Changes in conformation and slow refolding kinetics in mutant iso-2-cytochrome c with replacement of a conserved proline residue

Using oligonucleotide-directed mutagenesis, we have produced a mutant form of iso-2-cytochrome c of yeast in which threonine (Thr-71) replaces a conserved proline residue (Pro-71) located between two short alpha-helical segments in the native protein. Optical spectroscopy indicates that, at pH 7.2, Thr-71 iso-2-cytochrome c folds to a nonnative conformation possibly related to the alkaline form of the native protein. On titration to pH 5.2, Thr-71 iso-2-cytochrome c regains many of the optical properties of the normal protein. We have shown that the proline residue at position 71 has no effect on the kinetics of fluorescence-detected slow refolding. However, between pH 5 and pH 7.2 the amplitude for absorbance-detected slow folding is strongly pH dependent in the mutant protein but is largely independent of pH in the normal protein. We believe this to be due to the folding of Thr-71 iso-2-cytochrome c to a nonnative conformation at pH 7.2 that does not require the slow, absorbance-detected conformational changes observed in folding to the more native-like state at pH 5-6.     

Altered absorption spectra of iso-1-cytochromes c from mutants of yeast.

Low temperature (-190 degrees) spectrophotometric recordings were made of mutant strains of the yeast Saccharomyces cerevisiae containing various altered sequences of iso-1-cytochromes c. All mutants with replacements of the tryptophan 64 residue had abnormal Calpha-bands, in which the alpha2-peaks were accentuated to various degrees by being more separated from the major alpha1-peaks and by making up a larger portion of the total Calpha-peak. The altered iso-1-cytochromes c included those having the normal tryptophan 64 replaced by phenylalanine, leucine, tyrosine, cysteine, serine, or glycine as well as those having replacements at position 64 and additional replacements at other sites. Tryptophan 64 in iso-1-cytochrome c, which corresponds to tryptophan 59 in vertebrate cytochromes c, appears to be an important residue for preserving the electronic environment of the heme group. It is uncertain, however, whether altered spectra are due specifically to the abnormal residues at position 64 or due to distorted tertiary structures caused by the replacements.     

Thermodynamic stabilities of yeast iso-1-cytochromes c having amino acid substitutions for lysine 32

Iso-1-cytochromes c having lysine 32 replaced by leucine, glutamine, tyrosine, and tryptophan were prepared from strains of bakers' yeast, Saccharomyces cerevisiae, and chemically blocked at cysteine 107 with methyl methanethiolsulfonate to prevent dimerization. These modified ferricytochromes c were guanidine denatured, and the unfolding thermodynamics were determined by circular dichroism and fluorescence measurements. Thermal unfolding was also monitored by absorbance measurements. The guanidine denaturation midpoints for the altered proteins are smaller than the wild type, while the orders of stability from unfolding free energy changes are: Lys-32 (wild type) approximately Leu-32 approximately Gln-32 (circular dichroism), greater than Gln-32 (fluorescence) greater than Tyr-32 approximately Trp-32. Midpoints and differences in free energy changes for thermal unfolding parallel the fluorescence free energy changes for guanidine-induced unfolding. Thus, the blocked Leu-32 and Lys-32 proteins are equally stable with respect to both chemical and thermal denaturation. The reported data indicate that single replacements may significantly modify protein stability, and that substitution for an evolutionarily retained residue in normal cytochrome c structures does not always destabilize the protein. In addition, in vitro thermal stabilities approximately correlate with in vivo specific activities.     

