Cytochrome c chimerae from natural and synthetic fragments: significance of the biological properties

Probing the role of the conserved beta-II turn Pro-76/Gly-77 of mitochondrial cytochrome c

The loop segment comprising residues 70-84 in mitochondrial cytochrome c serves to direct the polypeptide backbone to permit the functionally required heme Fe - S (Met-80) co-ordination. The primary sequence here is highly conserved, which is something rarely observed in surface loop segments and suggests that its purpose is more complex than its obvious structural role. The beta-II turn formed by Pro-76 and Gly-77 is postulated to be key to the redirection of the peptide backbone required to execute the loop. We assessed the importance of Pro-76 and Gly-77 by mutating 1 or both of these residues to alanine such that the range of allowable dihedral angles was altered, and this resulted in significant changes in physicochemical properties and biological activities. We observed structural perturbations using circular dichroism spectroscopy and thermal denaturation studies. Based on these changes, we propose that the Pro-76/Gly-77 beta-II turn precisely orients the 70s loop, not only to maintain the backbone orientation required for the formation of the axial heme ligand, but also to provide a complementary surface to physiological partners.

Probing electrostatic interactions in cytochrome c using site-directed chemical modification

This communication reports the generation of an electrostatic probe using chemical modification of methionine side chains. The alkylation of methionine by iodoacetamide was achieved in a set of Saccharomyces cerevisiae iso-1-cytochrome c mutants, introducing the nontitratable, nondelocalized positive charge of a carboxyamidomethylmethionine sulfonium (CAMMS) ion at five surface and one buried site in the protein. Changes in redox potential and its variation with temperature were used to calculate microscopic effective dielectric constants operating between the probe and the heme iron. Dielectric constants (epsilon) derived from deltadeltaG values were not useful due to entropic effects, but epsilon(deltadeltaH) gave results that supported the theory. The effect on biological activity of surface derivatization was interpreted in terms of protein-protein interactions. The introduction of an electrostatic probe in cytochrome c often resulted in marked effects on activity with one of two physiological partners: cytochrome c reductase, especially if introduced at position 65, and cytochrome c oxidase, if at position 28.

Contribution of leucine 85 to the structure and function of Saccharomyces cerevisiae iso-1 cytochrome c

Cytochrome c is a small electron-transport protein whose major role is to transfer electrons between complex III (cytochrome reductase) and complex IV (cytochrome c oxidase) in the inner mitochondrial membrane of eukaryotes. Cytochrome c is used as a model for the examination of protein folding and structure and for the study of biological electron-transport processes. Amongst 96 cytochrome c sequences, residue 85 is generally conserved as either isoleucine or leucine. Spatially, the side chain is associated closely with that of the invariant residue Phe82, and this interaction may be important for optimal cytochrome c activity. The functional role of residue 85 has been examined using six site-directed mutants of Saccharomyces cerevisiae iso-1 cytochrome c, including, for the first time, kinetic data for electron transfer with the principle physiological partners. Results indicate two likely roles for the residue: first, heme crevice resistance to ligand exchange, sensitive to both the hydrophobicity and volume of the side chain; second, modulation of electron-transport activity through maintenance of the hydrophobic character of the protein in the vicinity of Phe82 and the exposed heme edge, and possibly of the ability of this region to facilitate redox-linked conformational change.

Conserved tryptophan in cytochrome c: importance of the unique side-chain features of the indole moiety

