Rebecca M. Nyquist scite author profile

Cytochrome c oxidase, the terminal protein in the respiratory chain, converts oxygen into water and helps generate the electrochemical gradient used in the synthesis of ATP. The catalytic action of cytochrome c oxidase involves electron transfer, proton transfer, and O2 reduction. These events trigger specific molecular changes at the active site, which, in turn, influence changes throughout the protein, including alterations of amino acid side chain orientations, hydrogen bond patterns, and protonation states. We have used IR difference spectroscopy to investigate such modulations for the functional intermediate states E, R2,Pm, and F. These spectra reveal deprotonation of its key glutamic acid E286 in the E and in the Pm states. The consecutive deprotonation and reprotonation of E286 twice within one catalytic turnover illustrates the role of this residue as a proton shuttle. In addition, the spectra point toward deprotonation of a redox-active tyrosine, plausibly Y288, in the F intermediate. Structural insights into the molecular mechanism of catalysis based on the subtle molecular changes observed with IR difference spectroscopy are discussed.

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Perfusion‐induced redox differences in cytochrome c oxidase: ATR/FT‐IR spectroscopy

Nyquist

Heitbrink

Bolwien

et al. 2001

FEBS Letters

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Attenuated total reflection (ATR) spectroscopy brings an added dimension to studies of structural changes of cytochrome c oxidase (CcO) because it enables the recording of reaction-induced infrared difference spectra under a wide variety of controlled conditions (e.g. pH and chemical composition), without relying on light or potentiometric changes to trigger the reaction. We have used the ATR method to record vibrational difference spectra of CcO with reduction induced by flowexchange of the aqueous buffer. Films of CcO prepared from Rhodobacter sphaeroides and beef heart mitochondria by reconstitution with lipid were adhered to the internal reflection element of the ATR device and retained their full functionality as evidenced by visible spectroscopy and time-resolved vibrational spectroscopy. These results demonstrate that the technique of perfusion-induced Fourier-transform infrared difference spectroscopy can be successfully applied to a large, complex enzyme, such as CcO, with sufficient signal/noise to probe vibrational changes in individual residues of the enzyme under various conditions. ß

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Counterion Condensation in Solutions of Rigid Polyelectrolytes

Nyquist

Liu

1999

Macromolecules

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We present a simple theory to examine counterion condensation in isotropic solutions of finite-length rigid polyelectrolytes. Electrostatic interactions are described by an extension of Debye−Hückel theory, in which a wavevector-dependent screening length takes into account the connectivity of the polyions. The counterions are divided into two classes, free and condensed, in chemical equilibrium. We demonstrate that trends in counterion condensation are affected by the polyion concentration, the polyion shape, and the solvent quality and that these trends in counterion condensation in turn affect the phase behavior and osmotic pressure of the polyelectrolyte solution.

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