相容性溶质对高盐废水生物处理应用研究进展
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摘要
综述了相容性溶质的调渗机制,总结了相容性溶质分别对蛋白质、DNA和脂质等的保护作用,介绍了相容性溶质对微生物耐盐性能影响和耐盐冲击的影响,展望了未来在高盐废水处理领域相容性溶质的研究方向。
The mechanism of osmoregulation of compatible solutes was reviewed,the protective effects of compatible solutes on protein DNA and lipid were summarized,the effect of compatible solutes on salt tolerance and salt shock resistance of microorganism was introduced,the research direction of compatible solute in the field of high salinity wastewater treatment was prospected.
The mechanism of osmoregulation of compatible solutes was reviewed,the protective effects of compatible solutes on protein DNA and lipid were summarized,the effect of compatible solutes on salt tolerance and salt shock resistance of microorganism was introduced,the research direction of compatible solute in the field of high salinity wastewater treatment was prospected.
引文
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[3] Pratiksha J,Mohita S,Prem D,et al. Bioelectrochemical approaches for removal of sulfate,hydrocarbon and salinity from produced water[J]. Chemosphere,2017,166:96-108.
[4] Sibel A,Nusret S. Salt inhibition on anaerobic treatment of high salinity wastewater by upflow anaerobic sludge blanket(UASB)reactor[J]. Desalination and Water Treatment,2016,57:12998-13004.
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[11]张玉华,凌沛学,籍保平.海藻糖的研究现状及其应用前景[J].食品与药品,2005,7(3):8-13.
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[14]卢良坤,罗立新,黎攀,等.甘氨酸甜菜碱和分子伴侣dna K在嗜盐四联球菌耐盐机制中的作用[J].中国酿造,2013,32(2):25-32.
[15] Arpita R,Dieter H,Filipp O. Effect of the compatible solute ectoine on the stability of the membrane proteins[J].Protein&Peptide Letters,2012,19:791-794.
[16] Stefan K,Rudolf L E,Galinski A. Extrinsic protein stabilization by the naturally occurring osmolytesβ-hydroxyectoine and betaine[J]. Extremophiles,1999(3):191-198.
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[18]朱道辰,刘杏荣.相容性溶质四氢嘧啶及其羟基化衍生物的研究进展[J].中国生物工程杂志,2011,31(2):95-101.
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[20]高志民,彭镇华.甜菜碱合成调控基因共表达载体的构建与抗盐初步研究[J].林业科学研究,2005,18(3):231-235.
[21] Cristina S P,Roberto D L,Indira C,et al. Interaction of the disaccharide trehalose with a phospholipid bilayer:A molecular dynamics study[J]. Biophysical Journal,2004,86:2273-2285.
[22]陈杰,何聪芬,叶兴国,等.海藻糖及其在生物工程方面的应用[J].生物技术通报,2005(6):29-33.
[23] Jens S,Rakesh K H,Hans J G,et al. Low concentrated hydroxyectoine solutions in presence of DPPC lipid bilayers:A computer simulation study[J]. Biophysical Chemistry,2013,180/181:102-109.
[24] Rakesh K H,Stephanie W,Georg L,et al. The effect of compatible solute ectoines on the structural organization of lipid monolayer and bilayer membranes[J]. Biophysical Chemistry,2010,15:37-46.
[25] Laura C C,JoséL S,Blanca E B. Biodegradation of organic pollutants in saline wastewater by halophilic microorganisms:a review[J]. Environmental Science Pollution Research,2014,21(16):9578-9588.
[26] Maricy R L,Matthew J G,Encarnacion M,et al. Biodegradation of aromatic hydrocarbons by Haloarchaea and their use for the reduction of the chemical oxygen demand of hypersaline petroleum produced water[J]. Chemosphere,2011,84:1671-1676.
[27] Muhammad A,Samina I,Sakandar R,et al. Characteristics of phenol biodegradation in saline solutions by monocultures of Pseudomonas aeruginosa and Pseudomonas pseudomallei[J]. Journal of Hazardous Materials,2007,149:60-66.
[28] Larissa Q,Claudio M S,Sergio O,et al. Nitrification of petroleum extraction produced water:Salt concentrations and nitrifying activity[J]. Environmental Engineering Science,2017,34(4):258-264.
[29] Scott D M,Michael L N,Andrew D H. Betaines and related osmoprotectants. Targets for metabolic engineering of stress resistance[J]. Plant Physiology,1999,120:945-949.
[30] Yerkes D W,Boonyakitsombut S,Speece R E. Antagonism of sodium toxicity by the compatible solute betaine in anaerobic methanogenic systems[J]. Water Science&Technology,1997,36(6/7):15-24.
