Direct evidence of nitrogen coupling in the copper(II) complex of bovine serum albumin by S-band electron spin resonance technique.

ESR spectra of the tight binding Cu(II) complex of bovine serum albumin (BSA) has been studied using S-band. At physiological pH, only one form of copper binding to BSA was detected from the ESR spectra. From previous X-band ESR spectra, nitrogen superhyperfine splittings were observable in the g perpendicular region; however, the resolution of the g parallel region was not sufficient to confirm the exact donor atoms of the complex. Using low-frequency ESR (2-4 GHz) at 77 K, we have resolved the nitrogen superhyperfine structure in the g parallel region. A computer simulation method has been developed for distinguishing between three and four nitrogen donor atoms. The Hyde-Froncisz theory of g and A strain broadening has been modified to use a field-swept calculation for the line shape. The observed intensity pattern and the computer simulation of such spectra positively confirm the structure of Cu(II) ion coordinated to four in-plane nitrogen atoms in frozen aqueous solutions of Cu(II)-BSA complexes at physiological pH. This is the first time that this binding site has been confirmed on the protein instead of a protein fragment or model compound. This work is another example of the usefulness of the S-band ESR technique for characterizing the metal-protein interactions when random variation in g factors cause line broadening in conventional X-band ESR spectra.

Interaction of hexachlorophene and other compounds with spin-labeled brain membranes.

Experiments reported here demonstrate that hexachlorophene influences oxidation-reduction events inside the brain membrane, possibly via a free radical mechanism. This was shown by nitroxide spin label quenching inside the rat cerebellum membrane bilayer due to the interaction between hexachlorophene and peroxidase-hydrogen peroxide system. Prior addition of antioxidants, e.g., vitamin E or butylated hydroxytoluene, prevented such membrane-bound fatty acid spin label reduction, presumably due to their free radical scavenging abilities. The 5-doxyl stearic acid spin probe attached to the brain membranes did not exhibit any detectable changes in their ESR spectra nor, consequently, in the microviscosity of the membranes when exposed to up to 40 mM hexachlorophene.

Modulation by S-adenosyl-L-methionine of hepatic Na+,K+-ATPase, membrane fluidity, and bile flow in rats with ethinyl estradiol-induced cholestasis.

Structural and functional changes in the surface membranes of hepatocytes play a pivotal role in the induction and reversion of some forms of drug-induced cholestasis. To elucidate the mechanism by which S-adenosyl-L-methionine (SAMe) leads to a partial reversion of bile flow impairment caused by ethinyl estradiol (EE), female Sprague-Dawley rats were given oral doses of EE (5 mg per kg per day, for 3 days) with and without simultaneous administration of SAMe (25 mg per kg, 3 times per day, for 3 days). Na+,K+-ATPase activity and membrane microviscosity as measured by fluorescent polarization were assayed in isolated liver plasma membranes (LPMs). SAMe administration to normal and EE-treated rats resulted in a marked increase in Na+,K+-ATPase activity and LPM fluidity. EE alone did not cause any change in the physicochemical properties of the LPMs. Hepatic Mg2+-ATPase and gamma-glutamyl transpeptidase activities were not affected by SAMe alone but increased when SAMe was given together with EE. These data indicate that the interaction of in vivo administered SAMe with hepatocyte plasmalemma and its effect on lipid fluidity and enzymes of the LPMs showed a high specificity and an inverse relationship between Na+,K+-ATPase activity and fluorescence polarization values. Furthermore, modulation of hepatic Na+,K+-ATPase was associated with SAMe-induced protection against bile flow impairment due to EE; however, it was not the causative factor for EE-induced cholestasis under the experimental conditions. These findings suggest that changes in surface membrane structure and function might account in part for the reversal by SAMe of EE-induced impairment of bile secretory function.

Electron spin resonance study of the copper(II) complexes of human and dog serum albumins abd some peptide analogs.

