个人简历

张涛博士，教授，博士生导师，东北师范大学生命科学学院、草地科学研究所、植被生态科学教育部重点实验室。主要从事土壤生态学、草地生态学、全球变化生态学、菌根生态学、植物生理生态学研究，研究领域包括：植物-土壤相互作用与全球变化、土壤微生物互作、全球变化背景下的丛枝菌根真菌生态功能、草地生态系统稳定性维持机制、土壤健康及其调控机制。主持国家自然科学基金面上项目2项、青年基金1项，吉林省中青年科技创新创业卓越人才（团队）项目、吉林省科技厅和教育厅“春苗人才”科研项目各1项，参与国家自然科学基金项目等多项。以第一或通讯作者在Agricultural and Forest Meteorology、Industrial Crops & Products、Science of the Total Environment、Geoderma、Pedosphere、Land Degradation & Development、Applied and Environmental Microbiology、Ecological Indicators、Plant and Soil、Applied Soil Ecology、Planta、New Phytologist、Journal of Applied Ecology、Physiologia Plantarum、等期刊发表SCI论文60余篇，部分研究成果被Science、PNAS、Ecology Letters等高水平期刊引用。另有多篇论文发表在《科学通报》、《植物生态学报》、《中国草地学报》《生态学报》等生态学主流期刊。荣获吉林省自然科学二等奖、东北师范大学教学成果奖等多项。 本研究组长期与中国科学院、山东大学、中国农业大学、瑞士、荷兰、美国、加拿大等国内外高水平实验室保持交流合作。 Pedobiologia、PLOS Climate、Frontiers in Plant Science编委； Global Change Biology、Functional Ecology、Journal of Ecology、Science of the Total Environment、 Ecology、Agricultural and Forest Meteorology、Ecological Applications、Land Degradation & Development、Plant and Soil、Field Crop Research、Geoderma、Catena、Frontiers in Plant Science、生态学报、应用生态学报等杂志审稿人，国家重点研发计划、自然科学基金等重大项目评审专家，吉林省生态示范创建专家，吉林省科创专员。 曾赴法国、瑞士、德国、捷克、美国、印度等国家进行学术交流。 欢迎对植物-土壤相互作用及全球变化生态学感兴趣的同学报考研究生(硕士/博士)，欢迎本科生加入菌根生态学实验室（惟真楼1011室）开展科研训练和创新大赛等。 招生专业： 硕士生：生态学、草学 博士生：生态学 工作经历 2021.06-至今 东北师范大学 生命科学学院 教 授 博士生导师 2019.09-2021.06 东北师范大学 生命科学学院 副教授 博士生导师 2016.06-2019.09 东北师范大学 生命科学学院 副教授 2016.03-2018.02 Agroscope, Switzerland, 博士后 合作导师 Marcel van der Heijden 2012.07-2016.06 东北师范大学 生命科学学院 讲师 主持参与课题： 1.国家自然科学基金面上项目，32171645， 增温和施氮条件下丛枝菌根真菌介导的松嫩草地土壤氮素周转分子调控机制，2022/01-2025/12, 58万元，主持 2.吉林省中青年科技创新创业卓越人才（团队）项目，全球变化背景下土壤微生物提高土壤质量和土壤固碳潜力的调控机制研究，2024/01-2025/12. 30万元，主持 3.国家自然科学基金面上项目，31770359， 丛枝菌根真菌对松嫩草地植物群落适应温度升高和氮沉降的调控机制，2018/01-2021/12, 60万元，主持 4.吉林省科技厅自然基金，20200201115JC. 温度升高和氮沉降背景下AM真菌对松嫩草地生态系统多功能性的影响机制研究，2020/01-2021/12，8万元，主持 5.中央高校基本科研项目：2412018ZD011，温度升高和氮沉降背景下AM真菌对草地生态系统多功能性的影响，2018.01-2019.12， 30万元，主持 6.国家自然科学基金面上项目，31470405，增温和施氮条件下AM真菌对草地生态系统植物和土壤C、N、P化学计量特征的影响，2015/01-2018/12，86万元，参加 7.国家自然科学基金青年项目，31300097，AM真菌与盐碱化草地藜科植物的共生机理 研究，2014/01-2016/12，23万元，主持 8.吉林省教育厅“春苗计划”研究项目，吉教科字[2013]5号，AM真菌对松嫩盐碱化草地植物群落物种组成的调节机制，2014/01-2015/12，主持 9.荒漠与绿洲生态国家重点实验室开放基金，AM真菌对古尔班通古特沙漠短命植物群 落养分资源分配和物种组成的调节，2013/01-2015/12，10万元，主持 获奖情况： 2014年 东北师范大学 优秀指导教师 2018年 东北师范大学 实践育人标兵 2021年 吉林省自然科学二等奖 排名第2（2/8） 2022年 全国大学生生命科学竞赛（创新创业类）一等奖 教学信息： 教学课程：土壤生态学、应用生态学、作物安全生产与绿色生活。 研究生指导：硕士毕业生8人，博士毕业生4名，多名研究生获得国家奖学金（4人次）、校长奖学金（5人次）、校级优秀博/硕士论文4人次（博士、硕士各2人）、吉林省优秀硕士(2人)/博士（2人）论文4人次，多人次获得优秀研究生。在读研究生(博/硕士)14人。 更多信息请浏览：https://www.researchgate.net/profile/Tao-Zhang-55 联系方式：zhangt946@nenu.edu.cn 发表论文： 2024 54. Gao S, Li M, Hu Y,Zhang T, et al., 2024. Comparative differences in maintaining membrane fluidity and remodeling cell wall between Glycine soja and Glycine max leaves under drought. Plant Physiology and Biochemistry. 108545 53. Chu Q, Feng W, Tian Y,... Zhang T*. 