The Reactions of H2O2 and GSNO with the Zinc Finger Motif of XPA. Not A Regulatory Mechanism, But No Synergy with Cadmium Toxicity.

Tetrathiolate zinc fingers are potential targets of oxidative assault under cellular stress conditions. We used the synthetic 37-residue peptide representing the tetrathiolate zinc finger domain of the DNA repair protein XPA, acetyl-DYVICEECGKEFMSYLMNHFDLPTCDNCRDADDKHK-amide (XPAzf) as a working model to study the reaction of its Zn(II) complex (ZnXPAzf) with hydrogen peroxide and S-nitrosoglutathione (GSNO), as oxidative and nitrosative stress agents, respectively. We also used the Cd(II) substituted XPAzf (CdXPAzf) to assess the situation of cadmium assault, which is accompanied by oxidative stress. Using electrospray mass spectrometry (ESI-MS), HPLC, and UV-vis and circular dichroism spectroscopies we demonstrated that even very low levels of H2O2 and GSNO invariably cause irreversible thiol oxidation and concomitant Zn(II) release from ZnXPAzf. In contrast, CdXPAzf was more resistant to oxidation, demonstrating the absence of synergy between cadmium and oxidative stresses. Our results indicate that GSNO cannot act as a reversible modifier of XPA, and rather has a deleterious effect on DNA repair.

Ap4A is not an efficient Zn(II) binding agent. A concerted potentiometric, calorimetric and NMR study.

Diadenosine 5',5''-P(1)P(4) tetraphosphate (Ap(4)A) has been considered as an intracellular partner for Zn(II). We applied potentiometry, ITC and NMR to study protonation equilibria of Ap(4)A and Zn(II) complexation by this dinucleotide. The values of binding constants obtained by these three techniques under various experimental conditions coherently demonstrated that Ap(4)A binds Zn(II) weakly, with an apparent binding constant of ca. 10(4) at neutral pH. Such a low stability of Zn(II) complexes with Ap(4)A excludes a possibility for interactions between these two agents in vivo.

Damage of zinc fingers in DNA repair proteins, a novel molecular mechanism in carcinogenesis.

Zinc finger motifs participate in protein-nucleic acid and protein-protein interactions in many groups of proteins, including those involved in DNA repair. The Zn(II) ion, bonded tetrahedrally to cysteine thiolates and/or histidine imidazole groups, maintains the three-dimensional structure, crucial for the function of the domain. Zinc fingers can thus be compromised by a substitution of Zn(II) with another metal ion or by a release of Zn(II), due to the oxidation of thiolate donors. The latter may result from an action of redox-active metals or other oxidative agents. Studies in cell cultures and ex vivo demonstrated that soluble compounds of definite carcinogenic metals and metalloids, such as arsenic, cadmium and nickel, and putative carcinogens, including cobalt and lead, inhibit zinc finger containing DNA repair proteins. Further experiments demonstrated that these metals, as well as endogeneous oxidative substances, including hydrogen peroxide, nitrosoglutathione, and reducible selenium compounds damage or distort zinc finger domains. This reactivity can therefore be regarded as a novel molecular mechanism in carcinogenesis.

Reaction of the XPA zinc finger with S-nitrosoglutathione.

S-Nitrosoglutathione (GSNO) is an intracellular redox signaling molecule, also implicated in nitrosative stress. GSNO actions include modifications of Cys thiols in proteins. In this study, we focused on a GSNO reaction with a Cys4 zinc finger (ZF) sequence of human protein XPA, crucial to the nucleotide excision repair pathway of DNA repair. By using a corresponding synthetic 37-residue peptide acetyl-DYVICEECGKEFMDSYLMNHFDLPTCDNCRDADDKHK-amide (XPAzf) and combining the detection of noncovalent and covalent complexes by ESI-MS with zinc release monitored by the zinc-sensitive chromophore 4-(2-pyridylazo)resorcinol (PAR), we demonstrated that the reaction of XPAzf with GSNO yielded S-nitrosylated intermediates, intrapeptide disulfides, and mixed glutathione disulfides. The reaction started with the formation of a complex of GSNO with ZnXPAzf followed by thiol transnitrosylation reactions and the final formation of disulfides. The results obtained suggest that at low levels/transient exposures, GSNO may act as a reversible regulator of Cys4 ZF activity, whereas transnitrosylation by GSNO, occurring at prolonged exposures, may cause deleterious effects to the functions of Cys 4 ZF proteins. In the case of XPA, this may lead to DNA repair inhibition.

Quantitative electrospray ionization mass spectrometry of zinc finger oxidation: the reaction of XPA zinc finger with H(2)O(2).

Oxidation plays an important role in the functioning of zinc fingers (ZFs). Electrospray ionization mass spectrometry (ESI-MS) is a very useful technique to study products of ZF oxidation, but its application has been limited largely to qualitative analysis of reaction products. On the other hand, ESI-MS has been applied successfully on several occasions to determine binding constants in metalloproteins. We used a synthetic 37-residue peptide acetyl-DYVICEECGKEFMDSYLMNHFDLPTCDNCRDADDKHK-amide (XPAzf), which corresponds to the Cys4 ZF sequence of human nucleotide excision repair protein XPA, to find out whether ESI-MS might be used quantitatively to study ZF reaction kinetics. For this purpose, we studied oxidation of the Zn(II) complex of XPAzf (ZnXPAzf) by H(2)O(2) using three techniques in parallel: high-performance liquid chromatography (HPLC) of covalent reaction products, 4-(2-pyridylazo)-resorcinol monosodium salt (PAR)-based spectrophotometric zinc release assay, and ESI-MS. Single and double intrapeptide disulfides were detected by ESI-MS to be the sole reaction products. All three techniques yielded independently the same reaction rate, thereby demonstrating that ESI-MS may indeed be used in quantitative kinetic studies of ZF reactions. The comparison of experimental information demonstrated that the formation of the Cys5-Cys8 single disulfide was responsible for zinc release.