Chromium corroles in four oxidation States.

We have isolated and characterized chromium complexes of 5,10,15-tris(pentafluorophenyl)corrole [(tpfc)H(3)] (1) in four oxidation states: [(tpfc(*))CrO][SbCl(6)] (6); [(tpfc)CrO] (2); [(tpfc)CrO][Cp(2)Co] (4); and [(tpfc)Cr(py)(2)] (3). Complex 6 was prepared both by electrochemical and chemical oxidation of 2; its formulation as a Cr(V)O ligand-radical species is based on UV-visible absorption as well as EPR measurements. Cobaltocene reduction of 2 gave 4; it was identified as a diamagnetic d(2) Cr(IV)O complex from its sharp (1)H NMR spectrum. Reaction of 2 with triphenylphosphine yielded a chromium(III) corrole, [(tpfc)Cr(OPPh(3))(2)] (5). Owing to its air sensitivity, 5 could not be isolated in the absence of excess OPPh(3). The structure of the Cr(III) bis-pyridine complex (3) was determined by X-ray crystallography (Cr-N distances: 1.926-1.952 A, pyrrole; 2.109, 2.129 A, pyridine).

Electron tunneling in single crystals of Pseudomonas aeruginosa azurins.

Rates of reduction of Os(III), Ru(III), and Re(I) by Cu(I) in His83-modified Pseudomonas aeruginosa azurins (M-Cu distance approximately 17 A) have been measured in single crystals, where protein conformation and surface solvation are precisely defined by high-resolution X-ray structure determinations: 1.7(8) x 10(6) s(-1) (298 K), 1.8(8) x 10(6) s(-1) (140 K), [Ru(bpy)2(im)(3+)-]; 3.0(15) x 10(6) s(-1) (298 K), [Ru(tpy)(bpy)(3+)-]; 3.0(15) x 10(6) s(-1) (298 K), [Ru(tpy)(phen)(3+)-]; 9.0(50) x 10(2) s(-1) (298 K), [Os(bpy)2(im)(3+)-]; 4.4(20) x 10(6) s(-1) (298 K), [Re(CO)3(phen)(+)] (bpy = 2,2'-bipyridine; im = imidazole; tpy = 2,2':6',2' '-terpyridine; phen = 1,10-phenanthroline). The time constants for electron tunneling in crystals are roughly the same as those measured in solution, indicating very similar protein structures in the two states. High-resolution structures of the oxidized (1.5 A) and reduced (1.4 A) states of Ru(II)(tpy)(phen)(His83)Az establish that very small changes in copper coordination accompany reduction but reveal a shorter axial interaction between copper and the Gly45 peptide carbonyl oxygen [2.6 A for Cu(II)] than had been recognized previously. Although Ru(bpy)2(im)(His83)Az is less solvated in the crystal, the reorganization energy for Cu(I) --> Ru(III) electron transfer falls in the range (0.6-0.8 eV) determined experimentally for the reaction in solution. Our work suggests that outer-sphere protein reorganization is the dominant activation component required for electron tunneling.

The red form of [Re(phen)(CO)3(H2O)]-CF3SO3.H2O.

The coordination geometry of the cations in the red form of aquatricarbonyl(1,10-phenanthroline-N,N')rhenium(I) trifluoromethanesulfonate hydrate, [Re(C12H8N2)(CO)3-(H2O)]CF3SO3.H2O, is approximately octahedral, with a facial arrangement of the linearly coordinated carbonyl ligands. The phenanthroline (phen) ligands interleave to form a columnar pi-stacked structure.

Structures of ruthenium-modified Pseudomonas aeruginosa azurin and [Ru(2,2'-bipyridine)2(imidazole)2]SO4 x 10H2O.

The crystal structure of Ru(2, 2'-bipyridine)2(imidazole)(His83)azurin (RuAz) has been determined to 2.3 A -resolution by X-ray crystallography. The spectroscopic and thermodynamic properties of both the native protein and [Ru(2, 2'-bipyridine)2(imidazole)2]2+ are maintained in the modified protein. Dark-green RuAz crystals grown from PEG 4000, LiNO3, CuCl2 and Tris buffer are monoclinic, belong to the space group C2 and have cell parameters a = 100.6, b = 35.4, c = 74.7 A and beta = 106. 5 degrees. In addition, [Ru(2,2'-bipyridine)2(imidazole)2]SO4 x 10H2O was synthesized, crystallized and structurally characterized by X-ray crystallography. Red-brown crystals of this complex are monoclinic, space group P21/n, unit-cell parameters a = 13.230 (2), b = 18.197 (4), c = 16.126 (4) A, beta = 108.65 (2) degrees. Stereochemical parameters for the refinement of Ru(2, 2'-bipyridine)2(imidazole)(His83) were taken from the atomic coordinates of [Ru(2,2'-bipyridine)2(imidazole)2]2+. The structure of RuAz confirms that His83 is the only site of chemical modification and that the native azurin structure is not perturbed significantly by the ruthenium label.

Paramagnetic NMR Spectroscopy of Cobalt(II) and Copper(II) Derivatives of Pseudomonas aeruginosa His46Asp Azurin.