2024. Soil microbial community contributes more to plant-soil feedback and plant-plant interactions than root traits under warming and drought. Plant Soil, https://doi.org/10.1007/s11104-024-06606-w 52. Cui N, Veresoglou S, Tian Y,... Zhang T*. 2024. Arbuscular mycorrhizal fungi offset NH3 emissions in temperate meadow soil under simulated warming and nitrogen deposition.Journal of Environmental Management 354, 120239. 51. Wang H, Tian Y, Guo, et al, Zhang T*. 2024.Arbuscular mycorrhizal fungi reduce NH3 emissions under different land-use types in agro-pastoral areas. Pedosphere,34(2): 497--507, 2023 50.Zhang SM, Hu Y, Wang Y,... Zhang T, Shi L. 2023. Integrated transcriptomics and metabolomics reveals that regulating biosynthesis and metabolism of HCN and GABA plays a key role in drought resistance of wild soybean. Environmental and Experimental Botany,215(2):105505 59. Cui XM, Chen Z, Wang B, Zhang T, Shi L. 2023. Comprehensive physiological, transcriptomic, and metabolomic analysis of the key metabolic pathways in millet seedling adaptation to drought stress. Physiologia Plantarum, 175:e14122 48. Zhang X, Zhang T, Liu YJ. 2023. Effects of arbuscular mycorrhizal fungi on plant invasion success driven by nitrogen fluctuations. Journal of Applied Ecology. 60:2425–2436. 47. Jiang M, Tian Y, Guo R, Li S, Guo J, Zhang T*.2023. Effects of warming and nitrogen addition on soil fungal and bacterial community structures in a temperate meadow. Front. Microbiol. 14:1231442 46. 贾阳阳，张涛，冯固. 2023. 气候变化背景下AM真菌维持荒漠生态系统稳定性研究进展. 科学通报，68（24）:3172 -3184. 45. Li J, Zhang T, Sun W, et al., 2023. Disruption of soil fungal hyphae suppressed litter-derived C retention and N turnover during decomposition under drought stress in a temperate grassland. Geoderma, 432, 116396 44. Hu Y, Li M, Hu Y, Han D, Wei J, Zhang T, Guo J, Shi L. 2023. Wild soybean salt tolerance metabolic model: Assessment of storage protein mobilization in cotyledons and C/N balance in the hypocotyl/root axis. Physiologia Plantarum. 175:e13863. 2022 43. Li J, Meng B, Yang X, Cui N, Zhao T, Chai H, Zhang T*, Sun W*. 2022. Suppression of AMF accelerates N2O emission by altering soil bacterial community and genes abundance under varied precipitation conditions in a semiarid grassland. Frontiers in Microbiology, 13:961969. 42. Chen J, Zhou J, Li MX , Li M, Hu Y, Zhang T*, Shi LX*. 2022. Membrane lipid phosphorus reusing and antioxidant protecting played key roles in wild soybean resistance to phosphorus deficiency compared with cultivated soybean. Pland and Soil, 474 (1-2):99-113. 41. Jia Y, Zhang T, Sun Y, et al., 2022. Can mycorrhizal fungi alleviate plant community instability caused by increased precipitation in arid ecosystems. Plant and Soil, 478, 559–577. 40. Li X, Guo R,Zhao Y, Liu D, Chen J, Miao N, Gao S, Guo J, Zhang T*, Shi L*. 