T-lymphocyte response to cytochrome c. I. Demonstration of a T-cell heteroclitic proliferative response and identification of a topographic antigenic determinant on pigeon cytochrome c whose immune recognition requires two complementing major histocompatibility complex-linked immune response genes.

The T-lymphocyte proliferative response to pigeon cytochrome c was studied in the mouse. H-2a and H-2k strains were responders to this antigen whereas H-2b, H-2d, H-2f, H-2ja, H-2p, H-2q, H-2r, H-2s, and H-2u strains were low or nonresponders. Genetic mapping demonstrated that two major histocompatibility complex (MHC)-linked Ir genes control the response, one in I-A, the other in I-E/I-C. The major antigenic determinant recognized in this response was localized by cross-stimulations with species variants and cyanogen bromide cleavage fragments of cytochrome c. It was found to be a topographic surface determinant composed of an isoleucine for valine substitution at residue 3, a glutamine for lysine substitution at residue 100 and a lysine for glutamic acid substitution at residue 104. Tobacco hornworm moth cytochrome c, which contains a glutamine at residue 100 but a terminal lysine at residue 103 (one amino acid closer to the glutamine), stimulated pigeon cytochrome c immune T cells better than the immunogen. This result demonstrates for the first time a functional T-cell heteroclitic proliferative response in a system under Ir gene control. Immunization with the cyanogen bromide cleavage fragments revealed that only pigeon cytochrome c fragment 81-104 was immunogenic. This fragment primed for a T-cell proliferative response whose specificity was nearly identical to that of the T-cell response primed for by the whole molecule, suggesting that the glutamine at 100 and the lysine at 104 form the immunodominant portion of the antigenic site. Furthermore, mixing experiments using the two cross-reacting antigens, hippopotamus cytochrome c and Pekin duck or chicken cytochrome c fragment (81-104), each of which contains only one of the two immunodominant substitutions, demonstrated that the T lymphocytes responding to the major antigenic determinant comprise a single family of clones that recognize both amino acids as part of the same determinant. Thus, two complementing MHC-linked Ir genes can control the immune response to a single antigenic determinant.

A peptide binding protein having a role in antigen presentation is a member of the HSP70 heat shock family.

The T cell recognition of globular protein antigens requires the processing and presentation of the antigen by Ia-expressing APCs. Processing is believed to involve the uptake of antigen into an acidic compartment where proteolysis occurs. The resulting peptides containing the T cell antigenic determinant are associated with Ia and presented at the cell surface to the specific T cells. The mechanisms by which antigenic peptides become associated with Ia is not known. We previously described a peptide binding protein of 72/74 x 10(3) Mr (PBP72/74) that plays a role in antigen presentation as shown by the ability of an antiserum raised in rabbits to affinity-purified PBP72/74 to block presentation of cytochrome c to a cytochrome c-specific T cell hybrid. Here we show that PBP72/74 is recognized by mAbs specific for members of the HSP70 family of proteins. In Western blots PBP72/74 is bound by mAb 7.10, specific for an evolutionarily conserved epitope of HSP proteins and by mAb N27, specific for both the constitutively expressed and inducible 72/73 x 10(3) Mr HSP70 proteins. In addition, PBP72/74 shares a second common feature of the HSP proteins, that of binding to ATP. Indeed, ATP causes the release of PBP72/74 from binding to a peptide fragment of cytochrome c (Pc 81-104) and PBP72/74 can be eluted from ATP columns by Pc 81-104. Finally, a portion of PBP72/74 is shown to be present on B cell surfaces by immunofluorescence staining. Thus, it appears that characteristics of the heat shock proteins are shared by a protein playing a role in antigen presentation, suggesting some commonality in function.

Antibodies to rabbit cytochrome c arising in rabbits.

Antibodies reactive with rabbit cytochrome c have been observed in rabbits immunized with several heterologous cytochromes. Such antibodies have also been observed in rabbits immunized with rabbit cytochrome c conjugated to bovine gamma globulin. The serum of a rabbit immunized with human cyto chrome c reacted with the cytochrome c of the same rabbit.

Cytochrome c: immunofluorescent localization of the testis-specific form.

