Salt-dependent structure change and ion binding in cytochrome c studied by two-dimensional proton NMR

Supercharging of Proteins by Salts during Polarity Reversed Nano-Electrospray Ionization

Supercharging is beneficial in many ways to the analysis of proteins by mass spectrometry (MS). In this work, a novel supercharging method was developed. It made use of our previously developed ionization technique: namely, polarity reversed nanoelectrospray ionization (PR-nESI) for the ionization of proteins. Supercharging of proteins was achieved by just adding 1-10 mM of a salt to the sample, such as sodium chloride (NaCl). The charge state of proteins obtained by our method was significantly higher than that by nano-ESI with 1% (v/v) acetic acid (HAc). Different kinds of salts were investigated. Salts with  strong acid anions were capable of supercharging proteins, including chlorides, bromides, iodides, and nitrates. The signal intensity and signal to noise ratio ( S/ N) of proteins were increased at the same time. Phosphates were also found to have a supercharging effect, due to the fact that phosphoric acid was a medium-strong acid. In comparison, salts with weak acid anions had no supercharging effect, such as carbonates, sulfides, acetates, and formates. The species of the salt anion was critical to the supercharging effect, while the species of the salt cation showed little influence on the supercharging effect. Investigations were made into the mechanism of our method. The supercharging effect was caused by interactions between protein molecules and salt anions, as well as the influence of protons. The present work offered us an alternative way for the supercharging of proteins. The use of common salts for supercharging made the procedure more convenient. The concentration of salts needed for supercharging was much lower than those conventionally used for supercharging reagents. Taking into consideration the fact that many biological samples are buffered with phosphates and chlorides, these samples could be directly supercharged by our method without any additional additives. Furthermore, as many salts are nontoxic and can easily be found in a chemical laboratory, the use of salts for supercharging would be a much more practical and economical choice. In addition, the present work also furthered our understandings about the mechanism of supercharging, as well as electrospray.

Phosphate mediated adsorption and electron transfer of cytochrome c. A time-resolved SERR spectroelectrochemical study

The study of proteins immobilized on biomimetic or biocompatible electrodes represents an active field of research as it pursues both fundamental and technological interests. In this context, adsorption and redox properties of cytochrome c (Cyt) on different electrode surfaces have been extensively reported, although in some cases with contradictory results. Here we report a SERR spectroelectrochemical study of the adsorption and electron transfer behaviour of the basic protein Cyt on electrodes coated with amino-terminated monolayers. The obtained results show that inorganic phosphate (Pi) and ATP anions are able to mediate high affinity binding of the protein with preservation of the native structure and rendering an average orientation that guarantees efficient pathways for direct electron transfer. These findings aid the design of Cyt-based bioelectronic devices and understanding the modulation by Pi and ATP of physiological functions of Cyt.

Structural changes of horse heart ferricytochrome C induced by changes of ionic strength and anion binding

To test the validity of the notion that changes in ionic strength and ion binding do not cause any major functionally relevant structural changes in cytochrome c, we measured the absorption and electronic circular dichroism (ECD) of horse heart ferricytochrome c for the Soret and 695 nm charge-transfer band as a function of dihydrogen phosphate and sodium acetate concentrations. This band is known to probe the integrity of the functionally pivotal Fe3+-M80 linkage. Spectral changes indicate that an ionic strength increase (via an increasing acetate ion concentration) affects only a subset of conformational substates of the Fe-M80 interface, probed by the 695 nm charge-transfer band, without a substantial modification of the heme environment. This result suggests that the substates probed by the 695 nm band differ with respect to their capability to transduce changes of solvent-protein interactions to the active site. The binding of H2PO4- ions causes more significant structural changes, which give rise to a large increase of the oscillator strength of the 695 nm band. This reflects a strengthening of the Fe-M80 bond in all substates, which probably destabilizes the oxidized state but stabilizes the folded state of the protein. Additional structural variations are likely to involve aromatic side chains, such as F82 and W59, and the hydrogen-bonding network in the heme pocket. In contrast to the current belief that anion binding to the binding domain of the protein for cytochrome c oxidase does not cause any functionally relevant structural changes, our results show that the structural variations that occur in the heme pocket are most likely of functional significance.

