Protein stability and mutations in the axial methionine loop of a minimal cytochrome c.

The minimal mono-heme ferricytochrome c from Bacillus pasteurii, containing 71 amino acids, has been further investigated through mutagenesis of different positions in the loop containing the iron ligand Met71. These mutations have been designed to sample different aspects of the loop structure, in order to obtain insights into the determinants of the stability of the iron(III) environment. In particular, positions 68, 72 and 75 have been essayed. Gln68 has been mutated to Lys to provide a suitable alternate ligand that can displace Met71 under denaturing conditions. Pro72 has been mutated to Gly and Ala to modify the range of allowed backbone conformations. Ile75, which is in van der Waals contact with Met71 and partly shields a long-lived water molecule in a protein cavity, has been substituted by Val and Ala to affect the network of inter-residue interactions around the metal site. The different contributions of the above amino acids to protein parameters such as structure, redox potential and the overall stability against unfolding with guanidinium hydrochloride are analyzed. While the structure remains essentially the same, the stability decreases with mutations. The comparison with mitochondrial c-type cytochromes is instructive.

Hydrogen exchange in a bacterial cytochrome c: a fingerprint of the cytochrome c fold.

The hydrogen exchange rates of backbone amides in a minimal (71 amino acid long) monoheme cytochrome c were determined as a function of pH in the absence and in the presence of guanidinium chloride. These data permitted the identification of units undergoing the opening reaction that precedes hydrogen exchange through a common mechanism. The opening units broadly correlate with the secondary structure elements of the protein. It is found that, despite the significant difference in primary sequence, the distribution of the opening units within the three-dimensional structure of the cytochrome studied here closely resembles that determined in mitochondrial c-type cytochromes. It is proposed that the observed distribution represents a fingerprint of the cytochrome c fold and has a role in directing the folding/unfolding of the protein.

Structure and dynamics of reduced Bacillus pasteurii cytochrome c: oxidation state dependent properties and implications for electron transfer processes.

The solution structure of reduced Bacillus pasteurii cytochrome c, which has only 71 amino acids, has been determined by NMR to an RMSD of 0.46 +/- 0.08 A for all backbone atoms and 0.79 +/- 0.08 A for all heavy atoms and refined through restrained energy minimization. The target function out of 1645 constraints is 0.52 +/- 0.11 A(2), and the penalty function is 66 +/- 12 kJ mol(-)(1). The structure appears very similar to that in the oxidized state, only Trp87 and the propionates showing significant differences. The mobility was investigated through (15)N R(1) and R(2) relaxation rates, (15)N-(1)H NOE, and (1)H/(2)H exchange. It is found that the oxidized form is generally more mobile than the reduced one. By comparing the redox-state dependence of the structural/dynamic properties of Fe-S proteins, cytochrome c, and blue copper proteins, hints are provided for a better comprehension of the electron transfer processes.

Unfolding and pH studies on manganese peroxidase: role of heme and calcium on secondary structure stability.

The present study characterizes the unfolding and folding processes of recombinant manganese peroxidase. This enzyme contains five disulfide bonds, two calcium ions, and one heme prosthetic group. Circular dichroism in the far UV was used to monitor global changes of the protein secondary structure, whereas UV-visible spectroscopy of the Soret band provided information about local changes in the heme cavity. The effects of reducing agents, oxidizing agents, and denaturants on this process were investigated. In addition to affecting the secondary structure content, these factors also affect the binding of the heme and the calcium ions, both of which have a significant effect on the folding process. Our results also show that denaturants induce irreversible changes, which are most likely due to the inability of the denatured protein to rebind either calcium or the heme. Breaking of disulfide bonds by 30 mM dithiothreitol causes complete unfolding of recombinant manganese peroxidase. The unfolding process was also studied at low and high pH, where the protein reaches the final unfolded state through two different intermediate states. The data also indicate that only the acidic folding-unfolding process is reversible. Our results indicate a complex synergistic relationship between the secondary structure content, the tertiary structure arrangement, and the binding of the heme and the calcium ions and disulfide bridge formation.

The unfolding of oxidized c-type cytochromes: the instructive case of Bacillus pasteurii.

The reversible unfolding of oxidized Bacillus pasteurii cytochrome c(553) by guanidinium chloride under equilibrium conditions has been monitored by NMR and optical spectroscopy. The results obtained indicate that unfolding takes place through a mechanism involving the detachment from heme iron coordination of the sulfur of the Met71 axial ligand and yielding either a high spin (HS) or a low spin (LS(1)) species, depending on the pH value. In the LS(1) form the Met71 is replaced by another protein ligand, possibly Lys. The ligand exchange reaction does not reach completion until the protein backbone reaches a largely unfolded state, as monitored through 1H-15N NMR experiments, thus demonstrating that there is a significant correlation between formation of the Fe-S bond and native structure stability. 1H/2H exchange data, however, show that helix alpha(3), the C-terminal region of helix alpha(4), and helix alpha(5) maintain low exchangeability of the amide protons in the LS(1) form. This finding most likely implies that these regions maintain some ordered non-covalent structure, in which the amide moieties are involved in H-bonds. Finally, a folding mechanism is proposed and discussed in terms of analogies and differences with the larger mitochondrial cytochrome c proteins. It is concluded that the thermodynamic stability of the region around the metal cofactor is determined by the chemical nature of the residues around the axial methionine residue.

Solution structure of a monoheme ferrocytochrome c from Shewanella putrefaciens and structural analysis of sequence-similar proteins: functional implications.

Within the frame of the characterization of the structure and function of cytochromes c, an 81-amino acid cytochrome c was identified in the genome of Shewanella putrefaciens. Because of the scarce information about bacterial cytochromes of this type and the large variability in sequences and possibly function, we decided to proceed to its structural characterization. This protein was expressed in Escherichia coli and purified. The oxidized species is largely high spin, with a detached methionine, whereas the reduced species has the classical His/Met axial ligation to iron. The NMR solution structure of the reduced form was determined on a (15)N-labeled sample, for which 99% of all non-proline backbone (1)H and (15)N resonances have been assigned. One thousand three hundred two meaningful NOEs, out of 1775 NOEs, together with 66 dihedral angles provide a structure with rmsd values from the mean of 0.50 and 0.96 A for backbone and all heavy atoms, respectively. A search of gene banks allowed us to locate 10 different cytochromes c, the sequences of which are more than 30% identical to that of the S. putrefacienscytochrome. For two of them, the structures are known. The structures of the others have been modeled by using the available templates and internally validated. Structural similarities in terms of surface properties account for their biophysical features and provide hints about the function.