Electron spin resonance spectra of the first Cu(II) complexes of human serum albumin, dog serum albumin, L-aspartyl-L-histidine N-methylamide and glycyl-gly-cyl-L-histidine N-methylamide have been studied using isotopically pure 65Cu in its chloride form. At 77 degrees K, the esr spectra of Cu(II) complex of human serum albumin exhibited only one form of esr signal between pH 6.5 and 11. No intermediate forms were detected. The presence of an equally spaced nine-line superhyperfine structure with spacing approximately 15 G indicated considerable covalent bonding between Cu(II) and four nitrogen atoms derived from the protein. The esr spectrum form of Cu(II) bound to human serum albumin detected at neutral pH would be consistent with the participation of four nitrogens from the alpha-NH2 group, two peptide groups, and the imidazole group of a histidine residue. In contrast, the esr spectra of Vu(II)-dog serum albumin complex showed a transition from a low pH form to a high pH form as the pH was increased to 9.5. These spectral changes were found to be reversible upon lowering the pH. Ligand superhyperfine splitting in the low pH form of the esr signal of Cu(II)-dog albumin were not resolved. The distinct pH dependence of the esr signals observed in human and dog serum albumin complexes could be correlated to their respective optical spectra changes as a function of pH. At room temperature and in the pH range between 6 and 11, the esr spectra of Cu(II) complexes of L-aspartyl-L-alanyl-L-histidine N-methylamide and glycyl-glycyl-L-histidine N-methylamide exhibited a well-resolved nine-line superhyperfine structure indicating metal coordination with four equivalent nitrogen atoms of peptide.

A spin label study of the thyroid hormone-binding sites in human plasma thyroxine transport proteins.

The binding site topographies of the three thyroid hormone-transporting proteins in human serum--prealbumin, thyroxine binding globulin, human serum albumin--have been studied with the aid of five spin-labeled analogs of L-thyroxine in which the distance between the phenolic hydroxyl and the nitroxide nitrogen ranged from 17 to 23 A. In the presence of prealbumin, the electron spin resonance spectrum of 3-([alpha-carboxy-4-(4-hydroxy-3,5-diiodophenoxy)-3,5-diiodophenethyl]-carbamoyl)-2,2,5,5-tetramethyl-3-pyrrolinl-yloxy-ethyl ester revealed the presence of a highly immobilized spin label. As the chain length between the thyroxyl moiety and the pyrroline ring was increased, the mobility of the nitroxide group in the prealbumin-bound labels increased. If the spin labels bind in an extended conformation, the thyroxine-binding site was estimated to be approximately 21 A in depth. This finding is consistent with the known crystal structure of prealbumin and suggests that the solution and crystal conformations of the protein are very similar. In contrast to prealbumin, the thyroxine-binding site on thyroxine-binding globulin was found to be more open and possibly deeper. Human serum albumin has two binding sites for thyroxine, one of which has a higher affinity and is deep enough to accommodate a molecule that is 23 A in length. The lower affinity site is somewhat shallower and probably wider, as thyroxine spin labels bound to this site exhibited greater mobility.

A spin label study of horseradish peroxidase.

The topography of the active sites of native horseradish peroxidase and manganic horseradish peroxidase has been studied with the aid of a spin-labeled analog of benzhydroxamic acid (N-(1-oxyl-2,2,5,5-tetramethylpyrroline-3-carboxy)-p-aminobenzhydroxamic acid). The optical spectra of complexes between the spin-labeled analog of benzhydroxamic acid and Fe3+ or Mn3+ horseradish peroxidase resembled the spectra of the corresponding enzyme complexes with benzhydroxamic acid. Electron spin resonance (ESR) measurement indicated that at pH 7 the nitroxide moiety of the spin-labeled analog of benzhydroxamic acid became strongly immobilized when this label bound to either ferric or manganic horseradish peroxidase. The titration of horseradish peroxidase with the spin-labeled analog of benzhydroxamic acid revealed a single binding site with association constant Ka approximately 4.7 . 10(5) M-1. Since the interaction of ligands (e.g. F-, CN-) and H2O2 with horseradish peroxidase was found to displace the spin label, it was concluded that the spin label did not indeed bind to the active site of horseradish peroxidase. At alkaline pH values, the high spin iron of native horseradish peroxidase is converted to the low spin form and the binding of the spin-labeled analog of benzhydroxamic acid to horseradish peroxidase is completely inhibited. From the changes in the concentration of both bound and free spin label with pH, the pK value of the acid-alkali transition of horseradish peroxidase was found to be 10.5. The 2Tm value of the bound spin label varied inversely with temperature, reaching a value of 68.25 G at 0 degree C and 46.5 G at 52 degrees C. The dipolar interaction between the iron atom and the free radical accounted for a 12% decrease in the ESR signal intensity of the spin label bound to horseradish peroxidase. From this finding, the minimum distance between the iron atom and nitroxide group and hence a lower limit to the depth of the heme pocket of horseradish peroxidase was estimated to be 22 A.