Organohalide respiratory chains: composition, topology and key enzymes

Abstract The utilization of halogenated organic compounds as terminal electron acceptors separates the phylogenetically diverse organohalide-respiring bacteria from other respiratory anaerobes that predominantly use nitrate, fumarate, sulfate or oxidized metals. Organohalide respiration is unique in...

Full description

Saved in:
Bibliographic Details
Published in:FEMS microbiology ecology 2018-04, Vol.365 (6), p.1
Main Authors: Schubert, Torsten, Adrian, Lorenz, Sawers, R Gary, Diekert, Gabriele
Format: Article
Language:English
Subjects:
Anaerobes
Anaerobic bacteria
Anaerobiosis - physiology
Bacteria
Chains
Chloroflexi - enzymology
Chloroflexi - metabolism
Coupling (molecular)
Cubane
Dehalogenation
Ecology
Electron transfer
Electron transport
Electron Transport - physiology
Electrons
Energy conservation
Ferredoxin hydrogenase
Fumarates - metabolism
Halocarbons
Halogenation
Heavy metals
Hydrogenase
Iron
Iron-sulfur proteins
Membrane proteins
Microbial respiration
Microbiological research
Microbiology
Nitrates - metabolism
Organic Chemicals - metabolism
Organic compounds
Oxidation-Reduction
Oxidoreductases - metabolism
Phylogeny
Physiological aspects
Quinones
Reductase
Structural analysis
Sulfates
Sulfates - metabolism
Sulfur
Topology
Translocation
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Abstract The utilization of halogenated organic compounds as terminal electron acceptors separates the phylogenetically diverse organohalide-respiring bacteria from other respiratory anaerobes that predominantly use nitrate, fumarate, sulfate or oxidized metals. Organohalide respiration is unique in recruiting a cobamide-containing iron–sulfur protein, the extracellular membrane-bound reductive dehalogenase, as terminal reductase in the electron transfer chain. In recent years substantial contributions have been made to the understanding of how electron transfer paths couple mechanistically to chemiosmosis in the organohalide-respiring bacteria. The structural analysis of a respiratory and a non-respiratory reductive dehalogenase revealed the intramolecular electron transfer via two cubane iron–sulfur clusters to the cobamide at the active site. Based on whether quinones are involved, two types of intermolecular electron transfer chains have been identified, which differ in their composition and mode of proton translocation. Indeed, various respiratory chain architectures have been unraveled and evidence for different putative coupling mechanisms presented. The identification of a multienzyme respiratory complex that combines uptake hydrogenase, a complex iron–sulfur molybdoenzyme and a reductive dehalogenase in Dehalococcoides mccartyi strain CBDB1 has raised new questions regarding the mode of energy conservation in these enigmatic microbes. In this mini-review, we highlight these findings and provide an outlook on potential future developments. The mini-review summarizes achievements made in the analysis of the molecular basis of coupling enzymatic reductive dehalogenation to chemiosmosis in anaerobic bacteria.
ISSN:1574-6941
0168-6496
1574-6941
DOI:10.1093/femsec/fiy035