Resource Status of Mycorrhizal Fungi Increase Plant Saline-alkaline Tolerance

doi:10.7668/hbnxb.2010.S2.055

Abstract

Abstract: "Salinization is a compelling global problem and large area of China is covered by saline-alkali soil,which has imposed severe influence over the agricultural development.Therefore,improving the salt-alkaline resistance of plants and reforming soil structure have been a very challenging issue to biological science.Mycorrhizal fungi are soil microorganisms universally existing in the ecological system,and they play a significant role in increasing the salt-alkaline resistance in the host plants,which has drawn increasing attention of scholars both at home and abroad.This article reviews recent national and international academic achievements based on the effects of mycorrihizal fungi on the growth and nutrition absorption of plants under salinity-alkalinity stress and the mechanism of the improvement of the plants' salt resistance.Furthermore,it also probes into current challenging issues and research tendency in the near future. "

Key words: Mycorrh izal fung, iMycorrh izal plant, Saline-alkaline to lerance

CLC Number:

S156.4

CHUAI Ze-yao, WANG Dong-mei. Resource Status of Mycorrhizal Fungi Increase Plant Saline-alkaline Tolerance[J]. ACTA AGRICULTURAE BOREALI-SINICA, 2010, 25(S2): 254-258. doi: 10.7668/hbnxb.2010.S2.055.