Mouse testes contain a unique form of cytochrome c. As demonstrated by the indirect immunofluorescence technique, the testis-specific cytochrome c is detectable in the primary spermatocyte and in cell types comprising the later stages of spermatogenesis. Interstitial cells, Sertoli cells, and spermatogonia contain the somatic form of cytochrome c, as does heart muscle.

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.

Interaction of cytochrome c with cytochrome c oxidase: an understanding of the high- to low-affinity transition.

The steady-state kinetics of high- and low-affinity electron transfer reactions between various cytochromes c and cytochrome c oxidase (ferrocytochrome c:oxygen oxidoreductase, EC 1.9.3.1) preparations were studied spectrophotometrically and polarographically. The dissociation constants for the binding of the first and second molecules of horse cytochrome c (I = 15 mM) are 5.10(-8) M and 1.10(-5) M, respectively, close to the spectrophotometric Km values and consistent with the controlled binding model for the interaction between cytochrome c and cytochrome oxidase (Speck, S.H., Dye, D. and Margoliash, E. (1984) Proc. Natl. Acad. Sci. USA 81, 346-351) which postulates that the binding of a second molecule of cytochrome c weakens that of the first, resulting in low-affinity kinetics. While the Km of the polarographically assayed high-affinity reaction is comparable to that observed spectrophotometrically, the low-affinity Km is over an order of magnitude smaller and cannot be attributed to the binding of a second molecule of cytochrome c. Increasing the viscosity has no effect on the Vmax of the low-affinity reaction assayed polarographically, but increases the Km. Thus, the transition from high- to low-affinity kinetics is dependent on the frequency of productive collisions, as expected for a hysteresis model ascribing the transition to the trapping of the oxidase in a primed state for turnover. At ionic strengths above 150 mM, the rate of cytochrome c oxidation decreases without any correlation to the calculated net charge of the cytochrome c, indicating rate-limiting rearrangement of the two proteins in proximity to each other.

Circular dichroism studies of the binding of mammalian and non-mammalian cytochromes c to cytochrome c oxidase, cytochrome c peroxidase, and polyanions.

The effects of binding of Candida krusei, Drosophila melanogaster, horse, human, and rat cytochromes c to beef cytochrome c oxidase (ferrocytochrome c: oxygen oxidoreductase, EC 1.9.3.1) and yeast cytochrome c peroxidase (ferricytochrome c: hydrogen-peroxide oxidoreductase, EC 1.11.1.5) on their circular dichroism spectra were determined. The binding to cytochrome oxidase results in a positive increase in the ellipticities of the positive and negative Cotton effects at 404 nm and 417 nm of cytochrome c. The horse, human, and rat cytochromes c display less of an increase in the ellipticity of the positive Cotton effect at 404 nm, but more of a positive change in the negative Cotton effect at 417 nm than the C. krusei or D. melanogaster proteins. Interaction with yeast cytochrome c peroxidase elicits only a positive change in the ellipticity of the positive Cotton effect at 404 nm. No significant change is observed in the negative Cotton effect at 417 nm. Rat cytochrome c variants with a phenylalanine in place of tyrosine-67 and/or an alanine in place of proline-30 all display circular dichroism spectral changes upon binding to cytochrome c oxidase or cytochrome c peroxidase identical to those of the unaltered protein. The increase in ellipticity at 404 nm upon binding occurs even though replacement of tyrosine-67 results in the loss of the positive Cotton effect at this position. Polyglutamate and phosvitin complexes of cytochrome c show changes in the circular dichroism spectrum similar to those observed with cytochrome c peroxidase. However, the magnitudes of the spectral changes were considerably less. A model is proposed in which the main cause of the circular dichroism spectral changes observed upon complexation arise from the exclusion of solvent from the exposed front heme edge. According to this model, the exclusion of solvent changes the relative asymmetry of the environment of the electronic transitions of the heme prosthetic group of cytochrome c, resulting in observed circular dichroic effects.

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.

The role of histidines 26 and 33 in the structural stabilization of cytochrome c.

