Anaerobic Metabolism of Aromatic Compounds

Heider, Johann; Fuchs, Georg

doi:10.1111/j.1432-1033.1997.00577.x

Cited by 285 publications

(234 citation statements)

References 179 publications

(200 reference statements)

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“…Rather, a further mechanism seems much more probable to explain the observed low labeling efficiency: the assimilation of acetyl-CoA derived from toluene in denitrifying, facultatively anaerobic BTEX degraders proceeds through the glyoxylate cycle (Heider and Fuchs, 1997;Rabus, 2005), allowing biomass buildup exclusively based on carbon from the labeled substrate. In accordance, abundant highly 13 C-labeled degrader DNA was observed in preliminary SIP incubations of the same inoculum using nitrate as electron acceptor (data not shown).…”

Section: Sip Of Aquifer Toluene Degraders C Winderl Et Almentioning

confidence: 99%

“…In accordance, abundant highly 13 C-labeled degrader DNA was observed in preliminary SIP incubations of the same inoculum using nitrate as electron acceptor (data not shown). However, strictly anaerobic sulfate reducers and other Peptococcaceae typically lack enzymes of the glyoxylate cycle (Kosaka et al, 2006;Chivian et al, 2008), and assimilate acetyl-CoA through reductive carboxylation to pyruvate by the pyruvate: ferredoxin oxidoreductase (Heider and Fuchs, 1997). Given that unlabeled CO 2 is used for carboxylation, this lowers maximal biomass labeling to B66%, which will be further reduced by additional carboxylation reactions in downstream anabolism.…”

Section: Sip Of Aquifer Toluene Degraders C Winderl Et Almentioning

confidence: 99%

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DNA-SIP identifies sulfate-reducing Clostridia as important toluene degraders in tar-oil-contaminated aquifer sediment

et al. 2010

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Global groundwater resources are constantly challenged by a multitude of contaminants such as aromatic hydrocarbons. Especially in anaerobic habitats, a large diversity of unrecognized microbial populations may be responsible for their degradation. Still, our present understanding of the respective microbiota and their ecophysiology is almost exclusively based on a small number of cultured organisms, mostly within the Proteobacteria. Here, by DNA-based stable isotope probing (SIP), we directly identified the most active sulfate-reducing toluene degraders in a diverse sedimentary microbial community originating from a tar-oil-contaminated aquifer at a former coal gasification plant. On incubation of fresh sediments with 13 C 7 -toluene, the production of both sulfide and 13 CO 2 was clearly coupled to the 13 C-labeling of DNA of microbes related to Desulfosporosinus spp. within the Peptococcaceae (Clostridia). The screening of labeled DNA fractions also suggested a novel benzylsuccinate synthase alpha-subunit (bssA) sequence type previously only detected in the environment to be tentatively affiliated with these degraders. However, carbon flow from the contaminant into degrader DNA was only B50%, pointing toward high ratios of heterotrophic CO 2 -fixation during assimilation of acetyl-CoA originating from the contaminant by these degraders. These findings demonstrate that the importance of non-proteobacterial populations in anaerobic aromatics degradation, as well as their specific ecophysiology in the subsurface may still be largely ungrasped.

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Section: Sip Of Aquifer Toluene Degraders C Winderl Et Almentioning

confidence: 99%

Section: Sip Of Aquifer Toluene Degraders C Winderl Et Almentioning

confidence: 99%

DNA-SIP identifies sulfate-reducing Clostridia as important toluene degraders in tar-oil-contaminated aquifer sediment

et al. 2010

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“…For comparison, MPN series were performed in parallel with benzoate and acetate. Benzoate was chosen as it is a common intermediate in the degradation of alkylbenzenes and polar aromatic compounds in freshwater denitrifying bacteria (Heider & Fuchs, 1997;Spormann & Widdel, 2000). Acetate is a key intermediate in the degradation and preservation of organic matter in marine sedimentary habitats.…”

Section: Abundance Of Hydrocarbon-degrading Nitrate Reducers In Marinmentioning

confidence: 99%

Anaerobic utilization of toluene by marine alpha- and gammaproteobacteria reducing nitrate

et al. 2012

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Aromatic hydrocarbons are among the main constituents of crude oil and represent a major fraction of biogenic hydrocarbons. Anthropogenic influences as well as biological production lead to exposure and accumulation of these toxic chemicals in the water column and sediment of marine environments. The ability to degrade these compounds in situ has been demonstrated for oxygen-and sulphate-respiring marine micro-organisms. However, if and to what extent nitratereducing bacteria contribute to the degradation of hydrocarbons in the marine environment and if these organisms are similar to their well-studied freshwater counterparts has not been investigated thoroughly. Here we determine the potential of marine prokaryotes from different sediments of the Atlantic Ocean and Mediterranean Sea to couple nitrate reduction to the oxidation of aromatic hydrocarbons. Nitrate-dependent oxidation of toluene as an electron donor in anoxic enrichment cultures was elucidated by analyses of nitrate, nitrite and dinitrogen gas, accompanied by cell proliferation. The metabolically active members of the enriched communities were identified by RT-PCR of their 16S rRNA genes and subsequently quantified by fluorescence in situ hybridization. In all cases, toluene-grown communities were dominated by members of the Gammaproteobacteria, followed in some enrichments by metabolically active alphaproteobacteria as well as members of the Bacteroidetes. From these enrichments, two novel denitrifying toluenedegrading strains belonging to the Gammaproteobacteria were isolated. Two additional toluenedegrading denitrifying strains were isolated from sediments from the Black Sea and the North Sea. These isolates belonged to the Alphaproteobacteria and Gammaproteobacteria. Serial dilutions series with marine sediments indicated that up to 2.2¾10 4 cells cm -3 were able to degrade hydrocarbons with nitrate as the electron acceptor. These results demonstrated the hitherto unrecognized capacity of alpha-and gammaproteobacteria in marine sediments to oxidize toluene using nitrate.

