Brian S. Leigh

Spectroscopic Comparison of Photogenerated Tryptophan Radicals in Azurin: Effects of Local Environment and Structure

Tryptophan radicals play a significant role in mediating biological electron transfer. We report the photogeneration of a long-lived, neutral tryptophan radical (Az48W*) from the native residue tryptophan-48 in the hydrophobic core of azurin. The optical absorption, electron paramagnetic resonance, and resonance Raman spectra strongly support the formation of a neutral radical, and the data are consistent with direct electron transfer between tryptophan and the copper(II) center. Spectra of the long-lived Az48W* species are compared to those of a previously studied, solvent-exposed radical at position 108 to identify signatures of tryptophan radicals that are sensitive to the local environment. The absorption maxima of Az48W* display an approximately 23 nm hypsochromic shift in the nonpolar environment. The majority of the resonance Raman frequencies are downshifted by approximately 7 cm(-1) relative to the solvent-exposed radical, and large changes in intensity are observed for some modes. The resonance Raman excitation profiles for Az48W* exhibit distinct maxima within the absorption envelope. Electron paramagnetic resonance spectroscopy yields spectra with partially resolved lines caused by hyperfine couplings; the differences between the coupling constants for the buried and solvent-exposed radical are primarily caused by variations in structure. The insights gained by electronic, vibrational, and magnetic resonance spectroscopy enhance our fundamental understanding of the effects of protein environment on radical properties. Hypotheses for the proton transfer pathway within azurin and a deprotonation rate of approximately 5 x 10(6) s(-1) are proposed.

Resonance Raman Characterization of a Stable Tryptophan Radical in an Azurin Mutant

Tryptophan radicals play a significant role in mediating biological electron transfer and catalytic processes. Here, we employ visible and UV resonance Raman, EPR, and absorption spectroscopy along with pH/isotope studies and calculations to probe a neutral closed-shell tryptophan and its oxidized radical counterpart in a modified azurin protein. Comparison of the resonance Raman spectra of the radical and closed-shell species combined with vibrational analysis reveals important structural differences between these two tryptophan species. We experimentally observe a significant reduction in bond order of the pyrrole ring of the radical, as evidenced by a 208 cm(-1) downshift of the W3 mode (predominantly C(2)-C(3) stretch). Analysis of the spectra acquired at acidic pH and in deuterated buffer highlights those vibrational modes of the radical that are sensitive to the hydrogen-bonding environment. The most significant change caused by the deuterated buffer is a 45 cm(-1) downshift of an indole nitrogen displacement mode (W17). Our spectra provide evidence that the radical species is a strong hydrogen bond acceptor, particularly in an acidic environment. Furthermore, the pK(a) for this tryptophan radical must be less than 4.0, which falls below previously reported values for l-tryptophan in aqueous solution. The normal mode assignments of the tryptophan radical help characterize its local environment, conformation, hydrogen bonding, and protonation state within a protein.

Photogeneration and Quenching of Tryptophan Radical in Azurin.

Tryptophan and tyrosine can form radical intermediates that enable long-range, multistep electron transfer (ET) reactions in proteins. This report describes the mechanisms of formation and quenching of a neutral tryptophan radical in azurin, a blue-copper protein that contains native tyrosine (Y108 and Y72) and tryptophan (W48) residues. A long-lived neutral tryptophan radical W48• is formed upon UV-photoexcitation of a zinc(II)-substituted azurin mutant in the presence of an external electron acceptor. The quantum yield of W48• formation (Φ) depends upon the tyrosine residues in the protein. A tyrosine-deficient mutant, Zn(II)Az48W, exhibited a value of Φ = 0.080 with a Co(III) electron acceptor. A nearly identical quantum yield was observed when the electron acceptor was the analogous tyrosine-free, copper(II) mutant; this result for the Zn(II)Az48W:Cu(II)Az48W mixture suggests there is an interprotein ET path. A single tyrosine residue at one of the native positions reduced the quantum yield to 0.062 (Y108) or 0.067 (Y72). Wild-type azurin with two tyrosine residues exhibited a quantum yield of Φ = 0.045. These data indicate that tyrosine is able to quench the tryptophan radical in azurin.

Insights into Protein Structure and Dynamics by Ultraviolet and Visible Resonance Raman Spectroscopy

Raman spectroscopy is a form of vibrational spectroscopy based on inelastic scattering of light. In resonance Raman spectroscopy, the wavelength of the incident light falls within an absorption band of a chromophore, and this overlap of excitation and absorption energy greatly enhances the Raman scattering efficiency of the absorbing species. The ability to probe vibrational spectra of select chromophores within a complex mixture of molecules makes resonance Raman spectroscopy an excellent tool for studies of biomolecules. In this Current Topic, we discuss the type of molecular insights obtained from steady-state and time-resolved resonance Raman studies of a prototypical photoactive protein, rhodopsin. We also review recent efforts in ultraviolet resonance Raman investigations of soluble and membrane-associated biomolecules, including integral membrane proteins and antimicrobial peptides. These examples illustrate that resonance Raman is a sensitive, selective, and practical method for studying the structures of biological molecules, and the molecular bonding, geometry, and environments of protein cofactors, the backbone, and side chains.