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殷冬梅

发布时间: 2024-02-20 08:18 点击数:
殷冬梅,女,博士,二级教授,博士生导师。国家高层次人才特殊支持计划领军人才,国务院特殊津贴专家,百千万人才工程国家级人选,国家有突出贡献中青年专家,教育部新世纪优秀人才,河南省优秀专家、中原学者。
职  称:教授(二级)
性    别:女
电子邮件:yindm@126.com,yindm@henau.edu.cn
所属创新团队:花生功能基因组与分子育种创新团队首席科学家
 
教育经历
1991-1995  华中农业大学农学专业攻读学士学位;
2000-2003  河南农业大学遗传育种专业攻读硕士学位;
2003-2006  河南农业大学遗传育种专业攻读博士学位;
2009-2012  中国科学院遗传与发育生物学研究所从事博士后研究。
 
工作经历
1995-2003 河南省农科院经作所从事花生遗传育种工作;
2006-2012  河南农业大学  讲师,副教授;
2013-2020    河南农业大学  教授;
2012年至今   河南省花生产业技术体系岗位专家;
2014.7-2015.6   美国Tuskegee University访问学者;
2015-2020    河南省高等学校特聘教授;
2021年至今  河南省二级岗位教授。
 
研究方向
花生功能基因组、种质创制与分子育种
学术兼职
中国绿色食品协会花生专业委员会副主任
中国作物学会油料作物专业委员会常务委员
国际期刊《Reproduction and Breeding》副主编
 
荣誉称号
国家“万人计划”科技创新领军人才
百千万人才工程国家级人选
国务院特殊津贴专家
国家有突出贡献中青年专家
教育部新世纪优秀人才
中原学者
河南省优秀专家
中原千人计划-基础研究领军人才
河南省科技创新杰出人才、杰出青年
河南省现代农业产业技术体系岗位专家
河南省先进工作者
河南省B类人才
 
获奖成果
1. 花生高产优质遗传基础解析与新品种研制及应用。教育部科学技术进步奖一等奖(第1完成人)(2020年);
2. 花生种子发育遗传解析与高产优质新品种培育及应用。河南省技术进步奖一等奖(第1完成人)(2024年);
3. 花生种质资源创制与新品种培育。河南省科学技术进步奖二等奖(第1完成人)(2016年);
4. 优质高产早熟大果花生新品种豫花7号。国家科学技术进步奖二等奖(第8完成人)(2001年);
5. 优质高产多抗矮杆花生新品种远杂9102。河南省科学技术进步奖一等奖(第7完成人)(2009年);
6. 花生功能基因组与种子发育遗传调控机制及育种应用。河南省教育厅科技成果奖一等奖(第1完成人)(2022年)。
 
主要承担科研项目(主持)
1.国家自然科学基金联合重点项目“花生荚果长和果重驯化性状关键基因功能及分子调控机制解析”,2023年至2026年,经费256万元;
2.国家自然科学基金联合重点项目“花生株型分子遗传调控网络及关键基因的功能解析”,2018年至2021年,经费230万元;
3.国家自然科学基金项目“花生油脂形成的基因网络解析及关键基因的功能研究”,2015年至2018年,经费83万元;
4.河南省重点研发专项“花生高产优质遗传基础解析与新品种设计育种”,2022年至2024年,经费130万元;
5. 中原千人计划-基础研究领军人才,2019-2021,经费100万;
6. 河南省现代农业产业技术体系岗位专家,2012-2026,经费420万;
 
审定品种
农大花103;农大花108;农大花206;农大黑7572;农大花201;农大花107;农大花7601;农大花7567;豫科花1号,豫科花2号,豫科花3号,豫科花6号
 
