Beta 93 modified hemoglobin: kinetic and conformational consequences.

The reactive sulfhydryl on Cys beta93 in human adult hemoglobin (HbA) has been the focus of much attention. It has purported functional roles such as a transporter of nitric oxide and a detoxifier of super oxide. In addition, it has a proposed role in the allosteric mechanism. The present study addresses the functional and conformational consequences of modifying the beta93 sulfhydryl using either maleimide or disulfide-based reactions. The geminate and bimolecular recombination of CO derivatives of several different beta93-modified Hbs in both solution and sol-gel matrixes provide a window into functional modifications associated with both the R and T states of these proteins. Nanosecond time-resolved visible resonance Raman spectroscopy is used to probe conformational consequences associated with the proximal heme environment. The results show functional and conformational consequences that depend on the specific chemistry used to modify beta93. Maleimide-based modification show the most significant alterations of R-state properties including a consistent pattern of a reduced geminate yield and a loss of the favorable heme-proximal histidine interaction normally seen for liganded R-state HbA. A mechanism based on a displacement of the side chain of Tyr beta145 is explored as a basis for this effect as well as other situations where there is loss of the quaternary enhancement effect. The quaternary enhancement effect refers to the enhancement of ligand binding properties of the alphabeta dimers when they are associated into the R-state tetramer.

Nitroxide SOD-mimics: modes of action.

Low molecular weight superoxide dismutase mimics have been shown to afford protection from oxidative damage. Such SOD-mimics can readily permeate cell membrane achieving sufficiently high levels both inside and outside the cell to effectively detoxify intracellular O2-.. Preliminary findings also indicated that metal-based and metal-free SOD-mimics can protect hypoxic cells from H2O2-induced damage. The present study explored the possibility that SOD-mimics such as desferrioxamine-Mn(III) chelate [DF-Mn] or cyclic nitroxide stable free radicals could protect from O2-.-independent damage. Killing of monolayered V79 Chinese hamster cells was induced by H2O2 or by t-butyl hydroperoxide (t-BHP) and assayed clonogenically. Neither catalase nor native SOD protected the cells from t-BHP. In contrast, both DF-Mn and cyclic nitroxides protected suggesting cytotoxic processes independent of O2-. or of O2-.-derived active species. The inhibition of the damage by both metal-free and metal-based SOD mimics is attributable to either SOD-mimic reacting with reduced transition metal to block the Fenton reaction and/or intercepting and detoxifying intracellular organic free radicals.

Biologically active metal-independent superoxide dismutase mimics.

Superoxide dismutase (SOD) is an enzyme that detoxifies superoxide (O2.-), a potentially toxic oxygen-derived species. Attempts to increase intracellular concentrations of SOD by direct application are complicated because SOD, being a relatively large molecule, does not readily cross cell membranes. We have identified a set of stable nitroxides that possess SOD-like activity, have the advantage of being low molecular weight, membrane permeable, and metal independent, and at pH 7.0 have reaction rate constants with O2.- ranging from 1.1 x 10(3) to 1.3 x 10(6) M-1 s-1. These SOD mimics protect mammalian cells from damage induced by hypoxanthine/xanthine oxidase and H2O2, although they exhibit no catalase-like activity. In addition, the nitroxide SOD mimics rapidly oxidize DNA-FeII and thus may interrupt the Fenton reaction and prevent formation of deleterious OH radicals and/or higher oxidation states of metal ions. Whether by SOD-like activity and/or interception of an electron from redox-active metal ions they protect cells from oxidative stress and may have use in basic and applied biological studies.