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李斌

发布日期:2024-09-20 09:33:17

   名:李斌

   别:男

   称:副研究员,硕士生导师

所在系别:作物遗传育种系

工作单位:中国农业科学院作物科学研究所

   话:010-82105805

电子邮箱:libin02@caas.cn





个人简历(学习/访学/工作简历

1999.09- 2003.07:山西大学,生物科学专业,理学学士;

2003.09- 2011.06:中科院遗传与发育生物学研究所,遗传学专业,理学博士;

2011.07-至今:中国农业科学院作物科学研究所 副研究员,硕士生导师。




研究领域

大豆产量品质性状形成遗传基础解析及分子育种




荣誉称号及社会兼职

1. 荣获首届阿里巴巴育种人才“青年科学家奖”,2021;

2. 入选所级“青年后备人才”,2021;

3. 担任中国农村专业技术协会大豆专业委员会秘书长,2018

4. 担任Agronomy期刊客座编辑,2023。



科研项目

1. 抗病虫高产大豆新品种设计与培育,科技创新2030重大项目,300万元,2023-2025,课题主持人。

2. 大豆油分和营养功能品质形成与改良的分子基础,国家重点研发计划,50万元,2016-2020,子课题主持人。

3. 大豆胞囊线虫抗性基因等位变异与小种特异性的关联分析,国家自然科学基金青年项目,23万元,2014-2016,主持人。

4. GmDOF3.7转录因子调控大豆油脂积累的分子机制研究,国家自然科学基金国际(地区)合作与交流项目,199万元,2022-2024,第二参加人。




◆授权专利

1. 孙君明、李斌、范胜栩、韩粉霞、闫淑荣、王连铮. 定性定量检测大豆脂肪酸组分的气相色谱方法,CN201510369719.7,发明专利,2017。

2. 孙君明、李斌、范胜栩、韩粉霞、闫淑荣、王连铮. 与大豆不饱和脂肪酸相对含量性状连锁的Indel标记及应用,CN201511021054.7,发明专利,2018。

3. 孙君明、张晟瑞、李斌、艾哈迈德·马布鲁克·阿卜杜勒法德尔·阿卜杜勒加尼、刘艺田、李静. 用于辅助鉴别大豆油脂含量高低的分子标记Oil-11-6708663、试剂盒和方法,CN202110678257.2,发明专利,2022。

4. 孙君明、张晟瑞、李斌、艾哈迈德·马布鲁克·阿卜杜勒法德尔·阿卜杜勒加尼、刘艺田、李静. 用于辅助鉴别大豆油脂含量高低的分子标记Oil-4-3776551、试剂盒和方法,CN202110677322.X,发明专利,2022。





◆审定品种

1. 孙君明、李斌、张晟瑞. 大豆,中黄106,北京市,京审豆20230001。

2. 孙君明、韩粉霞、李斌、张晟瑞. 大豆,中黄102,北京市,京审豆20210005。

3. 孙君明、王岚、赵荣娟、李斌、王连铮. 大豆,中黄73,国家,国审豆20200031。

4. 孙君明、韩粉霞、闫淑荣、杨华、李斌. 大豆,中黄78,国家,国审豆20180019。

5. 孙君明、韩粉霞、闫淑荣、杨华、李斌. 大豆,中黄203,国家,国审豆20231028。

6. 王连铮、孙君明、王岚、赵荣娟、李斌. 大豆,中黄45,国家,国审豆2014010。

7. 王连铮、孙君明、王岚、赵荣娟、李斌. 大豆,中黄54,国家,国审豆2012005。

8. 王连铮、赵荣娟、王岚、孙君明、李斌. 大豆,中黄67,北京市,京审豆2012004。





◆发表论文 #共同第一作者,*通讯作者)

1. Feng Y#Zhang S#Li J#Pei RTian LQi JAzam MAgyenim-Boateng K GShaibu A SLiu YZhu ZLi B*Sun J*. Dual-function C2H2-type zinc-finger transcription factor GmZFP7 contributes to isoflavone accumulation in soybean. New Phytologist, 2023, 237: 1794-1809


2. Agyenim-Boateng K G#Zhang S#Gu RZhang SQi JAzam·MMa CLi YFeng YLiu YLi JLi B*Qiu L*Sun·J*. Identification of quantitative trait loci and candidate genes for seed folate content in soybean. Theoretical and Applied Genetics, 2023, 136: 149