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“…This compound becomes reduced by benzoyl-CoA reductase (BCR), a key enzyme in anaerobic aromatic metabolism (1,2). It catalyzes the reductive dearomatization of BCoA to cyclohexa-1,5-diene-1-carbonyl-CoA ( Fig.…”

mentioning

confidence: 99%

Mechanism of ATP-driven electron transfer catalyzed by the benzene ring-reducing enzyme benzoyl- CoA reductase

Unciuleac

Boll

2001

Proc. Natl. Acad. Sci. U.S.A.

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Benzoyl-CoA reductase (BCR) from the bacterium Thauera aromatica catalyzes the two-electron reduction of benzoyl-CoA (BCoA) to a nonaromatic cyclic diene. In a process analogous to enzymatic nitrogen reduction, BCR couples the electron transfer to the aromatic ring to a stoichiometric hydrolysis of 2 ATP͞2e ؊ . Reduced but not oxidized BCR hydrolyzes ATP to ADP. In this work, purified BCR was shown to catalyze an isotope exchange from [ 14 C]ADP to [ 14 C]ATP, which was Ϸ15% of the ATPase activity in the presence of equimolar amounts of ADP and ATP. In accordance, BCR (␣␤␥␦-composition) autophosphorylated its ␥-subunit when incubated with [␥-32 P]ATP. Formation of the enzyme-phosphate was independent of the redox state, whereas only dithionitereduced BCR catalyzed a dephosphorylation associated with the ATPase activity. This finding suggests that the ATPase-and autophosphatase-partial activities of BCR exhibit identical redox dependencies. BCoA or the nonphysiological electron-accepting substrate hydroxylamine stimulated the redox-dependent effects; the rates of both the overall ATPase and the autophosphatase activities of reduced BCR were increased 6-fold. In contrast, BCoA and hydroxylamine had no effect on oxidized and phosphorylated BCR. The reactivity of the phosphoamino acid fits best with a phosphoamidate or acylphosphate linkage. The results obtained suggest a mechanism of ATP hydrolysis-driven electron transfer, which differs from that of nitrogenase by the transient formation of a phosphorylated enzyme.B enzoyl-CoA (BCoA) is a central intermediate in the metabolism of many aromatic compounds in anaerobic bacteria. This compound becomes reduced by benzoyl-CoA reductase (BCR), a key enzyme in anaerobic aromatic metabolism (1, 2). It catalyzes the reductive dearomatization of BCoA to cyclohexa-1,5-diene-1-carbonyl-CoA ( Fig. 1; ref. 3). In this reaction, the hydrolysis of two ATP to ADP and Pi is stoichiometrically coupled to the transfer of two single electrons from reduced ferredoxin to the aromatic substrate. Notably, BCR also catalyzes the ATP-dependent reduction of the nonphysiological substrate hydroxylamine (2). The stoichiometric coupling of ATP hydrolysis to an electron transfer process has long been considered as a unique feature of nitrogenases (4, 5). However, there are no amino acid sequence similarities between BCR and nitrogenases.The reduction of the aromatic ring is a mechanistically and energetically difficult process that in organic synthesis requires solvated electrons, which are generated by dissolving alkali metals in liquid ammonia. In a so-called Birch mechanism, the reduction of the aromatic ring proceeds in single electron and proton transfer steps by means of radical intermediates (6). A similar mechanism has been proposed for enzymatic benzene ring reduction (7). The crucial step is the first electron transfer to the aromatic ring yielding a nonaromatic radical anion, which requires a redox potential of Ϫ1.9 V (3). BCR overcomes this high redox barrier by coupling a stoichiomet...

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Anaerobic Metabolism of Aromatic Compounds

Cited by 285 publications

References 179 publications

DNA-SIP identifies sulfate-reducing Clostridia as important toluene degraders in tar-oil-contaminated aquifer sediment

DNA-SIP identifies sulfate-reducing Clostridia as important toluene degraders in tar-oil-contaminated aquifer sediment

Anaerobic utilization of toluene by marine alpha- and gammaproteobacteria reducing nitrate

Mechanism of ATP-driven electron transfer catalyzed by the benzene ring-reducing enzyme benzoyl- CoA reductase

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