Functional consequences of the excision of an omega loop, residues 40-55, from mitochondrial cytochrome c

The 40s ?-loop plays a critical role in the stability and the alkaline conformational transition of cytochrome c

The structural and redox properties of a non-covalent complex reconstituted upon mixing two non-contiguous fragments of horse cytochrome c, the residues 1-38 heme-containing N-fragment with the residues 57-104 C-fragment, have been investigated. With respect to native cyt c, the complex lacks a segment of 18 residues, corresponding, in the native protein, to an omega (Omega)-loop region. The fragment complex shows compact structure, native-like alpha-helix content but a less rigid atomic packing and reduced stability with respect to the native protein. Structural heterogeneity is observed at pH 7.0, involving formation of an axially misligated low-spin species and consequent partial displacement of Met80 from the sixth coordination position of the heme-iron. Spectroscopic data suggest that a lysine (located in the Met80-containing loop, namely Lys72, Lys73, or Lys79) replaces the methionine residue. The residues 1-38/57-104 fragment complex shows an unusual biphasic alkaline titration characterized by a low (p K(a1)=6.72) and a high p K(a)-associated state transition (p K(a2)=8.56); this behavior differs from that of native cyt c, which shows a monophasic alkaline transition (p K(a)=8.9). The data indicate that the 40s Omega-loop plays an important role in the stability of cyt c and in ensuring a correct alkaline conformational transition of the protein.

Cooperative omega loops in cytochrome c: role in folding and function

Hydrogen exchange experiments under slow exchange conditions show that an omega loop in cytochrome c (residues 40-57) acts as a cooperative unfolding/refolding unit under native conditions. This unit behavior accounts for an initial step on the unfolding pathway, a final step in refolding, and a number of other structural, functional and evolutionary properties.

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.

Temperature-sensitive variants of Saccharomyces cerevisiae iso-1-cytochrome c produced by random mutagenesis of codons 43 to 54

In vitro random mutagenesis within the CYC1 gene from the yeast Saccharomyces cerevisiae was used to produce a library of mutants encompassing codons 43 to 54 of iso-1-cytochrome c. This region consists of an evolutionarily conserved structure within an evolutionarily diverse sequence. The library, on a low-copy-number yeast shuttle phagemid, was introduced into a yeast strain lacking cytochrome c. The ability of transformants harboring a functional cytochrome c to grow on the non-fermentable carbon source glycerol at 30 degrees C and 37 degrees C was used to determine the phenotype of nearly 1000 transformants. Approximately 90% of the missense mutants present in the library give rise to the wild-type phenotype, 7% result in the temperature-sensitive (Cycts) phenotype, and 3% give rise to the non-functional (Cyc-) phenotype. Phagemids from 20 Cycts and 30 Cyc- transformants were subjected to DNA sequence analysis. All the mutations occur within the targeted region. One-third of the mutants from Cyc- transformants and all the mutants from Cycts transformants are missense mutants. The remaining mutants from Cyc- transformants are nonsense or frame-shift mutants. Missense mutations within the codons for Gly45, Tyr46, Thr49, Asn52 or Ile53 alone are sufficient to produce temperature-sensitive behavior both in vivo and in the variant proteins. The deduced amino acid substitutions correlate remarkably well with side-chain dynamics, secondary structure and tertiary structure of the wild-type protein.

Effects of point mutations in a hinge region on the stability, folding, and enzymatic activity of Escherichia coli dihydrofolate reductase

The role of a hinge region in the folding, stability, and activity of Escherichia coli dihydrofolate reductase was investigated with three site-directed mutants at valine-88, the central residue of the hinge. The three mutants, V88A and V88I and a valine-88 deletion, were created to perturb the packing of hydrophobic residues in the interior of a loose turn formed by residues 85-91. Deleting the valine-88 residue destabilized the protein by 2.93 +/- 0.6 kcal/mol as determined by equilibrium unfolding transitions in urea monitored by circular dichroism at 20 degrees C. Substitution of alanine for valine-88 stabilized the protein by -0.20 +/- 0.02 kcal/mol, and the isoleucine substitution was mildly destabilizing by 1.73 +/- 0.2 kcal/mol. Although there was no clear correlation between side-chain volume and stability, these results suggest that side-chain interactions in the interior of the turn influence the folding and stability of dihydrofolate reductase. The specific activity of the valine deletion mutant was approximately twice that of the wild-type protein while the specific activities of the V88A and V88I proteins were only slightly greater than the wild type. The full time courses of the reactions catalyzed by the mutants were almost identical with that for the wild type, indicating no major changes in the kinetic mechanism. Additionally, the rate constants associated with interconversion between various forms of the apoenzyme were identical for the mutant and wild-type enzymes. The rate constants for refolding transitions were examined by dilution of urea-inactivated protein.(ABSTRACT TRUNCATED AT 250 WORDS)

Deletions and replacements of omega loops in yeast iso-1-cytochrome c

omega (omega)-loops are protein secondary structural elements having small distances between segment termini. It should be possible to delete or replace certain of these omega-loops without greatly distorting the overall structure of the remaining portion of the molecule. Functional requirements of regions of iso-1-cytochrome c from the yeast Saccharomyces cerevisiae were investigated by determining the biosynthesis and activity in vivo of mutant forms in which four different omega-loops were individually deleted, or in which one omega-loop was replaced with five different segments. Deletions encompassing amino acid positions 27-33 and 79-83 either prevented synthesis of the holoprotein, or produced highly labile iso-1-cytochromes c, whereas deletions encompassing positions 42-45 and 48-55 allowed partial synthesis and activity. These two latter regions, therefore, are not absolutely required for any biosynthetic process such as heme attachment, mitochondrial import, or for enzymatic interactions. All replacements in Loop A (residue positions 24-33) with same size (10 amino acid residues), longer (13 and 15 amino acid residues), or shorter segments (6 amino acid residues), resulted in strains having at least partial levels of iso-1-cytochrome c; however, the relative activities ranged from zero to almost the normal level. Thus, Loop A does not appear to be essential for such biosynthetic steps as heme attachment and mitochondrial import. In contrast, the full range of relative activities suggest that this region interacts with physiological partners to carry out efficient electron transport.

A design approach to the structural analysis of interleukin-2

A semi-synthetic protein design approach has been employed for the structural investigation of a putative helical region at the C-terminus of Interleukin-2. With crystallographic or NMR derived conformational data as yet unavailable, we have relied only on primary sequence information and computer-assisted modelling to direct the analysis. By employing both chemical peptide synthesis and recombinant DNA methods, the C-terminus of IL-2 was modified according to a strategy designed to stabilize helical secondary structure. A semi-synthetic protein incorporating 12 simultaneous amino acid replacements was constructed, which possessed potentiated biological activity and displayed a far UV circular dichroism spectrum comparable to a hybrid protein with the authentic sequence. By comparison, another hybrid protein containing a C-terminal region designed to contain helix breaking residues was totally devoid of bioactivity. These findings provide evidence that the modelling method correctly identified a helix necessary for the formation of a bioactive tertiary fold. Moreover, by employing semi-synthesis it was possible to circumvent the difficulties associated with the preparation, purification and analysis of multiple recombinant proteins, and also to avoid the unreliability of total chemical synthesis for proteins greater than 100 residues.