/ / Recommend / Download Citations

URL: http://www.hbnxb.net/EN/10.7668/hbnxb.2010.S2.055

http://www.hbnxb.net/EN/Y2010/V25/IS2/254

References

[1] 吴强盛,刘琴.果树对盐胁迫的响应和耐盐机制[J].长江大学学报:自然科学版,2007(4):9-12.
[2] 刘友良,毛良才,汪良驹.植物耐盐性研究进展[J].植物生理学通讯,1987(4):1-7.
[3] 谢承陶.盐渍土改良原理与植物抗盐[M].北京:中国农业科技出版社,1993.
[4] Ruizl J M,Azcon R.Grass tetany of ruminants[J].Adv Agron,1970,22:332-374.
[5] 赵可夫,李法曾中国盐生植物[M].北京:科学出版社,1999.
[6] Rozrma J,Arp W.Occurrence and ecological siganificance of VAM in the salt marsh environment[J].Acta Botanical Nethlandica,1986,35(4):457-467.
[7] 王幼珊,张美庆,张驰.VA菌根真菌抗盐碱菌株的筛选[J].土壤学报,1994,21(5):79-83.
[8] 冯固,李晓林,张福锁,等.施磷和接种AM真菌对玉米耐盐性的研究[J].植物资源与环境学报,2000,9(2):22-26.
[9] 冯固,张福锁.丛枝菌根真菌对棉花耐盐性的影响研究[J].中国生态农业学报,2003,11(2):21-24.
[10] 唐振尧,何首林.菌根促进柑桔吸收难溶性磷肥的机理研究-I.磷酸酶活性对柑桔吸收磷的作用[J].中国南方果树,1991(2):7-10.
[11] 李敏,辛华,郭绍霞,等.AM真菌对盐渍土壤中番茄、辣椒生长和矿质养分吸收的影响[J].莱阳农学院学报,2005,22(1):38-41.
[12] 王曙光,林先贵,董元华,等.丛枝菌根(AM)对无性繁殖茶苗生长及茶叶品质的影响[J].植物学通报2002,19(4):462-468.
[13] 林智.VA菌根对茶树生长和矿质元素吸收的影响[J].茶叶科学,1993,2(l):15-20.
[14] 贺超兴,张志斌,王怀松,等.丛枝菌根真菌对番茄苗期生长及矿质营养吸收的作用[J].中国蔬菜,2006(1):9-11.
[15] 刘晓捷,曾明,杜建斌,等.AMF对葡萄扦插苗矿质营养及生长的影响[J].中国蔬菜,2005,20(10):286-289.
[16] 李登武,王冬梅,贺学礼.丛枝菌根真菌对烟草钾素吸收的研究[J].应用生态学报,2003,14(10):1719-1722.
[17] 周文龙,张政勤,姚丽贤.接种VA菌根对高粱吸收中、微量元素的影响[J].热带亚热带土壤科学,1998,7(1):72-74.
[18] 王发园,林先贵,尹睿.丛枝菌根真菌对海州香薷生长及其Cu吸收的影响[J].环境科学,2005(9):174-180.
[19] Guttay A J R.Impact of deicing salt upon the endomycorrhizae of roadside sugar maples[J].Soil Sci Soc Amerj,1976,40:952-954.
[20] Al-karaki G N,Hammad R,Rusan M.Response of two tomato cultivars differing in salt tolerance to inoculation with mycorrhizal fungi under salt stress[J].M ycorrhiza,2001,11:43-47.
[21] Yano-Melo A M,Saggin 0 J,Maia L C.Tolerance of mycorrhized banana(Musa sp.cv.pacovan)plantlets to saline stress[J].Agriculture,Ecosystems＆Environment,2003,9(5):343-348.
[22] Sharifi M,Ghorbanli M,Ebrahimzadeh H.Improved growth of salinity-stressed soybean after inoculation with salt pre-treated mycorrhizal fungi[J].Journal of Plant Physiology,2007,16(4):1144-1156.
[23] Ruizoj M,Azcon R,Gomezm.Alleviation of salt stress by arbuscular mycorrhiza Glomus species in lactuca sativap lants[J].Physiol Plant,1996,98(4):767-772.
[24] 冯固,白灯莎,杨茂秋.盐胁迫对VA菌根形成及接种VAM真菌对植物耐盐性的效应[J].应用生态学报,1999,10(1):79-82.
[25] 唐明.VA菌根提高植物抗盐碱和抗重金属能力的研究进展[J].土壤,1998,30(5):251-254.
[26] Muhsin T M,Zwiazek T J.Colonization with Heleloma crustuliniform increases water copductance and limits shoot sodium uptake in white spruce(Picea glauca)seedlings[J].Plant and Soi1,2002,23(8):217-225.
[27] 黄艺,姜学艳,梁振春,等.外生菌根真菌接种和施磷对油松幼苗抗盐性的影响[J].生态环境,2004,13(4):622-625.
[28] Cantrell I C,Linderman R G.Preinoculation of lettuce and onion with VA mycorhizal fungi reduces deleterious efects of soil salinity[J].Plant and Soil,2001,23(3):269-281.
[29] George E,Marschner H,Jakobsen I.Role of arbuscular mycorrhizal fungi in uptake of phosphorus and nitrogen from soil[J].Crit Rev Biotechno1,1995,15:257-270.
[30] Bolann S.A critical review of the role of mycorrhizal fungi in the uptake of phosphorus by plants[J].Plant Soil,1991,13(4):189-208.
[31] Burkert B,Robson A.Zn uptake in subterranean clover(Trifolium subterraneum L.)by three vesicular-arbuscular mycorhizal fungi in a root-free sandy soil[J].Soil Biof Biochem,1994,26(1):117-124.
[32] Graham J H.Citrus mycorhizae:potential bene(r)is and interactions with pathogens[J].Hort Science,1986,21(1):302-306.