Comparative studies of the importance of the two histidines of rat cytochrome c that are not ligands of the heme iron, for the stability of the protein, were carried out by site-directed mutagenesis. Histidine 26 was substituted by valine and the resulting effects on the stability of the Met-80-sulfur to heme iron bond to changes in pH and temperature, and of the global stability of the protein to unfolding in urea solutions, were measured. It is suggested that the loss of the hydrogen bond between the His-26 imidazole and the backbone amide of Asn-31 caused the observed decreases in local stability; and that, in addition, the elimination of the hydrogen bond between this imidazole and the carbonyl of Pro-44 resulted in an increase of the mobility of the lower loop (residues 41-47) on the right side of the protein and of its distance from the middle loop (residues 26-31), probably leading to greater hydration of the interior right side of the molecule. These changes resulted in a decrease in the global stability of the protein. Further mutation of Asn-52 to Ile led to a total recovery of the wild-type stability of the sulfur-iron bond, and a partial restoration of the global stability of the protein. Substitution of Phe for His-33 did not alter the sulfur-iron bond but caused a pronounced increase in the global stability of the protein. It is suggested that this effect results from hydrophobic interaction of the Phe-33 side chain with the lower loop on the right side of the protein. Such an interaction also explains the observation that the same mutation reversed the loss of global stability caused by substitution of Val to His-26, but did not restore the strength of the sulfur-iron bond that this mutation had brought about.

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.

The isolation of bovine-heart cytochrome c oxidase subunits. Dependence on phospholipid and cholate-content.

The polypeptide chains of bovine-heart cytochrome c oxidase were preparatively isolated by a simple large-scale procedure based on gel permeation chromatography in the presence of sodium dodecyl sulphate. The resolution of the subunits as a function of the cholate and phospholipid content of the preparation was investigated. Cholate, and to a lesser extent, phospholipids interfere with the separation of the subunits; however, they do not prevent dissociation of the enzyme by SDS. Bovine-heart cytochrome c oxidase consists of six major subunits (estimated molecular weights in thousands: 40, 25, 20, 14, 12 and 10). In addition, the enzyme preparation contains at least five minor constituents, present in less than stoichiometric amounts. The first two of the three large subunits, all of which are hydrophobic, have amino-terminal N-formylmethionine. Subunit III, however, has a free methionine N-terminus.

Major and minor epitopes on the self antigen mouse cytochrome c mapped by site-directed mutagenesis.

Variants of rat (mouse) cytochrome c, prepared by site-directed mutagenesis or represented by closely-related cytochromes c from different species, were employed to map the functional boundaries of a number of mouse monoclonal antibodies (mAb) specific for the major antigenic region on the self antigen (Ag) around residue 62 and the minor antigenic region around residue 44. The recombinant mouse cytochromes c tested were, unlike the tissue-derived Ag, trimethylated at position 72, and included the wild-type which was acetylated at the amino terminus, a variant that was unacetylated at the amino terminus, and variants with the following single amino acid residue replacements: V11I (valine to isoleucine at position 11), Q12M, A15S, A44P, F46Y, D50A, T58I and G89E. Of these, only the A44P variant affected the binding of mAb to the region previously localized to the vicinity of residue 44, thus confirming that assignment. Loss of the acetyl group at the amino terminus affected the binding of most of the mAb to the region around residue 62. The other mutations had little, if any, affect on mAb binding. The epitopes of mAb binding the region around residue 62 were shown in this study to have similar functional boundaries. This site on the self Ag, which encompasses at least three discontinuous segments of the polypeptide chain, is comparable in size to epitopes on other protein Ag that have been mapped by X-ray crystallography and is similar to an epitope in the corresponding region of the foreign Ag, horse cytochrome c, that has been mapped by hydrogen-deuterium exchange. In addition to the mAb binding the regions around residues 44 and 62, a third group of mouse cytochrome c-specific mAb known to be broadly reactive with mammalian cytochromes c and that represents a minor portion of the mAb was tested for binding the site-directed mutants of mouse cytochrome c. None of these mAb were affected by the mutations, indicating the presence of at least one more antigenic region on the self Ag in an area not encompassed by these mutations that is structurally highly conserved.

Role of phospholipid in the low affinity reactions between cytochrome c and cytochrome oxidase.

