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长江大学园艺园林学院导师教师师资介绍简介-吴强盛
本站小编 Free考研考试/2021-08-09
? 基本概况 男,1978年生,江西抚州人,博士,教授(专技三级),博士生/硕士生导师,长江大学根系生物学研究所(校级平台)所长,长江大学园艺园林学院任教。
[1] 湖北省新世纪高层次人才工程第二层次人选(2012年);
[2] 2012年第四届“青年科学之星”(中国科学院、中国工程院、国家自然科学基金委、中国科协、全国青年联合会指导支持,中国科学报社主办);
[3]湖北省自然科学基金“****人才基金”获得者(2012年);
[4]湖北省优秀共产党员(2013年);
[5]荆州市十大****(2014年);
[6]荆州市青年岗位能手(2014年);
[7]长江大学科研百人(2016年);长江大学教学名师。
?教育背景与研究经历
1997-2001,江西农业大学农学院园艺专业学习,获学士学位
2001-2006,华中农业大学园艺林学学院果树专业学习,获博士学位
2006-2010,长江大学园艺园林学院任教,讲师/副教授,硕士生导师
2011.12-至今,长江大学园艺园林学院任教,破格晋升教授
2014.12, 长江大学园艺园林学院任教,博士生导师
2016.3-至今 University of Hradec Kralove客座教授(Invited Professor)
?研究领域和方向
主要研究植物菌根生物技术。重点方向:
[1]菌丝桥在植物间的信号传导作用和功能;
[2]菌根增强植物(三叶草、枳)抗逆性的机理;
[3]菌根释放球囊霉素的机理及其相关功能;
[4]菌根改善植物根系构型的生理机制。
?主讲课程
《园艺植物营养诊断》、《科技写作》等
?主持项目
编号
来源
名称
执行年限
2018YFD**
国家重点研发计划
菌根调控柑橘抗旱性的生理和分子机制
2018-2022
鄂农发【2018】1号
2018年湖北省农业科技创新行动项目
柑橘菌根菌肥应用技术研究
柑橘岗位科学家
2018-2020
SKLTOF**
茶树生物学与资源利用国家重点实验室开放基金项目
AM真菌促进茶树P吸收的机制研究
2019-2021
2018ZYYD045
中央引导地方科技发展专项资金项目
鄂西北核桃良种应用及丰产栽培技术推广与示范(6万)
2018-2020
鄂农计发【2018】34号
湖北省农业厅重大技术
园艺作物“三增三减”健康栽培与加工
2018-2019
长江大学园艺园林学院科研创新团队建设项目
果树菌根分子生理研究
2016-2018
SKLTOF**
茶树生物学与资源利用国家重点实验室开放基金项目
菌根真菌调控茶树生长和根系发育的机制研究
2016-2018
T201604
湖北省高等学校优秀中青年科技创新团队计划项目
柑橘菌根生理和相关功能研究
2016~2018
**
国家自然科学基金
柑橘菌根根外菌丝释放球囊霉素相关土壤蛋白的特性及其相关功能研究
2014-2017
**
国家自然科学基金
柑橘丛枝菌根共生体与多胺的交互作用研究
2009-2011
211107
教育部科学技术研究重点项目
柑橘菌根释放球囊霉素的特点及其在碳代谢中的作用
2011-2014
2012FFA001
湖北省自然科学基金****人才基金
柑橘根际球囊霉素的相关功能研究
2013-2014
Q**
湖北省教育厅科学技术研究项目
柑橘菌根根外菌丝释放球囊霉素的特点及其作用研究
2011-2012
?主要学术兼职
[1] SCI杂志 Notulae Botanicae Horti Agrobotanici Cluj-Napoca编委;
[2]《Current Horticulture》编委;
[3] 《International Journal of Horticulture & Agriculture》编委
[4] 《Scientific World Journal》Guest editor
[5] 《Life Sciences: an International Journal》编委
[6]《长江大学学报》(自然科学版﹒农学卷)编委;
[7]湖北省柑桔学会理事;湖北省园艺学会理事。
[8]定期或不定期受邀为以下国际SCI期刊审阅稿件: Microbial Ecology、Fungal Diversity、Plant Physiology and Biochemistry、Environmental and Experimental Botany、Agriculture, Ecosystems and Environment、Plant Growth Regulation、Applied Soil Ecology、Scientia Horticulturae、European Journal of Soil Biology、Journal of Agricultural Science and Technology、Agroforestry Systems、Archives of Agronomy and Soil Science、Tur J Agric For、Sensors等
[9]不定期受邀为以下国内期刊审阅稿件: 《应用生态学报》、《生态学杂志》、《植物病理学报》、《广西植物》、《中国农业生态学报》、《西南林业大学学报》、《湖北林业科技》、《长江大学学报》(自然科学版﹒农学卷)。
?教学科研奖项
【1】吴强盛,刘乐承,邹英宁,饶贵珍,张义,王贵元. 园艺专业“三明治”教育培养模式的研究与实践. 湖北省高等学校教学成果奖二等奖. 编号:8296,2018-2-2
【2】 喀斯特植物适应性的菌根调控机理及菌根化育苗技术. 贵州省科学技术进步奖三等奖(排名第2) 2017J-3-46-2, 时间:2017-12-23
【3】指导的1篇硕士学位论文《干旱胁迫下丛枝菌根真菌对枳根系过氧化氢流出的作用研究》被评为湖北省优秀硕士学位论文(2017)
?专著
[1] Wu QS. Arbuscular Mycorrhizas and Stress Tolerance of Plants. Springer Nature Singapore Pte Ltd., 2017, p. 1-327
[2] 吴强盛. 园艺植物丛枝菌根研究与应用. 科学出版社,2010,25.7万字
[3] Giri Bhoopander, Prasad Ram, Wu Qiang-Sheng, Varma Ajit. Biofertilizers for Sustainable Agriculture and Environment. Springer Nature Switzerland AG, Gewerbestrasse, Cham, Switzerland, p. 1-544.
[4] 吴强盛主编. 邹英宁、邹华文副主编. 植物生理学实验指导. 北京:中国农业出版社,1-171
?授权专利
[1] 国家发明专利:一种观测丛枝菌根根外菌丝对水分吸收的方法. 吴强盛、邹英宁、黄咏明、倪秋丹. 专利号:ZL 2.1,授权时间:2016年6月8日