The absolute conservation of tryptophan at position 59 in cytochrome c is related to the unique chemical nature of its indole moiety. The indole side chain of Trp-59 possesses three salient features: bulk, hydrophobicity and the ability of its indole nitrogen to act as a hydrogen-bond donor. Crystallographic evidence identifies the indole nitrogen of Trp-59 as having a stabilizing hydrogen-bonding interaction with the buried carboxylate group of haem propionate 7. Side-chain bulk is also likely to be important because a Phe or Leu residue can replace Trp to give an at least partly functional protein, whereas the smaller Gly or Ser cannot. Semisynthetic analogues were designed to test the importance of the side-chain features of tryptophan by using a recently developed method for stereoselective fragment religation in yeast cytochrome c. Three yeast iso-1 cytochrome c analogues were produced in which Trp-59 was replaced by a non-coded amino acid: p-iodophenylalanine, beta-(3-pyridyl)-alanine or beta-(2-naphthyl)-alanine. Replacement of Trp-59 with these non-coded amino acids allows the reasons for its conservation to be analysed, because they vary with respect to size, hydrophobicity and hydrogen-bond potential. Our results show that decreasing the bulk and hydrophobicity of the side chain at position 59 has a profound but different impact on physicochemical and biological parameters from those of abolishing hydrogen-bond donor potential. This suggests that Trp-59 has both a local and a global stability effect by solvating a buried charge and by having a key role in the packing of the cytochrome c hydrophobic core.

Protein Matrix and Dielectric Effect in Cytochromec

The effect of the protein matrix on the standard potential of a buried redox center has been investigated by using a selection of mutants and chemical derivatives in Saccharomyces cerevisiae cytochrome c isoform 1. Assuming only local structural perturbation and no alteration of the iron-ligation chemistry, Delta E(m)(0)' can be regarded as a measure of the difference in polypeptide solvation of the heme charge, which reflects the dielectric properties of the protein. The evaluation of an apparent dielectric constant (U(exp)/U(theo)) yields variable, and sometimes even negative, values if U(exp) = Delta G(0)redox. However, some consistent result are observed if U(exp) = Delta H(0)redox, with a measured epsilon(Delta Delta)(H)(redox) = 19 +/- 6. The variability is thus attributed to an entropic factor (epsilon(Delta Delta)(S)(redox)) that is investigated using a series of substitutions of Asn(52) and/or Tyr(67). In double mutants Y67F/N52I Y67F/N52V, where most of the hydrogen bond network in the heme crevice is eliminated, Delta S(redox) compares to the wild type. This indicates that a fully consistent hydrogen bond network has a similar polarizability as an apolar matrix. We therefore argue that the variability in net dielectric susceptibility arises from conformational polarizability, a factor that is not a function of atomic properties and coordinates and is therefore hard to predict using conventional physical relationships.

A tale of two charges: Distinct roles for an acidic and a basic amino acid in the structure and function of cytochrome c

Cytochrome c is a small electron transport protein found in the intermembrane space of mitochondria. As it interacts with a number of different physiological partners in a specific fashion, its structure varies little over eukaryotic evolutionary history. Two highly conserved residues found within its sequence are those at positions 13 and 90 (numbering is based on the standard horse cytochrome c); with single exceptions, residue 13 is either Lys or Arg, and residue 90 is either Glu or Asp. There have been conflicting views on the roles to be ascribed to these residues, particularly residue 13, so the functional properties of a number of site-directed mutants of Saccaromyces cerevisiae iso-1 cytochrome c have been examined. Results indicate that the two residues do not interact specifically with each other; however, residue 13 (Arg) is likely to be involved in interactions between cytochrome c and other electro statically oriented physiological partners (intermolecular), whereas residue 90 (Asp) is involved in maintaining the intrinsic structure and stability of cytochrome c (intramolecular). This is supported by molecular dynamics simulations carried out for these mutants where removal of the negative charge at position 90 leads to significant shifts in the conformations of neighboring residues, particularly lysine 86. Both charged residues appear to exert their effects through electrostatics; however, biological activity is significantly more sensitive to substitutions of residue 13 than of residue 90.Key words: cytochrome c, structure-function studies, molecular modelling, surface electrostatics.

