OALib Journal期刊
ISSN: 2333-9721
费用：99美元

投递稿件

查看量	下载量

相关文章
更多...

应用与环境生物学报 2012

土壤氢氧化细菌促进作物生长机理研究进展

DOI: 10.3724/SP.J.1145.2012.00853, PP. 853-861

王瑾,王？之,董忠民

Keywords: 根瘤,生物固氮,轮作,氢氧化细菌,acc脱氨酶,土壤,植物根际促生菌（pgpr）

Full-Text Cite this paper Add to My Lib

Abstract:

综述了近十年来国内外关于豆科作物根际土壤促生菌中氢氧化细菌的研究进展，讨论了根瘤释放h2促进作物生长的可能机制.与豆科作物进行轮作、间作是提高土壤肥力、增加作物产量的一项传统的农业耕作方式.对于这种耕作方式优势的机制研究，过去大多数主要集中在土壤氮（n）元素含量的提高.而近期研究表明土壤氢氧化细菌以豆科作物根瘤菌在固氮过程中释放的h2为能量来源进行化能自养改变土壤微生物种群结构.一些土壤氢氧化细菌通过产生1-氨基环丙烷-1-羧酸脱氨酶和根瘤菌毒素抑制植物体内乙烯的合成，促进作物生长.此外，本文进一步讨论了利用现代分子生物学方法研究氢氧化细菌促进作物生长的途径.图3参77

