Ólöf Einarsdóttir scite author profile

A cross-linked histidine-phenol compound was synthesized as a chemical analogue of the active site of cytochrome c oxidase. The structure of the cross-linked compound (compound 1) was verified by IR, (1)H and (13)C NMR, mass spectrometry, and single-crystal X-ray analysis. Spectrophotometric titrations indicated that the pK(a) of the phenolic proton on compound 1 (8.34) was lower than the pK(a) of tyrosine (10.1) or of p-cresol (10.2). This decrease in pK(a) is consistent with the hypothesis that a cross-linked histidine-tyrosine may facilitate proton delivery to the binuclear site in cytochrome c oxidase. Time-resolved optical absorption spectra of compound 1 at room temperature, generated by excitation at 266 nm in the presence and absence of dioxygen, indicated a species with absorption maxima at approximately 330 and approximately 500 nm, which we assign to the phenoxyl radical of compound 1. The electron paramagnetic resonance (EPR) spectra of compound 1, obtained after UV photolysis, confirmed the generation of a paramagnetic species at low temperature. Because the cross-linked compound lacks beta-methylene protons, the EPR line shape was dramatically altered when compared to that of the tyrosyl radical. However, simulation of the EPR line shape and measurement of the isotropic g value was consistent with a small coupling to the imidazole nitrogen and with little spin density perturbation in the phenoxyl ring. The ground-state Fourier transform infrared (FT-IR) spectrum of compound 1 showed that addition of the imidazole ring perturbs the frequency of the tyrosine ring stretching vibrations. The difference FT-IR spectrum, associated with the oxidation of the cross-linked compound, detected significant perturbations of the phenoxyl radical vibrational bands. We postulate that phenol oxidation produces a small delocalization of spin density onto the imidazole nitrogen of compound 1, which may explain its unique optical spectral properties.

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Photodissociation and recombination of carbonmonoxy cytochrome oxidase: Dynamics from picoseconds to kiloseconds

Einarsdóttir

Rb²,

Dd³

et al. 1993

Biochemistry

131

156

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The kinetics of the flash-induced photodissociation and rebinding of carbon monoxide in cytochrome aa3-CO have been studied by time-resolved infrared (TRIR) and transient ultraviolet-visible (UV-vis) spectroscopy at room temperature and by Fourier transform infrared (FTIR) spectroscopy at low temperature. The binding of photodissociated CO to CuB+ at room temperature is conclusively established by the TRIR absorption at 2061 cm-1 due to the C-O stretching mode of the CuB(+)-CO complex. These measurements yield a first-order rate constant of (4.7 +/- 0.6) x 10(5) s-1 (t1/2 = 1.5 +/- 0.2 microseconds) for the dissociation of CO from the CuB(+)-CO complex into solution. The rate of rebinding of flash-photodissociated CO to cytochrome a(3)2+ exhibits saturation kinetics at [CO] > 1 mM due to a preequilibrium between CO in solution and the CuB(+)-CO complex (K1 = 87 M-1), followed by transfer of CO to cytochrome a(3)2+ (k2 = 1030 s-1). The CO transfer from CuB to Fe alpha 3 was followed by CO-FTIR between 158 and 179 K and by UV-vis at room temperature. The activation parameters over the temperature range 140-300 K are delta H++ = 10.0 kcal mol-1 and delta S++ = -12.0 cal mol-1 K-1. The value of delta H++ is temperature independent over this range; i.e., delta Cp++ = 0 for CO transfer. Rapid events following photodissociation and preceding rebinding of CO to cytochrome a(3)2+ were observed. An increase in the alpha-band of cytochrome a3 near 615 nm (t1/2 ca. 6 ps) follows the initial femtosecond time-scale events accompanying photodissociation. Subsequently, a decrease is observed in the alpha-band absorbance (t1/2 approximately 1 microsecond) to a value typical of unliganded cytochrome a3. This latter absorbance change appears to occur simultaneously with the loss of CO by CuB+. We ascribe these observations to structural changes at the cytochrome a3 induced by the formation and dissociation of the CuB(+)-CO complex. We suggest that the picosecond binding of photodissociated CO to CuB triggers the release of a ligand L from CuB. We infer that L then binds to cytochrome a3 on the distal side and that this process is directly responsible for the observed alpha-band absorbance changes. We have previously suggested that the transfer of L produces a transient five-coordinate high-spin cytochrome a3 species where the proximal histidine has been replaced by L. When CO binds to the enzyme from solution, these processes are reversed.(ABSTRACT TRUNCATED AT 400 WORDS)