2022. Wild soybean resists the stress of low phosphorus by increasing nutrient reuse between the young and old leaves.Plant Growth Regulation,97 (1).21-31. 39. Miao N, Zhou J, Li M, Zhang J, Hu Y, Guo J, Zhang T*, Shi L*.2022. Remodeling and protecting the membrane system to resist phosphorus deficiency in wild soybean (Glycine soja) seedling leaves. Planta, 255:53 38. Zhu X, Wang P, et al, Zhang T, Yang ZB*. 2022. Calmodulin-like protein CML24 interacts with CAMTA2 and WRKY46 to regulate ALMT1-dependent Al resistance in Arabidopsis thaliana. New Phytologist 233: 2471–2487 37. Yan Y, Sun X, Sun F, Zhao Y, Guo J, Sun W, Zhang T*. 2021. Sensitivity of soil fungal and bacterial community compositions to nitrogen and phosphorus additions in a temperate meadow. Plant and Soil. 471,477–490. 2021 36. Mei L, Zhang P, Cui G, Yang X, Zhang T*, Guo J. 2021. Arbuscular mycorrhizal fungi promote Leymus chinensis and Phragmites australis litter decomposition and alleviate nutrient limitations of soil microbes under conditions of warming and nitrogen application in a meadow ecosystem. Applied Soil Ecology, 171, 104318. 35. Shen W, Guo R, Zhao Y, Liu D, Chen J, Miao N, Gao S,Zhang T*, Shi LX*. 2021. Nutrient Reabsorption Mechanism Adapted to Low Phosphorus in Wild and Cultivated Soybean Varieties. Journal of Plant Growth Regulation, https://doi.org/10.1007/s00344-021-10495-z 34. Cui N, Zhao YN, Sun F, Wang M,Shi LX, Guo J, Sun W, Zhang T*. 2021 Elevated temperature and nitrogen deposition did not affect the impacts of arbuscular mycorrhizal fungi on soil carbon or nitrogen stocks in a temperate meadow. Ecological Indicators, 131,108209. 33. Yang X, Yuan M, Guo JX, Shi LX, Zhang T*. 2021.Suppression of arbuscular mycorrhizal fungi aggravate the negative interactive effects of warming and nitrogen addition on soil bacterial and fungal diversity and community composition. Applied and Environmental Microbiology,87(22):e01523-21. 32. Cui N, Shi LX, Guo J, Zhang T* 2021. Arbuscular mycorrhizal fungi alleviate elevated temperature and nitrogen deposition- induced warming potential by reducing soil N2O emissions in a temperate meadow. Ecological Indicators, 131,108193. 31. Yang X, Mariotte P, Guo J, Hautier Y*, Zhang T*. 2021. Suppression of arbuscular mycorrhizal fungi decreases the temporal stability of community productivity under elevated temperature and nitrogen addition in a temperate meadow. Science of the Total Environment, 762, 143137 30. Zhang T, Feng G. 2021. Arbuscular mycorrhizal fungi alleviate the negative effects of increases in phosphorus (P) resource diversity on plant community structure by improving P resource utilization. Plant Soil.461, 295–307. 29. 赵双，张涛*，石连旋，郭继勋.2021. 增温和施氮及AM真菌对草地土壤碳储量和团聚体稳定性的影响. 中国草地学报，第9期:97-106. 28. 王怀嵩，张涛*. 2021. 农业土壤健康评价体系研究进展. 生态与农村环境学报, 2022, 38(9): 1093-1100.。 27. 张涛，史宝库，孙伟. 2021. 基于生态文明理念培养的生态学课程体系建设存在问题与解决途径.