Exploring methane-oxidizing communities for the co-metabolic degradation of organic micropollutants

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• 作者：Jessica Benner (1)
  Delfien De Smet (1)
  Adrian Ho (1) (4)
  Frederiek-Maarten Kerckhof (1)
  Lynn Vanhaecke (2)
  Kim Heylen (3)
  Nico Boon (1)
  
  1. Laboratory of Microbial Ecology and Technology (LabMET) ; Department of Biochemical and Microbial Technology ; Faculty of Bioscience Engineering ; Ghent University ; Coupure Links 653 ; 9000 ; Ghent ; Belgium
  4. Department of Microbial Ecology ; Netherlands Institute of Ecology (NIOO-KNAW) ; Droevendaalsesteeg 10 ; 6708 PB ; Wageningen ; The Netherlands
  2. Laboratory of Chemical Analysis ; Department of Veterinary Public Health and Food Safety ; Faculty of Veterinary Medicine ; Ghent University ; Salisburylaan 133 ; 9820 ; Merelbeke ; Belgium
  3. Laboratory of Microbiology (LM-UGent) ; Department of Biochemistry and Microbiology ; Faculty of Sciences ; Ghent University ; K.L. Ledeganckstraat 35 ; 9000 ; Ghent ; Belgium
  
• 关键词：Methanotrophs ; Sulfamethoxazole ; Benzotrialzole ; sMMO ; pMMO ; Copper
• 刊名：Applied Microbiology and Biotechnology
• 出版年：2015
• 出版时间：April 2015
• 年：2015
• 卷：99
• 期：8
• 页码：3609-3618
• 全文大小：867 KB
• 参考文献：1. Alvarez-Cohen, L, Speitel, GE (2001) Kinetics of aerobic cometabolism of chlorinated solvents. Biodegradation 12: pp. 105-126 CrossRef
  2. Baani M, Liesack W (2008) Two isozymes of particulate methane monooxygenase with different methane oxidation kinetics are found in / Methylocystis sp strain. SCZ P Natl Acad Sci U S A 105:10203鈥?0208. doi:10.1073/pnas.0702643105
  3. Bedard C, Knowles R (1989) Physiology, biochemistry, and specific inhibitors of CH₄, NH⁴⁺, and co oxidation by methanotrophs and nitrifiers. Microbiol Rev 53:68鈥?4
  4. Begonja, A, Hrsak, D (2001) Effect of growth conditions on the expression of soluble methane monooxygenase. Food Technol Biotechnol 39: pp. 29-35
  5. Benner, J, Helbling, DE, Kohler, HPE, Wittebol, J, Kaiser, E, Prasse, C, Ternes, TA, Albers, CN, Aamand, J, Horemans, B, Springael, D, Walravens, E, Boon, N (2013) Is biological treatment a viable alternative for micropollutant removal in drinking water treatment processes?. Water Res 47: pp. 5955-5976 CrossRef
  6. Bodrossy, L, Stralis-Pavese, N, Murrell, JC, Radajewski, S, Weilharter, A, Sessitsch, A (2003) Development and validation of a diagnostic microbial microarray for methanotrophs. Environ Microbiol 5: pp. 566-582 CrossRef
  7. Boon, N, Goris, J, Vos, P, Verstraete, W, Top, EM (2000) Bioaugmentation of activated sludge by an indigenous 3-chloroaniline-degrading Comamonas testosteroni strain, I2gfp. Appl Environ Microbiol 66: pp. 2906-2913 CrossRef
  8. del Cerro C, Garcia JM, Rojas A, Tortajada M, Ramon D, Galan B, Prieto MA, Garcia JL (2012) Genome sequence of the methanotrophic Poly-beta-hydroxybutyrate producer / Methylocystis parvus OBBP. J Bacteriol 194:5709鈥?710. doi:10.1128/jb.01346-12
  9. Gros, M, Rodriguez-Mozaz, S, Barcelo, D (2012) Fast and comprehensive multi-residue analysis of a broad range of human and veterinary pharmaceuticals and some of their metabolites in surface and treated waters by ultra-high-performance liquid chromatography coupled to quadrupole-linear ion trap tandem mass spectrometry. J Chromatogr A 1248: pp. 104-121 CrossRef
  10. Hesselsoe, M, Boysen, S, Iversen, N, Jorgensen, L, Murrell, JC, McDonald, I, Radajewski, S, Thestrup, H, Roslev, P (2005) Degradation of organic pollutants by methane grown microbial consortia. Biodegradation 16: pp. 435-448 CrossRef
  11. Higgins, IJ, Best, DJ, Hammond, RC (1980) New findings in methane-utilizing bacteria highlight their importance in the biosphere and their commercial potential. Nature 286: pp. 561-564 CrossRef
  12. Ho, A, Roy, K, Thas, O, Neve, J, Hoefman, S, Vandamme, P, Heylen, K, Boon, N (2014) The more, the merrier: heterotroph richness stimulates methanotrophic activity. ISME J 8: pp. 1945-1948 CrossRef
  13. Ho, A, Luke, C, Frenzel, P (2011) Recovery of methanotrophs from disturbance: population dynamics, evenness and functioning. ISME J 5: pp. 750-758 CrossRef
  14. Ho, A, Vlaeminck, SE, Ettwig, KF, Schneider, B, Frenzel, P, Boon, N (2013) Revisiting methanotrophic communities in sewage treatment plants. Appl Environ Microbiol 79: pp. 2841-2846 CrossRef
  15. Hoefman, S, Ha, D, Vos, P, Boon, N, Heylen, K (2012) Miniaturized extinction culturing is the preferred strategy for rapid isolation of fast-growing methane-oxidizing bacteria. Microb Biotechnol 5: pp. 368-378 CrossRef
  16. Hrsak, D, Begonja, A (2000) Possible interactions within a methanotrophic-heterotrophic groundwater community able to transform linear alkylbenzenesulfonates. Appl Environ Microbiol 66: pp. 4433-4439 CrossRef
  17. Kaiser, E, Prasse, C, Wagner, M, Broder, K, Ternes, TA (2014) Transformation of oxcarbazepine and human metabolites of carbamazepine and oxcarbazepine in wastewater treatment and sand filters. Environ Sci Technol 48: pp. 10208-10216 CrossRef
  18. Lee, SW, Keeney, DR, Lim, DH, Dispirito, AA, Semrau, JD (2006) Mixed pollutant degradation by Methylosinus trichosporium OB3b expressing either soluble or particulate methane monooxygenase: can the tortoise beat the hare?. Appl Environ Microbiol 72: pp. 7503-7509 CrossRef
  19. Liu, Y-S, Ying, G-G, Shareef, A, Kookana, RS (2011) Biodegradation of three selected benzotriazoles under aerobic and anaerobic conditions. Water Res 45: pp. 5005-5014 CrossRef
  20. M眉ller, A, Weiss, SC, Bei脽wenger, J, Leukhardt, HG, Schulz, W, Seitz, W, Ruck, WKL, Weber, WH (2012) Identification of ozonation by-products of 4- and 5-methyl-1H-benzotriazole during the treatment of surface water to drinking water. Water Res 46: pp. 679-690 CrossRef
  21. Muyzer, G, Dewaal, EC, Uitterlinden, AG (1993) Profiling of complex microbial-populations by denaturing gradient gel-electrophoresis analysis of polymerase chain reaction-amplified genes-coding for 16s ribosomal-RNA. Appl Environ Microbiol 59: pp. 695-700
  22. Semrau, JD (2011) Bioremediation via methanotrophy: overview of recent findings and suggestions for future research. Front Microbiol 2: pp. 1-7 CrossRef
  23. Semrau, JD, DiSpirito, AA, Yoon, S (2010) Methanotrophs and copper. FEMS Microbiol Rev 34: pp. 496-531
  24. Semrau, JD, Jagadevan, S, DiSpirito, AA, Khalifa, A, Scanlan, J, Bergman, BH, Freemeier, BC, Baral, BS, Bandow, NL, Vorobev, A, Haft, DH, Vuilleumier, S, Murrell, JC (2013) Methanobactin and MmoD work in concert to act as the 鈥榗opper-switch鈥?in methanotrophs. Environ Microbiol 15: pp. 3077-3086
  25. Ha, D, Hoefman, S, Boeckx, P, Verstraete, W, Boon, N (2010) Copper enhances the activity and salt resistance of mixed methane-oxidizing communities. Appl Microbiol Biotechnol 87: pp. 2355-2363 CrossRef
  26. Ha, D, Vanwonterghem, I, Hoefman, S, Vos, P, Boon, N (2013) Selection of associated heterotrophs by methane-oxidizing bacteria at different copper concentrations. Anton Leeuw Int J Gen Mol Microbiol 103: pp. 527-537 CrossRef
  
