现任中国科学院植物研究所研究员,博士生导师,研究团队负责人,中国科学院特聘研究岗位专家。兼任中国植物生理学会修复生物学专业委员会委员、北京植物学会理事、植物学报编委。迄今承担国家自然科学基金联合基金重点项目和面上项目、国家重点研发计划、国家高技术研究发展计划、科技基础性工作重大专项、中国科学院先导专项等多个项目;研究成果在Nat. Commun.、Crit. Rev. Environ. Sci. Technol.、New Phytol.、J. Hazard. Mater.、Plant Cell Environ.等刊物上发表学术论文30余篇;获得国家授权专利近30项,PCT国际专利1项,登记新品种5个。
博士生导师
何振艳
何振艳
联系方式:010-62836690 E-mail:hezhenyan@ibcas.ac.cn
- 研究方向
1. 植物矿物离子
2. 低积累重金属安全作物培育
3. 重金属污染修复技术研发
4. 耐盐碱作物培育
研究论文
Zhu X, Yan HL, Tu C, Li RJ, Zhang H, Li Y, Yang S, Zhao FJ , Peijnenburg W J G M, Ma M, He ZY*, Luo YM*. 2025. Promoter pLsi1 driven PvACR3 expression in rice enhances arsenic phytoextraction in paddy soils. Eco-Environment and Health, https://doi.org/10.1016/j.eehl.2025.100168
Yan HL, Peng ZM, Zhang HZF, Wang BH, Xu WX, He ZY*. 2024. Cadmium minimization in crops: A trade-Off with mineral nutrients in safe breeding. Plant Cell and Envrionment, 48:1-14
Yan HL, Zhang HZF, Hao SN, Wang LY, Xu WX, Ma M, Luo YM*, He ZY*. 2023. Cadmium contamination in food crops: Risk assessment and control in smart age. Critical Reviews in Environmental Science and Technology, 53:1643-1661
Yan HL, Guo HY, Xu WX, Dai CH, Wilson K, Xie JY, Li T, Zhang HZF, Ma M, Hao ZF*, He ZY*. 2023. GWAS-assisted genomic prediction of cadmium accumulation in maize kernel with machine learning and linear statistical methods. Journal of Hazardous Materials, 441: 129929
Yan HL, Guo HY, Li T, Zhang HZF, Xu WX, Xie JY, Zhu XY, Yu YJ, Chen J, Zhao SQ, Xu J, Hu MJ, Jiang YG, Zhang HL, Ma M, He ZY*. 2023. High-precision early warning system for rice cadmium accumulation risk assessment. Science of The Total Environment, 859: 160135
Yan HL, Xu WX, Zhang T, Feng L, Liu RX, Wang LY, Wu LL, Zhang H, Zhang XH, Li T, Peng ZM, Jin C, Yu YJ, Ping JA, Ma M, He ZY*. 2022. Characterization of a novel arsenite long-distance transporter from arsenic hyperaccumulator fern Pteris vittata. New Phytologist, 233: 2488-2502
Huan YM, Li FB, Yi JC, Yan HL, He ZY, Li XM*. 2022. Transcriptomic and physio-biochemical features in rice (Oryza sativa L.) in response to mercury stress. Chemosphere, 309: 136612
Feng L, Yan HL, Dai CH, Xu WX, Gu FY, Zhang F, Li T, Xian JY, He XQ, Yu YJ, Ma M, Wang F*, He ZY*. 2020. The systematic exploration of cadmium-accumulation characteristics of maize kernel in acidic soil with different pollution levels in China. Science of the Total Environment, 729: 138972
Liu ZQ, Li HL, Zeng XJ, Lu C, Fu JY, Guo LJ, Kimani WM, Yan HL, He ZY, Hao HQ*, Jing HC*. 2020. Coupling phytoremediation of cadmium-contaminated soil with safe crop production based on a sorghum farming system. Journal of Cleaner Production, 275: 123002
Zhang F, Gu FY, Yan HL, He ZY, Wang BL, Liu H, Yang TT, Wang F*. 2020. Effects of soaking process on arsenic and other mineral elements in brown rice. Food Science and Human Wellness, 9(2): 168-175