主要代表作(第一作者或通讯作者)
1. Zhao, K., Xue, H., Li, G., Chitikineni, A., Fan, Y., Cao, Z., Dong, X., Lu, H., Zhao, K., Zhang, L., Qiu, D., Ren, R., Gong, F., Li, Z., Ma, X., Wan, S., Varshney, R. K., Wei, C., & Yin, D. (2025). Pangenome analysis reveals structural variation associated with seed size and weight traits in peanut. Nature Genetics. https://doi.org/10.1038/s41588-025-02170-w
2. Zhao, K., Zhang, J., Fan, Y., Du, X., Zhu, S., Li, Z., Qiu, D., Cao, Z., Ma, Q., Li, Y., Cao, D., Hu, S., Zhao, K., Gong, F., Ren, R., Ma, X., Zhang, X., & Yin, D. (2025). PSC1, a basic/helix–loop–helix transcription factor controlling the purplish‐red testa trait in peanut. Journal of Integrative Plant Biology, jipb.13847. https://doi.org/10.1111/jipb.13847
3. Xue, H., Zhao, K., Dong, X., Ma, Q., Hu, S., Cao, Z., Shu, Y., Li, Y., Huang, X., Zhao, K., Qiu, D., Shao, W., Ren, R., Li, Z., Gong, F., Ma, X., Wei, C., & Yin, D. (2026). PeanutOmics: A comprehensive platform with an integrative multi-omics atlas for peanut research. Plant Communications, 7(1), 101622. https://doi.org/10.1016/j.xplc.2025.101622
4. Cao, Z., Zhao, K., Li, H., Ma, X., Cao, D., Li, Y., Hu, S., Ma, Q., Li, Y., Fan, Y., Hou, M., Zhao, K., Qiu, D., Gong, F., Li, Z., Ren, R., & Yin, D. (2026). AhBWR15, A Novel RLK Gene, Confers Resistance to Ralstonia solanacearum in Peanut. Plant Biotechnology Journal, https://onlinelibrary.wiley.com/doi/10.1111/pbi.70605
5. Hou, M., Li, H., Cao, Z., Wang, F., Hu, S., Li, Y., Ma, Q., Li, Y., Fan, Y., Zhao, K., Zhao, K., Qiu, D., Gong, F., Li, Z., Ma, X., Ren, R., & Yin, D. (2026). AhNHL24 enhances peanut resistance to bacterial wilt and stem rot via glutathione and phenylpropanoid pathways. Plant Science, 362, 112791. https://doi.org/10.1016/j.plantsci.2025.112791
6. Ren, R., Cao, Z., Ma, X., Li, Z., Zhao, K., Cao, D., Ma, Q., Hou, M., Zhao, K., Zhang, L., Qiu, D., Gong, F., Zhang, X., Liu, H., & Yin, D. (2025). Multi‐Omics Analysis Reveals That AhNHL Contributes to Melatonin‐Mediated Cadmium Tolerance in Peanut Plants. Journal of Pineal Research, 77(2), e70035. https://doi.org/10.1111/jpi.70035
7. Li, Z., Zhang, Y., Liu, Y., Fan, Y., Qiu, D., Li, Z., Zhou, Y., Gong, F., & Yin, D. (2025). Comprehensive analysis of high-oil peanut cultivars in China: Agronomic performance, disease resistance, and breeding insights. Reproduction and Breeding, 5(3), 102~109. https://doi.org/10.1016/j.repbre.2025.06.001
8. Zhao, K., Li, Y., Cao, Z., Tu, Y., Guo, Y., Qiu, J., Ma, X., Gong, F., Li, Z., Zhang, L., Qiu, D., Ren, R., Zhao, K., & Yin, D. (2025). The Homocysteine S-Methyltransferase Family and Functional Analysis of AhEXF4LS Resistance to Bacterial Wilt in Peanut. Journal of Agricultural and Food Chemistry, 73(36), 22672~22683. https://doi.org/10.1021/acs.jafc.5c09751
9. Zhao, K., Li, Y., Li, Z., Cao, Z., Ma, X., Ren, R., Wang, K., Meng, L., Yang, Y., Yao, M., Yang, Y., Wang, X., Wang, J., Hu, S., Li, Y., Ma, Q., Cao, D., Zhao, K., Qiu, D., & Yin, D. (2025). Genome-wide analysis of AhCN genes reveals that AhCN34 is involved in bacterial wilt resistance in peanut. Journal of Integrative Agriculture, 24(10), 3757~3771. https://doi.org/10.1016/j.jia.2024.03.006
10. Hou, M., Li, H., Cao, Z., Wang, F., Hu, S., Li, Y., Ma, Q., Li, Y., Fan, Y., Zhao, K., Zhao, K., Qiu, D., Gong, F., Li, Z., Ma, X., Ren, R., & Yin, D. (2026). AhNHL24 enhances peanut resistance to bacterial wilt and stem rot via glutathione and phenylpropanoid pathways. Plant Science, 362, 112791. https://doi.org/10.1016/j.plantsci.2025.112791