Folding/unfolding kinetics of mutant forms of iso-1-cytochrome c with replacement of proline-71

Proline-71, an evolutionally conserved residue that separates two short alpha-helical regions, is replaced by valine, threonine, or isoleucine in at least partially functional forms of iso-1-cytochrome c from Saccharomyces cerevisiae [Ernst, J. F., Hampsey, D. M., Stewart, J. W., Rackovsky, S., Goldstein, D., & Sherman, F. (1985) J. Biol. Chem. 260, 13225-13236]. To assign the effects of perturbations at position 71 to steps in the process of protein folding, the kinetic properties of the folding/unfolding reactions of normal protein and the three mutant forms are compared. At pH 6.0, 20 degrees C, fluorescence-detected folding/unfolding kinetics are monitored below, within, and above the equilibrium transition zone by using stopped-flow mixing to perform guanidine hydrochloride concentration jumps. Three kinetic phases are detected for each of the four proteins. The fastest of these phases (tau 3) differs in rate for the wild type and mutant proteins. The remaining kinetic phases (tau 1 and tau 2) have similar rates for all four proteins over the entire range of folding/unfolding conditions. The guanidine hydrochloride dependence of the relative amplitudes of the kinetic phases is complex and is sensitive to the nature of the substituent at position 71: each of the four proteins shows differences in the fraction of folding/unfolding associated with the two fastest rate processes. The results suggest that it is the location of the mutation in the primary structure rather than the nature of the substituent that determines which kinetic step (or steps) is changed in rate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Enhanced thermodynamic stabilities of yeast iso-1-cytochromes c with amino acid replacements at positions 52 and 102.

We have determined the structures and thermodynamic stabilities of the wild type Asn-52 and unusually thermostable mutant Ile-52 yeast iso-1-cytochromes c (Das, G., Hickey, D. R. McLendon, D., McLendon, G., and Sherman, F. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 496-499). Although both structures were similar, Water-166, buried within the wild type protein, is excluded from the Ile-52 mutant, which substantially reorganizes the local hydrogen bonding. Wild type Cys-102 was replaced with alanine or serine to eliminate dimerization in vitro. The Cys-102 (wild type), Ala-102, and Ser-102 proteins were equally stable, whereas the chemically modified Cys-102-SCH3 was less stable. The order of stability observed with replacements at positions 52 and 102 was as follows: Ile-52 Ala-102 greater than Ala-52 Ala-102 greater than Asn-52 Ala-102 ("normal") greater than Gly-52 Ala-102. No significant stabilization was attributed to potential energy interactions expressed as helix-forming propensities of replacements at position 52. A high correlation between differences in free energy changes and transfer free energies suggests hydrophobic interactions are the main factor for enhancing stability in the Ile-52 mutant. Additional possible contributions to the thermostability of the Ile-52 variant are energetic effects due to packing and hydrogen bonding changes surrounding position 52.     

Guanidine hydrochloride induced equilibrium unfolding of mutant forms of iso-1-cytochrome c with replacement of proline-71

Proline-71, an evolutionally conserved residue that separates two short alpha-helical regions, is replaced by valine, threonine, or isoleucine in at least partially functional forms of iso-1-cytochrome c from Saccharomyces cerevisiae [Ernst, J. F., Hampsey, D. M., Stewart, J. W., Rackovsky, S., Goldstein, D., & Sherman, F. (1985) J. Biol. Chem. 260, 13225-13236]. Treatment of these proteins with a specific sulfhydryl blocking reagent (methyl methanethiosulfonate) to block Cys-102 has allowed investigation of the properties of monomeric forms of the proteins, denoted iso-1-MS. Comparison of the UV-visible absorbance properties (pH 6, 20 degrees C) shows minor differences between the normal Pro-71 iso-1-MS and two of the three mutant proteins. The Val-71 iso-1-MS protein has absorbance properties indistinguishable from those of the normal Pro-71 iso-1-MS protein, but the Ile-71 iso-1-MS and Thr-71 iso-1-MS proteins show reduced intensity of the 695-nm absorbance band and a small shift in the Soret maximum, from 408 nm for the Pro-71 iso-1-MS and Val-71 iso-1-MS proteins to 406 nm for the Thr-71 iso-1-MS and Ile-71 iso-1-MS proteins. Second derivative spectroscopy is used to assess differences in the polarity of the environment of tyrosine residues. The average degree of exposure of tyrosines to solvent is similar in all four proteins: 0.39 for the normal Pro-71 iso-1-MS and Val-71 iso-1-MS proteins; 0.40 for the Ile-71 iso-1-MS protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Replacement of a conserved proline and the alkaline conformational change in iso-2-cytochrome c