当代教育实践与教学研究,11：61-63. 2020 26. Yang X, Guo R, Knops JMH, Mei L, Kang F, Zhang T*, Guo J. 2020. Shifts in plant phenology induced by environmental changes are small relative to annual phenological variation. Agricultural and Forest Meteorology. 294，108144. 25. Kang F，Yang B, Wujisiguleng, Yang X, Wang L, Guo J, Sun W, Zhang Q, Zhang T*. 2020. Arbuscular mycorrhizal fungi alleviate the negative effect of nitrogen deposition on ecosystem functions in meadow grassland. Land Degradation & Development. 31:748–759. 24. Jia YY, Sun Y, Zhang T, Shi ZY, et al. 2020. Elevated precipitation alters the community structure of spring ephemerals by changing dominant species density in Central Asia.Ecology and Evolution. 10:2196–2212. 23. Khan Y, Yang X, Zhang XL, Yaseen T,Shi LX, Zhang T*. 2020. Tabassum Arbuscular mycorrhizal fungi promote plant growth of Leymus chinensis (Trin.) Tzvelev by increasing the metabolomics activity under nitrogen addition. Grassland Science. ;67:128–138。 2019 22. Mei L, Yang X, Zhang SQ, Zhang T*, Guo J. 2019. Arbuscular mycorrhizal fungi alleviate phosphorus limitation by reducing plant N:P ratios under warming and nitrogen addition in a temperate meadow ecosystem. Science of the Total Environment.686, 1129–1139. 21. Zhao YN, Yang B, Li MX, Xiao RQ, Rao KY, Wang JQ, Zhang T*, Guo JX. 2019. Community composition, structure and productivity in response to nitrogen and phosphorus additions in a temperate meadow. Science of the Total Environment 654: 863–871. 20. Li J, Meng B, Chai H, Yang X, Song W, Li S, Lu A, Zhang T*, Sun W*. 2019. Arbuscular mycorrhizal fungi alleviate drought stress in C3 (Leymus chinensis) and C4 (Hemarthria altissima) grasses via altering antioxidant enzyme activities and photosynthesis. Front. Plant Sci. 10:499. 19. Gong S, Zhang T, Guo J. 2019. Warming and nitrogen deposition accelerate soil phosphorus cycling in a temperate meadow ecosystem. Soil Research, 58(1) 109-115 18. Yang B, Zhang T, Huang S, Bhusal DB, Pang X. 2019. Response of Soil Nematode Community to Phosphorous Amendment in a Subalpine Spruce Plantation. Clean – Soil, Air, Water, 1800202 17. Mei L, Yang X, Cao H, Zhang T*, Guo J. 2019. Arbuscular Mycorrhizal Fungi Alter Plant and Soil C:N:P Stoichiometries Under Warming and Nitrogen Input in a Semiarid Meadow of China. Int. J. Environ. Res. Public Health. 16(3), 397. 2018 16. Zhang T*, Hu YJ, Zhang K, Tian CY, Guo JX. Arbuscular mycorrhizal fungi improve plant growth of Ricinus communis by altering photosynthetic properties and increasing pigments under drought and salt stress. Industrial Crops & Products 117: 13–19. 15. Dennert F, Imperiali N, Staub C, Schneider J, Laessle T, Zhang T. et al. 2018. Conservation tillage and organic farming induce minor variations in Pseudomonas abundance, their antimicrobial function and soil disease resistance. FEMS Microbiology Ecology, 94, fy075. 