[2] 国家实用新型专利:一种根箱培养装置. 吴强盛、张艺灿、邹英宁、张泽志. 专利号:ZL 5.8,授权时间: 2016年6月29日
[3] 吴强盛;池格格;邹英宁. 五室植物培养装置;2016/11/30, 中国, 中华人民共和国国家知识产权局, ZL 2.2
?SCI收录论文(*通讯作者)
2019
[1] Zou YN, Wu HH, Giri B, Wu QS*, Kuca K. Mycorrhizal symbiosis down-regulates or does not change root aquaporin expression in trifoliate orange under drought stress. Plant Physiology and Biochemistry, 2019, 144:292-299
[2] Wu, Q.S., He, J.D., Srivastava, A.K., Zou, Y.N., Kuca, K., 2019. Mycorrhizas enhance drought tolerance of citrus by altering root fatty acid compositions and their saturation levels. Tree Physiology 39(7):1149-1158 doi:10.1093/treephys/tpz039.
[3] ZhangF,ZouYN,WuQS*,Ku?aK.Arbuscularmycorrhizasmodulaterootpolyaminemetabolismtoenhancedroughttoleranceoftrifoliateorange.EnvironmentalandExperimentalBotany,doi:10.1016/j.envexpbot.2019.103926
[4] Zhang YC, Zou YN, Liu LP, Wu QS*. Common mycorrhizal networks activate salicylic acid defense responses of trifoliate orange (Poncirus trifoliata). Journal of Integrative Plant Biology, 2019, 61(10):1099-1111
[5] He JD#, Dong T#, Wu HH, Zou YN*, Wu QS*, Kuca K. Mycorrhizas induce diverse responses of root TIP aquaporin gene expression to drought stress in trifoliate orange. Scientia Horticulturae, 2019, 243:64-69
[6] Zhang DJ, Liu CY, Yang YJ, Wu QS*, Li YY*. Plant root hair growth in response to hormones. Notulae Botanicae Horti Agrobotanici Cluj-Napoca, 2019, 47(2):278-281
[7] Lü LH, Srivastava AK, Shen YL, Wu QS*. A negative feedback regulation of peplanted soil microorganisms on plant growth and soil properties of peach. Notulae Botanicae Horti Agrobotanici Cluj-Napoca, 2019, 47(1):255-261
[8] Zhang YC#, Xie MM#, Feng HD, Zhou M, Zhang ZZ, Liu CY, Wu QS* (2018). Common mycelium networks with Paraglomus occultum induce better plant growth and signal substance changes between trifoliate orange seedlings. Acta Scientiarum Polonorum - Hortorum Cultus, 17(6):95–104
[9] Gao WQ, Wang P, Wu QS*. Functions and application of glomalin-related soil proteins: A review. Sains Malaysiana, 2019, 48(1):111-119
[10] He JD, Li JL, Wu QS*. Effects of Rhizoglomus intraradices on plant growth and root endogenous hormones of trifoliate orange under salt stress. Journal of Animal and Plant Sciences, 2019, 29(1):245-250
[11] Wu QS*, Shao YD, Gao XB, Xia TJ, Kuca K. Characterization of AMF-diversity of endosphere versus rhizosphere of tea (Camellia sinensis) crops. Indian Journal of Agricultural Sciences, 2019, 89(2):348-352
[12] Zou YN, Zhang DJ, Liu CY, Wu QS*. Relationships between mycorrhizae and root hairs. Pakistan Journal of Botany, 2019, 51(2):727-733
[13] Lü LH, Zou YN, Wu QS*. Mycorrhizas mitigate soil replant disease of peach through regulating root exudates, soil microbial population, and soil aggregate stability. Communications in Soil Science and Plant Analysis, 2019, 50(7):909-921
[14] Zhang F#, Wang P#, Zou YN, Wu QS*, Kuca K. Effects of mycorrhizal fungi on root-hair growth and hormone levels of taproot and lateral roots in trifoliate orange under drought stress. Archives of Agronomy and Soil Science, 65:9, 1316-1330, DOI: 10.1080/**.2018.**