References

[1]	xuxy(徐祥玉),wanghm(王海明),yuanjf(袁家富).effectofsoilfertilityqualityandyieldandqualityoftheflue-tobaccoondifferentgreenmanure.chinagricscibull(中国农学通报),2009,25(13):58~61
[2]	zhaoqg(赵其国),sunb(孙波),zhangtl(张桃林).土壤质量与持续环境ⅰ.土壤质量的定义及评价方法.soil(土壤),1997(3):113~120
[3]	medeotdb,pauluccins,albornozai,fumeromv,buenomv,garciamb,woelkemr,okony,dardanellims.plantgrowthpromotingrhizobacteriaimprovingthelegume-rhizobiasymbiosis.in:khanms,zaidia,musarratjeds.microbesforlegumeimprovement.newyork:spring-verlag,2010.473~494
[4]	shenxn(沈学年),liuxh(刘巽浩).multiplecropping.beijing,china:chinaagriculturepress(北京:中国农业出版社),1983.2~3
[5]	shijg(石建国).河西灌区玉米间套作吨粮栽培综合农艺措施数学模型的研究及应用.jmaizesci(玉米科学),2000,8(3):46~50
[6]	glasenerkm,waggermg,mackownct,volkrj.contributionsofshootandrootnitrogen-15labeledlegumenitrogensourcestoasequenceofthreecerealcrops.soilscisocamj,2002,66:523~530
[7]	peoplesmb,craswellet.biologicalnitrogenfixation:investments,expectationsandactualcontributionstoagriculture.plant&soil,1992,141:13~39
[8]	nuruzzamanm,lambersh,bollandmda,veneklaasej.phosphorusbenefitsofdifferentlegumecropstosubsequentwheatgrownindifferentsoilsofwesternaustralia.plant&soil,2005,271:175~187
[9]	stevensonfc,vankc.alandscape-scaleassessmentofthenitrogenandnon-nitrogenbenefitsofpeainacroprotation.soilscisocamj,1996,60:1797~1805
[10]	wanglg(汪立刚),liangyc(梁永超).soilfertilityimprovement,soilandwaterconservation,andeco-environmentalandeconomicbenefitasaffectedbycrop/forageintercroppinginslopingarablelands.chinagricscibull(生态农业科学),2008,24(10):482~486
[11]	bullockdg.croprotation.critrevplantsci,1992,11:309~226
[12]	hobbsja.yieldsandproteincontentsofcropsinvariousrotations.agronj,1971,63:832~836
[13]	peoplesmb,bowmanam,gaultrr,herridgedf,mccallummh,mccormickkm,nortonrm,rochesterij,scammellgj,schwenkegd.factorsregulatingthecontributionsoffixednitrogenbypastureandcroplegumestodifferentfarmingsystemsofeasternaustralia.plant&soil,2001,228:29~41
[14]	tinglech,chandlerjm.theeffectofherbicidesandcroprotationonweedcontrolinglyphosate-resistantcrops.weedtechnol,2004,18:940~946
[15]	sivcevi,stankovics,kosticm,lakicn,popovicz.populationdensityofdiabroticavirgiferavirgiferalecontebeetlesinserbianfirstyearandcontinuousmaizefields.japplentomol,2009,133:430~437
[16]	boltonef,vadirks,aylesworthwa.someeffectsofalfalfa,fertilizerandlimeoncornyieldinrotationsonclaysoilduringarangeofseasonalmoistureconditions.soilsci,1976,56:21~25
[17]	hestermanob,sheaffercc,barnesdk,lueschenwe,fordjh.alfalfadrymatterandnitrogenproduction,andfertilizernitrogenresponseinlegume-cornrotations.agronomy,1986,78:19~23
[18]	fysona,oaksa.growthpromotionofmaizebylegumesoil.plant&soil,1990,122:259~266
[19]	zanettis,hartwigua,lüschera,hebeisent,frehnerm,fischerbu,hendreygr,blumh,nosbergerj.stimulationofsymbioticn2fixationintrifoliumrepensl.underelevatedatmosphericpco2inagrasslandecosystem.plantphysiol,1996,112:575~583
[20]	dongz,layzelldb.whydolegumenodulesevolvehydrogengas?in:finantm,o’brianmr,layzelldb,vesseyjk,newtonweds.nitrogenfixationglobalperspectives.wallingford:cabipublishing,2002.331~335
[21]	phelpsas,wilsonpw.occurrenceofhydrogenaseinnitrogen-fixingorganisms.procsocexpbiol,1941,47:473~476
[22]	zhujl(朱建良),fengyz(冯有智).hydrogenproductionmechanismofnitrogenfixationmicrobe.jnanjingunivtechnol(南京工业大学学报自然科学版),2003,25(1):102~106
[23]	hunts,layzelldb.gasexchangeoflegumenodulesandtheregulationofnitrogenaseactivity.annurevplantphysiolmolbiol,1993,44:483~511
[24]	nelsonlm,salminenso.uptakehydrogenaseactivityandatpformationinrhizobiumleguminosarumbacteroids.jbacteriol,1982,151(2):989~995
[25]	dixonrod.hydrogenaseinlegumerootnodulebacteroids:occurrenceandproperties.archmicrobiol,1972,85:193~201
[26]	bensondr,arpdj,burrisrh.hydrogenaseinactinorhizalrootnodulesandrootnodulehomogenates.jbacteriol,1980,142(1):138~144