Although point mutations usually lead to minor localized changes in protein structure, replacement of conserved Pro-76 with Gly in iso-2-cytochrome c induces a major conformational change. The change in structure results from mutation-induced depression of the pK for transition to an alkaline conformation with altered heme ligation. To assess the importance of position 76 in stabilizing the native versus the alkaline structure, the equilibrium and kinetic properties of the pH-induced conformational change have been compared for normal and mutant iso-2-cytochrome c. The pKapp for the conformational change is reduced from 8.45 (normal iso-2) to 6.71 in the mutant protein (Gly-76 iso-2), suggesting that conservation of Pro-76 may be required to stabilize the native conformation at physiological pH. The kinetics of the conformational change for both the normal and mutant proteins are well-described by a single kinetic phase throughout most of the pH-induced transition zone. Over this pH range, a minimal mechanism proposed for horse cytochrome c [Davis, L. A., Schejter, A., & Hess, G. P. (1974) J. Biol. Chem. 249, 2624-2632] is consistent with the data for normal and mutant yeast iso-2-cytochromes c: NH KH----N + H+ kcf in equilibrium kcb A NH and N are native forms of cytochrome c with a 695-nm absorbance band, A is an alkaline form that lacks the 695-nm band, KH is a proton dissociation constant, and kcf and kcb are microscopic rate constants for the conformational change. The Gly-76 mutation increases kcf by almost 70-fold, but kcb and KH are unchanged.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structure determination and analysis of yeast iso-2-cytochrome c and a composite mutant protein.

As part of a study of protein folding and stability, the three-dimensional structures of yeast iso-2-cytochrome c and a composite protein (B-2036) composed of primary sequences of both iso-1 and iso-2-cytochromes c have been solved to 1.9 A and 1.95 A resolutions, respectively, using X-ray diffraction techniques. The sequences of iso-1 and iso-2-cytochrome c share approximately 84% identity and the B-2036 composite protein has residues 15 to 63 from iso-2-cytochrome c with the rest being derived form the iso-1 protein. Comparison of these structures reveals that amino acid substitutions result in alterations in the details of intramolecular interactions. Specifically, the substitution Leu98Met results in the filling of an internal cavity present in iso-1-cytochrome c. Further substitutions of Val20Ile and Cys102Ala alter the packing of secondary structure elements in the iso-2 protein. Blending the isozymic amino acid sequences in this latter area results in the expansion of the volume of an internal cavity in the B-2036 structure to relieve a steric clash between Ile20 and Cys102. Modification of hydrogen bonding and protein packing without disrupting the protein fold is illustrated by the His26Asn and Asn63Ser substitutions between iso-1 and iso-2-cytochromes c. Alternatively, a change in main-chain fold is observed at Gly37 apparently due to a remote amino acid substitution. Further structural changes occur at Phe82 and the amino terminus where a four residue extension is present in yeast iso-2-cytochrome c. An additional comparison with all other eukaryotic cytochrome c structures determined to date is presented, along with an analysis of conserved water molecules. Also determined are the midpoint reduction potentials of iso-2 and B-2036 cytochromes c using direct electrochemistry. The values obtained are 286 and 288 mV, respectively, indicating that the amino acid substitutions present have had only a small impact on the heme reduction potential in comparison to iso-1-cytochrome c, which has a reduction potential of 290 mV.     