[15] Wu QS, He JD, Srivastava AK, Zhang F, Zou YN. Development of propagation technique of indigenous AMF and their inoculation response in citrus. Indian Journal of Agricultural Sciences, 2019, 89(7):1190-1194.
[16] Shao YD, Zhang DJ, Hu XC, Wu QS*, Jiang CJ*, Gao XB, Kuca K. Arbuscular mycorrhiza improves leaf food quality of tea plants. Notulae Botanicae Horti Agrobotanici Cluj-Napoca, 2019, 47(3):608-614
[17] Liu CY, Zou YN, Zhang DJ, Shu B, Wu QS*. Mycorrhizae and tolerance of abiotic stress in citrus plants. In: Giri B, Prasad R, Wu QS, Varma A. Biofertilizers for Sustainable Agriculture and Environment, Springer Nature Switzerland AG, 2019, pp. 465-487
2018
[18] Zou YN, Srivastava AK, Wu QS. Water redistribution in mycorrhizosphere of trifoliate orange. Indian Journal of Agricultural Sciences, 2018, 88(8):1198-1201
[19] Lu LH, Wu QS*. Mitigation of replant disease by mycorrhization in horticultural plants:A review. Folia Horticulturae, 2018, 30(2):269-282
[20] Zhang F, Zou YN, Wu QS*. Quantitative estimation of water uptake by mycorrhizal extraradical hyphae in citrus under drought stress. Scientia Horticulturae, 2018, 229:132-136
[21] Xie MM, Wu QS*. Arbuscular mycorrhizal fungi regulate flowering of Hyacinths orientalis L. Anna marie. Emirates Journal of Food and Agriculture, 2018, 30(2):144-149
[22] Liu CY, Wang P, Zhang DJ, Zou YN, Kuca K, Wu QS*. Mycorrhiza-induced change in root hair growth is associated with IAA accumulation and expression of EXPs in trifoliate orange under two P levels. Scientia Horticulturae, 2018, 234:227-235
[23] Liu CY, Zhang F, Zhang DJ, Srivastava AK, Wu QS*, Zou YN*. 2018. Mycorrhiza stimulates root-hair growth and IAA synthesis and transport in trifoliate orange under drought stress. Scientific Reports, 2018, 8:1978
[24] Zhang F, He JD, Ni QD, Wu QS, Zou YN*. 2018. Enhancement of drought tolerance in trifoliate orange by mycorrhiza: changes in root sucrose and proline metabolisms. Notulae Botanicae Horti Agrobotanici Cluj-Napoca, 2018, 46(1):270-276
[25] Zhang DJ, Yang YJ, Liu CY, Zhang F, Hu W, Gong SB, Wu QS*. Auxin modulates root-hair growth through its signaling pathway in citrus. Scientia Horticulturae, 2018, 236:73-78
[26] Shao YD, Zhang DJ, Hu XC, Wu QS*, Jiang CJ, Xia TJ, Gao XB, Ku?a K (2018): Mycorrhiza-induced changes in root growth and nutrient absorption of tea plants. Plant Soil and Environment, 64: 283–289
[27] Lü LH, Zou YN, Wu QS (2018) Relationship Between Arbuscular Mycorrhizas and Plant Growth: Improvement or Depression?. In: Giri B., Prasad R., Varma A. (eds) Root Biology. Soil Biology, vol 52. Springer, Cham, pp. 451-464
[28] Zhang DJ, Yang YJ, Liu CY, Zhang F, Wu QS (2018) Root Hair Growth and Development in Response to Nutrients and Phytohormones. In: Giri B., Prasad R., Varma A. (eds) Root Biology. Soil Biology, vol 52. Springer, Cham, pp. 65-84
