Ni-containing superoxide dismutase (NiSOD) is the most recently discovered member of the class of metalloenzymes that detoxify the superoxide radical in aerobic organisms. In this study, we have employed a variety of spectroscopic and computational methods to probe the electronic structure of the NiSOD active site in both its oxidized (NiSOD(ox), possessing a low-spin (S = (1)/(2)) Ni(3+) center) and reduced (NiSOD(red), containing a diamagnetic Ni(2+) center) states. Our experimentally validated computed electronic-structure description for NiSOD(ox) reveals strong sigma-bonding interactions between Ni and the equatorial S/N ligands, which give rise to intense charge-transfer transitions in the near-UV region of the absorption spectrum. Resonance Raman (rR) spectra obtained with laser excitation in this region exhibit two features at 349 and 365 cm(-)(1) that are assigned to Ni-S(Cys) stretching modes. The NiSOD(red) active site also exhibits a high degree of metal-ligand bond covalency as well as filled/filled pi-interactions between Ni and S/N orbitals, which serve to adjust the redox potential of the Ni(2+) center. Comparison of our computational results for NiSOD(red) with those obtained in parallel studies of synthetic [NiS(2)N(2)] complexes reveals that the presence of an anionic N-donor ligand is crucial for promoting metal-based (versus S-based) oxidation of the active site. The implications of our electronic-structure descriptions with respect to the function of NiSOD are discussed, and a comparison of M-S(Cys) bonding in NiSOD and other metalloenzymes with sulfur ligation is provided.
Superoxide dismutases rely on protein structural elements to adjust the redox potential of the metallocenter to an optimum value near 300 mV (vs. NHE), to provide a source of protons for catalysis, and to control the access of anions to the active site. These aspects of the catalytic mechanism are examined herein for recombinant preparations of the nickel-dependent SOD (NiSOD) from Streptomyces coelicolor, and for a series of mutants that affect a key tyrosine residue, Tyr9 (Y9F-, Y62F-, Y9FY62F- and D3A-NiSOD). Structural aspects of the nickel sites are examined by a combination of EPR and x-ray absorption spectroscopies, and by single crystal x-ray diffraction at ~ 1.9 Å resolution in the case of Y9F- and D3A-NiSODs. The functional effects of the mutations are examined by kinetic studies employing pulse radiolytic generation of O2− and by redox titrations. These studies reveal that although the structure of the nickel center in NiSOD is unique, the ligand environment is designed to optimize the redox potential at 290 mV and results in the oxidation of 50% of the nickel centers in the oxidized hexamer. Kinetic investigations show that all of the mutant proteins have considerable activity. In the case of Y9F-NiSOD, the enzyme shows saturation behavior that is not observed in WT-NiSOD and suggests that release of peroxide is inhibited. The crystal structure of Y9F-NiSOD reveals an anion binding site that is occupied by either Cl− or Br− and is located close to, but not within bonding distance of the nickel center. The structure of D3A-NiSOD reveals that in addition to affecting the interaction between subunits, this mutation repositions Y9 and leads to altered chemistry with peroxide. Comparisons with Mn(SOD) and Fe(SOD) reveal that although different strategies are employed to adjust the redox potential and supply of protons, NiSOD has evolved a similar strategy to control the access of anions to the active site.
Nickel-dependent superoxide dismutases (NiSODs) represent a novel solution to controlling the deleterious effects of reactive oxygen species derived from superoxide in biology. The expression of recombinant Streptomyces coelicolor NiSOD and its in vitro processing and reconstitution to yield fully active enzyme is reported. The results of studies of NiSODs involving mutations in two putative nickel binding ligands are also reported. These studies show that mutation of M28, a strictly conserved residue and one of only three S-donor ligands in the enzyme, has no measurable effect on the spectroscopic or catalytic properties of the enzyme. In contrast, mutation of the strictly conserved N-terminal H residue has dramatic effects on both the spectroscopic and catalytic properties. These results provide insights into structural and mechanistic aspects of the novel nickel-containing reactive site.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.