Replacement of a conserved proline eliminates the absorbance-detected slow folding phase of iso-2-cytochrome c

As a test of the proline isomerization model, we have used oligonucleotide site-directed mutagenesis to construct a mutant form of iso-2-cytochrome c in which proline-76 is replaced by glycine [Wood, L. C., Muthukrishnan, K., White, T. B., Ramdas, L., & Nall, B. T. (1988) Biochemistry (preceding paper in this issue)]. For the oxidized form of Gly-76 iso-2, an estimate of stability by guanidine hydrochloride induced unfolding indicates that the mutation destabilizes the protein by 1.2 kcal/mol under standard conditions of neutral pH and 20 degrees C (delta G degrees u = 3.8 kcal/mol for normal Pro-76 iso-2 versus 2.6 kcal/mol for Gly-76 iso-2). The kinetics of folding/unfolding have been monitored by fluorescence changes throughout the transition region using stopped-flow mixing. The rates for fast and slow fluorescence-detected refolding are unchanged, while fast unfolding is increased in rate 3-fold in the mutant protein compared to normal iso-2. A new kinetic phase in the 1-s time range is observed in fluorescence-detected unfolding of the mutant protein. The presence of the new phase is correlated with the presence of species with an altered folded conformation in the initial conditions, suggesting assignment of the phase to unfolding of this species. The fluorescence-detected and absorbance-detected slow folding phases have been monitored as a function of final pH by manual mixing between pH 5.5 and 8 (0.3 M guanidine hydrochloride, 20 degrees C).(ABSTRACT TRUNCATED AT 250 WORDS)     

pH dependence of folding of iso-2-cytochrome c

Starting from a standard unfolded state (3.0 M guanidine hydrochloride, pH 7.2), the kinetics of refolding of iso-2-cytochrome c have been investigated as a function of final pH between pH 3 and pH 10. Absorbance in the ultraviolet and visible spectral regions and tryptophan fluorescence are used to monitor folding. Over most of the pH range, fast and slow folding phases are detected by both fluorescence and absorbance probes. Near neutral pH, the rate of fast folding appears to be the same when monitored by absorbance and fluorescence probes. At higher and lower pH, there are two fast folding reactions, with absorbance-detected fast folding occurring in a slightly faster time range than fluorescence-detected fast folding. The rates of both fast folding reactions pass through broad minima near neutral pH, indicating involvement of ionizable groups in rate-limiting steps. The rates of slow folding also depend on the final pH. At acid pH, there appears to be a single slow folding phase for both fluorescence and absorbance probes. At neutral pH, the absorbance-detected and fluorescence-detected slow folding phases separate into distinct kinetic processes which differ in rate and relative amplitude. At high pH, absorbance-detected slow folding is no longer observed, while fluorescence-detected slow folding is decreased in amplitude. In contrast, the equilibrium and kinetic properties of proline imide bond isomerization, believed to be involved in the slow folding reactions, are largely independent of pH. The results suggest that the pH dependence of slow folding involves coupling of pH-sensitive structure to proline imide bond isomerization.(ABSTRACT TRUNCATED AT 250 WORDS)     

The specificities of yeast methionine aminopeptidase and acetylation of amino-terminal methionine in vivo. Processing of altered iso-1-cytochromes c created by oligonucleotide transformation

The specificities of methionine aminopeptidase and amino-terminal acetylation in the yeast Saccharomyces cerevisiae were investigated in vivo by sequencing a series of altered iso-1-cytochrome c. Twenty iso-1-cytochromes c, each having a different penultimate residue in the sequence Met-Xaa-Phe-Leu-, were created by transforming yeast directly with synthetic oligonucleotides. The degree of methionine cleavage and amino-terminal acetylation was estimated from the levels of pertinent peptides separated by high performance liquid chromatography. The results confirmed our earlier hypothesis (Sherman, F., Stewart, J. W., and Tsunasawa, S. (1985) BioEssays 3, 27-31) that methionine is completely removed from penultimate residues having radii of gyration of 1.29 A or less (glycine, alanine, serine, cysteine, threonine, proline, and valine). However, only partial cleavage occurred in the sequences Met-Thr-Pro-Leu- and Met-Val-Pro-Leu-, demonstrating that proline at the third position inhibits methionine cleavage when the penultimate residue has an intermediate radius of gyration. Acetylation of the retained amino-terminal methionine occurred completely with the Ac-Met-Glu-Phe-Leu- and Ac-Met-Asp-Phe-Leu- sequences and partially with the Ac-Met-Asn-Phe-Leu-sequence. Although the consensus for acetylation of the retained amino-terminal methionine is not completely known, these results and the results of published sequences indicated that Ac-Met-Glu- and Ac-Met-Asp- (methionine followed by an acidic residue) is sufficient for amino-terminal acetylation in eukaryotes but not in prokaryotes.     