[33] Copeman R H,Martin C A,Stutz J C.Tomato growth in response to salinity and mycorhizal fungi from saline or nonsaline soil[J].Hort Science,1996,3(1):341-344.
[34] 毕银丽,丁保建,全文智,等.VA菌根对白三叶吸收水分和养分的影响[J].草地学报,2001,9(2):154-158.
[35] Ruiz-Lozano J M,Azcon R,Gomez M.Alleviation of salt stress by arbuscular-mycorhizal Glomus species in L actuca sativa plants[J].Physiologia Plantarum,1996,9(8):767-772.
[36] Schubert A,Lubraco G.Mycorhizal inoculation enhances growth and nutrien t uptake of micropropagated apple rootstocks during weaning in commercial substrates of high nutrient availability[J].Applied Soil Ecology,2000,1(5):113-118.
[37] Morin F,Fortin J A,Hamelc,el al.Apple rotstock response tovesicular-arbuscular mycorhizal fungi in a high phosphorous soil[J].J Am Soc Hort Science,1994,19(1):578-583.
[38] Grattan S R Grieve M.Mineral element acquisition and growth response of plants growth in saline environments[J].Agriculture,Ecosystem and Environment,1992,3(8):275-300.
[39] Awad A S,Edwards D G,Campbell L C.Phosphorus enhancement of salt tolerance of tomato[J].Corp Science,1990,30:123-128.
[40] Gouia H,Ghorbal M H,Touraine B.Efects of NaCl on flows of N and mineral ions and on N0_3 reduction rate within whole plants of salt-sensitive bean and salt-tolerant cotton[J].Plant Physiol,1994,10(5):1409-1418.
[41] 冯固,杨茂秋,白灯莎.盐胁迫下VA菌根真菌对无芒雀麦体内矿质元素含量及组成的影响[J].草业学报,1998,3;21-28.
[42] Franklin J A,Zwlazek J J.Effect of NaCl and Na_2SO_4 on red-osier dogwood(Cornus stolonifera Michx)seedlings[J].Plant and Soil,2001,23(3):261-268.
[43] Dalton F N,Maggio A,Piainni G.Simulation of shot chloride accumulation:separation of physical and biochemical proc esses governing plant sal tolerance[J].Plant and Soil,2000,21(9):1-11.
[44] Berta G,Fusconi A,Trotta A,et al.Morphogenetic modifications induced by the mycorhizal fungus strain E3 in the root system of Alliumporrum L[J].New Phytol,1990,11(4):207-215.
[45] Davies F T,Porter J R,Linderman R G.Drought resistance of mycorhizal pepper plants-independent of leaf phosphorus concentration,response in gas exchange,and water relations[J].Physiol Plant,1993,8(7):45-53.
[46] 冯固,李晓林,张福锁,等.VA菌根提高植物耐盐性研究进展[J].西北农业大学学报,1999,27(3):94-100.
[47] 姚艳玲,冯固,白灯沙?买买提艾力.NaCl胁迫下VA菌根对玉米耐盐能力的影响[J].新疆农业科学,1999(1):20-22.
[48] Guttay A J R.Impact of deicing salt upon the endomycorhizae of roadside sugar maples[J].Soil Sci Soc Miner J,1976,4:952-954.
[49] Duan X,Neuman D,Reiber J,et al.Mycorhizal influence on hydraulic and hormonal factors implicated in the control of stomatal conductance during drought[J].J Exp Bot,1996,4(7):1541-1550.
[50] 刘润进,郝文英.VA菌根真菌对植物水分代谢的影响[J].土壤学报,1994,3(增刊):46-53.
[51] 冯固,李晓林,张福锁,等.盐胁迫下丛枝菌根真菌对玉米水分和养分状况的影响[J].应用生态学报,2000,11(4):595-598.
[52] Rosendahl C N,Rosendahl S.Influence of vesicular-arbuscular mycorhizal fungi(Glomus spp.)on the response of cucumber(Cucumis sativus L.)to salt stress[J].Environ Exp Bot,1991,31(3):313-318.
[53] Jindal V,Atwal A,Sekson B S,et al.Effect of vesicular-arbuscular mycorhizae on metabolism of moong plants under NaCl salinity[J].Plant Physiol Biochem,1993,3(1):475-481.
[54] Duke E R,Johnson C R,Koch K E.Accumulation of phosphorus,dry mater and betalne during NaCl stress of slip-root citrus seedlings colonized with vasicular-arbuscular mycorhizal fungi on zero,one or two halves[J].New Photo1,1986,10(4):583-590.

Please choose a citation manager

Content to export