[29] Chi GG, Srivastava AK, Wu QS*. Exogenous easily extractable glomalin-related soil protein improves drought tolerance of trifoliate orange. Archives of Agronomy and Soil Science, 2018, 64(10)1341-1350
[30] Tian L, Wu QS*, Kuca K, Rahman MH. Responses of four citrus plants to Phytophthora-induced root rot. Sains Malaysiana, 2018, 47:1693-1700
[31] Tian L, Li Y, Wu QS*. Exogenous carbon magnifies mycorrhizal effects on growth behaviour and sucrose metabolism in trifoliate orange. Notulae Botanicae Horti Agrobotanici Cluj-Napoca, 2018, 46:365-370
[32] Tian L, Nasrullah, Huang XY, Wu QS*. Nitric oxide accelerates mycorrhizal effects on plant growth and root development of trifoliate orange. Sains Malaysiana, 2017, 46(10):1687-1691
2017
[33] Chi GG, Wu QS*. Effects of mycorrhizal fungion plant growth and soil properties in trifoliate orange seedlings grown in root-box. Philipp Agric Scientist, 2017, 100(3):271-277
[34] Sun P, Zhang YC, Shen YL, Feng CQ, Wu QS*. 2017. Identification of fungal community in citrus rhizosphere by ITS gene sequencing. Biotechnology, 16: 85-91.
[35] Xie Miao-Miao, Wu Qiang-Sheng*. 2017. Mycorrhiza modulates morphology, color and duration of flowers in hyacinth. Biotechnology, 16: 116-122.
[36] Liu CY, Srivastava AK, Wu QS*. Mycorrhizal fungi regulate root responses and leaf physiological activities in trifoliate orange. Notulae Botanicae Horti Agrobotanici Cluj-Napoca, 2017, 45:17-21
[37] Zhang YC, Liu CY, Wu QS*. Mycorrhiza and common mycorrhizal network regulate the production of signal substances in trifoliate orange (Poncirus trifoliata). Notulae Botanicae Horti Agrobotanici Cluj-Napoca, 2017, 45:43-49
[38] Tuo XQ, He L, Zou YN*. Alleviation of drought stress in white clover after inoculation with arbuscular mycorrhizal fungi. Notulae Botanicae Horti Agrobotanici Cluj-Napoca, 2017, 45:220-224
[39] Lu LH, Wu QS*. Mycorrhizas promote plant growth, root morphology and chlorophyll production in white clover. Biotechnology, 2017, 16:34-39
[40] Liu CY, Wu QS*. Responses of plant growth, root morphology, chlorophyll and indoleacetic acid to phosphorus stress in trifoliate orange. Biotechnology, 2017, 16:40-44
[41] Zou YN, Wang P, Liu CY, Ni QD, Zhang DJ, Wu QS*. Mycorrhizal trifoliate orange has greater root adaptation of morphology and phytohormones in response to drought stress. Scientific Reports, 2017, 7:41134; doi: 10.1038/srep41134
[42] Wu HH, Zou YN, Rahman MM, Ni QD, Wu QS*. Mycorrhizas alter sucrose and proline metabolism in trifoliate orange exposed to drought stress. Scientific Reports, 2017, 7:42389; doi: 10.1038/srep42389
[43] Huang YM, Zou YN, Wu QS*. Alleviation of drought stress by mycorrhizas is related to increased root H2O2 efflux in trifoliate orange. Scientific Reports, 2017, 7:42335; doi: 10.1038/srep42335
[44] Wang WX, Zhang F, Chen ZL, Liu J, Guo C, He JD, Zou YN, Wu QS* Responses of phytohormones and gas exchange to mycorrhizal colonization in trifoliate orange subjected to drought stress, Archives of Agronomy and Soil Science, 2017, 63:1, 14-23.
