甘艳露;周婵;夏黎;刘洁;

• 1:新疆维吾尔自治区遥感中心

摘要(Abstract)：

介绍了国内外在水稻植株厌氧降解过程中脂肪酸类物质微生物互养氧化降解机理方面的研究进展,并对今后的研究方向提出了建议。

关键词(KeyWords)： 厌氧水稻土;中间产物;脂肪酸;互养氧化;产甲烷

Abstract:

Keywords:

基金项目(Foundation): 新疆维吾尔自治区高技术研究与发展计划项目(200815119)

作者(Author): 甘艳露;周婵;夏黎;刘洁;

Email:

DOI: 10.13989/j.cnki.0517-6611.2010.22.087

参考文献(References)：

• [1]东秀珠.甲酸盐和分子氢在丙酸和丁酸互营降解中的作用[J].微生物学通报,1997,24(1):51-56.
• [2]李晶,王明星,郑循华,等.稻田生态系统甲烷排放的机理研究[J].中国基础科学研究进展,2000(7):19-23.
• [3]BOONE D RA,D BRYANTMP.Propionate-degradingbacterium,Syntro-phobacterwoliniisp.nov.gen.Nov,frommethanogenic ecosystems.Applied and Environmental Microbiology,1980,40:626-632.
• [4]BRYANTMP,WOLINE A,WOLINMJ,et al.Methanobacillus omelian-skii,a symbiotic association of two species of bacteria[J].Arch Mikrobiol,1967,59:20-31.
• [5]BRYANTMP.Microbial methane production-theoretical aspects[J].Jour-nal of Animal Science,1979,48:193-201.
• [6]CHINK J,CONRAD R.Intermediary metabolism in methanogenic paddy soil and the influence of temperature[J].FEMS Microbiology Ecology,1995,18:85-102.
• [7]CONRAD R.Mechanisms controlling methane emission from wetland rice fields[M]∥ORMELAND RS.The biogeochemistryof global change:radi-oactive trace gases.NewYork:Chapman and Hall,1993:317-335.
• [8]CONRADR.Contributionofhydrogentomethane productionand control of hydrogen concentrations in methanogenic soils and sediments[J].Minire-view.FEMS Microbiology Ecology,1999,28:193-202.
• [9]CRUTZENP J.Methanes'sinks and sources[J].Nature,1991,350:380-381.
• [10]DE BOKF AM,STAMS AJ M,DIJKEMAC,et al.Pathway of propio-nate oxidation bya syntrophic culture ofSmithella propionica andMetha-nospirillumhungatei[J].Applied and Environmental Microbiology,2001,67:1800-1804.
• [11]DWYER D F,WEEG-AERSSENS E,SHELTOND R,et al.Bioenergetic conditions of butyrate metabolismbya syntrophic,anaerobic bacteriumin coculture with hydrogen-oxidizing methanogenic and sulfidogenic bacteri-a.Applied and Environmental Microbiology,1988,54:1354-1359.
• [12]FUKUZAKI S,NISHION,SHOBAYASHI M,et al.Inhibition of the fer-mentation of propionate to methane by hydrogen,acetate,and propionate[J].Applied and Environmental Microbiology,1990,56:719-723.
• [13]GLISSMANNK,CONRAD R.Fermentation pattern of methanogenic deg-radation of rice strawin anoxic paddysoil[J].FEMSMicrobiologyEcolo-gy,2000,31:117-126.
• [14]HARMSENHJ M,WULLINGSB,AKKERMANSADL,etal.etal Phy-logenetic analysis ofSyntrophobacter woliniireveals a relationship with sulfate-reducing bacteria[J].Archives of Microbiology,1993,160:238-240.
• [15]HARMSENHJ M,KENGENKMP,AKKERMANS AD L.Phylogenetic analysis of2syntrophic propionate-oxidizing bacteria in enrichments cul-tures[J].Systematic and Applied Microbiology,1995,18:67-73.
• [16]HARMSENHJ M.Detection,phylogenyand population dynamics of syn-trophic propionate-oxidizing bacteria in anaerobic granular sludge[D].The Netherlands:Wageningen Agricultural University,Wageningen,1996:154.
• [17]HOGANKB.Methane on the greenhouse agenda[J].Nature,1991,354:1811-1821.
• [18]HOUWENF P,DIJKEMAC,SCHOENMAKERS C HH,et al.13C-NMR study of propionate degradation by a methanogenic coculture[J].FEMS Microbiol Lett,1987,41:269-274.
• [19]HOUWENF P,PLOKKER J,STAMS A J M,et al.Enzymatic evidence for involvementofthe methylmalonyl-CoApathwayinpropionate oxidation bySyntrophobacterwolinii[J].Archives of Microbiology,1990,155:52-55.
• [20]IMACHI H,SEKIGUCHI Y,KAMAGATA Y,et al.Pelotomaculum ther-mopropionicumgen.nov.,sp nov.,an anaerobic,thermophilic,syntrophic propionate-oxidizing bacterium[J].International Journal of Systematic and Evolutionary Microbiology,2002,52:1729-1735.
• [21]METXB,DAVIDSONOR,BOSCHPR,etal.Climate change2007:Miti-gation.Contribution ofWorkinggroup III tothe FourthAssessmentReport of the Intergovernmental Panel on Climate Change[R].Cambridge Uni-versityPress,Cambridge,United Kingdomand NewYork,NY,USA,2007.
• [22]KHALIL M A,RASMUSSEN R A,SHEARER M J.Factors affecting methane emissions fromrice fields[J].Journal of Geophysical Research,1998,103:25219-25231.
• [23]KRYLOVANI,JANSSENP H,CONRAD R.Turnover of propionate in methanogenic paddysoil[J].FEMSMicrobiologyEcology,1997,23:107-117.
