Pathway analysis on electron transfer in ruthenium modified cytochrome C

Tsang, Chun-kit.

January 2000

Thesis (M. Phil.)--University of Hong Kong, 2001. / Includes bibliographical references.

Charge exchange Cytochrome c. Ruthenium.

Structural characterization of omega loop peptides from cytochrome c

Norris, Judy Barnett

08 1900

No description available.

Peptides

Protein folding

Cytochrome c

Characterization of Cox15p, a cytochrome c oxidase assembly factor and component of the eukaryotic heme A synthase

Rumley, Alina C.

Unknown Date

No description available.

cytochrome c oxidase

heme A

Cox15p

Semi-synthetic model studies related to cytochrome c

White, P. D.

January 1987

No description available.

572

Cytochrome c model studies

Model studies of the cub-histidine-tyrosine centre in cytochrome c oxidase

Lee, Sang Tae, Chemistry, Faculty of Science, UNSW

January 2005

This thesis reports the synthesis and copper coordination chemistry of covalently-linked aryl-imidazole derivatives designed as models for the crosslinked imidazole-phenol sidechains of the His-Tyr cofactor in the CcO. Three new imidazole- (HL1 - HL3) and three new indole- (HL4 - H2L6) containing tripodal ligands were synthesised. The conjugate addition of an imidazole to activated quinone derivatives was developed as a new route to organic models for the Tyr His cofactor. Two monodentate imidazole-aryl, Im-hq(OH)2 and Im-ArOH, and an imidazole-quinone, Im bq were obtained using this route. The X-ray crystal structure of Im-hq(OH)2.EtOH was determined. The route was also used to give new chelating ligands, H2L10 and HL12, containing a cross-linked imidazole-phenol surrogate for the Tyr244-His240 cofactor. Copper complexes of Im-hq(OH)2, Im-bq, Im-ArOH, H2L10-HL12, and HL1-H2L6 were prepared, and the X-ray crystal structures of [Cu(terpy)(Im-bq)][BF4]2 and five other copper complexes were determined. The physiochemical properties of the copper complexes were characterized by FT-IR, UV-Vis-NIR, EPR and (spectro)electrochemical studies. Key results include: the oxidation of Im-ArO- anion affords the semiquinone radical, Im-sq(4OH)(1O??????), in a hydrous solvent. However, the oxidations of neutral Im-ArOH and [Cu(tpa)(Im-ArOH)]2+ produce the corresponding phenoxy radical species that rapidly and reversibly dimerise to give quinol cyclohexadienone, QCHD, dimers. Significantly [Cu(tpa)(Im-sq(4OH)(1O??????))]2+ was EPR silent, perhaps due to antiferromagnetic coupling between the Cu(II) (S=1/2) and semiquinonyl radical (S=1/2) centres. Deprotonation of the hydroquinone in [Cu(tpa)(Im-hq(OH)2]2+ produces the hydroquinone dianion which reduces the Cu(II) centre. The semiquinone radical is coordinatively labile and dissociates from the Cu(I) centre. The biological implications of these results are mentioned.

Cytochrome C oxidase

Histidine

Tyrosine

Electron paramagnetic resonance study of cytochrome C solutions and single crystals

Mailer, Colin

January 1971

Electron paramagnetic resonance (EPR) signals from tuna ferricytochrome c solutions were obtained between 4.2°K and 77°K, with g-values g(1) = 1.25, g(2) = 2.25, g(3) = 3.05« The g(3) line is 380 gauss wide between 4.2°K and 50°K with Gaussian shape, but has become 700 gauss wide with Lorentzian shape at 77°K. The temperature independent shape and width are best explained by a distribution of rhombic crystal field potentials (r.m.s. deviation = 11%). The Lorentzian shape arises from a short (10(-8) sec.) spin-lattice relaxation time. EPR spectra from horse heart ferricytochrome c single crystals were analysed to obtain the orientation of the g-axes relative to the crystallographic axes. The g(3)-axis was 76° from the crystal c-axis, close to the heme normal (71.5° to c-axis) determined from the 3-dimensional X-ray structure by Dickerson. The other 2 g-axes lay approximately along the N-Fe-N directions in the heme ring. An amended version of Eisenberger and Pershan's theory was used to explain the angular variation of the broad lines (300-2000 gauss) seen in the crystals—best fit was obtained with the distribution of ligand fields from the solution study plus a 1.5° variation in g-axis orientation. The undifferentiated absorption line shapes observed at 4.2°K in both solutions and single crystals were explained by the Portis theory of rapid adiabatic passage in solids. This theory was tested with a model system of charred dextrose, and found to be valid. Using the theory the relaxation time (τ) of the cytochrome c system was found to be, from the phase lag of the EPR signal relative to the magnetic field modulation, 3.8 x 10(-6) sec. at 4.2°K. τ was obtained between 4.2°K and 18°K from the rapid passage signals, and between 50°K and 70°K from the linewidth of the spectra. The temperature dependence of τ below 20°K could arise from a combination of a T(9) Raman spin-lattice relaxation process with a temperature independent spin-spin relaxation time of order 10(-8) seconds (which might arise from dipolar interactions between neighboring iron atoms). / Science, Faculty of / Physics and Astronomy, Department of / Graduate

Cytochrome c.

Electron paramagnetic resonance

Photoacoustic Calorimetry Studies of the Earliest Events in Horse Heart Cytochrome-c Folding

Word, Tarah A.