Conformational stability and dynamics of cytochrome c affect its alkaline isomerization

The alkaline isomerization of horse heart ferricytochrome c (cyt c) has been studied by electronic absorption spectroscopy in the presence of the Hofmeister series of anions: chloride, bromide, rhodanide and perchlorate. The anions significantly affect the apparent pK (a) value of the transition in a concentration-dependent manner according to their position in the Hofmeister series. The Soret region of the absorption spectra is not affected by the presence of the salts and shows no significant structural perturbation of the heme crevice. In the presence of perchlorate and rhodanide anions, the cyanide exchange rate between the bulk solvent and the binding site is increased. These results imply higher flexibility of the protein structure in the presence of chaotropic salts. The thermal and isothermal denaturations monitored by differential scanning calorimetry and circular dichroism, respectively, showed a decrease in the conformational stability of cyt c in the presence of the chaotropic salts. A positive correlation between the stability, DeltaG, of cyt c and the apparent pK (a) values that characterize the alkaline transition indicates the presence of a thermodynamic linkage between these conformational transitions. In addition, the rate constant of the cyanide binding and the partial molar entropies of anions negatively correlate with the pK (a) values. This indicates the important role of anion-induced solvent reorganization on the structural flexibility of cyt c in the alkaline transitions.

Structure-function relationship of reduced cytochrome c probed by complete solution structure determination in 30% acetonitrile/water solution

The complete solution structure of ferrocytochrome c in 30% acetonitrile/70% water has been determined using high-field 1D and 2D (1)H NMR methods and deposited in the Protein Data Bank with codes 1LC1 and 1LC2. This is the first time a complete solution protein structure has been determined for a protein in nonaqueous media. Ferrocyt c retains a native protein secondary structure (five alpha-helices and two omega loops) in 30% acetonitrile. H18 and M80 residues are the axial heme ligands, as in aqueous solution. Residues believed to be axial heme ligands in the alkaline-like conformers of ferricyt c, specifically H33 and K72, are positioned close to the heme iron. The orientations of both heme propionates are markedly different in 30% acetonitrile/70% water. Comparative structural analysis of reduced cyt c in 30% acetonitrile/70% water solution with cyt c in different environments has given new insight into the cyt c folding mechanism, the electron transfer pathway, and cell apoptosis.

Salt-promoted protein folding, preferential binding, or electrostatic screening?

The extended coil/molten globule conformational equilibrium exhibited by ferricytochrome c in 10 to 20 mM HCl was examined using free boundary capillary electrophoresis. Addition of the osmolyte glucitol, also called sorbitol, to shift the conformational equilibrium toward the molten globule markedly diminished the mobility of the protein. This diminution can be entirely assigned to the relative viscosity of the added glucitol. The insensitivity of the viscosity corrected protein mobility to added glucitol suggests that both the extended coil and molten globule conformations of cytochrome c are free draining in an electrophoresis measurement. Addition of a neutral salt to shift the conformational equilibrium toward the molten globule conformation also markedly diminished the mobility of the protein. This diminution can be entirely assigned to the electrostatic screening afforded by the added salt. The onset of the conformational transition observed by optical measurements and the onset of electrostatic screening observed by mobility measurements appear to be in common for some but not all neutral salts. The exception suggests that preferential binding of the anion of a neutral salt to the molten globule conformation and not electrostatic screening is principally responsible for the shift in the conformational equilibrium of cytochrome c in acidic solutions.