3. Azam M#Zhang S#Huai YAbdelghany AMShaibu ASQi JFeng YLiu YLi JQiu LLi B*Sun J*. Identification of genes for seed isoflavones based on bulk segregant analysis sequencing in soybean natural population. Theoretical and Applied Genetics, 2023, 136: 1-12


4. Zhang S#Abdelghany A M#Azam MQi JLi JFeng YLiu YFeng HMa CGebregziabher B SGhosh SAgyenim-Boateng K GShaibu A SHtway H T PWu TLi B*Q L*Sun J*. Mining candidate genes underlying seed oil content using BSA-seq in soybean. Industrial Crops and Products, 2023, 194: 116308


5. Gerbregziabher BS#Zhang S#Azam MQi JAgyenim-Boateng KGFeng YLiu YLi JLi B*Sun J*. Natural variation and geographical distribution of seed carotenoids and chlorophylls in 1167 Chinese soybean accessions. Journal of Integrative Agriculture, 2023, 22: 2632-2647


6. Azam M#Zhang S#Li J#Ahsan MAgyenim-Boateng K GQi JFeng YLiu YLi B*Qiu L*Sun J*. Identification of hub genes regulating isoflavone accumulation in soybean seeds via GWAS and WGCNA approaches. Frontier in Plant Science, 2023, 14: 1120498


7. Zhang S#Agyenim-Boateng KG#Zhang S#Gu YQi JAzam MMa CLi YFeng YLiu YLi JLi B*Qiu L*Sun J*. QTL mapping for seed tocopherol content in soybean. Agronomy, 2023, 13:1188


8. Agyenim-Boateng KG#Zhang S#Zhang SKhattak ANShaibu AAbdelghany AMQi JAzam MMa CFeng YFeng HLiu YLi JLi B*Sun J*. The nutritional composition of the vegetable soybean (maodou) and its potential in combatting malnutrition. Frontiers in Nutrition, 2023, 9:1034115


9. Shaibu A S#Zhang S#Ma JFeng YHuai YQi JLi JAbdelghany M AAzam MHtway T P HSun J*Li B*. The GmSNAP11 contributes to resistance to soybean cyst nematode race 4 in Glycine max. Frontiers in Plant Science, 2022, 13: 939763


10. Agyenim-Boateng K G #Zhang S#Islam S#Gu Y#Li B#Azam MAbdelghany AMQi JGhosh SShaibu A SGebregziabher BFeng YLi JLi YZhang CQiu LLiu Z*Liang Q*Sun J*. Profiling of naturally occurring folates in a diverse soybean germplasm by HPLC-MS/MS. Food Chemistry, 2022, 384: 132520


11. Qi JZhang SAzam MShaibu A SAbdelghany A MFeng YHuai YFeng HLiu YMa CGebregziabher B SGhosh SLi JLi B*Qiu L*Sun J*. Profiling seed soluble sugar compositions in 1164 Chinese soybean accessions from major growing ecoregions. The Crop Journal, 2022, 10: 1825-1831


12. Ghosh SZhang SAzam MGebregziabher B SAbdelghany A MShaibu A SQi JFeng YAgyenim-Boateng KLiu YFeng HLi YLi JLi B*Sun J*. Natural variation of seed tocopherol composition in diverse world soybean accessions from maturity group 0 to VI grown in China. Plants, 2022, 11: 206


13. Ghosh SZhang SAzam MAgyenim-Boateng KGQi JFeng YLi YLi JLi B*Sun J*. Identification of genomic loci and candidate genes related to seed tocopherol content in soybean. Plants, 2022, 11: 1703


14. Gebregziabher BSZhang SGhosh SShaibu ASAzam MAbdelghany AMQi JAgyenim-Boateng KGHtway HTPFeng YMa CLi YLi JLi B*Qiu L*Sun J*. Origin, maturity group and seed coat color influence carotenoid and chlorophyll concentrations in soybean seeds. Plants, 2022, 11: 848


15. Abdelghany A M#Zhang S#Azam MShaibu A SFeng YQi JLi JLi YTian YHong HLamlom S FLi B*Sun J*. Exploring the phenotypic stability of soybean seed compositions using multi-trait stability index approach. Agronomy, 2021, 11:2200