2017 14. Zhao YN, Yu HQ, Zhang T*, Guo JX*.2017. Mycorrhizal colonization of chenopods and itsinfluencing factors in different saline habitats, China. Journal of Arid Land. 9(1): 143–152. 2016 13. Zhang T*, Yang X, Guo R, Guo J*. 2016. Response of AM fungi spore population to elevated temperature and nitrogen addition and their influence on the plant community composition and productivity. Scientific Reports. 6, 24749, doi: 10.1038/srep24749. 12. Zhang T*, Yang SB, Guo R, Guo J*. 2016. Warming and Nitrogen Addition Alter Photosynthetic Pigments, Sugars and Nutrients in a Temperate Meadow Ecosystem. PLoS ONE. 11(5): e0155375. 11. Yang X, Yu HQ, Zhang T*, Guo J. 2016. Arbuscular Mycorrhizal Fungi Improve the Antioxidative Response and the Seed Production of Suaedoideae Species Suaeda physophora Pall under Salt Stress. Not Bot Horti Agrobo，44（2）：533-540. 2015 10. Zhang T, Guo R, Gao S, Guo J*, Sun W*. 2015. Response of plant community composition and productivity to warming and nitrogen deposition in a temperate meadow ecosystem. PLoS ONE, 10(4): e0123160. 9. Gong S#, Zhang T #, Guo R, Shi L, Guo J*, Sun W*. 2015. Response of soil enzyme activity to warming and nitrogen addition in a meadow steppe. Soil Research. 53: 242–252. (Co-first Author) 8. Gong S, Guo R, Zhang T*, Guo J. 2015. Warming and nitrogen addition increase litter decomposition in a temperate meadow ecosystem. PLoS ONE. 10(3): e0116013. (Co-corresponding Author) 7. Zhang T, Song J, Fan JL, Feng G*. 2015. Adaptations of two halophytes and a xerophyte to saline waterlogging and dryness/moist rotations during seed germination. Plant Species Biology, 30, 231–236. 6. Han DF, Cao HB, Shi LX, Zhang T*, Guo J. 2015. Salinity influence on Leymus chinensis characteristics in a temperate meadow ecosystem. Not Bot Horti Agrobo, 43(2):462-467. (Corresponding Author) 2014 5. Cai X, Peng Y, Yang M, Zhang T*, Zhang Q. 2014. Grassland degradation decrease AM fungi species diversity in Tibet Plateau. Not Bot Horti Agrobo, 42(2):333-339. (Corresponding Author) 2012 4. Zhang T, Shi N, Bai DS, Chen YL, Feng G*. 2012. Arbuscular mycorrhizal fungi promote the growth of Ceratocarpus arenarius (Chenopodiaceae) with no nhancement of phosphorus nutrition. PLoS ONE, 7(9): e41151. 3. Zhang T, Tian CY, Sun Y, Bai DS, Feng G*. 2012. Dynamics of arbuscular mycorrhizalfungi associated with ephemeral plants in Gurbantunggut Desert. Journal of Arid Land, (4)1: 43-51. 2. Zhang T, Sun Y, Shi ZY, Feng G*. 2012. Arbuscular mycorrhizal fungi can accelerate the restoration of degraded spring grassland in Central Asia. Rangeland ecology & management, 65(4):426–432. 2011 1. Zhang T, Sun Y, Song YC, Tian CY, Feng G*. 2011. On-site growth response of a desert ephemeral plant, Plantago minuta, to indigenous arbuscular mycorrhizal fungi in a central Asia desert. Symbiosis, 55:77–84.