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Intermediates in the Reaction of Fully Reduced Cytochrome c Oxidase with Dioxygen

1998

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The reduction of dioxygen to water by cytochrome c oxidase was monitored in the Soret region following photolysis of the fully reduced CO complex. Time-resolved optical absorption difference spectra collected between 373 and 521 nm were measured at delay times from 50 ns to 50 ms and analyzed using singular value decomposition and multiexponential fitting. Five processes were resolved with apparent lifetimes of 0.9 micros, 8 micros, 36 micros, 103 micros, and 1.2 ms. A mechanism is proposed and spectra of intermediates are extracted and compared to model spectra of the postulated intermediates. The model builds on an earlier mechanism that used data only from the visible region (Sucheta et al. (1997) Biochemistry 36, 554-565) and provides a more complete mechanism that fits results from both spectral regions. Intermediate 3, the ferrous-oxy complex (compound A) decays into a 607 nm species, generally referred to as P, which is converted to a 580 nm ferryl form (Fo) on a significantly faster time scale. The equilibrium constant between P and Fo is 1. We propose that the structure of P is a3(4+)=O CuB2+-OH- with an oxidizing equivalent residing on tyrosine 244, located close to the binuclear center. Upon conversion of P to Fo, cytochrome a donates an electron to the tyrosine radical, forming tyrosinate. Subsequently a proton is taken up by tyrosinate, forming F(I) [a3(4+)=O CuB2+-OH- a3+ CuA+]. This is followed by rapid electron transfer from CuA to cytochrome a to produce F(II) [a3(4+)=O CuB2+-OH- a2+ CuA2+].

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Nature and functional implications of the cytochrome a3 transients after photodissociation of CO-cytochrome oxidase.

Woodruff

Einarsdóttir

Dyer

et al. 1991

Proc. Natl. Acad. Sci. U.S.A.

114

117

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Time-resolved electronic absorption, infrared, resonance Raman, and magnetic circular dichroism spectroscopies are applied to characterization of the intermediate that is formed within 20 ps after photodissociation of CO from cytochrome a3 in reduced cytochrome oxidase. This intermediate decays with the same half-life (1l is) as the postphotodissociation Cu'-CO species previously observed by time-resolved infrared. The transient UV/visible spectra, kinetics, infrared, and Raman evidence suggest that an endogenous ligand is transferred from CUB to Fe,3 when CO binds to CUB, forming a cytochrome a3 species with axial ligation that differs from the reduced unliganded enzyme. The timeresolved magnetic circular dichroism results suggest that this transient is high-spin and, therefore, five-coordinate. Thus we infer that the ligand from CUB binds on the distal side of cytochrome a3 and displaces the proximal histidine imidazole. This remarkable mechanistic feature is an additional aspect of the previously proposed "ligand-shuttle" activity of the CuB/Fe,3 pair. We speculate as to the identity ofthe ligand that is transferred between CUB and Fe,13 and suggest that the ligand shuttle may play a functional role in redox-linked proton translocation by the enzyme.In a recent time-resolved infrared (TRIR) study (1) of the events after photodissociation of CO from cytochrome (cyt) a3 of reduced beef heart cytochrome oxidase (CcO), we reported conclusive evidence that photodissociated CO binds quantitatively to CuB at room temperature prior to equilibrating with solution. In a parallel kinetics study (6.E., P. M.

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