[31] Vallero M V,Lettinga G,Lens P N. Assessment of compatible solutes to overcome salinity stress in thermophilic(55℃)methanol-fed sulfate reducing granular sludges[J]. Water Science&Technology:A Journal of the International Association on Water Pollution Research,2003,48(6):195-202.
[32] Kargi F,Dincer A R. Enhancement of biological treatment performance of saline wastewater by halophilic bacteria[J]. Bioprocess Engineering,1996,15:51-58.
[33] Wang J L,Zhang X M,Feng Y C,et al. Effect of salinity variations on the performance of activated sludge system[J]. Biotechnology and Environmental Sciences,2005,18:5-8.
[34] Welles L,Lopez-vazquez C M,Hooijmans C M,et al. Impact of salinity on the anaerobic metabolism of phosphateaccumulating organisms(PAO)and glycogen-accumulating organisms(GAO)[J]. Applied Microbiology&Biotechnology,2014,98(17):7609-7622.
[35]杨红薇,何婷,谢帆.甜菜碱对肝素钠废水好氧处理的影响[J].环境工程学报,2015,9(11):5387-5392.
[36] Yoshie K,Ayako T,Misako K,et al. Accumulation of cyclitols functioning as compatible solutes in the haptophyte alga Pavlova sp.[J]. Phycological Research,2007,55:81-90.
[37]陈立伟,蔡天明.外源渗透保护剂对活性污泥耐盐能力的影响[J].环境工程,2011,29(1):116-120.
[38]何健,施国新,李顺鹏,等.四氢嘧啶在Halomonas sp.BYS-1渗透调控中的作用[C]∥第八次全国环境微生物学术研讨会论文集.哈尔滨:中国微生物学会,2006:569-573.
[2] Mojtaba P,Gholamreza M,Kamyar Y. Enhanced biodegradation of phenol in a novel cyclic activated sludge integrated with a rotating bed bioreactor in anoxic and peroxidase-mediated conditions[J]. RSC Advances,2018(8):6293-6305.
[3] Pratiksha J,Mohita S,Prem D,et al. Bioelectrochemical approaches for removal of sulfate,hydrocarbon and salinity from produced water[J]. Chemosphere,2017,166:96-108.
[4] Sibel A,Nusret S. Salt inhibition on anaerobic treatment of high salinity wastewater by upflow anaerobic sludge blanket(UASB)reactor[J]. Desalination and Water Treatment,2016,57:12998-13004.
[5]郭天明.低温下外源保护剂对含盐废水好氧生化处理的影响研究[D].成都:西南交通大学,2017:9-10.
[6] John E,Brent M. Response of Halomonas campisalis to saline stress:changes ingrowth kinetics,compatible solute production and membrane phospholipid fatty acid composition[J]. FEMS Microbiol Lett,2007,274:196-203.
[7] Shapir N,Mandelbaum R T,Gottlieb H. Atrazine degradation in saline wastewater by Pseudomonas sp. strain ADP[J]. Journal of Industrial Microbiology&Biotechnology,1998,20:153-159.
[8]王颖群,陶涛.微生物渗透压调节过程中的相容性溶质[J].微生物学通报,1994,21(5):293-296.
[9]夏颖,闵航,吕正兵,等.耐盐细菌的渗透保护剂及其调渗机制[J].生物学通报,2002,37(12):4-5.
[10]赵百锁,杨礼富,王磊,等.中度嗜盐菌相容性溶质机制的研究进展[J].微生物学报,2007,47(5):937-941.
[11]张玉华,凌沛学,籍保平.海藻糖的研究现状及其应用前景[J].食品与药品,2005,7(3):8-13.
[12]何健.甜菜碱和四氢嘧啶提高Pseudomonas putida KT2440耐盐性的分子机理研究[D].南京:南京农业大学,2005:1-14.
[13] Mary F R. Organic compatible solutes of halotolerant and halophilic microorganisms[J]. Saline Systems,2005(1):1-30.
[14]卢良坤,罗立新,黎攀,等.甘氨酸甜菜碱和分子伴侣dna K在嗜盐四联球菌耐盐机制中的作用[J].中国酿造,2013,32(2):25-32.
[15] Arpita R,Dieter H,Filipp O. Effect of the compatible solute ectoine on the stability of the membrane proteins[J].Protein&Peptide Letters,2012,19:791-794.
[16] Stefan K,Rudolf L E,Galinski A. Extrinsic protein stabilization by the naturally occurring osmolytesβ-hydroxyectoine and betaine[J]. Extremophiles,1999(3):191-198.