The cytochrome c fold can be attained from a compact apo state by occupancy of a nascent heme binding site

NMR techniques and 8-anilino-1-napthalenesulphonate (ANS) binding studies have been used to characterize the apo state of a variant of cytochrome c(552) from Hydrogenobacter thermophilus. In this variant the two cysteines that form covalent thioether linkages to the heme group have been replaced by alanine residues (C11A/C14A). CD studies show that the apo state contains approximately 14% helical secondary structure, and measurements of hydrodynamic radii using pulse field gradient NMR methods show that it is compact (R(h), 16.6 A). The apo state binds 1 mol of ANS/mol of protein, and a linear reduction in fluorescence enhancement is observed on adding aliquots of hemin to a solution of apo C11A/C14A cytochrome c(552) with ANS bound. These results suggest that the bound ANS is located in the heme binding pocket, which would therefore be at least partially formed in the apo state. Consistent with these characteristics, the formation of the holo state of the variant cytochrome c(552) from the apo state on the addition of heme has been demonstrated using NMR techniques. The properties of the apo state of C11A/C14A cytochrome c(552) reported here contrast strongly with those of mitochondrial cytochrome c whose apo state resembles a random coil under similar conditions.

Structure of the soluble domain of cytochrome c(552) from Paracoccus denitrificans in the oxidized and reduced states

The crystal structure of the soluble domain of the membrane bound cytochrome c(552) (cytochrome c(552)') from Paracoccus denitrificans was determined using the multiwavelength anomalous diffraction technique and refined at 1.5 A resolution for the oxidized and at 1. 4 A for the reduced state. This is the first high-resolution crystal structure of a cytochrome c at low ionic strength in both redox states. The atomic model allowed for a detailed assessment of the structural properties including the secondary structure, the heme geometry and interactions, and the redox-coupled structural changes. In general, the structure has the same features as that of known eukaryotic cytochromes c. However, the surface properties are very different. Cytochrome c(552)' has a large strongly negatively charged surface part and a smaller positively charged area around the solvent-exposed heme atoms. One of the internal water molecules conserved in all structures of eukaryotic cytochromes c is also present in this bacterial cytochrome c. It contributes to the interactions between the side-chain of Arg36 and the heme propionate connected to pyrrole ring A. Reduction of the oxidized crystals does not influence the conformation of cytochrome c(552)' in contrast to eukaryotic cytochromes c. The oxidized cytochrome c(552)', especially the region of amino acid residues 40 to 56, appears to be more flexible than the reduced one.

A 1H NMR study of structurally relevant inter-segmental hydrogen bond in cytochrome c

NMR signal arising from His 26 N(epsilon)H proton in horse and tuna ferrocytochromes c has been assigned. This His residue is highly conserved in most mitochondrial cytochromes c and X-ray crystallographic studies strongly suggested that its side-chain imidazole participates in an internal hydrogen bond network which is relevant to the stability of the non-helical protein folding near the heme active site. The shift and line width of the assigned signal indicated that this NH hydrogen is indeed involved in an internal hydrogen bond. On the basis of the X-ray crystal structures, the carbonyl oxygen of the residue at 44 is thought to act as a proton-acceptor for this hydrogen. The observation of nuclear Overhauser effect correlation between His 26 C(epsilon)H and Asn 31 main-chain amide NH proton signals in the present proteins also demonstrated the formation of the hydrogen bond between these residues. Consequently, the presence of a unique triad hydrogen bond network in these cytochromes c in solution has been confirmed. Taking advantage of the sensitivity of His 26 N(epsilon)H proton signal to the structural properties of this hydrogen bond network, influences of the presence of high concentration of salt or various concentrations of denaturant on the protein folding were inferred from the analysis of the NMR spectral parameters of the signal.

Factors affecting protein interaction at sorbent interfaces

Interactions between surfaces and macromolecules are the fundamentals in separation and detection of diverse solutes. In this very brief review the central aspects of protein-surface interactions are discussed with the intention of identifying the important factors influencing such processes and placing them in relation to the established knowledge in this field. Some perspectives of new techniques related to scanning probe microscopy for studying interactions at the nanometer level are also discussed.