Yeast mutants defective in iso-2-cytochrome c.

The structural gene CYC7 for yeast iso-2-cytochrome c was previously identified by isolating a mutant, cyc7-1-1, totally lacking iso-2-cytochrome c and demonstrating that revertants of this mutant contained iso-2-cytochrome c with an altered primary structure (Downie et al., 1977). In this paper we describe a variety of different types of mutants that completely or partially lack iso-2-cytochrome c due to mutations in either the structural gene, CYC7, or unlinked “regulatory” genes. The iso-2-cytochrome c-deficient mutants were isolated by benzidine staining of over 3 × 10⁵ colonies from ?^? strains (cytoplasmic petites) that lacked iso-1-cytochrome c due to the deletion cyc1-1 and that contain abnormally high levels of iso-2-cytochrome c due to a chromosomal translocation, CYC7-1, adjacent to the normal structural gene CYC7 +. The cytochrome c content of mutants not staining with the benzidine reagents was estimated by low temperature spectroscopy, and 139 mutants containing significantly decreased levels of iso-2-cytochrome c were analyzed genetically by complementation with previously identified cyc mutants. In this way 50 mutants at the cyc2 and cyc3 loci were identified along with a group of 62 mutants of the structural gene cyc7. The different types of mutants of the structural gene which were uncovered and which were more or less anticipated included those that completely lacked iso-2-cytochrome c, those that were suppressible by UAA or UAG suppressors, those that lacked iso-2-cytochrome c but had increased levels after growth at lower temperatures, and those that exhibited visibly altered c_a absorption bands of iso-2-cytochrome c. Iso-2-cytochrome c mutants with altered primary structures were obtained from intragenic revertants of several of these mutants, confirming our earlier conclusion that cyc7 is the structural gene. In addition we observed an unexpected class of mutants that lacked iso-2-cytochrome c when in the ?^? state but contained approximately the CYC7-1 parental level when in the ?⁺ state. Two of these mutants, cyc7-1-47 and cyc7-1-49, were shown to contain altered iso-2-cytochromes c. The different contents of the abnormal iso-2cytochromes c suggest that cytochrome c has different environments in ?⁺ and ?^? mitochondria and that the ?⁺ condition may stabilize certain altered proteins.     

Structural gene for yeast iso-2-cytochrome c.

Protein analysis and genetic studies have led to the identification of the structural genes of iso-1-cytochrome c and iso-2-cytochrome c, which constitute, respectively, 95% and 5% of the total amount of cytochrome c in the yeast Saccharomyces cerevisiae. The structural gene CYC1 for iso-1-cytochrome c was previously identified by Sherman et al. (1966) and the structural gene CYC7 for iso-2-cytochrome c is identified in this investigation. A series of the following mutations were selected by appropriate procedures and shown by genetic tests to be allelic: CYC7+ →CYC7-1 →cyc7-1-1 →CYC7-1-1-A, etc., where CYC7 + denotes the wild-type allele determining iso-2-cytochrome c; CYC7-1 denotes a dominant mutant allele causing an approximately 30-fold increase of iso-2-cytochrome c with a normal sequence, and was used as an aid in selecting deficient mutants; cyc7-1-1 denotes a recessive mutant allele causing complete deficiency of iso-2-cytochrome c; and CYC7-1-1-A denotes an intragenic revertant having an altered iso-2-cytochrome c at the same level as iso-2-cytochrome c in the CYC7-1 strains. The suppression of cyc7-1-1 with the known amber suppressor SUP7-a indicated that the defect in cyc7-1-1 was an amber (UAG) nonsense codon. Sequencing revealed a single amino acid replacement of a tyrosine residue for the normal glutamine residue at position 24 in iso-2-cytochrome c from the suppressed cyc7-1-1 strain and also in five revertants of cyc7-1-1, of which three were due to extragenic suppression and two to intragenic reversion. The nature of the mutation that elevated the level of normal iso-2-cytochrome c in the CYC7-1 strain was not identified, although it occurred at or very near the CYC7 locus but outside the translated portion of the gene and it may be associated with a chromosomal aberration. Genetic studies demonstrated that CYC7 is not linked to CYC1, the structural gene for iso-1-cytochrome c.     

