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Physiological and phylogenetic characterization of a stable benzene-degrading, chlorate-reducing microbial community
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2007
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| Author: |
Weelink, S.A.B.
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Tan, N.C.G.
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Broeke, H. ten
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Doesburg, W. van
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Langenhoff, A.A.M.
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Gerritse, J.
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Stams, A.J.M.
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| Keywords: |
Environment · Benzene degradation · Chlorate reduction · Enrichment culture · benzene · chlorate · anoxic conditions · bacterium · benzene · biodegradation · inorganic salt · microbial community · oxic conditions · phylogenetics · physiology · alicycliphilus denitrificans · anoxia · article · bacterial gene · bacterial growth · bacterial strain · bacterium culture · degradation kinetics · denaturing gradient gel electrophoresis · Mesorhizobium · microflora · molecular cloning · molecular phylogeny · molecular stability · nucleotide sequence · priority journal · sequence homology · stenotrophomonas acidaminiphila · zoogloea resiniphila · Bacteria · Benzene · Chlorates · DNA, Bacterial · Ecosystem · Electrophoresis · Molecular Sequence Data · Oxidation-Reduction · Phylogeny · Polymerase Chain Reaction · RNA, Ribosomal, 16S · Sequence Analysis, DNA · Alicycliphilus denitrificans · Bacteria (microorganisms) · Mesorhizobium sp. WG · Stenotrophomonas acidaminiphila · Zoogloea resiniphila
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A stable anoxic enrichment culture was obtained that degraded benzene with chlorate as an electron acceptor. The benzene degradation rate was 1.65 mM benzene per day, which is similar to reported aerobic benzene degradation rates but 20-1650 times higher than reported for anaerobic benzene degradation. Denaturing gradient gel electrophoresis of part of the 16S rRNA gene, cloning and sequencing showed that the culture had a stable composition after the seventh transfer. Five bacterial clones were further analyzed. Two clones corresponded to bacteria closely related to Alicycliphilus denitrificans K601. The three other clones corresponded to bacteria closely related to Zoogloea resiniphila PIV-3A2w, Mesorhizobium sp. WG and Stenotrophomonas acidaminiphila. DGGE analysis of cultures grown with different electron donors and acceptors indicated that the bacterium related to Alicycliphilus denitrificans K601 is able to degrade benzene coupled to chlorate reduction. The role of the other bacteria could not be conclusively determined. The bacterium related to Mesorhizobium sp. WG can be enriched with benzene and oxygen, but not with acetate and chlorate, while the bacterium related to Stenotrophomonas acidaminophila grows with acetate and chlorate, but not with benzene and oxygen. As oxygen is produced during chlorate reduction, an aerobic pathway of benzene degradation is most likely. © 2007 Federation of European Microbiological Societies.
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[Abstract]
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Isolation and characterization of Alicycliphilus denitrificans strain BC, which grows on benzene with chlorate as the electron acceptor
| article |
2008
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| Author: |
Weelink, S.A.B.
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Tan, N.C.G.
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Broeke, H. ten
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Kieboom, C. van den
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Doesburg, W. van
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Langenhoff, A.A.M.
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Gerritse, J.
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Junca, H.
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Stams, A.J.M.
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| Keywords: |
Geosciences · Biochemistry · Biodegradation · Catalysts · Cell culture · Degradation · Encoding (symbols) · Enzymes · Gene encoding · Genes · Nitrates · Oxygen · Oxygenation · Proteins · Benzene biodegradations · Benzene degradations · Biochemical datum · Cyclohexanol · Dioxygenase enzymes · Dismutase · Dismutation · Electron acceptors · Encoding · Enrichment cultures · External- · Gene sequences · Genes encoding · In cells · Isolation and characterizations · Monooxygenase · Monooxygenations · Organic molecules · Oxygenase · Oxygenases · Pcr primers · Primer sets · Short rods · Benzene · bacterial enzyme · benzene · benzene oxygenase · catechol · catechol 1,2 dioxygenase · chlorate · chlorite dismutase · estradiol dioxygenase · nitrate · oxygenase · unclassified drug · bacterium · benzene · biochemistry · biodegradation · catabolism · chlorite · denitrification · detection method · electron · enzyme activity · gene expression · mutation · nitrate · oxic conditions · oxygen · polymerase chain reaction · Alicycliphilus denitrificans · article · bacterial growth · bacterial strain · bacterium isolate · biodegradation · electron transport · energy yield · gene amplification · gene sequence · genetic code · nonhuman · nucleotide sequence · oxygenation · phylogeny · polymerase chain reaction · Proteobacteria · unindexed sequence · Bacterial Proteins · Benzene · Chlorates · Comamonadaceae · Dioxygenases · DNA, Bacterial · DNA, Ribosomal · Genes, rRNA · Locomotion · Mixed Function Oxygenases · Molecular Sequence Data · Nitrates · Nitrites · Nitrogen · Oxidoreductases · Oxygen · Phylogeny · Polymerase Chain Reaction · RNA, Bacterial · RNA, Ribosomal, 16S · Sequence Analysis, DNA · Sequence Homology, Nucleic Acid · Alicycliphilus denitrificans · Bacteria (microorganisms) · Negibacteria
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A bacterium, strain BC, was isolated from a benzene-degrading chlorate-reducing enrichment culture. Strain BC degrades benzene in conjunction with chlorate reduction. Cells of strain BC are short rods that are 0.6 μm wide and 1 to 2 μm long, are motile, and stain gram negative. Strain BC grows on benzene and some other aromatic compounds with oxygen or in the absence of oxygen with chlorate as the electron acceptor. Strain BC is a denitrifying bacterium, but it is not able to grow on benzene with nitrate. The closest cultured relative is Alicycliphilus denitrificans type strain K601, a cyclohexanol-degrading nitrate-reducing betaproteobacterium. Chlorate reductase (0.4 U/mg protein) and chlorite dismutase (5.7 U/mg protein) activities in cell extracts of strain BC were determined. Gene sequences encoding a known chlorite dismutase (cld) were not detected in strain BC by using the PCR primers described in previous studies. As physiological and biochemical data indicated that there was oxygenation of benzene during growth with chlorate, a strategy was developed to detect genes encoding monooxygenase and dioxygenase enzymes potentially involved in benzene degradation in strain BC. Using primer sets designed to amplify members of distinct evolutionary branches in the catabolic families involved in benzene biodegradation, two oxygenase genes putatively encoding the enzymes performing the initial successive monooxygenations (BC-BMOa) and the cleavage of catechol (BC-C23O) were detected. Our findings suggest that oxygen formed by dismutation of chlorite can be used to attack organic molecules by means of oxygenases, as exemplified with benzene. Thus, aerobic pathways can be employed under conditions in which no external oxygen is supplied. Copyright © 2008, American Society for Microbiology. All Rights Reserved.
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[Abstract]
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