Biochemical, Structural and Functional Characterization of Diheme-Containing Quinol:Fumarate Reductases : The Role of Heme Propionates and the Enzymes from Pathogenic E-Proteobacteria

The quinol:fumarate reductase (QFR) is the terminal reductase of anaerobic fumarate respiration, the most commonly occurring type of anaerobic respiration. This membrane protein complex couples the oxidation of menaquinol to menaquinone to the reduction of fumarate to succinate. The three-dimensional crystal structure of the QFR from Wolinella succinogenes has previoulsy been solved at 2.2 Å resolution.Although the diheme-containing QFR from W. succinogenes is known to catalyze an electroneutral process, structural and functional characterization of parental and variant enzymes has revealed active site locations which indicate electrogenic catalysis across the membrane. A solution to this apparent controversy was proposed with the so-called “Epathway hypothesis”. According to this, transmembrane electron transfer via the heme groups is strictly coupled to a parallel, compensatory transfer of protons via a transiently established pathway, which is inactive in the oxidized state of the enzyme. Proposed constituents of the E-pathway are the side chain of Glu C180, and the ring C propionate of the distal heme. Previous experimental evidence strongly supports such a role for the former constituent. One aim of this thesis is to investigate by a combination of specific 13C-heme propionate labeling and FTIR difference spectroscopy whether the ring C propionate of the distal heme is involved in redox-coupled proton transfer in the QFR from W. succinogenes.In addition to W. succinogenes, the primary structures of the QFR enzymes of two other e- proteobacteria are known. These are Campylobacter jejuni and Helicobacter pylori, which unlike W. succinogenes are human pathogens. The QFR from H. pylori has previously been established to be a potential drug target, and the same is likely for the QFR from C. jejuni. The two pathogenic species colonize mucosal surfaces causing several diseases. The possibility of studying these QFRs from these bacteria and creating more efficient drugs specifically active for this enzyme depends substantially on the availability of large amounts of high-quality protein. Further, biochemical and structural studies on QFR enzymes from e- proteobacteria species other than W. succinogenes can be valuable to enlighten new aspects or corroborate the current understanding of this class of membrane proteins.