NMR spectra of paramagnetic Co(II) and Cu(II) derivatives of Pseudomonas aeruginosa His46Asp azurin have been investigated. In each derivative, assignment of hyperfine-shifted resonances outside the diamagnetic envelope of spectra recorded at 200 and 500 MHz confirms that the Asp carboxylate is coordinated to the paramagnetic metal center. The reduced paramagnetic shifts of the Cys112 proton resonances in Cu(II) and Co(II) His46Asp azurins compared to those of the corresponding wild type proteins indicate that metal-S(Cys) bonding is weakened in this mutant. The downfield shifts of the gamma-CH(2) of Met121 suggest a stronger interaction between the metal and the Met thioether group than is present in the wild type protein. Molecular modeling of the metal site structure indicates a distorted tetrahedral geometry with Asp46 (monodentate carboxylate), Cys112, and His117 equatorial ligands. In this structure, the metal ion is shifted 0.3 Å out of the O(Asp)S(Cys)N(His) trigonal plane toward Met121.

Electron tunneling in azurin: the coupling across a beta-sheet.

BACKGROUND: We would like to understand how electron flow is controlled in biological molecules. Standard theories calculate the rate for long distance electron transfer (ET) as the product of electronic coupling (the square of the electron tunneling matrix element) and nuclear (Franck-Condon) factors. Much attention has been directed to the role of protein secondary and tertiary structure in the tunneling coupling, focusing on the interplay between different types of chemical bonds. Here we have evaluated the relative contributions of covalent bonds, hydrogen bonds and through-space jumps in coupling through a beta-strand or across a beta-sheet section of a blue copper protein, azurin. RESULTS: We have analyzed four distant electronic couplings in azurin. Each coupling is between the copper atom and a Ru(bpy)2(im) complex attached to a histidine on the protein surface. In three experiments the intervening medium was a simple beta-strand, while in the fourth experiment it was a section of beta-sheet. CONCLUSIONS: We have shown that electron tunneling in a protein can be broken down into ET 'tubes' of pathways through specific covalent and hydrogen bonds. These ET tubes encapsulate trivial interference effects and can expose crucial inter-tube interference effects. In coupling through a beta-sheet, hydrogen bonds are as important as covalent links, and are the primary source for tube interference.

Electron transfer in ruthenium-modified proteins.

Photochemical techniques have been used to measure the kinetics of intramolecular electron transfer in Ru(bpy)2(im)(His)2(+)-modified (bpy = 2,2'-bipyridine; im = imidazole) cytochrome c and azurin. A driving-force study with the His33 derivatives of cytochrome c indicates that the reorganization energy (lambda) for Fe2+-->Ru3+ ET reactions is 0.8 eV. Reductions of the ferriheme by either an excited complex, *Ru2+, or a reduced complex, Ru+, are anomalously fast and may involve formation of an electronically excited ferroheme. The distance dependence of Fe2+-->Ru3+ and Cu+-->Ru3+ electron transfer in 12 different Ru-modified cytochromes and azurins has been analyzed using a tunneling-pathway model. The ET rates in 10 of the 12 systems exhibit an exponential dependence on metal-metal separation (decay constant of 1.06 A-1) that is consistent with prediction of the pathway model.

Site saturation of the histidine-46 position in Pseudomonas aeruginosa azurin: characterization of the His46Asp copper and cobalt proteins.

Cassette mutagenesis has been used to replace the copper ligand His46 of Pseudomonas aeruginosa azurin with 19 other amino acids and a stop codon. Several mutant proteins were expressed in Escherichia coli and isolated; however, only the variant in which His was replaced by Asp exhibited the spectral characteristics of a blue (type 1) center. The spectroscopic and electrochemical properties of this mutant protein show that the copper site is perturbed relative to wild-type azurin. The absorption spectrum of Cu(II)(His46Asp) azurin exhibits a S(Cys)-->Cu(II) band at 612 nm, as well as weaker features at approximately 300, 454, and approximately 850 nm; its EPR spectrum is rhombic (g parallel = 2.327(1), gx approximately 2.03, and gy approximately 2.07; A parallel = 22(2) x 10(-4), Ax approximately 46 x 10(-4), and Ay approximately 22 x 10(-4) cm-1). The reduction potential of the mutant (260 mV vs NHE at pH 8.5; 297 mV at pH 5.0) is lower than that of wild-type azurin (288 mV at pH 8.5; 349 mV at pH 5.0). The S(Cys)-->Co(II) absorption bands (approximately 300 and 362 nm) in Co(II)(His46Asp) azurin are strongly blue-shifted relative to those (330 and 375 nm) in the spectrum of the Co(II) (His46) protein, whereas the intensities of the ligand-field bands in the 500-650-nm region (epsilon approximately 100 M-1 cm-1) indicate a five-coordinate Co(II) environment.

In vitro scavenger activity of some flavonoids and melanins against O2-(.).

The scavenger activity against O2-. of some flavonoids and melanins (synthetic melanins and melanins isolated from animal tissues, vegetable seeds, and mushroom spores) has been studied by ESR spectrometry. All these substances, except flavon and flavanone, diminish the signal of O2-. generated in vitro by a system containing H2O2 and acetone in an alkaline medium. It is shown that the presence of hydroxyl groups in the B ring of flavonoids is essential for their scavenger activity. Moreover, the presence of a hydroxyl at C-3 enhances the scavenger ability of flavonoids. Generally, aglycons are more active than their glycosides. It seems plausible that the antioxidant property of these substances comes from their scavenger activity against O2-(.). It is also pointed out that the scavenger activity shown by melanins, is strictly correlated with their nature of stable free radical.