Anion binding to cytochrome c2: implications on protein-Ion interactions in class I cytochromes c

The binding of several inorganic and carboxylate anions to cytochrome c2 from Rhodopseudomonas palustris has been investigated by monitoring the salt-induced changes in the redox potential of the heme, using an interpretative model based on the extended Debye-Hückel equation. Most anions were found to interact specifically with the protein at one or multiple sites. Binding constants to the oxidized protein in the range 10(1)-10(2) m-1 were determined from the anion concentration dependence of the chemical shift of the isotropically shifted heme methyl resonances. For several anions the stoichiometry and strength of the binding to cytochrome c2 were found comparable with those determined for mitochondrial cytochromes c, in spite of the limited sequence similarity (less than 40%) and the lower positive charge of the bacterial protein. These analogies were interpreted as indicative of the existence of common binding sites which are proposed to be located in the conserved lysine-rich domain around the solvent-exposed heme edge, which is also the surface area likely involved in the interaction with redox partners. The changes in E degrees due to partial neutralization of the positive charge of cytochrome c2 due to specific anion binding were found comparable with those for the mitochondrial species.

Anion binding to mitochondrial cytochromes c studied through electrochemistry. Effects of the neutralization of surface charges on the redox potential

The redox potential of horse and bovine heart cytochromes c determined through cyclic voltammetry is exploited to probe for anion-protein interactions, using a Debye-Hückel-based model. In parallel, protein charge neutralization resulting from specific anion binding allows monitoring for surface-charge/E(o) relationships. This approach shows that a number of anions, most of which are of biological relevance, namely CI-, HPO(2-)4, HCO3-, NO3, SO(2-)4, CIO4-, citrate3- and oxalate2-, bind specifically to the protein surface, often in a sequential manner as a result of the presence of multiple sites with different affinities. The binding stoichiometries of the various anions toward a given cytochrome are in general different. Chloride and phosphate appear to bind to a greater extent to both proteins as compared to the other anions. Differences in binding specificity toward the two cytochromes, although highly sequence-related, are observed for a few anions. The data are discussed comparatively in terms of electrostatic and geometric properties of the anions and by reference to the proposed location and amino acid composition of the anion binding sites, when available. Specific binding of this large set of anions bearing different charges allows the electrostatic effect on Eo due to neutralization of net positive protein surface charge(s) to be monitored. (J)H NMR indeed indicates the absence of significant salt-induced structural perturbations, hence the above change in Eo is predominantly electrostatic in origin. A systematic study of protein surface-charge/Eo relationships using this approach is unprecedented. Values of 15-25 mV (extrapolated at zero ionic strength) are obtained for the decrease in Eo due to neutralization of one positive surface charge, which are of the same order of magnitude as previous estimates obtained with either mutation or chemical modification of surface lysines. The effects of the anion-induced decrease of net positive charge on Eo persist also at a relatively high ionic strength and add to the general effects related to the charge shielding of the protein as a whole due to the surrounding ionic atmosphere: hence the ionic strength dependence of the rate of electron transfer between cytochromes c and redox partners could also involve salt-induced changes in the driving force.

Cyclic voltammetry and 1H-NMR of Rhodopseudomonas palustris cytochrome c2. Probing surface charges through anion-binding studies

The effects of increasing concentrations of Cl-, ClO4-, and HCO3- on the redox potential of Rhodopseudomonas palustris cytochrome c2 indicate that the two polyatomic anions bind specifically to the protein at one site, while chloride simply exerts an ionic atmosphere effect. The change in E degree upon specific anion binding allows us to probe for the influence of surface charges on the redox potential of cytochromes c. The decrease in redox potential at null ionic strength (delta E degree I = 0) due to anion neutralization of one positive surface charge was found to be 23 mV with perchlorate and 33 mV with bicarbonate. These values compare reasonably well with previous theoretical predictions and estimates of the effect of charge alteration on the E degree values in cytochromes c chemically modified or mutated at surface lysines. These delta E degree values, determined on the unmodified protein, are unprecedented for c-type cytochromes. The anion-induced chemical shift changes of the hyperfine-shifted heme 1H-NMR resonances of the oxidized protein yield lower limit values of 53 M-1 and 18 M-1 for the affinity constant for specific HCO3- and ClO4- binding, respectively.