16. Azam M#Zhang S#Qi J#Abdelghany A M#Shaibu A SGhosh SFeng YHuai YGebregziabher B SLi JLi B*Sun J*. Profiling and associations of seed nutritional characteristics in Chinese and USA soybean cultivars. Journal of Food Composition and Analysis, 2021, 98: 103803


17. Gebregziabher B S#Zhang S#Qi JAzam MGhosh SFeng YHuai YLi JLi B*Sun J*. Simultaneous determination of carotenoids and chlorophylls by the HPLC-UV-VIS method in soybean seeds. Agronomy. 2021, 11: 758


18. Ghosh S#Zhang S#Azam M#Qi JAbdelghany M AShaibu S AGebregziabher S BFeng YHuai YHtway T P HAgyenim-Boateng G KLiu YFeng HLi JSong WLi B*Sun J*. Seed tocopherol assessment and geographical distribution of 1151 Chinese soybean accessions from diverse ecoregions. Journal of Food Composition and Analysis, 2021, 100: 103932


19. Azam M#Zhang S#Abdelghany M A#Shaibu S AFeng YLi YTian YHong HLi B*Sun J*. Seed isoflavone profiling of 1168 soybean accessions from major growing ecoregions in China. Food Research International, 2020. 130: 108957


20. Abdelghany A M#Zhang S#Azam M#Shaibu S AFeng YLi YTian YHong HLi B*Sun J*. Profiling of seed fatty acid composition in 1025 Chinese soybean accessions from different ecoregions. The Crop Journal, 2020, 8: 635-644


21. Shaibu A SLi B*Zhang SSun J*. Soybean cyst nematode resistance: Gene identification and breeding strategies. The Crop Journal, 2020, 8: 892-904


22. Abdelghany A M#Zhang S#Azam MShaibu A SFeng YQi JLi YTian YHong HLi B*Sun J*. Natural variation in fatty acid composition of diverse world soybean germplasms grown in China. Agronomy, 2020, 10: 24


23. Zhang S#Li B#Chen YShaibu A.SZheng HSun J*. Molecular-assisted distinctness and uniformity testing using SLAF-sequencing approach in soybean. Genes, 2020, 11: 175


24. Pei RZhang JTian LZhang SHan FYan SWang LLi B*Sun J*. Identification of novel QTL associated with soybean isoflavone content. The Crop Journal, 2018, 6: 244-252


25. Li BFan SYu FChen YZhang SHan FYan SWang LSun J*. High-resolution mapping of QTL for fatty acid composition in soybean using specific-locus amplified fragment sequencing. Theoretical and Applied Genetics, 2017, 130: 1467-1479


26. Zhang J#; Li B#; Yang YMu PQian WDong LZhang KLiu XQin HLing HWang D*. A novel allele of L-galactono-1,4-lactone dehydrogenase is associated with enhanced drought tolerance through affecting stomatal aperture in common wheat. Scientific Reports, 2016, 6: 30177


27. Ma L#Li B#Han FYan SWang LSun J*. Evaluation of the chemical quality traits of soybean seeds, as related to sensory attributes of soymilk. Food Chemistry, 2015, 173: 694-701


28. Fan S#Li B#Yu FHan FYan SWang LSun J*. Analysis of additive and epistatic quantitative trait loci (QTLs) underlying fatty acid components in soybean seeds across multiple environments. Euphytica, 2015, 206: 689-700


29. Li B#Tian L#Zhang J#Huang L#Han FYan SWang LZheng H*Sun J*. Construction of a high-density genetic map based on large-scale markers developed by specific length amplified fragment sequencing (SLAF-seq) and its application to QTL analysis for isoflavone content in Glycine max. BMC Genomics, 2014, 15: 1086


30. Li BYang YYu CLi SChen JLiu XQin HWang D*. Partial suppression of l-galactono-1,4-lactone dehydrogenase causes significant reduction in leaf water loss through decreasing stomatal aperture size in Arabidopsis. Plant Growth Regulation, 2014, 72: 171-179


31. Li BSun JWang LZhao RWang L*. Comparative analysis of gene expression profiling between resistant and susceptible varieties infected with soybean cyst nematode race 4 in Glycine max. Journal of Integrative Aagriculture, 2014, 13: 2594-2607




◆出版教材著作

王连铮、孙君明、叶兴国、李斌 . 2019. 王连铮文选. 中国农业科学技术出版社, 2019.


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