Site-specific independent double labeling of proteins with reporter atoms

Many types of physical, spectroscopic, and biological studies of proteins and other macromolecules are facilitated by the incorporation of reporter groups. In many cases these are single atom substitutes, for example isotopes (13C for C), or light (F for H) and heavy (Se for S) atom homologs. In some circumstances the incorporation of two different labels in the same molecule would be greatly desirable. Commonly used protein engineering methods for incorporating them can rarely cope with differential double labeling, and have other limitations such as universal, non-specific, or random incorporation. Although de novo peptide synthesis has the power to achieve highly specific labeling, the difficulties inherent in creating long sequences lead us to propose protein semisynthesis as the most practical approach. By ligating combinations of natural and labeled synthetic fragments to reform holoproteins, we can overcome any of the limitations discussed. Using cytochrome c as a model protein we show that two reporter atoms, selenium and bromine, can be simultaneously and site-specifically incorporated without significant consequences to structure and (or) function. This capability opens up the prospect of advances in a number of areas in structural biology.

Key words: semisynthesis, peptide synthesis, reporter groups, cytochrome c, structural biology.

Synergy in protein engineering. Mutagenic manipulation of protein structure to simplify semisynthesis

Semisynthesis is a chemical technique of protein engineering that provides a valuable complement to directed mutagenesis. It is the method of choice when the structural modification requires, for example, a noncoded amino acid. The process involves specific and limited protein fragmentation, structural manipulation of the target sequence, and subsequent religation of fragments to give the mutant holoprotein. We suggested and demonstrated that mutagenesis and semisynthesis could be used synergistically to achieve protein engineering goals otherwise unobtainable, if mutagenesis was used to shuffle methionine residues in the yeast cytochrome c sequence (Wallace, C. J. A., Guillemette, J. G., Hibiya, Y., and Smith, M. (1991) J. Biol. Chem. 266, 21355-21357). These residues can not only be sites of specific cleavage by CNBr but also of spontaneous peptide bond synthesis between fragments in noncovalent complexes, which greatly facilitates the semisynthetic process. We have now used an informed "methionine scan" of the protein sequence to discover other useful sites and to characterize the factors that promote this extraordinary and convenient autocatalytic religation. Of eight sites canvassed, in a wide range of settings, five efficiently provoked peptide bond synthesis. The principal factor determining efficiency seems to be the hydropathy of the religation site. The mutants created have also provided some new insights on structure-function relationships in the cytochrome.

A chemical modification of cytochrome-c lysines leading to changes in heme iron ligation

Although 13 lysines of horse cytochrome c are invariant, and three more are extremely conserved, the modification of their side-chain epsilon-amino groups by beta-thiopropionylation caused important changes in protein properties for only three of them; lysines 72,73 and 79. Optical spectroscopy, electron and nuclear paramagnetic resonance, electron spin echo envelope modulation, and molecular weight studies, as well as the unique features of their reaction with cytochrome-c oxidase, indicate that in the oxidized state the modification of these lysines resulted in equilibria between two different states of iron ligation: the native state, in which the metal is coordinated by the methionine-80 sulfur, and a new state in which this ligand is displaced by the sulfhydryl groups of the elongated side chains. The reduction potentials of the TP Lys-72 and the TP Lys-79 derivatives were 201 and 196 millivolt, respectively, indicating that the equilibria favored the sulfhydryl ligated state by 1.5 and 1.7 kcal/mol, respectively. In the ferric state, the protein modified at lysine 72 remained stable as a monomer, but that modified at lysine 73 dimerized rapidly through disulfide bond formation, while the TP Lys-79 cytochrome c dimerized with a half-time of approx. 3 h, both recovering the native-like iron ligation. By contrast, in the ferrous state the monomeric state and the native ligation were preserved in all cases, indicating that the affinity of the cytochrome-c ferrous iron for the methionine-80 sulfur is particularly strong. The dimerized derivatives lost most, but not all, of the capability of the native protein for electron transfer from ascorbate-TMPD to cytochrome-c oxidase.