11. Li, H., Hou, M., Cao, Z., Dang, Y., Li, Q., Li, Y., Ma, Q., Li, Y., Hu, S., Fan, Y., Zhao, K., Zhao, K., Qiu, D., Gong, F., Li, Z., Ma, X., Ren, R., & Yin, D. (2025). Genome‐Wide Identification of the Pathogenesis‐Related Superfamily Genes in Peanut Resistance Against Ralstonia solanacearum.Physiologia Plantarum, 177(6), e70689. https://doi.org/10.1111/ppl.70689
12. Li, Z., Zhang, Y., Liu, Y., Fan, Y., Qiu, D., Li, Z., Gong, F., & Yin, D. (2025). Research Progress on High-Protein Peanut (Arachis hypogaea L.) Varieties in China. Plants, 14(18), 2917. https://doi.org/10.3390/plants14182917
13. Zhao, K., Li, Y., Wang, J., Tu, Y., Cao, Z., Ma, X., Gong, F., Li, Z., Zhang, L., Qiu, D., Zhang, X., Ren, R., Zhao, K., & Yin, D. (2025). Genome-wide characterization of AhBAG genes in peanut reveals their role in bacterial wilt resistance and hormone response. BMC Plant Biology, 25(1), 513. https://doi.org/10.1186/s12870-025-06552-4
14. Xue, H., Zhao, K., Zhao, K., Han, S., Chitikineni, A., Zhang, L., Qiu, D., Ren, R., Gong, F., Li, Z., Ma, X., Zhang, X., Varshney, R. K., Zhang, X., Wei, C., & Yin, D. (2024). A near complete genome of Arachis monticola, an allotetraploid wild peanut. Plant Biotechnology Journal, 22(8), 2110~2112. https://doi.org/10.1111/pbi.14331
15. Cao, D., Ma, Y., Cao, Z., Hu, S., Li, Z., Li, Y., Wang, K., Wang, X., Wang, J., Zhao, K., Zhao, K., Qiu, D., Li, Z., Ren, R., Ma, X., Zhang, X., Gong, F., Jung, M. Y., & Yin, D. (2024). Coordinated Lipid Mobilization during Seed Development and Germination in Peanut ( Arachis hypogaea L.). Journal of Agricultural and Food Chemistry, 72(6), 3218~3230. https://doi.org/10.1021/acs.jafc.3c06697
16. Cao, Z., Li, Z., Meng, L., Cao, D., Zhao, K., Hu, S., Li, Y., Zhao, K., Ma, Q., Li, Y., Fan, Y., Ma, X., Gong, F., Li, Z., Qiu, D., Zhang, L., Zhang, X., Ren, R., & Yin, D. (2024). Genome-wide characterization of pyrabactin resistance 1-like (PYL) family genes revealed AhPYL6 confer the resistance to Ralstonia solanacearum in peanut. Plant Physiology and Biochemistry, 217, 109295. https://doi.org/10.1016/j.plaphy.2024.109295
17. Gong, F., Cao, D., Sun, X., Li, Z., Qu, C., Fan, Y., Cao, Z., Zhao, K., Zhao, K., Qiu, D., Li, Z., Ren, R., Ma, X., Zhang, X., & Yin, D. (2024). Homologous mapping yielded a comprehensive predicted protein–protein interaction network for peanut (Arachis hypogaea L.). BMC Plant Biology, 24(1), 873. https://doi.org/10.1186/s12870-024-05580-w
18. Li, Z., Cao, Z., Ma, X., Cao, D., Zhao, K., Zhao, K., Ma, Q., Gong, F., Li, Z., Qiu, D., Zhang, X., Liu, H., Ren, R., & Yin, D. (2024). Natural resistance-associated macrophage proteins are involved in tolerance to heavy metal Cd2+ toxicity and resistance to bacterial wilt of peanut (Arachis hypogaea L.). Plant Physiology and Biochemistry, 207, 108411. https://doi.org/10.1016/j.plaphy.2024.108411
19. Gong, F., Cao, D., Li, Z., Fan, Y., Zhang, Y., Zhang, L., Zhao, K., Qiu, D., Li, Z., Ren, R., Ma, X., Zhang, X., Zhao, K., & Yin, D. (2024). Metabolomic and Transcriptomic Analysis Reveals Flavonoid-Mediated Regulation of Seed Antioxidant Properties in Peanut Seed Vigor. Antioxidants, 13(12), 1497. https://doi.org/10.3390/antiox13121497
20. Gong, F., Li, Z., Sun, X., Fan, Y., Liu, Y., Dang, Y., Li, H., Zhang, X., Ma, X., Li, Z., Zhao, K., & Yin, D. (2024). Comprehensive analysis and selection of high oleic peanut varieties in China: A study on agronomic, yield, and quality traits. Oil Crop Science, 9(4), 265~274. https://doi.org/10.1016/j.ocsci.2024.09.001
21. Zhao, K., Du, X., Zhang, J., Fan, Y., Ma, Q., Li, Y., Cao, Z., Cao, D., Hu, S., Qiu, D., Zhao, K., Gong, F., Li, Z., Ren, R., Zhang, L., Ma, X., Zhang, X., & Yin, D. (2024). Fine mapping of a major QTL on chromosome A05 conferring pod size in peanut. The Crop Journal, 12(6), 1745~1753. https://doi.org/10.1016/j.cj.2024.10.009