[45] Zhang YC, Wang P, Wu QH, Zou YN, Bao Q, Wu QS*. Arbuscular mycorrhizas improve plant growth and soil structure in trifoliate orange under salt stress. Archives of Agronomy and Soil Science, 2017, 63:491-500.
[46] Wu QS*, Zhang YC, Zhang ZZ, Srivastava AK. Underground communication of root hormones by common mycorrhizal network between trifoliate orange and white clover. Archives of Agronomy and Soil Science, 2017, 63:1187-1197
[47] Wu QS*, Srivastava AK, Zou YN, Malhotra SK. Mycorrhizas in citrus : Beyond soil fertility and plant nutrition. Indian Journal of Agricultural Sciences, 2017, 87:427-443
[48] Wu QS, Sun P, Srivastava AK. AMF diversity in citrus rhizosphere. Indian Journal of Agricultural Sciences, 2017, 87(5):653-656
[49] Liu CY, Srivastava AK, Zhang DJ, Zou YN, Wu QS*. Exogenous phytohormones and mycorrhizas modulate root hair configuration of trifoliate orange. Not Bot Horti Agrobo, 2016, 44(2):548-556
[50] Wu, Q.S., Zou, Y.N., 2017. Arbuscular mycorrhizal fungi and tolerance of drought stress in plants. In: Wu, Q.S. (Ed.), Arbuscular Mycorrhizas and Stress Tolerance of Plants. Springer Nature Singapora Pte Ltd., p. 25–42.
2016
[51] Zou YN, Chen X, Srivastava AK, Wang P, Xiang L, Wu QS*. Changes in rhizosphere properties of trifoliate orange in response to mycorrhization and sod culture. Applied Soil Ecology, 2016, 107:307-312
[52] Wu QS*, Liu CY, Zhang DJ, Zou YN, He XH, Wu QH. Mycorrhiza alters the profile of root hairs in trifoliate orange. Mycorrhiza, 2016, 26:237-247
[53] Wu QS*, Cao MQ, Zou YN, Wu C, He XH. Mycorrhizal colonization represents functional equilibrium on root morphology and carbon distribution of trifoliate orange grown in a split-root system. Scientia Horticulturae, 2016, 199:95-102
[54] Wu QS*, Wang S, Srivastava AK. Mycorrhizal hyphal disruption induces changes in plant growth, glomalin-related soil protein and soil aggregation of trifoliate orange in a core system. Soil and Tillage Research, 2016, 160:82-91
[55] Wu Q.-S. Srivastava A.K., Cao M.-Q. (2016): Systematicness of glomalin in roots and mycorrhizosphereof a split-root trifoliate orange. Plant Soil Environ., 62: 508-514
[56] Zou YN, Srivastava AK, Wu QS*. Glomalin: a potential soil conditioner for perennial fruits. International Journal of Agriculture and Biology, 2016, 18:293-297
[57] Liu J, Guo C, Chen ZL, He JD, Zou YN*. Mycorrhizal inoculation modulates root morphology and root phytohormone responses in trifoliate orange under drought stress. Emirates Journal of Food and Agriculture. 2016. 28(4): 251-256
2015
[58] Tuo XQ, Li S, Wu QS, Zou YN*. 2015. Alleviation of waterlogged stress in peach seedlings inoculated with Funneliformis mosseae: Changes in chlorophyll and proline metabolism. Scientia Horticulturae, 197:130-134
[59] Zhang ZZ, Lou YG, Deng DJ, Rahman MM, Wu QS*. Effects of common mycorrhizal network on plant carbohydrates and soil properties in trifoliate orange–white clover association. PLOS ONE, 2015, 10:e**
[60] Zhang F, Du P, Song CX, Wu QS*. Alleviation of mycorrhiza to magnesium deficiency in trifoliate orange: changes in physiological activity. Emirates Journal of Food and Agriculture, 2015, 27(10): 763-769
[61] Wu QS, Srivastava AK, Li Y. Effect of mycorrhizal symbiosis on growth behavior and carbohdyrate metabolism of trifoliate orange under different substrate P levels. Journal of Plant Growth Regulation, 2015, 34:495-508
[62] Zou YN, Srivastava AK, Ni QD, Wu QS*. Disruption of mycorrhizal extraradical mycelium and changes in leaf water status and soil aggregate stability in rootbox-grown trifoliate orange. Frontiers in Microbiology, 2015, 6:203, DOI: 10.3389/fmicb.2015.00203