The low ionic strength crystal structure of horse cytochrome c at 2.1 A resolution and comparison with its high ionic strength counterpart

BACKGROUND

Cytochrome c is an integral part of the mitochondrial respiratory chain. It is confined to the intermembrane space of mitochondria, and has the function of transferring electrons between its redox partners. Solution studies of cytochrome c indicate that the conformation of the molecule is sensitive to the ionic strength of the medium.

RESULTS

The crystal structures of cytochromes c from several species have been solved at extremely high ionic strengths of near-saturated solutions of ammonium sulfate. Here we present the first crystal structure of ferricytochrome c at low ionic strength refined at 2.1 A resolution. In general, the structure has the same features as those determined earlier. However, there are some differences in both backbone and side-chain conformations in several areas. These areas coincide with those observed by NMR and resonance Raman spectroscopy to be sensitive to ionic strength.

CONCLUSIONS

Neither ionic strength nor crystal-packing interactions have much influence on the conformation of horse cytochrome c. Nevertheless, some differences in the side-chain conformations at high and low ionic strengths may be important for understanding how the protein functions. Close examination of the gamma-turn (residues 27-29) conserved in cytochromes c leads us to propose the 'negative classical' gamma-turn to describe this unusual feature.

Lipid dynamics and peripheral interactions of proteins with membrane surfaces

A large body of evidence strongly indicates biomembranes to be organized into compositionally and functionally specialized domains, supramolecular assemblies, existing on different time and length scales. For these domains and intimate coupling between their chemical composition, physical state, organization, and functions has been postulated. One important constituent of biomembranes are peripheral proteins whose activity can be controlled by non-covalent binding to lipids. Importantly, the physical chemistry of the lipid interface allows for a rapid and reversible control of peripheral interactions. In this review examples are provided on how membrane lipid (i) composition (i.e., specific lipid structures), (ii) organization, and (iii) physical state can each regulate peripheral binding of proteins to the lipid surface. In addition, a novel and efficient mechanism for the control of the lipid surface association of peripheral proteins by [Ca2+], lipid composition, and phase state is proposed. The phase state is, in turn, also dependent on factors such as temperature, lateral packing, presence of ions, metabolites and drugs. Confining reactions to interfaces allows for facile and cooperative large scale integration and control of metabolic pathways due to mechanisms which are not possible in bulk systems.

Mutagenesis of the conserved lysine 14 of cytochrome c-550 from Thiobacillus versutus affects the protein structure and the electron self-exchange rate

The lysine residue K14 of cytochrome c-550 of Thiobacillus versutus has been mutated to a glutamine (Q) and a glutamate (E) residue. These mutations have a minimal effect on the pKa for replacement of the methionine ligand (the "alkaline transition"), indicating that a presumptive salt bridge between K14 and E11 does not help stabilize the native form. This is in contrast with mitochondrial cytochrome c, where the homologous K13 forms a structurally important salt bridge with glutamate 90. The NMR signals of protons close to the heme iron in wild-type and mutant ferricytochrome c-550 shift considerably with increasing ionic strength. These effects resemble those seen in mitochondrial cytochrome c upon addition of salt and upon complex formation with redox partners. It is likely that electrostatic screening of positive charges near the heme crevice leads to a slight redistribution of the electron density in the heme. At low ionic strength the NMR spectrum of wild-type cytochrome c-550 shows broad peaks. Line widths decrease upon addition of salt up to 200 mM. In K14Q and K14E cytochrome c-550 the line widths are much smaller at low ionic strength. Wild-type cytochrome c-550 may exist in two exchanging conformations, one of which may represent a more open (non-native) form, in analogy with cytochrome c. However, in the case of cytochrome c-550 this non-native form does not show ligand replacement. The electron self-exchange rates of wild type and mutants have been determined as a function of the ionic strength.(ABSTRACT TRUNCATED AT 250 WORDS)