Beta-thiopropionyl cytochromes c modified at lysyl residues: preparation and characterization of the monosubstituted horse cytochromes c

beta-Thiopropionyl derivatives of horse cytochrome c singly modified at each of 18 different lysine epsilon-amino groups have been prepared using sulfosuccinimidyl-2-(biotinamido)ethyl-1,3-dithiopropionate and purified to homogeneity by high-pressure liquid chromatography. These derivatives were characterized by determination of: (i) the location of the modification; (ii) reduction potentials; (iii) visible and NMR spectra: and by (iv) measurement of electron transfer activity with cytochrome-c oxidase. No significant changes in structure were indicated, except for the ferric forms of the derivatives modified at lysines 72, 73, and 79 which are discussed separately. The electron transfer activity of the beta-thiopropionyl cytochromes c with bovine heart cytochrome-c oxidase was decreased to extents dependent on the position of the modification. Aminoethylation, a secondary modification which reverses the charge change, restored the electron transfer rate to that observed with the unmodified cytochrome c, irrespective of the location of the primary modification. These results afford a direct experimental demonstration that alterations in kinetics with physiological electron transfer partners resulting from modifications which cause a change of the charge of surface side chains are solely due to the electrostatic effects. Of the many chemically modified cytochromes c prepared to date, the singly substituted beta-thiopropionyl cytochromes c are likely to be particularly useful as the thiol allows covalent linkage of any sulfhydryl-reactive reagent to a well-defined location on the protein surface by a simple procedure, even when the secondary modifier is relatively unstable, a crucial advantage not otherwise readily achieved.

Mutations of iso-1-cytochrome c at positions 13 and 90. Separate effects on physical and functional properties

Residues at positions 13 (lysine or arginine) and 90 (glutamate or aspartate) of eukaryotic cytochromes c have been conserved during evolution; Cys102, however, is found only in yeast cytochrome c. The positively charged residue at position 13 and the negatively charged residue at position 90 are close together in those cytochromes c for which three-dimensional structures are available. We have replaced the amino acids at these two positions by cysteine in Saccharomyces cerevisiae iso-1-cytochrome c; in an earlier study, Cys102 was replaced by threonine without negatively influencing the physical or enzymic properties of the protein. The mutated proteins [R13C, C102T]cytochrome c (iso-1-cytochrome c containing Arg13-->Cys and Cys102-->Thr mutations), [D90C, C102T]cytochrome c (iso-1-cytochrome c containing Asp90-->Cys and Cys102-->Thr mutations) and [R13C, D90C, C102T]cytochrome c (iso-1-cytochrome c containing Arg13-->Cys, Asp90-->Cys, and Cys102-->Thr mutations) are functional in vivo. Free sulfhydryl titration shows that the doubly mutated forms each contain one sulfhydryl group while the triple mutant contains two sulfhydryl groups. The stability of mutant [R13C, C102T]cytochrome c resembles that of [C102T] cytochrome c, whereas the stability of [D90C, C102T]cytochrome c resembles the stability of [R13C, D90C, C102T]cytochrome c. The activity of cytochrome-c oxidase using cytochrome c was monitored polarographically. Compared to the wild-type or [C102T]cytochrome c, which shows two kinetic phases with cytochrome-c oxidase, [D90C, C102T]cytochrome c has much the same profile; [R13C, C102T]cytochrome c and [R13C, D90C, C102T]cytochrome c exhibit one kinetic phase with decreased activity. Electron-transfer activity of the mutant cytochromes c is inhibited by Hg2+. The inhibition is highest for the triple mutant, less for [R13C, C102T]cytochrome c, even less for [D90C, C102T]cytochrome c and insignificant for the wild type. It would appear as though the stability of the triple mutant follows the changes that result from the Asp90-->Cys mutation while the activity changes follow those of the Arg13-->Cys mutation.