22. Zhao, K., Li, Z., Ke, Y., Ren, R., Cao, Z., Li, Z., Wang, K., Wang, X., Wang, J., Ma, Q., Cao, D., Zhao, K., Li, Y., Hu, S., Qiu, D., Gong, F., Ma, X., Zhang, X., Fan, G., & Yin, D. (2024). Dynamic N6 ‐methyladenosine RNA modification regulates peanut resistance to bacterial wilt. New Phytologist, 242(1), 231~246. https://doi.org/10.1111/nph.19568
23. 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(10), 2113~2124. https://doi.org/10.1111/pbi.14117
24. Li, Z., Liu, Q., Zhao, K., Cao, D., Cao, Z., Zhao, K., Ma, Q., Zhai, G., Hu, S., Li, Z., Wang, K., Gong, F., Ma, X., Zhang, X., Ren, R., Qiu, D., Zhao, Y., & Yin, D. (2023). Dynamic DNA methylation modification in peanut seed development. iScience, 26(7), 107062. https://doi.org/10.1016/j.isci.2023.107062
25. Zhao, K., Ren, R., Ma, X., Zhao, K., Qu, C., Cao, D., Ma, Q., Ma, Y., Gong, F., Li, Z., Zhang, X., & Yin, D. (2022). Genome-wide investigation of defensin genes in peanut (Arachis hypogaea L.) reveals AhDef2.2 conferring resistance to bacterial wilt. The Crop Journal, 10(3), 809~819. https://doi.org/10.1016/j.cj.2021.11.002
26. Zhang, X., Pandey, M. K., Wang, J., Zhao, K., Ma, X., Li, Z., Zhao, K., Gong, F., Guo, B., Varshney, R. K., & Yin, D. (2021). Chromatin spatial organization of wild type and mutant peanuts reveals high-resolution genomic architecture and interaction alterations. Genome Biology, 22(1), 315. https://doi.org/10.1186/s13059-021-02520-x
27. Li, Z., Zhang, X., Zhao, K., Zhao, K., Qu, C., Gao, G., Gong, F., Ma, X., & Yin, D. (2021). Comprehensive Transcriptome Analyses Reveal Candidate Genes for Variation in Seed Size/Weight During Peanut (Arachis hypogaea L.) Domestication. Frontiers in Plant Science, 12, 666483. https://doi.org/10.3389/fpls.2021.666483
28. Gao, G., Zhang, X., Zhao, K., Zhao, K., Cao, D., Ma, Q., Zhu, S., Qu, C., Ma, Y., Gong, F., Li, Z., Ren, R., Ma, X., & Yin, D. (2021). Genome wide identification and expression analysis of patatin-like protein family members in peanut (Arachis hypogaea L.). Reproduction and Breeding, 1(1), 48~54. https://doi.org/10.1016/j.repbre.2021.03.002
29. Li, P., Ma, Q., Qu, C., Zhu, S., Zhao, K., Ma, X., Li, Z., Zhang, X., Gong, F., & Yin, D. (2021). Genome-wide identification and expression analysis of auxin response factors in peanut ( Arachis hypogaea L.). PeerJ, 9, e12319. https://doi.org/10.7717/peerj.12319
30. Ma, X., Zhang, X., Traore, S. M., Xin, Z., Ning, L., Li, K., Zhao, K., Li, Z., He, G., & Yin, D. (2020). Genome-wide identification and analysis of long noncoding RNAs (lncRNAs) during seed development in peanut (Arachis hypogaea L.). BMC Plant Biology, 20(1), 192. https://doi.org/10.1186/s12870-020-02405-4
31. Yin, D., Ji, C., Song, Q., Zhang, W., Zhang, X., Zhao, K., Chen, C. Y., Wang, C., He, G., Liang, Z., Ma, X., Li, Z., Tang, Y., Wang, Y., Li, K., Ning, L., Zhang, H., Zhao, K., Li, X., & Chen, Z. J. (2020). Comparison of Arachis monticola with Diploid and Cultivated Tetraploid Genomes Reveals Asymmetric Subgenome Evolution and Improvement of Peanut. Advanced Science, 7(4), 1901672. https://doi.org/10.1002/advs.201901672
32. Zhao, K., Li, K., Ning, L., He, J., Ma, X., Li, Z., Zhang, X., & Yin, D. (2019). Genome-Wide Analysis of the Growth-Regulating Factor Family in Peanut (Arachis hypogaea L.). International Journal of Molecular Sciences, 20(17), 4120. https://doi.org/10.3390/ijms20174120
33. Yin, D., Ji, C., Ma, X., Li, H., Zhang, W., Li, S., Liu, F., Zhao, K., Li, F., Li, K., Ning, L., He, J., Wang, Y., Zhao, F., Xie, Y., Zheng, H., Zhang, X., Zhang, Y., & Zhang, J. (2018). Genome of an allotetraploid wild peanut Arachis monticola: A de novo assembly. GigaScience, 7(6), giy066. https://doi.org/10.1093/gigascience/giy066
 