• [24]LIUYT,BALKWILLD L,ALDRICHHC,et al.Characterization of the anaerobic propionate-degrading syntrophsSmithella propionicagen.nov.,sp.nov.andSyntrophobacterwolinii[J].International Journal of Systemat-ic Bacteriology,1999,49:545-556.
• [25]LUY,WATANABE A,KIMURA M.Carbon dynamics of rhizodeposits,root-and shoot-residues in rice soil[J].Soil Biology and Biochemistry,2003,35:1223-1230.
• [26]LUEDERS T,POMMERENKE B,FRIEDRICHMW.Stable-isotope pro-bing ofmicroorganismsthrivingatthermodynamic limits:syntrophic propi-onate oxidation in flooded soil[J].Applied and Environmental Microbiol-ogy,2004,70:5778-5786.
• [27]MARIKOS,HARAZONOY,OWAN,et al.Methane in flooded soil water and the emission through rice plants to the atmosphere[J].Environmen-tal and Experimental Botany,1991,31:343-350.
• [27]MCINERNEYMJ,BRYANTMP,PFENNIGN.Anaerobic bacteriumthat degrades fatty acids in syntrophic association with methanogens[J].Ar-chives of Microbiology,1979,122:129-135.
• [28]PENGJ J,LUZ,RUI J P,et al.Dynamics of the methanogenic archaeal community duringplant residue decomposition in an anoxic rice field soil[J].Applied and Environmental Microbiology,2008,74:2894-2901.
• [29]PLUGGECM,DIJKEMAC,STAMSAJ M.Acetyl-CoAcleavage pathway in a syntrophic propionate oxidizingbacteriumgrowingon fumarate in the absence of methanogens[J].FEMS Microbiology Letters,1993,110:71-76.
• [30]PLUGGE C M,BALKMSTAMS AJ M.Desulfotomaculumthermobenzoi-cumsubspthermosyntrophicumsubsp nov.,a thermophilic,syntrophic,propionate-oxidizing,sporeforming bacterium[J].International Journal of Systematic and Evolutionary Microbiology,2002,52:391-399.
• [31]RAMAKRISHNANB,LUEDERST,DUNFIELDPF,etal.Archaeal com-munity structures in rice soils from different geographical regions before and after initiation of methane production[J].FEMS Microbiology Ecolo-gy,2001,37:175-186.
• [32]SASSRL,FISHERJ FM.Methane emissionfromrice paddies:Aprocess studies summary[J].NutrientCyclinginAgroecosystems,1997,49:119-127.
• [33]SCHUTZ H,HOLZAPFEL-PSCHORN A,CONRAD R,et al.A3-year continuous record on the influence of daytime,season,and fertilizer treat-ment on methane emission rates froman Italian rice paddy[J].Journal of Geophysical Research,1989,94:16405-16416.
• [34]SCHINK B,THAUER R K.Energetics of syntrophic methane formation and the influence of aggregation[M]∥LETTINGAG,ZEHNDER AJ B,GROTENHUIS J TC,et al.Granular anaerobic sludge;microbiology and technology.Wageningen,The Netherlands:Pudoc,1988:5-17.
• [35]SCHINK B.Syntrophism among prokaryotes[M]∥BALOWS A,TRU-PER H G,DWORKIN M,et al.The prokaryotes.2nd ed.New York:Springer-Verlag,1991:276-299.
• [36]SCHINKB.Energetics of Syntrophic Cooperation in Methanogenic Degra-dation[J].Microbiology and Molecular Biology Reviews,1997,61:262-280.
• [37]SCHINK B,STAMS A J M.Syntrophism among prokaryotes[M]∥DWORKINM.The prokaryotes.NewYork:Springer,2002.
• [38]SCHMIDTJ E,AHRINGB K.Interspecies electron transfer duringpropi-onate and butyrate degradation in mesophilic granularsludge[J].Applied and Environmental Microbiology,1995:61:2765-2767.
• [39]STAMSAJ M.Metabolic interactionsbetweenanaerobic bacteria inmeth-anogenic environments[J].Antonie van Leeuwenhoek,1994,66:271-294.
• [40]WALLRABENSTEIN C,HAUSCHILD E,SCHINK B.Pure culture and cytological properties ofSyntrophobacterwolinii[J].FEMS Microbiol Lett1994,123:249-254.
• [41]WATANABE A,KATOHK,KIMURAM.Effect of rice strawapplication on CH4emission frompaddyfields.2.Contribution of organic constituents in rice straw[J].Soil Science and Plant Nutrition,1993,39:707-712.
• [42]WOLIN MJ.Microbiol interaction and communities[M].London:Aca-demic Press,1982:323-356.
• [43]ZINDER S H.Physiological ecology of methanogens[M]∥FERRY J G.Methanogenesis:Ecology,Physiology,Biochemistry and Genetics.New York:Chapman and Hall,1993:128-206.
• [44]WANG R L,HUA C,ZHOUF,et al.Effects of salt stress on fatty acid composition of thylakoid membrane of two rice cultivars differing in salt tolerance[J].Agricultural Science&Technology,2008,9(4):8-13.
• [45]周杰,王海英.尿素浓度对三角褐指藻的生长及其脂肪酸组成的影响[J].畜牧与饲料科学,2008,29(4):24-26.