[63] Zou YN, Huang YM, Wu QS*, He XH. Mycorrhiza-induced lower oxidative burst is related with higher antioxidant enzyme activities, net H2O2 effluxes, and Ca2+ influxes in trifoliate orange roots under drought stress. Mycorrhiza, 2015, 25:143-152
[64] Wu QS, Li Y, Zou YN, He XH. Arbuscular mycorrhiza mediates glomalin-related soil protein production and soil enzyme activities in the rhizosphere of trifoliate orange grown under different P levels. Mycorrhiza, 2015, 25:121-130
[65] Wu QS, Lou YG, Li Y. Plant growth and tissue sucrose metabolism in the system of trifoliate orange and arbuscular mycorrhizal fungi. Sci Hortic, 2015, 181:189-193
[66] Wu, Q.S., Srivastava, A.K., Cao MQ, Wang J. 2015. Mycorrhizal function on soil aggregate stability in root zone and root-free hyphae zone of trifoliate orange. Archives of Agronomy and Soil Science 51:831-825
[67] Wu, Q.S., A.K. Srivastava, S. Wang and J.X. Zeng, 2015. Exogenous application of EE-GRSP and changes in citrus rhizosphere properties. Ind. J. Agric. Sci., 85: 802–806
[68] Wang S, Wu QS*, He XH. Exogenous easily extractable glomalin-related soil protein promotes soil aggregation, relevant soil enzyme activities and plant growth in trifoliate orange. Plant Soil and Environment, 2015, 61:66-71
2014
[69] Wu QS, Cao MQ, Zou YN, He X. Direct and indirect effects of glomalin, mycorrhizal hyphae, and roots on aggregate stability in rhizosphere of trifoliate orange. Scientific Reports, 2014, 4:5823
[70] Huang YM, Srivastava AK, Zou YN, Ni QD, Han Y, Wu QS*. Mycorrhizal-induced calmodulin mediated changes in antioxidant enzymes and growth response of drought-stressed trifoliate orange. Frontiers in Microbiology, 2014, 5:682
[71] Wang S, Srivastava AK, Wu QS*, Fokom R. The effect of mycorrhizal inoculation on the rhizosphere properties of trifoliate orange (Poncirus trifoliata L. Raf.). Scientia Horticulturae, 2014, 170:137-142
[72] Wu QS, Wang S, Cao MQ, Zou YN, Yao YX. Tempo-spatial distribution and related functionings of root glomalin and glomalin-related soil protein in a citrus rhizosphere. Journal of Animal and Plant Sciences, 2014, 24:245-251
[73] Liu CY, Huang YM, Zou YN*, Wu QS. Regulation of root length and lateral root number in trifoliate orange applied by peroxide hydrogen and arbuscular mycorrhizal fungi. Not Bot Horti Agrobo, 2014,42(1):94-98
[74] Liu CY, Wu QS*. Relationships between mycorrhizas and antioxidant enzymes in citrus (Citrus tangerina) seedlings inoculated with Glomus mosseae. Pakistan Journal of Botany, 2014, 46(3):1125-1128
[75] Wu QS, Huang YM, Li Yan Nasrullah, He XH. Contribution of arbuscular mycorrhizas to glomalin-related soil protein, soil organic carbon and aggregate stability in citrus rhizosphere. International Journal of Agriculture and Biology, 2014, 16:207-212
[76] Wu QS, Ni QD, Que YC, Huang W. Calcium and calmodulin involve in mycorrhizal and root development in trifoliate orange colonized by Rhizophagus intraradices. Not Bot Horti Agrobo, 2014,42(2):380-385
[77] Zou YN, Srivastava AK, Wu QS*, Huang YM. Glomalin-related soil protein and water relations in mycorrhizal citrus (Citrus tangerina) during soil water deficit. Archives of Agronomy and Soil Science, 2014, 60:1103-1114
2013
[78] Zou YN, Wu QS*, Huang YM, Ni QD, He XH. Mycorrhizal-mediated lower proline accumulation in Poncirus trifoliata under water deficit derives from the integration of inhibition of proline synthesis with increase of proline degradation. PLoS ONE 8(11): e80568.
