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南京农业大学资源与环境科学学院导师教师师资介绍简介-赵方杰

/2021-03-27


赵方杰
教授, 博士生导师,国家特聘专家

通讯地址:南京农业大学 资源与环境科学学院 联系方式:(0086) 25 84396509 (Tel)
Email:Fangjie.Zhao@njau.edu.cn

从事专业:
环境生物学,植物营养学
招收“农业资源与环境”博士生,“植物营养学”“环境科学”“环境工程”硕士生。

研究方向:
植物吸收重金属及必需微量元素的分子机理,污染元素生物地球化学,污染土壤修复

个人简历:
1992 年获英国 Newcastle 大学博士学位。1992 至 2012 年任职英国洛桑研究所(Rothamsted Research) , 先后任研究员( Principal
Scientist )、资深研究员( Senior Principal Scientist)。2012
年起任南京农业大学全职特聘教授。主要从事环境生物学与植物营养学研究,在植物重金属吸收与解毒的分子机制、污染土壤生物修复、作物硫素和微量元素营养等方面研究取得重要成果。迄今已发表 SCI 论文 300
余篇,在 Web of Science 被引用次数超过 3万次,H 指数 95,入选 2017 - 2020 年科睿唯安全球高被引用学者,爱思唯尔中国高被引学者。2020
年被评为南京农业大学“优秀研究生导师”。

教学情况:
主讲研究生课程“环境科学进展与研究方法”
参讲“农业资源与环境前沿”、“农业资源与环境学科导论”

学术期刊及学会任职:
? 《Plant and Soil》领域编辑
? 《European Journal of Soil Science 》副主编
? 《New Phytologist》、《Environmental Pollution》、 《Rice》编委
? 国际微量元素生物地球化学学会(International Society for Trace Element Biogeochemistry)执行委员(2009-2013,
2017-2021)
? 国际植物营养学会(International Plant Nutrition Council)理事(2017 至今)
? 中国土壤学会常务理事(2012-2020)
? 生态环境部土壤生态环境保护专家咨询委员会委员
? 农村农业部土壤污染防治技术指导委员会成员

主持科研项目:
1. 国家自然科学基金委重大项目“土传植物致病菌与抗生素抗性基因互作和传播机制”350万元,2021–2025

2. 国家自然科学基金委重点项目“诱发水稻旱青立病的土壤生物地球化学机制与防控措施” 303 万元,2020–2024
3. 国家自然科学基金委国际合作重点项目“基于离子组学和基因组学技术揭示水稻重金属积累的分子机理”,333 万元,2016-2020
4. 国家自然科学基金委国际合作重点项目“污染稻田镉、砷的生物地球化学过程与降低水稻镉、砷吸收的稻田管理措施”,296 万元,2017-2020
5. 国家自然科学基金委重点项目“水稻土砷形态转化的生物学机理与调控措施”308 万元, 2014–2018
6. 国家自然科学基金委面上项目“水稻 NIP 水通道蛋白向籽粒运输砷的功能解析”86 万元,2014–2017
7. 农业部公益性行业科研专项“阻控作物重金属积累的遗传改良研究与示范”,1512 万元,2014–2018
8. 环保部公益性行业科研专项“现行土壤环境质量标准中镉元素标准值的合理性论证”95万元,2014–2016
9. 教育部“植物营养生物学”创新团队,300 万元,2013–2015; 第二期滚动支持,300 万元,2018-2020
10. 江苏省“植物营养学”创新团队,300 万元,2013–2015
11. 江苏省双创计划,100 万元,2014–2016
12. Unilever (联合利华)“影响茶叶铝积累的环境与生理因子研究”35 万元,2012–2015

专著:
Meharg, A. A. and Zhao, F. J. 2012. Arsenic & Rice. Springer, Dordrecht, The Netherlands.


近期代表性文章(* 通讯作者):

1. 赵方杰*,谢婉滢,汪鹏. 2020. 土壤与人体健康. 土壤学报, 57(1): 1-11.
2. Sun S.K., Xu X.J., Tang Z., Tang Z., Huang X.Y., Wirtz M., Hell R., Zhao F.J.* 2021. A
molecular switch in sulfur metabolism to reduce arsenic and enrich selenium in rice
grain. Nature Communications 12: 1392.
3. Zhang L.X., Gao C., Chen C., Zhang W.W., Huang X.Y. and Zhao F.J.* 2020. Overexpression of
rice OsHMA3 in wheat greatly decreases cadmium accumulation in wheat grain. Environmental Science &
Technology 54: 10100?10108.
4. Chen J., Huang, X.Y., Salt D.E. and Zhao F.J.* 2020. Mutation in OsCADT1 enhances cadmium
tolerance and enriches selenium in rice grain. New Phytologist 226: 838–850.
5. Chang J.D., Huang S., Yamaji N., Zhang W.W., Ma J. F., Zhao F.J.* 2020.
OsNRAMP1 transporter contributes to cadmium and manganese uptake in rice. Plant, Cell and
Environment 43:2476–2491.

