Erik Sedlák

Ferricytochrome c protects mitochondrial cytochrome c oxidase against hydrogen peroxide-induced oxidative damage

An excess of ferricytochrome c protects purified mitochondrial cytochrome c oxidase and bound cardiolipin from hydrogen peroxide-induced oxidative modification. All of the peroxide-induced changes within cytochrome c oxidase, such as oxidation of Trp(19,IV) and Trp(48,VIIc), partial dissociation of subunits VIa and VIIa, and generation of cardiolipin hydroperoxide, no longer take place in the presence of ferricytochrome c. Furthermore, ferricytochrome c suppresses the yield of H(2)O(2)-induced free radical detectable by electron paramagnetic resonance spectroscopy within cytochrome c oxidase. These protective effects are based on two mechanisms. The first involves the peroxidase/catalase-like activity of ferricytochrome c, which results in the decomposition of H(2)O(2), with the apparent bimolecular rate constant of 5.1±1.0M(-1)s(-1). Although this value is lower than the rate constant of a specialized peroxidase, the activity is sufficient to eliminate H(2)O(2)-induced damage to cytochrome c oxidase in the presence of an excess of ferricytochrome c. The second mechanism involves ferricytochrome c-induced quenching of free radicals generated within cytochrome c oxidase. These results suggest that ferricytochrome c may have an important role in protection of cytochrome c oxidase and consequently the mitochondrion against oxidative damage.

Cofactor assisted gating mechanism in the active site of NADH oxidase from Thermus thermophilus

NADH oxidase (NOX) from Thermus thermophilus is a member of a structurally homologous flavoprotein family of nitroreductases and flavin reductases. The importance of local conformational dynamics in the active site of NOX has been recently demonstrated. The enzyme activity was increased by 250% in the presence of 1 M urea with no apparent perturbation of the native structure of the protein. The present in silico results correlate with the in vitro data and suggest the possible explanation about the effect of urea on NOX activity at the molecular level. Both, X‐ray structure and molecular dynamics (MD) simulations, show open conformation of the active site represented by −f0.9 nm distance between the indole ring of Trp47 and the isoalloxazine ring of FMN412. In this conformation, the substrate molecule can bind in the active site without sterical restraints. MD simulations also indicate more stable conformation of the active site called “closed” conformation. In this conformation, Trp47 and the isoalloxazine ring of FMN412 are so close to each other (−f0.5 nm) that the substrate molecule is unable to bind between them without perturbing this conformation. The open/close transition of the active site between Trp47 and the flavin ring is accompanied by release of the “tightly” bound water molecule from the active site—cofactor assisted gating mechanism. The presence of urea in aqueous solutions of NOX prohibits closing of the active site and even unlocks the closed active site because of the concomitant binding of a urea molecule in the active site cavity. The binding of urea in the active site is stabilized by formation of one/two persistent hydrogen bonds involving the carbonyl group of the urea molecule. Our report represents the first MD study of an enzyme from the novel flavoprotein family of nitroreductases and flavin reductases. The common occurrence of aromatic residues covering the active sites in homologous enzymes suggests the possibility of a general gating mechanism and the importance of local dynamics within this flavoprotein family. Proteins 2006.

Destabilization of the Quaternary Structure of Bovine Heart Cytochrome c Oxidase upon Removal of Tightly Bound Cardiolipin

The quaternary structural stability of cardiolipin-containing (CcO(CL+)) versus CL-free cytochrome c oxidase (CcO(CL-)) was compared using structural perturbants as probes. Exposure to increasing concentrations of urea or guanidinium chloride causes sequential dissociation of five subunits from CcO(CL+) in the order VIa and VIb, followed by III and VIIa, and ultimately Vb. Removal of CL from CcO destabilizes the association of each of these five subunits with the core of CcO. Subunits VIa and VIb spontaneously dissociate from CcO(CL-) even in the absence of denaturant and are no longer present after purification of the CL-free 11-subunit complex by ion exchange chromatography. The other 11 subunits remain associated in a partially active complex, but the association of subunits III, VIIa, and Vb is weakened; i.e., the midpoints for the subunit dissociation curves are each shifted to a lower perturbant concentration (lower by 1.1-1.7 M urea; lower by 0.3-0.4 M GdmCl). This corresponds to a decrease of ∼9 kJ in the Gibbs free association energy for each of these subunits when CL is removed from CcO. With either CcO(CL+) or CcO(CL-), loss of enzymatic activity occurs coincident with dissociation of subunits III and VIIa. The loss of activity is irreversible, and reactivation of CcO(CL-) by exogenous CL occurs only if both subunits remain associated with the core of CcO. Inclusion of sulfate anions stabilizes the association of VIIa more than III, resulting in a slight separation of the urea-induced dissociation curves. In this case, activity loss correlates much better with dissociation of subunit VIIa than III. We conclude that (1) bound cardiolipin is an important stabilizing factor in the quaternary structure of CcO and (2) association of subunit VIIa (possibly together with subunit III) is critical for functional CL binding and full electron-transfer activity of CcO.