[79] Wu QS, Zou YN, Huang YM. The arbuscular mycorrhizal fungus Diversispora spurca ameliorates effects of waterlogging on growth, root system architecture and antioxidant enzyme activities of citrus seedlings. Fungal Ecology, 2013, 6:37-43
[80] Wu QS, Zou YN, Huang YM, Li Y, He XH. Arbuscular mycorrhizal fungi induce sucrose cleavage for carbon supply of arbuscular mycorrhizas in citrus genotypes. Scientia Horticulturae, 2013, 160:320-325
[81] Wu QS, Zou YN, He XH. Mycorrhizal symbiosis enhances tolerance to NaCl stress through selective absorption but not selective transport of K+ over Na+ in trifoliate orange. Scientia Horticulturae, 2013, 160:366-374
[82] Wu QS, He XH, Cao MQ, Zou YN, Wang S, Li Y. Relationships between glomalin-related soil protein in water-stable aggregate fractions and aggregate stability in citrus rhizosphere. International Journal of Agriculture and Biology, 2013, 15:603-606
[83] Cao MQ, Wu QS*, Zou YN. An improved ink-acetic acid technique for staining arbuscular mycorrhizas of citrus. International Journal of Agriculture and Biology, 2013, 15:386-388
[84] Wu QS, Srivastava AK, Zou YN. AMF-induced tolerance to drought stress in citrus : A review. Scientia Horticulturae, 2013, 164: 77-87
[85] Wu QS, Zou YN. Mycorrhizal symbiosis alters root H+ effluxes and root system architecture of trifoliate orange seedlings under salt stress. Journal of Animal and Plant Sciences, 2013, 23:143-148
2012
[86] Wu QS, He XH, Zou YN, He KP, Sun YH, Cao MQ. Spatial distribution of glomalin-related soil protein and its relationships with root mycorrhization, soil aggregates, carbohydrates, activity of protease and β-glucosidase in the rhizosphere of Citrus unshiu. Soil Biology and Biochemistry, 2012, 45:181-183
[87] Wu QS, He XH, Zou YN, Liu CY, Xiao J, Li Y. Arbuscular mycorrhizas alter root system architecture of Citrus tangerine through regulating metabolism of endogenous polyamines. Plant Growth Regulation, 2012, 68:27-35
[88] Wu QS, Zou YN, Liu CY, Lu T. Interacted effect of arbuscular mycorrhizal fungi and polyamines on root system architecture of citrus seedlings. Journal of Integrative Agriculture, 2012, 11:1675-1681
[89] Wu QS, Zou YN. Evaluating effectiveness of four inoculation methods with arbuscular mycorrhizal fungi on trifoliate orange seedlings. International Journal of Agriculture and Biology, 2012, 14:266-270
[90] Wu QS, Zou YN, Liu M, Cheng K. Effects of exogenous putrescine on mycorrhiza, root system architecture, and physiological traits of Glomus mosseae-colonized trifoliate orange Sseedlings. Notulae Botanicae Horti Agrobotanici Cluj-Napoca, 2012, 40:80-85
2011
[91] Wu QS, Zou YN, He XH, Luo P. Arbuscular mycorrhizal fungi can alter some root characters and physiological status in trifoliate orange (Poncirus trifoliata L. Raf.) seedlings. Plant Growth Regulation, 2011, 65:273-278
[92] Wu QS. Mycorrhizal efficacy of trifoliate orange seedlings on alleviating temperature stress. Plant Soil and Environment, 2011, 57(10):459-464
[93] Wu QS, Zou YN, He XH. Differences of hyphal and soil phosphatase activities in drought-stressed mycorrhizal trifoliate orange (Poncirus trifoliata) seedlings. Scientia Horticulturae, 2011, 129:294-298
[94] Wu QS, Zou YN, Peng YH, Liu CY. Root morphological modification of mycorrhizal citrus (Citrus tangerine) seedlings after application with exogenous polyamines. Journal of Animal & Plant Sciences, 2011, 21:20-25
[95] Wu QS, Zou YN, Wang GY. Arbuscular mycorrhizal fungi and acclimatization of micropropagated citrus. Communications in Soil Science and Plant Analysis, 2011, 42:1825-1832
[96] Wu QS, Li GH, Zou YN. Roles of arbuscular mycorrhizal fungi on growth and nutrient acquisition of peach (Prunus persica L. Batsch) seedlings. Journal of Animal & Plant Sciences, 2011, 21(4): 746-750