 
主要学术著作(主编或副主编)
1. 河南省花生主要病虫害图谱与综合防治,中国农业科学技术出版社,9787511628749,专著(独著)
2. 花生高油酸基因工程,中国农业科学技术出版社,9787511604248,专著(独著)
 
授权专利
1. 殷冬梅,张幸果,马兴立,王允,一种花生全基因组SNP开发方法,2021.4.16,中国,ZL201610952876.5;
2. 殷冬梅,崔党群,花生△12脂肪酸脱氢酶基因高效表达的方法,2010.5.10,中国,ZL200610128499.X;
3. 一种花生全基因组SNP开发方法,2021,201610952876.5
4. 一种荚果大小相关InDel分子标记及应用,2024,ZL202310785357.4
5. 花生种皮颜色调控相关基因AhPSC1及其相关应用,2024,ZL202311725963.3
6. 花生荚果大小相关基因AhPSW1及其应用,2024,ZL202310785354.0
7. 一种花生荚果大小相关分子标记InDel_XE的应用,2025,ZL20231 0785357.4
8. 一种种皮花青素调控相关的SNP分子标记及其应用,2025,ZL20241 0641645.7
9. 一种花生带壳播种装置及播种工艺,2025,ZL202510221642.2
10. 殷冬梅,张幸果,马兴立,植物新品种权(农大花103),中国,CNA20151982.9;
11. 殷冬梅,马兴立,张幸果,李忠峰,植物新品种权(农大花201),中国,CNA20211003666;
12. 殷冬梅,张幸果,马兴立,李忠峰,植物新品种权(农大黑7572),中国,CNA20211004547;
13. 殷冬梅,植物新品种权(农大紫7567),中国,CNA20211003512;
14. 殷冬梅,植物新品种权(农大花7601),中国,CNA20211003517;
15. 殷冬梅,植物新品种权(农大白7626),中国,CNA20211003665.
 

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