• 刊物类别：Chemistry and Materials Science
• 刊物主题：Chemistry
  Biotechnology
  Microbiology
  Microbial Genetics and Genomics
  
• 出版者：Springer Berlin / Heidelberg
• ISSN：1432-0614

文摘

Methane-oxidizing cultures from five different inocula were enriched to be used for co-metabolic degradation of micropollutants. In a first screening, 18 different compounds were tested for degradation with the cultures as well as with four pure methane-oxidizing bacterial (MOB) strains. The tested compounds included pharmaceuticals, chemical additives, pesticides, and their degradation products. All enriched cultures were successful in the degradation of at least four different pollutants, but the compounds degraded most often were sulfamethoxazole (SMX) and benzotriazole (BTZ). Addition of acetylene, a specific methane monooxygenase (MMO) inhibitor, revealed that SMX and BTZ were mainly degraded co-metabolically by the present MOB. The pure MOB cultures exhibited less degradation potential, while SMX and BTZ were also degraded by three of the four tested pure strains. For MOB, copper (Cu2+) concentration is often an important factor, as several species have the ability to express a soluble MMO (sMMO) if the Cu2+ concentration is low. In literature, this enzyme is often described to have a broader compound range for co-metabolic degradation of pollutants, in particular when it comes to aromatic structures. However, this study indicated that co-metabolic degradation of the aromatic compounds SMX and BTZ was possible at high Cu2+ concentration, most probably catalyzed by pMMO.