Evaluation of cooperative interactions between substructures of iso-1-cytochrome c using double mutant cycles

A double mutant cycle has been used to evaluate interaction energies between the global stabilizer mutation asparagine 52 --> isoleucine (N52I) in iso-1-cytochrome c and mutations producing single surface histidines at positions 26, 33, 39, 54, 73, 89, and 100. These histidine mutation sites are distributed through the four cooperative folding units of cytochrome c. The double mutant cycle starts with the iso-1-cytochrome c variant AcTM, a variant with no surface histidines and with asparagine at position 52. Isoleucine is added singly at position 52, AcTMI52 variant, as are the surface histidines, AcHX variants, where X indicates the histidine sequence position. The double mutant variants, AcHXI52, provide the remaining corner of the double mutant cycle. The stabilities of all variants were determined by guanidine hydrochloride denaturation and interaction energies were calculated between position 52 and each histidine site. Six of the seven double mutants show additive (AcH33I52, AcH39I52, AcH54I52, AcH89I52, and AcH100I52) stability effects or weak interaction energies (AcH73I52) of the histidine mutations and the N52I mutation, consistent with cooperative effects on protein folding and stability being sparsely distributed through the protein structure. The AcH26I52 variant shows a strong favorable interaction energy, 2.0 +/- 0.5 kcal/mol, between the N52I mutation in one substructure and the addition of His 26 to an adjacent substructure. The data are consistent with an entropic stabilization of the intersubstructure hydrogen bond between His 26 and Glu 44 by the Ile 52 mutation.     

Structural intermediates in folding of yeast iso-2 cytochrome c

The kinetic properties of the folding reactions of iso-2 cytochrome c from Saccharomyces cerevisiae have been investigated by stopped-flow and temperature-jump methods. Three different structural probes are compared: (1) absorbance changes in the visible reflecting changes in heme environment, (2) ultraviolet absorbance changes due to the exposure of aromatic groups to solvent, and (3) tryptophan fluorescence attributable principally to the average distance between the tryptophan residue (donor) and the heme (quencher). In addition, two probes either indicative of or correlated with function, ascorbic acid reducibility and the 695-nm absorbance band, have been used to monitor specifically the rate of formation of the native protein on refolding. The fastest phase observed (tau 3) has a measurable relative amplitude only when monitored by visible absorbance changes, suggesting that this reaction involves changes in heme environment in the absence of significant changes in the heme to tryptophan distance or in the extent to which aromatic groups are exposed to solvent. Different slow phases are observed when complete refolding is monitored by visible or ultraviolet absorbance (tau 1a) as opposed to tryptophan fluorescence (tau 1b), the fluorescence changes being complete on a time scale 4-8-fold faster than for absorbance. A mid-range kinetic phase (tau 2) is detected by all three structural probes. When ascorbic acid reducibility or 695-nm absorbance changes are used to monitor the rate of formation of the native protein, two phases are detected: tau 2 and tau 1a. Taken together these results demonstrate that kinetic phase tau 1b results in the formation of a structural intermediate in folding with fluorescence close to that of the native protein but with distinct absorbance properties.     