16 September 2015

The protein folding problem involves understanding how the tertiary structure of a protein is related to its primary structure. Hence, understanding the thermodynamics associated with the rate-limiting steps for the formation of the earliest events in folding is most crucial to understanding how proteins adopt native secondary and tertiary structures. In order to elucidate the mechanism and pattern of protein folding, an extensively studied protein, Cytochrome-c (Cc), was chosen as a folding system to obtain detailed time-resolved thermodynamic profiles for the earliest events in the protein folding process. Cytochrome-c is an ideal system for understanding the folding process for several reasons. One being that the system can unfold and refold reversibly without the loss of the covalently attached heme group. A number of studies have shown that under denaturing conditions, ferrous Cc (Fe2+Cc) heme group in the presence of carbon monoxide (CO) results in a disruption of the axial heme Methionine-80 (Met80) bond ultimately unfolding the protein. CO-photolysis of this ferrous species results in the formation of a transient unfolded protein that is poised in a non-equilibrium state with the equilibrium state being that of the native folded Fe2+Cc complex. This allows for the refolding reaction of the protein to be photo-initiated and monitor on ns - ms timescales. While CO cannot bind to the ferric form, nitrogen monoxide (NO) photo-release has been developed to photo-trigger ferric Cc (Fe3+Cc) unfolding under denaturing conditions. Photo-dissociation of NO leaves the Fe3+complex in a conformational state that favors unfolding thus allowing the early unfolding events of Fe3+Cc to be probed. Overall the results presented here involve the use of the ligands CO and NO along with photoacoustic calorimetry (PAC) to photo-trigger the folding/unfolding reaction of Cc (and modified Cc). Thus, obtaining enthalpy and molar volume changes directly associated with the initial folding/unfolding events occurring in the reaction pathways of both Fe2+ and Fe3+Cc systems that are most essential to understanding the driving forces involved in forming the tertiary native conformation. The PAC data shows that folding of proteins results from a hierarchy of events that potentially includes the formation of secondary structures, hydrophobic collapse, and/or reorganization of the tertiary complex occurring over ~ns – tens of µs time ranges. In addition, the PAC kinetic fits presented in this work is the first to report Cc folding exhibiting heterogeneous kinetics (in some cases) by utilizing a stretched exponential decay function.

Protein Folding

Chloramine-T Cytochrome-c

Ferric Cytochrome-c

Ferrous Cytochrome-c

Carbon Monoxide-bound

Nitrogen Monoxide-bound

Biophysics

Chemistry

TRANSIENT KINETICS OF ELECTRON TRANSFER REACTIONS OF FLAVODOXIN (CLOSTRIDIUM, PASTEURIANUM).

SIMONDSEN, ROYCE PAUL.

January 1983

Electron transfer reactions between Clostridium pasteurianum flavodoxin semiquinone and various oxidants (horse heart cytochrome c, ferricyanide, and ferric EDTA) have been studied as a function of ionic strength using stopped-flow spectrophotometry. The cytochrome c reaction is complicated by the existence of two cytochrome species which react at different rates and whose relative concentrations are ionic strength dependent. Only the faster of these two reactions is considered here. At low ionic strength, complex formation between cytochrome c and flavodoxin is indicated by a levelling-off of the pseudo-first order rate constant at high cytochrome c concentration. This is not observed for either ferricyanide or ferric EDTA. For cytochrome c, the rate and association constants for complex formation were found to increase with decreasing ionic strength, consistent with negative charges on flavodoxin interacting with the positively charged cytochrome electron transfer site. Both ferricyanide and ferric EDTA are negatively charged oxidants and the rate data respond to ionic strength changes as would be predicted for reactants of the same charge sign. These results demonstrate that electrostatic interactions involving negatively charged groups are important in orienting flavodoxin with respect to oxidants during electron transfer. The effects of structural modifications of the FMN prosthetic group of C. pasteurianum flavodoxin on the kinetics of electron transfer to the oxidized form (from 5-deazariboflavin semiquinone produced by laser flash photolysis) and from the semiquinone form (to horse heart cytochrome c using stopped-flow spectrophotometry) have been investigated. The analogs used were 7,8-dichloroFMN, 8-chloroFMN, 7-chloroFMN and 5,6,7,8-tetrahydroFMN. The ionic strength dependence of cytochrome c reduction was not affected by chlorine substitution, although the specific rate constants for complex formation and decay were appreciably smaller. On the other hand, all of the chlorine analogs had the same rate constant for deazariboflavin semiquinone oxidation. The rate constants for tetrahydroFMN flavodoxin semiquinone reduction of cytochrome c were considerably smaller than those for the native protein. The results for the chlorine analogs indicate the important roles that the polarity of the exposed flavin edge and the substitution of the 8 position play in electron transfer. The data obtained with the tetrahydroFMN analog indicates that the (pi) electron system of the flavin is necessary for rapid electron transfer. These implications are discussed for the electron transfer mechanism of flavodoxin.

Cytochrome c.

Flavoproteins.

Flavins.

Oxidation-reduction reaction.

Biochemical mechanisms of apoptosis : ordering of the biochemical events in chemical-induced apoptosis

Zhuang, Jianguo

January 1999

No description available.

572

Laser pulse induced electron-transfer between cytochrome C and inorganic complexes.

January 1984

by Cheng Fat-chi. / Bibliography: leaves 85-86 / Thesis (M.Ph.)--Chinese University of Hong Kong, 1984

Laser pulses, Ultrashort

Electron transport

Cytochrome c