The steady-state oxidation of ferrocytochrome c by cytochrome oxidase monitored spectrophotometrically showed that: (1) the kinetics were strictly biphasic with purified enzyme, while mitochondrial membrane-bound enzyme exhibited multiphasic kinetics with extended low affinity phases; (2) the TNmax for the highest affinity phase was as slow as 5-10 electron X s-1 for both preparations, while for the low affinity phases it was about 45 electron X s-1 for the purified enzyme and 150 electron X s-1 for the mitochondrial membrane-bound enzyme; (3) reconstitution of purified enzyme into acidic phospholipid vesicles partially repleted the extended low affinity phases, while reconstitution into uncharged vesicles had no effect.

The source of heterogeneity in the heme vicinity of ferricytochrome c.

Heterogeneity in the heme vicinity of ferricytochrome c was reported to be detectable by a split of the NMR signal of the heme methyl 3 group [P.D. Burns and G.N. La Mar, J. Am. Chem. Soc. 101 (1979) 5844]. Using cytochrome c mutants and computer simulations of the native and mutated cytochromes, the source of this heterogeneity is found to originate from the His-33 residue motions. The H33F mutation abolished the NMR split and computer simulations of the H33F mutant revealed a narrower distribution of fluctuations of the radius of gyration, suggesting a more rigid structure due to the mutation. The stabilization of the mutant was further demonstrated by a reduction in the H33F mutant of 4 Kcal/mol in the calculated interaction energy between residue 33 and the rest of the cytochrome, in keeping with known experimental results.

Using entropies of reaction to predict changes in protein stability: tyrosine-67-phenylalanine variants of rat cytochrome c and yeast Iso-1 cytochromes c.

Using the voltammetric method of square-wave voltammetry, a direct electrochemical examination was made of the wild type and Tyr67Phe mutant of both rat cytochrome c and yeast iso-1-cytochrome c. In addition to determining the equilibrium reduction potential (E0') for each cytochrome, the entropy of reaction, deltaS0'(Rxn)(deltaS0'(Rxn) = S0'(Red) - S0'(Ox)), for the reduction process was determined via the non-isothermal method. Having determined deltaS0'(Rxn) and E0', deltaH0' was calculated. For rat cytochrome c, it was found that deltaS0'(Rxn) = -43 J mol(-1) K(-1) for the wild type and -53 J mol(-1) K(-1) for the Tyr67Phe variant, with the deltaH0' for both the wild type and variant nearly identical, indicating that the changes in reduction potential and probably stability are due to changes in deltaS0'(Rxn). In contrast the measured deltaS0'(Rxn) for yeast iso-1-cytochrome c demonstrated significant changes in both entropic and enthalpic contributions in going from wild type to mutant cytochrome c. The entropy of reaction provides information regarding the relative degree of solvation, and very likely the degree of compactness, of the oxidized state versus the reduced state of the redox protein. A thermodynamic scheme and stability derivation are presented that show how the entropies of reaction of wild type versus variant cytochromes contribute to and predict changes in stability in going from oxidized to reduced protein. For yeast iso-1-cytochrome c, the thermodynamically predicted change in stability was very close to the experimentally observed value, based on previous differential scanning calorimetric stability measurements. While such data is not available for rat cytochrome c, consideration of the enormously increased local stability of the rat oxidized cytochrome c variant predicts that the reduced rat variant will be even more stable than the already stabilized oxidized variant.

Analysis of a complex antigenic site on horse cytochrome c.

Of the antigenic determinants so far identified for cytochrome c, only one involves more than a single amino acid substitution between the immunogen and host proteins. Both a threonine at position 89 and a glutamic acid at position 92 control one of the three antigenic sites identified in horse cytochrome c, as expressed in rabbits. Three antibody subpopulations, all directed against this region of the molecule, were isolated from the serum of a single rabbit by adsorption on a series of insolubilized cytochromes c. Antibody fluorescence quenching titrations with a variety of cytochromes c were used to confirm the identification of the antigenic determinant and to examine the subtle differences in the specificities of the three subpopulations. The determinant in the region of Residues 89-92 is affected by amino acid substitutions at positions 88 and 96. Since all these residues are in an alpha-helix the farthest distance between them is only 12 A and therefore, the Residues 88-96 can all be accommodated in the antibody binding site. The ability to identify and describe the antigenic determinant, as well as separate subpopulations directed against this site, demonstrates the resolution possible using a series of homologous protein antigens.