[27]	conradr,seilerw.contributionofhydrogenproductionbybiologicalnitrogenfixationtotheglobalhydrogenbudget.jgeophysres,1980,85:5493~5498
[28]	uratsusl,keyserhh,weberdf,limst.hydrogenuptake(hup)activityofrhizobiumjaponicumformmajoru.s.soybeanproductionareas.cropsci,1982,22:600~602
[29]	dongz,wul,kettlewellb,caldwellcd,layzelldb.hydrogenfertilizationofsoils―isthisabenefitoflegumesinrotation?.plantcell&environ,2003,26:1875~1879
[30]	aragnom,schlegelhg,starrmp,stolph,truperhg.theprokaryotes-ahandbookonhabitats,isolationandidentificationofbacteria.newyork,usa:spring-verlag,1981.865~893
[31]	maimaitij.isolationandcharacterizationofh2oxidizingbacteriainh2treatedsoilandsoiladjacenttohupsoybeannodules:[masterdegreedissertation].saintmary’suniversity,halifax,ns,canada,2005
[32]	freidrichb,schwartze.molecularbiologyofhydrogenutiliztioninaerobicchemolithotrophs.annurevmicrobiol,1993,47:351~383
[33]	holtjg,kriegnr,sneathpha,staleyjt,williamsst.bergey’smanualofdeterminativebacteriology.baltimore:williams&wilkins,1994
[34]	chenxd(陈兴都),wangww(王卫卫),fub(付博),xiaolm(肖黎明),guoy(郭燕).growthpromotingeffectofhydrogen-oxidizingbacteriainsoybeanrhizosphere.actabotbor-occidsin(西北植物学报),2008,28(1):136~140
[35]	haringv,kluberhd,conradr.localizationofatmospherich2-oxidizingsoilhydrogenasesindifferentparticlefractionsofsoi.biolfertsoil,1994,18:109~114
[36]	mayx(马悦欣),carolah,jeremyw,staffank.applicationofdenaturinggradientgelelectrophoresis(dgge)inmicrobialecology.actaecolsin(生态学报),2003,23(8):1561
[37]	leedh,zoyg,kimsj.nonradioactivemethodtostudygeneticprofilesofnaturalbacterialcommunitiesbypcr-single-stand-conformationpolymorphism.applmicrobiol,1996,62:3112~3120
[38]	dengmy(邓墨渊),wangbc(王伯初),yangzc(杨再昌),wangl(王黎).theapplicationoftechniquesofmolecularbiologyinclassificationandidentificationofendophytes.aminoacids&bioticresour(氨基酸和生物资源),2006,28(3):9~14
[39]	steins,selesid,schillingr,pattisi,schmidm,hartmanna.microbialactivityandbacterialcompositionofh2-treatedsoilswithnetco2fixation.soilbiolbiochem,2005,37:1938~1945
[40]	taizl,zeigere.plantphysiology.redwood:benjamin/cummingspublishingcompany,1991.565
[41]	hunterwj.ethyleneproductionbyrootnodulesandeffectofethyleneonnudulationinglycinemax.applenvironmicrobiol,1993,59(6):1947~1950
[42]	shahs,lij,moffattba,glickbr.isolationandcharacterizationofaccdeaminasegenesfromtwodifferentplantgrowth-promotingrhizobacteria.canjmicrobiol,1998,44:833~843
[43]	weij(卫军),qil(其林),zhangyq(张永清),qiubs(邱并生),caimy(蔡妙英).isolationandidentificationofsoilbacteriacontainingaccdeaminase.chinbiodiv(生物多样性),1994,2(1):29~32
[44]	sugawaram,okazakis,nukuin,ezurah,mitsuih,minamisawak.rhizobitoxinemodulatesplant-microbeinteractionsbyethyleneinhibition.biotechnoladv,2006,24:382~388
[45]	marciaah,peterbk.hormonalregulationoflateralbud(tiller)releaseinoats.plantphysiol,1980,66:1123~1127
[46]	wanggy,volkerr,licj,bangerthf.involvementofauxinandcksinborondeficiencyinducedchangesinapicakdominanceofpeaplants.jplantphysiol,2006,163:591~600
[47]	licx(李春喜),zhaogc(赵广才),daixm(代西梅),jiangln(姜丽娜),shangyl(尚玉磊).researchontherelationshipbetweenwheattilleringdynamicsandendogenoushormone.actaagronsin(作物学报),2000,26(6):963~968
[48]	angerrhm,prasadpc,laudehm.effectsofkinetinontillerbudelongationinwheat(triticumaestivuml.).annbot,1973,37:565~571
[49]	pattenc,glickb.roleofpseudomonasputidaindoleaceticacidindevelopmentofthehostplantrootsystem.applenvironmicrobiol,2002,68:3795~3801
[50]	selvaduraiel,brownae,hamiltonjtg.productionofindole-3-aceticacidanaloguesbystrainsofbacilluscereusinrelationtotheirinfluenceonseedlingdevelopment.soilbiolbiochem,1991,23:401~403
[51]	lebuhnm,heulint,hartmanna.productionofauxinandotherindolicandphenoliccompoundsbypaenibacilluspolymyxastrainsisolatedfromdifferentproximitytoplantroots.femsmicrobiolecol,1997,22:325~334
[52]	ryucm,faragma,huch,reddyms,weihx,parépw,kloepperjw.bacterialvolatilespromotegrowthinarabidopsis.procnatlacadsciusa,2003,100:4927~4932
