, Li Y, Ouyang S, Yu M, Wang Y, Fang X, He K,Yu F* (2024) The soil emergence-related transcription factor PIF3 regulates root penetration by interacting with the receptor kinase FER. Developmental Cell. 59: 434-447.e8.

[55]Xu F#, Wang L#, Li Y, Shi J, Staiger D,Yu F* (2024) Phase separation of GRP7 facilitated by FERONIA-mediated phosphorylation inhibits mRNA translation to modulate plant temperature resilience. Molecular Plant. 17: 460-477.

[56]Fu Q#, Liu Q#, Zhang R, Chen J, Guo H, Ming Z*,Yu F*, Zheng H* (2024) Large-scale analysis of the N-terminal regulatory elements of the kinase domain in plant receptor-like kinase family. BMC Plant Biology. 24: 174.

[57]Liu Q#, Fu Q#, Yan Y, Jiang Q, Mao L, Wang L,Yu F*, Zheng H* (2024) Curation, nomenclature, and topological classification of Receptor-like kinases from 528 plant species for novel domain discovery and functional inference. Molecular Plant. In press.

[58]Chen J,Yu F*, Xu F* (2024) Not just signals: RALFs as cell wall-structuring peptides. Trends in Plant Science. In press.

[59]Li Y#, Lin J#, Li L, Peng Y, Wang W, Zhou Y, Tang D, Zhao X,Yu F, Liu X* (2016) DHHC-cysteine-rich domain S-acyltransferase protein family in rice: organization, phylogenetic relationship and expression pattern during development and stress. Plant Systematics and Evolution 302: 1405-1417.

[60]Zhou YB#, Liu C#, Tang DY#, Yan L#, Wang D, Yang YZ, Gui JS, Zhao XY, Li LG, Tang XD,Yu F, Li JL, Liu LL, Zhu YH, Lin JZ*, Liu XM* (2018) The receptor-like cytoplasmic kinase STRK1 phosphorylates and activates CatC, thereby regulating H2O2 homeostasis and improving salt tolerance in rice. The Plant Cell 30: 1100-1118.

[61]Zeng S, Liu D, Li C,Yu F, Fan L, Lei C*, Huang Y*, Nie Z*, Yao S (2018) Cell-surface-anchored ratiometric DNA tweezer for real-time monitoring of extracellular and apoplastic pH. Analytical Chemistry 90: 13459-13466.

[62]Lu C#, Xie Z#,Yu F, Tian L, Hao X, Wang X, Chen L*, Li D* (2020) Mitochondrial ribosomal protein S9M is involved in male gametogenesis and seed development in Arabidopsis. Plant Biology 22: 655-667.

[63]Zhang X#, Wang D#, Chen J, Wu D*, Feng X*,Yu F(2021) Nematode RALF-like 1 targets soybean malectin-like receptor kinase to facilitate parasitism. Frontiers in Plant Science 12: 775508.

[64]Liu X#, Cai J#, Li X,Yu F, Wu D* (2022) Can bacterial type III effectors mediate pathogen-plant-microbiota ternary interactions? Plant, Cell and Environment 45: 5-11.

发明专利：

[1]一种烟草NbFER基因及其在烟草种植中的作用。于峰、徐国云、汪龙，201510399271.3

[2]一种水稻OsFLRs基因及其应用。汪龙、林亲录、于峰、杨涛、李驰宇、刘选明，201610914213.4

[3]根结线虫RALF蛋白质、编码基因及其应用。于峰、张鑫、廖红东、彭焕、彭德良，201911333833.9

[4]一种基因FERONIA的应用。宋丽梅、于峰、李婷婷，202010135008.4

[5]激酶抑制剂Reversine在提高植物青枯病抗性的应用。于峰、刘红斌、汪龙、伍斗生、李晓旭，202110131369.6

[6]激酶抑制剂LavendustinA在提高植物青枯病抗性的应用。汪龙、于峰、刘红斌、伍斗生、李晓旭，202110131381.7

[1]2021，卫志明青年创新奖

[2]2021，高等学校科学研究优秀成果奖(科学技术)二等奖 （排名第二）

[3]2017，教育部青年CJ学者

[4]2017，湖南大学“优秀教师”

[5]2017，湖南大学“优秀共产党员”

[6]2016，中国科协“青年人才托举计划”

[7]2015，湖南省优秀博士论文

[8]2013，湖南省优秀毕业生

[9]2013，首届研究生国家奖学金(博士)

[10]2012，湖南省芙蓉学子-学术科研奖