Semi-synthetic analogs of cytochrome C at positions 67 and 74

Use of 19F NMR to probe protein structure and conformational changes

19F NMR has proven to be a powerful technique in the study of protein structure and dynamics because the 19F nucleus is easily incorporated at specific labeling sites, where it provides a relatively nonperturbing yet sensitive probe with no background signals. Recent applications of 19F NMR in mapping out structural and functional features of proteins, including the galactose-binding protein, the transmembrane aspartate receptor, the CheY protein, dihydrofolate reductase, elongation factor-Tu, and D-lactose dehydrogenase, illustrate the utility of 19F NMR in the analysis of protein conformational states even in molecules too large or unstable for full NMR structure determination. These studies rely on the fact that the chemical shift of 19F is extremely sensitive to changes in the local conformational environment, including van der Waals packing interactions and local electrostatic fields. Additional information is provided by solvent-induced isotope shifts or line broadening of the 19F resonance by aqueous and membrane-bound paramagnetic probes, which may reveal the proximity of a 19F label to bulk solvent or a biological membrane. Finally, the effect of exchanging conformations on the 19F resonance can directly determine the kinetic parameters of the conformational transition.

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.

Clostripain-catalyzed re-formation of a peptide bond in a cytochrome C fragment complex

Enzymatically-catalyzed condensation of cytochrome c fragments, ferrous heme fragment (1-38) and apofragment (39-104), has allowed the back-conversion of cytochrome c complex to native cytochrome c. The conversion was accomplished in 90% (v/v) glycerol, a solvent which has been shown to decrease the ionization of the terminal alpha-carboxyl group liberated during hydrolysis of a peptide bond. The effect on the pK is probably the main reason the thermodynamic obstacle to re-synthesis is minimized. A 30% conversion to cytochrome c was obtained. The cytochrome c product was distinguished from the non-covalent complex and separated fragments by molecular weight analysis with sodium dodecyl sulfate polyacrylamide gel electrophoresis, by elution from Sephadex G-50 and sulfopropyl-Sephadex in the presence of denaturant, by amino acid analysis of the product purified under complex-dissociation conditions, and by spectral analysis of the absorption bands of the heme. This method provides an opportunity to study the covalent rather than the complex form of cytochrome c analogs.