6. Chen J., Wang X., Zhang W.W., Zhang S.Q. and Zhao F.J.* 2020. Protein
phosphatase 2A alleviates cadmium toxicity by modulating ethylene production in Arabidopsis
thaliana. Plant, Cell and Environment 43: 1008–1022.
7. Zhang J., Chai C. W., ThomasArrigo L., Zhao S. C., Kretzschmar R., Zhao F. J.* 2020. Nitrite
accumulation is required for microbial anaerobic iron oxidation, but not for arsenite oxidation in
two heterotrophic denitrifiers. Environmental Science & Technology 54: 4036?4045.
8. Zhao F.J.* and Wang P. 2020. Arsenic and cadmium in rice and mitigation strategies. Plant
and Soil 446: 1–21.
9. Chang J.D., Huang S., Konishi N., Wang P., Chen J., Huang X.Y., Ma J. F. and Zhao F. J.*
2020. Overexpression of the manganese/cadmium transporter OsNRAMP5 reduces cadmium
accumulation in rice grain. Journal of Experimental Botany 71: 5705–5715.
10. Tang Z., Wang Y.J., Gao A.X., Ji Y.C., Yang B.Y., Wang P., Tang Z. and Zhao F. J.* 2020.
Dimethylarsinic acid is the causal agent inducing rice straighthead disease.
Journal of Experimental Botany 71: 5631–5644.
11. Chen C., Li L.Y., Huang K., Zhang J., Xie W.Y., Lu Y.H., Dong X.Z. and Zhao F.J.* 2019
Sulfate- reducing bacteria and methanogens are involved in arsenic methylation and
demethylation in paddy soils. The ISME Journal 13: 2523–2535.
12. Zhang L.X., Wu J., Tang Z., Huang X.Y., Wang X.W., Salt D.E., Zhao F.J.* Variation in the
BrHMA3 coding region controls natural variation in cadmium accumulation in Brassica rapa
vegetables. Journal of Experimental Botany 70: 5865–5878.
13. Lu C.N., Zhang L.X.,Tang Z., Huang X.Y., Ma J.F., Zhao F.J.* 2019. Producing cadmium-free
Indica rice by overexpressing OsHMA3. Environmental International 126: 619–626.
14. Wang P.T., Chen X., Xu X., Lu C., Zhang W., Zhao F.J.* 2018. Arabidopsis
ARSENATE INDUCED CHLOROSIS 1/TRANSLOCON AT THE OUTER ENVELOPE MEMBRANE OF CHLOROPLASTS 132 protects
chloroplasts from arsenic toxicity. Plant Physiology 178, 1568- 1583.
15. Sun, S.K., Chen, Y., Che, J., Konishi, N., Tang, Z., Miller, A.J., Ma, J.F. and Zhao, F.J.*
2018. Decreasing arsenic accumulation in rice by overexpressing OsNIP1;1 and OsNIP3;3
through disrupting arsenite radial transport in roots. New Phytologist 219: 641–653.
16. Wang, C.C., Na, G.N., Sanchez Bermejo, E., Chen, Y., Banks, J.A., Salt, D.E. and Zhao, F.J.*
2018. Dissecting the components controlling root-to-shoot arsenic translocation in Arabidopsis
thaliana. New Phytologist. 217: 206–218.
17. Huang, K., Xu, Y., Packianathan, C., Gao, F., Chen, C., Zhang, J., Shen, Q.R., Rosen, B.P.
and Zhao, F.J.* 2018. Arsenic methylation by a novel ArsM As(III)
S-adenosylmethionine methyltransferase that requires only two conserved cysteine residues.
Molecular Microbiology 107: 265–276.

