Richard C. Conover

Oxidative stress defense mechanisms to counter iron-promoted DNA damage in Helicobacter pylori

Iron, a key element in Fenton chemistry, causes oxygen-related toxicity to cells of most living organisms. Helicobacter pylori is a microaerophilic bacterium that infects human gastric mucosa and causes a series of gastric diseases. Exposure of H. pylori cells to air for 2 h elevated the level of free iron by about 4-fold as measured by electron paramagnetic resonance spectroscopy. H. pylori cells accumulated more free iron as they approached stationary phase growth, and they concomitantly suffered more DNA damage as indicated by DNA fragmentation analysis. Relationships between the intracellular free iron level, specific oxidative stress enzymes, and DNA damage were identified, and new roles for three oxidative stress-combating enzymes in H. pylori are proposed. Mutant cells defective in either catalase (KatA), in superoxide dismutase (SodB) or in alkyl hydroperoxide reductase (AhpC) were more sensitive to oxidative stress conditions; and they accumulated more free (toxic) iron; and they suffered more DNA fragmentation compared to wild type cells. A significant proportion of cells of sodB, ahpC, or katA mutant strains developed into the stress-induced coccoid form or lysed; they also contained significantly higher amounts of 8-oxo-guanine associated with their DNA, compared to wild type cells.

Biotin sulfoxide reductase: Tryptophan 90 is required for efficient substrate utilization.

Rhodobacter sphaeroides f. sp. denitrificans biotin sulfoxide reductase (BSOR) catalyzes the reduction of d-biotin d-sulfoxide to biotin and contains the molybdopterin guanine dinucleotide (MGD) cofactor as its sole prosthetic group. Comparison of the primary sequences of BSOR and the closely related enzyme dimethyl sulfoxide reductase (DMSOR) indicated a number of conserved residues, including an active-site tryptophan residue (W90), which has been suggested to be involved in hydrogen bonding to the oxo group on the Mo(VI) center in BSOR. Site-directed mutagenesis has been used to replace tryptophan 90 in BSOR with phenylalanine, tyrosine, and alanine residues to examine the role of this residue in catalysis. All three BSOR mutant proteins were purified to homogeneity and contained MGD. The mutant proteins retained very limited activity toward the oxidizing substrates tested, with W90F retaining the most activity (3.4% of wild type). All three W90 mutant proteins exhibited greatly reduced k(cat) values compared to that of the wild-type enzyme, which was accompanied by little change in K(mapp). In addition, the mutant proteins had perturbed visible absorption and circular dichroism spectra suggesting different oxidation states of the Mo center. Purified samples of wild-type BSOR did not exhibit electron paramagnetic resonance (EPR) signals indicating a Mo(VI) center. After redox-cycling, partially reduced samples of wild-type BSOR revealed a proton-split S=1/2 Mo(V) resonance (g(1,2,3)=1.999, 1.981, 1.967; A(1,2,3)=1.40, 1.00, 1.05 mT) analogous to that observed in DMSOR. In contrast, EPR studies of the purified W90 mutant proteins revealed distinct S=1/2 Mo(V) resonances that were resistant to both oxidation and reduction, indicating that the Mo was trapped in the intermediate Mo(V) oxidation state. These results strongly suggest that W90 in BSOR plays a critical role in catalysis by serving as a hydrogen bond donor to the oxo group on the Mo(VI) center.

Investigation by EPR and ENDOR spectroscopy of the novel 4Fe ferredoxin fromPyrococcus furiosus

The hyperthermophilic archaeonPyrococcus furiosus contains a four-Fe ferredoxin (Pf- Fd) that differs from most other 4Fe-Fd’s in that its [Fe4S4] cluster is anchored to protein by only three cysteinyl residues.Pf- Fd also is of interest because in its reduced form, [Fe4S4]+, the cluster exhibits bothS = 1/2 andS = 3/2 spin states. Addition of excess cyanide ion converts the cluster exclusively to anS = 1/2 state (g1 = 2.09, g2 = 1.95, g3 = 1.92), however dialysis restores the EPR signal of native reduced protein indicating that the cluster is not irreversibly altered by cyanide. Both the native protein and protein in the presence of excess cyanide ion (Pf- Fd 4Fe-CN) were investigated here using the techniques of electron paramagnetic resonance (EPR) and electron-nuclear double resonance (ENDOR) spectroscopy. In particular,Pf- Fd 4Fe-CN was investigated using13CN− and C15N− ligands.13C and15N ENDOR indicated that a single cyanide ion bound directly, with the cluster showing an unusually small contact interaction (aiso(13C)∼ −3 MHz, aiso(15N) ∼ 0). This is in contrast to cyanide bound to monomeric low-spin Fe(III)-containing proteins such as transferrin and myoglobin, for which the13C hyperfine coupling has a large isotropic component (aiso(13C) ≈ −30 MHz). This small contact interaction is not due to low spin density of Fe, as57Fe ENDOR of the singly and triply labeledPf- Fd 4FeCN isotopologs, [57FeFe3S4]+ and [Fe57Fe3S4]+, show hyperfine coupling characteristic for [Fe4S4]+ clusters, particularly for the Fe to which cyanide binds. Thus, the low spin density on13C is not due to low spin density on the Fe ion to which it binds. Further theoretical work is needed to explain the contrast between the strong electronic effect of cyanide ion binding with the low spin density on the ligand.