[17] Yu I,Nagaoka M. Slowdown of water diffusion around protein in aqueous solution with ectoine[J]. Chemical Physics Letters,2004,388:316-321.
[18]朱道辰,刘杏荣.相容性溶质四氢嘧啶及其羟基化衍生物的研究进展[J].中国生物工程杂志,2011,31(2):95-101.
[19] Chadalavada S V,Rajendrakumar,Tangirala S,et al. DNA helix destabilization by proline and betaine:possible role in the salinity tolerance process[J]. FEBS Letters,1997,410:201-205.
[20]高志民,彭镇华.甜菜碱合成调控基因共表达载体的构建与抗盐初步研究[J].林业科学研究,2005,18(3):231-235.
[21] Cristina S P,Roberto D L,Indira C,et al. Interaction of the disaccharide trehalose with a phospholipid bilayer:A molecular dynamics study[J]. Biophysical Journal,2004,86:2273-2285.
[22]陈杰,何聪芬,叶兴国,等.海藻糖及其在生物工程方面的应用[J].生物技术通报,2005(6):29-33.
[23] Jens S,Rakesh K H,Hans J G,et al. Low concentrated hydroxyectoine solutions in presence of DPPC lipid bilayers:A computer simulation study[J]. Biophysical Chemistry,2013,180/181:102-109.
[24] Rakesh K H,Stephanie W,Georg L,et al. The effect of compatible solute ectoines on the structural organization of lipid monolayer and bilayer membranes[J]. Biophysical Chemistry,2010,15:37-46.
[25] Laura C C,JoséL S,Blanca E B. Biodegradation of organic pollutants in saline wastewater by halophilic microorganisms:a review[J]. Environmental Science Pollution Research,2014,21(16):9578-9588.
[26] Maricy R L,Matthew J G,Encarnacion M,et al. Biodegradation of aromatic hydrocarbons by Haloarchaea and their use for the reduction of the chemical oxygen demand of hypersaline petroleum produced water[J]. Chemosphere,2011,84:1671-1676.
[27] Muhammad A,Samina I,Sakandar R,et al. Characteristics of phenol biodegradation in saline solutions by monocultures of Pseudomonas aeruginosa and Pseudomonas pseudomallei[J]. Journal of Hazardous Materials,2007,149:60-66.
[28] Larissa Q,Claudio M S,Sergio O,et al. Nitrification of petroleum extraction produced water:Salt concentrations and nitrifying activity[J]. Environmental Engineering Science,2017,34(4):258-264.
[29] Scott D M,Michael L N,Andrew D H. Betaines and related osmoprotectants. Targets for metabolic engineering of stress resistance[J]. Plant Physiology,1999,120:945-949.
[30] Yerkes D W,Boonyakitsombut S,Speece R E. Antagonism of sodium toxicity by the compatible solute betaine in anaerobic methanogenic systems[J]. Water Science&Technology,1997,36(6/7):15-24.
[31] Vallero M V,Lettinga G,Lens P N. Assessment of compatible solutes to overcome salinity stress in thermophilic(55℃)methanol-fed sulfate reducing granular sludges[J]. Water Science&Technology:A Journal of the International Association on Water Pollution Research,2003,48(6):195-202.
[32] Kargi F,Dincer A R. Enhancement of biological treatment performance of saline wastewater by halophilic bacteria[J]. Bioprocess Engineering,1996,15:51-58.
[33] Wang J L,Zhang X M,Feng Y C,et al. Effect of salinity variations on the performance of activated sludge system[J]. Biotechnology and Environmental Sciences,2005,18:5-8.
[34] Welles L,Lopez-vazquez C M,Hooijmans C M,et al. Impact of salinity on the anaerobic metabolism of phosphateaccumulating organisms(PAO)and glycogen-accumulating organisms(GAO)[J]. Applied Microbiology&Biotechnology,2014,98(17):7609-7622.
[35]杨红薇,何婷,谢帆.甜菜碱对肝素钠废水好氧处理的影响[J].环境工程学报,2015,9(11):5387-5392.
[36] Yoshie K,Ayako T,Misako K,et al. Accumulation of cyclitols functioning as compatible solutes in the haptophyte alga Pavlova sp.[J]. Phycological Research,2007,55:81-90.
[37]陈立伟,蔡天明.外源渗透保护剂对活性污泥耐盐能力的影响[J].环境工程,2011,29(1):116-120.
[38]何健,施国新,李顺鹏,等.四氢嘧啶在Halomonas sp.BYS-1渗透调控中的作用[C]∥第八次全国环境微生物学术研讨会论文集.哈尔滨:中国微生物学会,2006:569-573.
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