ATP binding to cytochrome c diminishes electron flow in the mitochondrial respiratory pathway

Eukaryotic cytochrome c possesses an ATP-binding site of substantial specificity and high affinity that is conserved between highly divergent species and which includes the invariant residue arginine91. Such evolutionary conservatism strongly suggests a physiological role for ATP binding that demands further investigation. We report the preparation of adducts of the protein and the affinity labels 8-azido adenosine 5'-triphosphate, adenosine 5'-triphosphate-2',3'-dialdehyde, and 5'-p-fluorosulfonylbenzoyladenosine. The two former reagents were seen to react at the arginine91-containing site, yet the reaction of the latter, although specific, occurred elsewhere, suggesting caution is necessary in its use. None of the adducts displayed significant modification of global structure, stability, or physicochemical properties, leading us to believe that the 8-N3-ATP and oATP adducts are good stabilized models of the noncovalent interaction; yet modification led to significant, and sometimes pronounced, effects on biological activity. We therefore propose that the role of ATP binding to this site, which we have shown to occur when the phosphorylation potential of the system is high under the equivalent of physiological conditions, is to cause a decrease in electron flow through the mitochondrial electron transport chain. Differences in the degree of inhibition produced by differences in adduct chemistry suggest that this putative regulatory role is mediated primarily by electrostatic effects.

The role of tyrosine 67 in the cytochrome c heme crevice structure studied by semisynthesis

Tyr-67 of mitochondrial cytochrome c is thought to be involved in important hydrogen bonding interactions in the hydrophobic heme pocket of the protein (Takano, T., Dickerson, R. E. (1981) J. Mol. Biol. 153:95-115). The role of this highly conserved residue in heme pocket stability was studied by comparing properties of semisynthetic (Phe-67) and (p-F-Phe-67) analogs with those of native cytochrome c and a "control" analog, (Hse-65)cytochrome c. The (Phe-67) and (p-F-Phe-67) analogs have well-developed 695-nm visible absorption bands and are active in a cytochrome c oxidase assay. The reduction potentials of both analogs are lower than the native protein by approximately 50 mV. Although both analogs bind imidazole with higher affinity than the native protein, only the (p-F-Phe-67) analog has a 3- to 5-fold lower binding constant for cyanide. Only the (Phe-67) analog was significantly more stable toward alkaline isomerization. These results are not consistent with stabilization of the native protein heme pocket via hydrogen bonding of Tyr-67 to Met-80. An alternative steric role for Tyr-67 is proposed in which the residue controls the heme reduction potential by limiting the number of internal H2O molecules in the heme pocket.

Total synthesis of horse heart apocytochrome c by conformation-assisted condensation of two chemically synthesized fragments

A fully synthetic peptide, corresponding to the entire 104-residue sequence of horse heart apocytochrome c with Met65 replaced by homoserine, has been obtained by an original conformation-assisted three-fragment condensation procedure. The method involves the selective joining of two synthetic fragments, namely residues 1-65 of the apopeptide with Met65 replaced by homoserine lactone and residues 66-104 of the protein in the presence of fragment 1-25 of the native heme-containing peptide. The joining conditions have been optimized with regard to solvent, pH and possible influence of additives. The presence of radical scavengers and the complete exclusion of oxygen were found essential in order to prevent oxidative side reactions. A sensitive method based on reverse-phase HPLC has been used to monitor the course of the reaction. Condensation yields up to 80% were obtained. The data obtained by this new three-fragment rejoining approach are discussed and compared to those of a similar two-fragment condensation procedure. Our data demonstrate how the folding properties of large synthetic peptide fragments, organized in a complex, can be utilized to extend the presently improved solid-phase peptide methods to the synthesis of a functioning protein with more than 100 residues.

The oxidation-state-dependent ATP-binding site of cytochrome c. Implication of an essential arginine residue and the effect of occupancy on the oxidation-reduction potential

Arg-91 is not part of the active site of cytochrome c that mediates binding and electron transfer, yet it is absolutely conserved in eukaryotic cytochromes c, indicating a special function. The physicochemical properties of analogues are unaffected by the modification of this residue, so they can be used with confidence to study the role of Arg-91. We have established limiting conditions under which this residue alone is specifically modified by cyclohexane-1,2-dione, and have subsequently shown that ATP, and to a lesser extent ADP or Pi, protects it from the action of the reagent in an oxidation-state-dependent manner. These observations strongly support the idea that this site exerts a controlling influence on cytochrome c activity in the electron transport or other cellular redox systems, and we have commenced a study of how that influence might operate. We find that the redox potentials of both cytochrome c and analogue are little affected by changing ATP or Pi concentrations.