[53]	yasare,sezaie,ayhanh,ramazanc.effectsofplantgrowthpromotingrhizobacteria(pgpr)onrootingandrootgrowthofkiwifruit(actinidiadeliciosa)stemcuttings.biolres,2010,43:91~98
[54]	gans,amoasinorm.inhibitionofleafsenescencebyauto-regulatedproductionofcytokinin.science,1995,270:1986~1988
[55]	fuyc(付永彩),dingyy(丁月云),liuxf(刘新仿),suncq(孙传清),caosy(曹守云),wangdj(王东江),hesj(何锶洁),wangxk(王象坤),lilc(李良才),tianwz(田文忠).抑制衰老的嵌合基因在水稻中的转化.chinscibull(科学通报),1998,43(18):1963~1967
[56]	schuheggerr,ihringa,gantners,bahnwegg,knappec,voggg,hutzlerp,schmidtm,vanbreusegemf,eberll.inductionofsystemicplantresistancebyn-acylhomoserinelactone-producingrhizospherebacteria.plantcellenviron,2006,29:909~918
[57]	bornemanj,skrochpw,o’sullivankm,palusja,rumjanekng,jansenjl,nienhuisj,triplettew.molecularmicrobialdiversityofanagriculturalsoilinwisconsin.applenvironmicrobiol,1996,62:1935~1943
[58]	wuch(吴存浩).中国农业史.beijing,china(北京).警官教育出版社,1996.554
[59]	rochesterij,peoplesmb,hulugallenr,gaultrrandconstablega.usinglegumestoenhancenitrogenfertilityandimprovesoilconditionincottoncroppingsystems.fieldcropsres,2000,70:27~41
[60]	dongz,layzelldb.h2oxidation,o2uptakeandco2fixationinhydrogentreatedsoils.plant&soil,2001,229:1~12
[61]	conradr,seilerw.fieldmeasurementsofhydrogenevolutionbynitrogen-fixinglegumes.soilbiolbiochem,1979a,11:689~690
[62]	conradr,seilerw.theroleofhydrogenbacteriaduringthedecompositionofhydrogenbysoil.femsmicrobiollet,1979b,6:143~145
[63]	deanc,sunw,dongz,caldwellcd.soybeannodulehydrogenmetabolismaffectssoilhydrogenuptakeandgrowthofrotationcrops.canjplantsci,2006,86:1355~1359
[64]	mclearnn,dongz.microbialnatureofthehydrogenoxidizingagentinhydrogentreatedsoil.biolfertilsoil,2002,35:465~469
[65]	irvinep,smithm,dongz.hydrogenfertilizer:bacteriaorfungi?actahorticult,2004,631:239~242
[66]	maimaitij,zhangy,yangj,cenyp,layzelldb,peoplesm,dongz.isolationandcharacterizationofhydrogen-oxidizingbacteriainducedfollowingexposureofsoiltohydrogengasandtheirimpactonplantgrowth.environmicrobiol,2007,9:435~444
[67]	chenxd(陈兴都),wangww(王卫卫),guolw(郭立伟).isolation,screeningandcharacterizationofhydrogen-oxidizingbacteriainsoybeanrhizosphere.chinjapplecol(应用生态学报),2007,18(9):2069~2074
[68]	kliberhd,lechners,cornadr.characterizationofpopulationsofaerobichydrogen-oxidizingsoilbacreria.fensmicrobiolecol,1995,16:167~176
[69]	lechners,conradr.detectioninsoilofaerobichydrogen-oxidizingbacteriarelatedtoalcaligeneseutrophusbypcrandhybridizationassaystargetingthegeneofthemembrane-bound(nife)hydrogenase.femsmicrobiolecol,1997,22:193~206
[70]	zhangy,hex,dongz.effectofhydrogenonsoilbacterialcommunitystructureintwosoilsasdeterminedbyterminalrestrictionfragmentlengthpolymorphism.plant&soil,2009,320:295~305
[71]	goldinga,dongz.hydrogenproductionbynitrogenaseasapotentialcroprotationbenefit.environchemlett,2010,8:101~121
[72]	arkhipovatn,veselovsu,melentievai,mertynenkoev,kudoyarovagr.abilityofbacteriumbacillussubtilistoproducecytokininsandtoinfluencethegrowthandendogenoushormonecontentoflettuceplants.plant&soil,2005,272:201~209
[73]	mohammadsk,almasz,parvazeaw,mohammado.roleofplantgrowthpromotingrhizobacteriaintheremediationofmetalcontaminatedsoils.environchemlett,2009,7:1~19
[74]	gabrieleb.plant�microbeinteractionspromotingplantgrowthandhealth:perspectivesforcontrolleduseofmicroorganismsinagriculture.applmicrobiolbiotechnol,2009,84:11~18
[75]	hynesrk,leunggcy,hirkaladlm,nelsonlm.isolation,selection,andcharacterizationofbene?cialrhizobacteriafrompea,lentil,andchickpeagrowninwesterncanada.canjmicrobiol,2008,54(4):248~258
[76]	zwolinskimd.dnasequencing:strategiesforsoilmicrobiology.soilscisocamj,2007,71:592~600
[77]	siezenrj,wilsong,todtt.prokaryoticwhole-transcriptomeanalysis:deepsequencingandtilingarrays.microbialbiotechnol,2010,3:125~130

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133