Oxidation state-dependent conformational changes in cytochrome c

High-resolution three-dimensional structural analyses of yeast iso-1-cytochrome c have now been completed in both oxidation states using isomorphous crystalline material and similar structure determination methodologies. This approach has allowed a comprehensive comparison to be made between these structures and the elucidation of the subtle conformational changes occurring between oxidation states. The structure solution of reduced yeast iso-1-cytochrome c has been published and the determination of the oxidized protein and a comparison of these structures are reported herein. Our data show that oxidation state-dependent changes are expressed for the most part in terms of adjustments to heme structure, movement of internally bound water molecules and segmental thermal parameter changes along the polypeptide chain, rather than as explicit polypeptide chain positional shifts, which are found to be minimal. This result is emphasized by the retention of all main-chain to main-chain hydrogen bond interactions in both oxidation states. Observed thermal factor changes primarily affect four segments of polypeptide chain. Residues 37-39 show less mobility in the oxidized state, with Arg38 and its side-chain being most affected. In contrast, residues 47-59, 65-72 and 81-85 have significantly higher thermal factors, with maximal increases being observed for Asn52, Tyr67 and Phe82. The side-chains of two of these residues are hydrogen bonded to the internally bound water molecule, Wat166, which shows a large 1.7 A displacement towards the positively charged heme iron atom in the oxidized protein. Further analyses suggest that Wat166 is a major factor in stabilizing both oxidation states of the heme through differential orientation of dipole moment, shift in distance to the heme iron atom and alterations in the surrounding hydrogen bonding network. It also seems likely that Wat166 movement leads to the disruption of the hydrogen bond from the side-chain of Tyr67 to the Met80 heme ligand, thereby further stabilizing the positively charged heme iron atom in oxidized cytochrome c. In total, there appear to be three regions about which oxidation state-dependent structural changes are focussed. These include the pyrrole ring A propionate group, Wat166 and the Met80 heme ligand. All three of these foci are linked together by a network of intermediary interactions and are localized to the Met80 ligand side of the heme group. Associated with each is a corresponding nearby segment of polypeptide chain having a substantially higher mobility in the oxidized protein.(ABSTRACT TRUNCATED AT 400 WORDS)

Redox-dependent changes in beta-extended chain and turn structures of cytochrome c in water solution determined by second derivative amide I infrared spectra

The redox-dependent changes in secondary structure of cytochromes c from horse, cow, and dog hearts in water at 20 degrees C have been determined by amide I infrared spectroscopy. Second derivative amide I spectra were obtained by use of a procedure that includes a convenient method for the effective subtraction of the spectrum of water vapor in the system. The band at 1657 cm-1 representing the helix structure was unaffected by a change in redox state whereas changes in bands due to turns at 1680, 1672, and 1666 cm-1, unordered structure at 1650 cm-1, and beta-structures at 1632 and 1627 cm-1 occurred. About one-fourth of the beta-extended chain spectral region and one-fifth of the beta-turn region (involving a total of approximately 9-13 residues) were sensitive to the oxidation state of heme iron. No significant changes in the secondary structure of either the reduced or oxidized protein due to changes in ionic strength were detected. The localized structural rearrangements triggered by the changes in oxidation state of heme iron are consistent with differences in the binding of heme iron to a histidine imidazole nitrogen and a methionine sulfur atom from the beta-extended chain. The demonstrated ability to obtain highly reproducible second derivative amide I infrared spectra confirms the unique utility of such spectral measurements for localization of subtle changes in secondary structure within a protein, especially for changes among the multiple turns and beta-structures.