Network of interactions between unlinked genes: synergistic and antagonistic regulation of iso-1-cytochrome c, iso-2-cytochrome c and cytochrome b2 synthesis]

Five chromosomal genes, CYPI to CYP5 involved in the regulation of the synthesis of iso-1-cytochrome c, iso-2-cytochrome c and cytochrome b2 are described. The function of these genes was studied either by varying the proportion of the mutated and wild type alleles in the cell vy varing the growth conditions, or else by transforming the mutants into sigma-cytoplasmic petites. We have shown a network of genetic interactions which regulate the synthesis of three structurally different proteins : iso-1-cytochrome c, iso-2-cytochrome c and cytochrome b2, by two unlinked genes : CYC1 and CYP1, one of which (CYC1) is the structural gene by iso-1-cytochrome c. Within this network the interactions are proportional to the gene dosage and are either antagonistic or synergistic depending on the allele combination and the protein studied. The mutated alleles cyp1 stimulate the synthesis of iso-2-cytochrome c, inhibit the synthesis of iso-1-cytochrome c, while the cytochrome b2 synthesis is also inhibited but by a combination of cyp1 mutated alleles CYC1 wild type allele. Other loci, CYP2, CYP3, CYP4 and CYP5 were also studied in various allelic combinations. They show some interactions between them or with CYC1 locus but these interactions are different and less pronounced than those involving loci CYP1 and CYC1.     

Enhanced stability in vivo of a thermodynamically stable mutant form of yeast iso-1-cytochrome c

Previous work has established that the N57I amino acid replacement in iso-1-cytochrome c from the yeast Saccharomyces cerevisiae causes an unprecedented increase in thermodynamic stability of the protein in vitro, whereas the N57G replacement diminishes stability. Spectrophotometric measurements of intact cells revealed that the N57I iso-l-cytochrome c is present at higher than normal levels in vivo. Although iso-1-cytochrome c turnover is negligible during aerobic growth, transfer of fully derepressed, aerobically grown cells to anaerobic growth conditions leads to reduction in the levels of all of the cytochromes. Pulsechase experiments carried out under these anaerobic conditions demonstrated that the N57I iso-l-cytochrome c has a longer half-life than the normal protein. This is the first report of enhanced stability in vivo of a mutant form of a protein that has an enhanced thermodynamic stability in vitro. Although the N57I protein concentration is higher than the normal level, reduced growth in lactate medium indicated that the specific activity of this iso-l-cytochrome c in vivo is diminished relative to wild-type. On the other hand, the level of the thermodynamically labile N57G iso-1-cytochrome c was below normal. The in vivo levels of the N57I and N57G iso-l-cytochrome c suggest that proteins in the mitochondrial intermembrane space can be subjected to degradation, and that this degradation may play a role in controlling their normal levels.     

An extensive deletion causing overproduction of yeast iso-2-cytochrome c

CYC7-H3 is a cis-dominant regulatory mutation that causes a 20-fold overproduction of yeast iso-2-cytochrome c. The CYC7-H3 mutation is an approximately 5 kb deletion with one breakpoint located in the 5' noncoding region of the CYC7 gene, approximately 200 base from the ATG initiation codon. The deletion apparently fuses a new regulatory region to the structural portion of the CYC7 locus. The CYC7-H3 deletion encompasses the RAD23 locus, which controls UV sensitivity and the ANP1 locus, which controls osmotic sensitivity. The gene cluster CYC7-RAD23-ANP1 displays striking similarity to the gene cluster CYC1-OSM1-RAD7, which controls, respectively, iso-1-cytochrome c, osmotic sensitivity and UV sensitivity. We suggest that these gene clusters are related by an ancient transpositional event.     

Replacement of cysteine-107 of Saccharomyces cerevisiae iso-1-cytochrome c with threonine: improved stability of the mutant protein

Site-directed mutagenesis has been used to change the codon for cysteine-107 of Saccharomyces cerevisiae iso-1-cytochrome c to a threonine codon. The resulting protein is active in vivo, is methylated as in the wild-type protein and has optical properties indistinguishable from those of the wild-type protein. The threonine-107 iso-1-cytochrome c demonstrated fully reversible electrochemical behaviour and a mid-point reduction potential of 272 mV versus NHE. In addition, this mutant does not demonstrate a tendency to autoreduce or to dimerize as does the wild-type protein. These properties of the threonine-107 mutant establish that it will provide a useful background in which to make subsequent mutations for mechanistic and physical studies of yeast iso-1-cytochrome c.