Partially formed native tertiary interactions in the A-state of cytochrome c.

Considerable insight into protein structure, stability, and folding has been obtained from studies of non-native states. We have studied the extent of native tertiary contacts in one such molecule, the A-state of yeast iso-1-ferricytochrome c. Previously, we showed that the interface between the N and C-terminal helices is completely formed in the A-state. Here, we focus on interactions essential for forming the heme pocket of eukaryotic cytochromes c. To determine the extent of these interactions, we used saturation mutagenesis at the evolutionarily invariant residue leucine 68, and measured the free energy of denaturation for the native states and the A-states of functional variants. We show that, unlike the interaction between the terminal helices, the native interactions between the 60s helix and the rest of the protein are not completely formed in the A-state.

Protein thermal denaturation, side-chain models, and evolution: amino acid substitutions at a conserved helix-helix interface.

Random mutant libraries with substitutions at the interface between the N- and C-terminal helices of Saccharomyces cerevisiae iso-1-cytochrome c were screened. All residue combinations that have been identified in naturally occurring cytochrome c sequences are found in the libraries. Mutants with these combinations are biologically functional. Enthalpies, heat capacities, and midpoint temperatures of denaturation are used to determine the entropy and Gibbs free energy of denaturation (delta GD) for the ferri form of the wild-type protein and 13 interface variants. Changes in delta GD cannot be allocated solely to enthalpic or entropic effects, but there is no evidence of enthalpy-entropy compensation. The lack of additivity of delta GD values for single versus multiple amino acid substitutions indicates that the helices interact thermodynamically. Changes in delta GD are not in accord with helix propensities, indicating that interactions between the helices and the rest of the protein outweigh helix propensity. Comparison of delta GD values for the interface variants and nearly 90 non-cytochrome c variants to side-chain model data leads to several conclusions. First, hydrocarbon side chains react to burial-like transfer from water to cyclohexane, but even weakly polar side chains respond differently. Second, despite octanol being a poor model for protein interiors, octanol-to-water transfer free energies are useful stability predictors for changing large hydrocarbon side chains to smaller ones. Third, unlike cyclohexane and octanol, the Dayhoff mutation matrix predicts stability changes for a variety of substitutions, even at interacting sites.(ABSTRACT TRUNCATED AT 250 WORDS)