The specificity and Kd at physiological ionic strength of an ATP-binding site on cytochrome c suit it to a regulatory role

Cytochrome c binds ATP with marked specificity at a site that contains the evolutionarily invariant residue Arg-91. The binding of ATP to this site was studied using equilibrium gel filtration, equilibrium dialysis and affinity chromatography. At physiological ionic strength the affinity is such that the major change in occupancy coincides with the normal cellular ATP concentration range, and the degree of saturation is proportional to the ratio of [ATP]/[ADP]. The specificity of binding at this site is more a function of the degree of phosphorylation of the nucleotide, than of the nature of the nucleoside moiety. Thus under physiological conditions the degree of occupancy of this site is proportional to the energy state of the cell, providing a means for the regulation of the respiratory chain which is sensitive to cytoplasmic ATP levels.

Differences in thermal stability between reduced and oxidized cytochrome b562 from Escherichia coli

The thermal stabilities of ferri- and ferrocytochrome b562 were examined. Thermally induced spectral changes, monitored by absorption and second-derivative spectroscopies, followed the dissociation of the heme moiety and the increased solvation of tyrosine residue(s) located in close proximity to the heme binding site. All observed thermal transitions were independent of the rate of temperature increase (0.5-2 degrees C/min), and the denatured protein exhibited partial to near-complete reversibility upon return to ambient temperature. The extent of renaturation of cytochrome b562 is dependent on the amount of time the unfolded conformer is exposed to temperatures above the transition temperature, Tm. All thermally induced spectra changes fit a simple two-state model, and the thermal transition was assumed to be reversible. The thermal transition for ferrocytochrome b562 yielded Tm and van't Hoff enthalpy (delta HvH) values of 81.0 degrees C and 137 kcal/mol, respectively. In contrast, Tm and delta HvH values obtained for the ferricytochrome were 66.7 degrees C and 110 kcal/mol, respectively. The estimated increase in the stabilization free energy at the Tm of ferricytochrome b562 following the one-electron reduction to the ferrous form, where delta delta G = delta Tm delta Sm [delta Sm = 324 cal/(K.mol), delta Tm = 14.3 degrees C] [Becktel, W. J., & Schellman, J. A. (1987) Biopolymers 26, 1859-1877], is 4.6 kcal/mol.

Horse heart ferricytochrome c: conformation and heme configuration of high ionic strength acidic forms

The absorption, circular dichroism, and resonance Raman spectra of horse heart ferricytochrome c in the presence of 0.2 M KCl, 0.1 M NaClO4, and 0.2 M KNO3, in the pH region 7 to 0.5, have been investigated to determine the nature and the course of the processes involved. As in the absence of salts (Myer, Y., and Saturno, A. F. (1990) J. Protein Chem, 9, 379-387), the change from neutral to low acidic pH's in the presence of salts is a three-step process: state IIIs----state IIIS,a----state IIS----state IS, with pKa's of 3.5 +/- 0.2, 2.2 +/- 0.2, and 1.1 +/- 0.2, and with two, one, and one number of protons, respectively. The addition of salts at neutral pH's has little or no effect on the protein conformation and the heme-iron configuration (i.e., they remain the same, low-spin hexacoordinated heme iron with a Met-80-Fe-His-18 axial coordination), but such addition does cause a slight tightening of the heme crevice and the enlargement of the porphyrin core. State IIIS,a is a folded state with about the same degree of folding and with a similar spin state and coordination configuration of iron, but the heme crevice is loosened and the porphyrin core is smaller. Both states IIS and IS are also essentially folded forms, but with a smaller degree of protein secondary structure. State IIS has a high-spin hexacoordinated heme iron with a water molecular and a protonated and/or hydrogen-bonded imidazole of his-18 as the two axial ligates; and state IS has a high-spin pentacoordinated heme iron, which is about 0.49 A out of the porphyrin plane, with a protonated and/or hydrogen-bonded imidazole nitrogen as the only axial ligate. The addition of anions causes the stabilization of the protein secondary structures and the state IIIa----state II transition. The mode of effectiveness of anions appears to be nonspecific (i.e., because of electrostatic shielding and/or disruption of salt bridges).