Alkylamine derivatives of cytochrome c. Comparison with other lysine-modified analogues illuminates structure/function relations in the protein

For investigations of the functional roles of the lysine residues of cytochrome c, analogues in which these residues are modified without charge loss are highly desirable. The 19 lysine residues of the horse heart protein have been modified by reductive alkylation. Two analogues were prepared, using formaldehyde and acetone as the dialkylating and monoalkylating reagent respectively. Modification was shown to be clean and quantitative. Characterisation of the alkylamine derivatives by physicochemical measurements and biological activity determinations was carried out. The potential of these analogues in structure/function studies of cytochrome c is discussed. It is illustrated by their use, in conjunction with other lysine-modified derivatives, to investigate the extent to which surface charge determines redox potential, and to study the physicochemical changes that accompany rising pH. In the latter case the observed phenomena are not as closely correlated as previously thought, suggesting that there is a complex set of rearrangements of structure underlying the functional changes. The data confirm that modification of the lysine residues influences these changes. These residues participate in numerous surface intramolecular links, so the lack of correlation may be explained if each of the changing parameters were under the influence of a different set of residues. However, neither a lysine residue, nor a histidine residue directly displaces methionine from the sixth coordination position of the haem iron at alkaline pH.

Semisynthesis of cytochrome c analogues. The effect of modifying the conserved residues 38 and 39

We have used chemical and enzymic protein engineering techniques to create analogues of the semisynthetic two-fragment complex (1-37).(38-104) of mitochondrial cytochrome c. This complex, unlike the natural product of specific tryptic cleavage, (1-38).(39-104), from which it is prepared, quite closely resembles the parent protein in functional characteristics and is thus a suitable substrate for modifications designed to study structure-function relations. We have replaced the invariant Arg-38 and the conserved Lys-39 with a range of alternative amino acids and have studied the effects on the principal functional parameters. The hydrogen-bonding capacity of Arg-38 is crucial to the stabilization of the bottom omega-loop, while the positive charge of Lys-39 helps maintain the high redox potential by electrostatic effects at the haem iron.

On the relationship between oxidation-reduction potential and biological activity in cytochrome c analogues. Results from four novel two-fragment complexes

We have confirmed the propensity of fragments of cytochrome c to form complexes that reproduce the structure and, in part, the functionality, of the native protein by preparing four novel complexes. We have used trypsin under three different sets of conditions in sequence to prepare a contiguous two-fragment complex (1-55).(56-104). One of the intermediates is a stable overlapping complex (1-65).(56-104). Conditions for limited acid hydrolysis of peptide bonds in cytochrome c have been developed that optimize the yield of fragments (1-50) and (51-104). These two fragments also form a stable association, as do (1-50) and (56-104). These complexes are potentially useful for the semisynthesis of analogues modified in the region of the cleavage sites, which include a number of highly conserved amino acid residues, and are being used for studies of protein folding, interactions with oxidase, cytochrome c immunogenicity and of artificially induced spontaneous resyntheses between complexing fragments. Like other known two-fragment complexes of cytochrome c, they exhibit normal visible spectra, including the presence of the 695 nm band, indicative of a functional haem crevice. Studies of their biological activities and redox potentials lead to a number of conclusions on structure-function relationships in cytochrome c. Most significantly there is a linear relationship between the logarithm of electron-transfer rates from cytochrome c reductase and redox potential in this series of analogues, indicating that such transfer is thermodynamically controlled. This discovery contributes to our understanding of the interaction of cytochrome and reductase. Since the relationship is obeyed by other types of analogues, except for those that involve modification of the active site of cytochrome c, we have a useful diagnostic for those residues that participate directly in electron transfer.