Yan HL, Xu WX, Xie JY, Gao YW, Wu LL, Sun L, Feng L, Chen X, Zhang T, Dai CH, Li T, Lin XN, Zhang ZY, Wang XQ, Li FM, Zhu XY, Li JJ, Li ZC, Chen CY, Ma, M, Zhang HL*, He ZY*. 2019. Variation of a major facilitator superfamily gene contributes to differential cadmium accumulation between rice subspecies. Nature Communications, 10: 2562
Yan HL, Gao YW, Wu LL, Wang LY, Zhang T, Dai CH, Xu WX, Feng L, Ma M, Zhu YG*, He ZY*. 2019. Potential use of the Pteris vittata arsenic hyperaccumulation-regulation network for phytoremediation. Journal of Hazardous Materials, 368: 386-396
Zhang T, Xu WX, Lin XN, Yan HL, Ma M, He ZY*. 2019. Assessment of heavy metals pollution of soybean grains in North Anhui of China. Science of The Total Environment, 646: 914-922
He ZY, Yan HL, Chen YS, Shen HL, Xu WX, Zhang HY, Shi L, Zhu YG, Ma M. 2016. An aquaporin PvTIP4;1 from Pteris vittata may mediate arsenite uptake. New Phytologist, 209: 746-761
Sun YY, Xu WZ, Wu L, Wang RZ, He ZY, Ma M*. 2016. An Arabidopsis mutant of inositol pentakisphosphate 2-kinase AtIPK1 displays reduced arsenate tolerance. Plant Cell and Environment, 39: 416-426
Xu WZ, Dai WT, Yan HL, Li S, Shen HL, Chen YS, Xu H, Sun YY, He ZY, Ma M*. 2015. Arabidopsis NIP3;1 plays an important role in arsenic uptake and root-to-shoot translocation under arsenite stress conditions. Molecular Plant, 8: 722-733
Shen HL, He ZY*, Yan HL, Xing ZN, Chen YS, Xu WX, Xu WZ, Ma M. 2014. The fronds tonoplast quantitative proteomic analysis in arsenic hyperaccumulator Pteris vittata L. Journal of Proteomics, 105: 46-57
王璐瑶,陈謇,赵守清,闫慧莉,许文秀,刘若溪,麻密,虞轶俊*,何振艳*. 2022. 水稻镉积累特性的生理和分子机制研究概述. 植物学报, 57: 236-249
李婷,胡敏骏,徐君,蒋玉根,闫慧莉,虞轶俊,何振艳*. 2021. 镉低积累水稻品种选育研究进展. 中国农业科技导报, 23(11): 36-46
张田,闫慧莉,何振艳*.2020. 蜈蚣草中砷超富集的分子机制研究进展. 生物工程学报, 36(3): 397-406
新品种及专利
木稷4号,2025,编号:GPD高粱(2025)110002
木稷3号,2025,编号:GPD高粱(2025)110001
木稷2号,2023,编号:GPD高粱(2023)110109
木稷1号,2023,编号:GPD高粱(2023)110108
晋牧7号,2022,编号:GPD高粱(2022)140081
创制砷高积累工程水稻的重组载体及其在砷污染水体和土壤修复,专利号:ZL 202410732604.9
检测玉米基因组中 SNP 的多态性的物质在鉴定玉米镉含量中的应用,专利号:ZL 202011319425.0
高粱 SbDW3 基因的 SNP 分子标记及应用,专利号:ZL 2022 1 1501919.X
培育低镉积累水稻的方法及其相关材料的用途,专利号:ZL 201711001191.3
水稻籽粒镉含量相关基因 LCd7 的联合单倍型分子标记及其应用,专利号:202310555774.X
水稻籽粒镉含量相关基因 LCd-11 的 SNP 分子标记的应用,专利号:ZL 201610104530.X
水稻籽粒镉含量相关基因 LCd-22 的 SNP 分子标记的应用,专利号:ZL 201610113156.X
水稻籽粒镉含量相关基因 LCd-31 的 SNP 分子标记的应用,专利号:ZL 201610172662.6
水稻籽粒镉含量相关基因 LCd-38 的 SNP 分子标记的应用,专利号:ZL 201610108474.7
水稻籽粒镉含量相关基因 LCd-41 的 SNP 分子标记的应用,专利号:ZL 201610121407.9
水稻籽粒镉含量相关基因 YZCd1 的 SNP 分子标记的应用,专利号:ZL 2024 1 0791842.7
水稻籽粒镉含量相关基因 YZCd2 的 SNP 分子标记的应用,专利号:ZL 2024 1 0791749.6
一种蛋白及其编码基因与应用,专利号:ZL 201010528752.7
一种降低镉在植物中积累的方法及其应用,专利号:ZL 03157195.6
一种检测植物中目标蛋白的方法及其专用 SPR 生物传感器,专利号:ZL 201110081230.1
一种抗砷相关蛋白及其相关生物材料与应用,专利号:2024 202010933445.0
一种培育低重金属积累植物的方法,专利号:ZL 200410096858.9
一种蜈蚣草 ABC 转运蛋白及其编码基因与应用,专利号:ZL 200410080857.5
一种蜈蚣草经绿色球状体再生植株的方法及其专用培养基,专利号:ZL 200810239942.X
一种植物砷抗性相关的蛋白及编码基因及其应用,专利号:ZL 201010116 397.2
一种与砷响应相关的调控片段及其应用,专利号:ZL 2010 0128600.8
一种与玉米籽粒镉含量相关基因 ZmCd9 的单倍型分子标记及其应用,专利号:ZL 202011336462.2