Proton homonuclear correlated spectroscopy as an assignment tool for hyperfine-shifted resonances in medium-sized paramagnetic proteins: cyanide-ligated yeast cytochrome c peroxidase as an example

Two types of homonuclear proton COSY experiments are shown to be useful in making resonance assignments in cyanide-ligated cytochrome c peroxidase, a 34 kDa paramagnetic heme protein. Both magnitude COSY and phase-sensitive COSY experiments provide spectra useful for making proton assignments to resonances of strongly relaxed hyperfine-shifted protons. This initial investigation demonstrates that COSY experiments combined with NOESY experiments are feasible for hyperfine-shifted protons of paramagnetic proteins larger than metmyoglobins and ferricytochromes c, for which the nuclear spin-lattice relaxation times are in the range 70-300 ms. Taken together, COSY and NOESY experiments, although not yet widely applied to paramagnetic metalloproteins, provide a reliable protocol for accurately assigning hyperfine-shifted resonances that are part of a metalloenzyme's active site. Specific examples of expected proton homonuclear COSY connectivities that were not observed in these experiments are presented, and utilization of COSY with respect to the proton resonance line widths and apparent nuclear relaxation times is discussed. The COSY experiments presented here provide valuable verification of previously proposed hyperfine resonance assignments for cyanide-ligated cytochrome c peroxidase, which were made by using NOESY experiments alone, and in several instances expand these assignments to additional protons in particular amino acid spin systems.

Proton-NMR studies of the effects of ionic strength and pH on the hyperfine-shifted resonances and phenylalanine-82 environment of three species of mitochondrial ferricytochrome c

Ferricytochromes c from three species (horse, tuna, yeast) display sensitivity to variations in solution ionic strength or pH that is manifested in significant changes in the proton NMR spectra of these proteins. Irradiation of the heme 3-CH3 resonances in the proton NMR spectra of tuna, horse and yeast iso-1 ferricytochromes c is shown to give NOE connectivities to the phenyl ring protons of Phe82 as well as to the beta-CH2 protons of this residue. This method was used to probe selectively the Phe82 spin systems of the three cytochromes c under a variety of solution conditions. This phenylalanine residue has previously been shown to be invariant in all mitochondrial cytochromes c, located near the exposed heme edge in proximity to the heme 3-CH3, and may function as a mediator in electron transfer reactions [Louie, G. V., Pielak, G. J., Smith, M. & Brayer, G. D. (1988) Biochemistry 27, 7870-7876]. Ferricytochromes c from all three species undergo a small but specific structural rearrangement in the environment around the heme 3-CH3 group upon changing the solution conditions from low to high ionic strength. This structural change involves a decrease in the distance between the Phe82 beta-CH2 group and the heme 3-CH3 substituent. In addition, studies of the effect of pH on the 1H-NMR spectrum of yeast iso-1 ferricytochrome c show that the heme 3-CH3 proton resonance exhibits a pH-dependent shift with an apparent pK in the range of 6.0-7.0. The chemical shift change of the yeast iso-1 ferricytochrome c heme 3-CH3 resonance is not accompanied by an increase in the linewidth as previously described for horse ferricytochrome c [Burns, P. D. & La Mar, G. N. (1981) J. Biol. Chem. 256, 4934-4939]. These spectral changes are interpreted as arising from an ionization of His33 near the C-terminus. In general, the larger spectral changes observed for the resonances in the vicinity of the heme 3-CH3 group in yeast iso-1 ferricytochrome c with changes in solution conditions, relative to the tuna and horse proteins, suggest that the region around Phe82 is more open and that movement of the Phe82 residue is less constrained in yeast ferricytochrome c. Finally, it is demonstrated here that both the heme 8-CH3 and the 7 alpha-CH resonances of yeast ferricytochrome c titrate with p2H and exhibit apparent pK values of approximately 7.0. The titrating group responsible for these spectral changes is proposed to be His39.