18. Xu, J.M., Shi, S.L., Wang, L., Tang, Z., Lv, T.T., Zhu, X.L., Ding, X.M., Wang, Y.F., Zhao,
F.J.* and Wu, Z.C.* 2017. OsHAC4 is critical for arsenate tolerance and regulates arsenic
accumulation in rice. New Phytologist 215: 1090–1101.
19. Zhang, J., Zhao, S.C., Xu, Y., Zhou, W.X., Huang, K., Tang, Z. and Zhao, F.J.* 2017. Nitrate
stimulates anaerobic microbial arsenite oxidation in paddy soils. Environmental Science
and Technology 51: 4377?4386.
20. Chen, C., Huang, K., Xie, W.Y., Chen, S.H., Tang, Z. and Zhao, F.J.* 2017. Microbial
processes mediating the evolution of methylarsine gases from dimethylarsenate in
paddy soils. Environmental Science and Technology 51: 13190?13198.
21. Xu, J.M., Shi, S.L., Wang, L., Tang, Z., Lv, T.T., Zhu, X.L., Ding, X.M., Wang, Y.F., Zhao,
F.J.* and Wu, Z.C.* 2017. OsHAC4 is critical for arsenate tolerance and regulates arsenic
accumulation in rice. New Phytologist 215: 1090–1101.
22. Shi, S.L., Wang, T., Chen, Z., Tang, Z., Wu, Z.C., Salt, D.E., Chao, D.Y.* and Zhao, F.J.*
2016. OsHAC1;1 and OsHAC1;2 function as arsenate reductases and regulate arsenic
accumulation. Plant Physiology 172: 1708–1719.
23. Xie, W.Y., McGrath, S.P., Su,J.Q., Hirsch, P., Clark, I., Shen, Q.R., Zhu, Y.G. and Zhao,
F.J.* 2016. Long-term impact of field applications of sewage sludge on soil antibiotic
resistome. Environmental Science and Technology 50: 12602?12611.
24. Huang, K., Chen, C., Zhang, J., Tang, Z., Shen, Q.R., Rosen, B.P. and Zhao, F.J.* 2016.
Efficient arsenic methylation and volatilization mediated by a novel bacterium
from an arsenic- contaminated paddy soil. Environmental Science and Technology 50: 6389?6396.
25. Yan, J.L., Wang, P.T., Wang, P., Yang, M., Lian, X.M., Tang, Z., Huang, C.F., Salt, D.E. and
Zhao, F.J.* 2016. A loss-of-function allele of OsHMA3 associated with high
cadmium accumulation in shoots and grain of Japonica rice cultivars. Plant, Cell and
Environment 39: 1941–1954.
26. Zhao, F.J.*, Ma, Y.B., Zhu, Y.G., Tang, Z. and McGrath, S.P. 2015. Soil contamination in
China: Current status and mitigation strategies. Environmental Science and Technology 49: 750-759.
27. Zhang, J., Zhou, W.X., Liu, B.B., He, J., Shen, Q.R. and Zhao, F.J. * 2015. Anaerobic
arsenite oxidation by an autotrophic arsenite-oxidizing bacterium from an arsenic-contaminated
paddy soil. Environmental Science and Technology 49: 5956–5964.
28. Chao DY*, Chen Y, Chen JG, Shi SL, Chen ZR, Wang CC, Danku JM, Zhao FJ* and Salt DE*. 2014.
Genome-wide association mapping identifies a new arsenate reductase enzyme critical for limiting
arsenic accumulation in plants. PLoS Biology 12(12): e1002009.
29. Zhao, F.J.*, Moore, K.L., Lombi, E. and Zhu, Y.G. 2014. Imaging element
distribution and speciation in plant cells. Trends in Plant Science 19: 183-192.
30. Moore, K.L.*, Chen, Y., van de Meene, A.M.L., Hughes, L., Liu, W.J., Geraki, T., Mosselmans,
F., McGrath, S.P., Grovenor, C., and Zhao, F.J.* 2014 Combined NanoSIMS and Synchrotron X-

ray fluorescence reveals distinct cellular and subcellular distribution patterns of trace elements
in rice tissues. New Phytologist 201: 104–115
31. Zhao, F.J.*, Zhu, Y.G. and Meharg, A.A. 2013. Methylated arsenic species in rice:
Geographical variation, origin, and uptake mechanisms. Environmental Science & Technology 47:
3957-3966.
32. Lomax, C., Liu, W.J., Wu, L.Y., Xue, K., Xiong, J., Zhou, J.Z., McGrath, S.P., Meharg, A.A.,
Miller, A.J. and Zhao, F.J.* 2012. Methylated arsenic species in plants originate from
soil microorganisms. New Phytologist 193: 665–672.
33. Wu, Z.C., Ren, H.Y., McGrath, S.P., Wu, P. and Zhao, F.J. * 2011. Investigating the
contribution of the phosphate transport pathway to arsenic accumulation in rice. Plant Physiology
157: 498- 508.
34. Zhao, F.J.*, McGrath, S.P. and Meharg, A.A. 2010. Arsenic as a food-chain
contaminant: mechanisms of plant uptake and metabolism and mitigation strategies. Annual Review of
Plant Biology 61: 535–559.
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