[97] Wu QS, Li GH, Zou YN. Improvement of root system architecture in peach (Prunus persica) seedlings by arbuscular mycorrhizal fungi, related to allocation of glucose/sucrose to root. Not Bot Horti Agrobo, 2011, 39:232-236
[98] Zou YN, Wu QS*. Sodium chloride stress induced changes in leaf osmotic adjustment of trifoliate orange (Poncirus trifoliata) seedlings inoculated with mycorrhizal fungi. Not Bot Horti Agrobo, 2011, 39:64-69
2010
[99] Wu QS, Zou YN. Beneficial roles of arbuscular mycorrhizas in citrus seedlings at temperature stress. Scientia Horticulturae, 2010, 125:289-293
[100] Wu QS, Zou YN, Zhan TT, Liu CY. Polyamines participate in mycorrhizal and root development of citrus (Citrus tangerine) seedling. Not Bot Hort Agrobot Cluj, 2010, 38:25-31
[101] Wu QS, Zou YN, Liu W, Ye XF, Zai HF, Zhao LJ Alleviation of salt stress in citrus seedlings inoculated with mycorrhiza: changes in leaf antioxidant defense systems. Plant, Soil and Environment, 2010, 56:470-475
[102] Wu QS, Zou YN, He XH. Exogenous putrescine, not spermine or spermidine, enhances root mycorrhizal development and plant growth of trifoliate orange (Poncirus trifoliata) seedlings. International Journal of Agriculture & Biology, 2010, 12:576-580
[103] Wu QS, Zou YN, He XH. Contributions of arbuscular mycorrhizal fungi to growth, photosynthesis, root morphology and ionic balance of citrus seedlings under salt stress. Acta Physiologia Plantarum, 2010, 32:297-304
[104] Wu QS, Peng YH, Zou YN, Liu CY. Exogenous polyamines affect mycorrhizal development of Glomus mosseae-colonized citrus (Citrus tangerine) seedlings. ScienceAsia, 2010, 36:254-258
2009
[105] Wu QS, Zou YN. Mycorrhiza has a direct effect on reactive oxygen metabolism of drought-stressed citrus. Plant, Soil and Environment, 2009, 55:436-442
[106] Wu QS, Zou YN. Adaptive responses of birch-leaved pear (Pyrus betulaefolia) seedlings to salinity stress. Not Bot Hort Agrobot Cluj, 2009, 37(1):133-138
[107] Wu QS, Zou YN. The effect of dual application of arbuscular mycorrhizal fungi and polyamines upon growth and nutrient uptake on trifoliate orange (Poncirus trifoliata) seedlings. Not Bot Hort Agrobot Cluj, 2009, 37(2):95-98
[108] Wu QS, Zou YN. Mycorrhizal influence on nutrient uptake of citrus exposed to drought stress. Philipp Agric Scientist, 2009, 92:33-38
[109] Wu QS, Zou YN. Arbuscular mycorrhizal symbiosis improves growth and root nutrient status of citrus subjected to salt stress. ScienceAsia, 2009, 35:388-391
2008
Wu QS, Xia RX, Zou YN. Improved soil structure and citrus growth after inoculation with three arbuscular mycorrhizal fungi under drought stress. European Journal of Soil Biology, 2008, 44:122-128
2007
[110] Wu QS, Zou YN, Xia RX, Wang MY. Five Glomus species affect water relations of Citrus tangerine during drought stress. Botanical Studies, 2007, 48:147-154
[111] Wu QS, Xia RX, Zou YN, Wang GY. Osmotic solute responses of mycorrhizal citrus (Poncirus trifoliata) seedlings to drought stress. Acta Physiologia Plantarum, 2007, 29:543-549
2006
[112] Wu QS, Xia RX. Arbuscular mycorrhizal fungi influence growth, osmotic adjustment and photosynthesis of citrus under well-watered and water stress conditions. Journal of Plant Physiology, 2006, 163:417-425
[113] Wu QS, Xia RX, Zou YN. Reactive oxygen metabolism in mycorrhizal and non-mycorrhizal citrus (Poncirus trifoliata) seedlings subjected to water stress. Journal of Plant Physiology, 2006, 163:1101-1110
[114] Wu QS, Zou YN, Xia RX. Effects of water stress and arbuscular mycorrhizal fungi on reactive oxygen metabolism & antioxidant production by citrus (Citrus tangerine) roots. Eur J Soil Biol, 2006, 42:166-172
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