Stereoselective in vitro formation of c-type cytochrome variants from Hydrogenobacter thermophilus containing only a single thioether bond

In vitro formation of Hydrogenobacter thermophilus cytochrome c552 has previously been demonstrated (Daltrop, O., Allen, J. W. A., Willis, A. C., and Ferguson, S. J. (2002) Proc. Natl. Acad. Sci. U. S. A. 99, 7872-7876). Now we report that the single cysteine variants of H. thermophilus c552, which bind heme via a single thioether bond, also form in vitro. Furthermore, reaction of the apocytochromes containing either AXXCH or CXXAH in the binding motif with 2-vinyldeuteroheme and 4-vinyldeuteroheme resulted predominantly in covalent attachment between Cys-11 and the 2-vinyl moiety and Cys-14 and the 4-vinyl functionality. This observation shows that the covalent attachment of heme to apocytochrome is stereoselective, indicating that the initial non-covalent complexes between apoprotein and heme have to be in the correct stereochemical orientation for preferential promotion of thioether bond formation. Additionally, the heme derivatives 2-vinyldeuteroheme and 4-vinyldeuteroheme were reacted with wild-type H. thermophilus c552 to yield another modification of cytochromes containing only one thioether bond. These results show that the formation of the two thioether bonds in typical c-type cytochromes can occur independently from one another. Aspects of rotational isomerism of heme in heme-proteins are discussed.     

The Escherichia coli cytochrome c maturation (Ccm) system does not detectably attach heme to single cysteine variants of an apocytochrome c

Cytochromes c are typically characterized by the covalent attachment of heme to polypeptide through two thioether bonds with the cysteine residues of a Cys-Xaa-Xaa-Cys-His peptide motif. In many Gram-negative bacteria, the heme is attached to the polypeptide by the periplasmically functioning cytochrome c maturation (Ccm) proteins. Exceptionally, Hydrogenobacter thermophilus cytochrome c(552), which has a normal CXXCH heme-binding motif, and variants with AXXCH, CXXAH, and AXXAH motifs, can be expressed as stable holocytochromes in the cytoplasm of Escherichia coli. By targeting these proteins to the periplasm using a signal peptide, with or without co-expression of the Ccm proteins, we have assessed the ability of the Ccm system to attach heme to proteins with no, one, or two cysteine residues in the heme-binding motif. Only the wild-type protein, with two cysteines, was effectively processed and thus accumulated in the periplasm as a holocytochrome. This is strong evidence for disulfide bond formation involving the two cysteine residues of apocytochrome c as an intermediate in Ccm-type Gram-negative bacterial cytochrome c biogenesis and/or that only a pair of cysteines can be recognized by the heme attachment apparatus.     

Loss of either of the two heme-binding cysteines from a class I c-type cytochrome has a surprisingly small effect on physicochemical properties

Almost without exception, c-type cytochromes have heme covalently attached via two thioether linkages to the cysteine residues of a CXXCH motif. The reasons for the covalent attachment are not understood. Reported here is cytoplasmic expression in Escherichia coli of AXXCH and CXXAH variants of cytochrome c(552) from Hydrogenobacter thermophilus; remarkably, the single thioether bond proteins have, apart from an altered visible absorption spectrum, almost identical properties, including thermal stability and reduction potential, to the wild type CXXCH protein. In combination with previous work showing that an AXXAH variant of cytochrome c(552) is much less stable than the CXXCH form, it can be concluded that covalent attachment of heme via either of thioether bonds is sufficient to confer considerable stability and that these bonds contribute little to the setting of the reduction potential. The absence of AXXCH or CXXAH heme-binding motifs from bacterial cytochromes c may relate to the coexistence of the assembly pathway with that for formation of disulfide bonds in the bacterial periplasm.     

Cytochrome c maturation. The in vitro reactions of horse heart apocytochrome c and Paracoccus dentrificans apocytochrome c550 with heme

C-type cytochromes are characterized by having the heme moiety covalently attached via thioether bonds between the heme vinyl groups and the thiols of conserved cysteine residues of the polypeptide chain. Previously, we have shown the in vitro formation of Hydrogenobacter thermophilus cytochrome c(552) (Daltrop, O., Allen, J. W. A., Willis, A. C., and Ferguson, S. J. (2002) Proc. Natl. Acad. Sci. U. S. A. 99, 7872-7876). In this work we report that thioether bonds can form spontaneously in vitro between heme and the apocytochromes c from horse heart and Paracoccus denitrificans via b-type cytochrome intermediates. Both apocytochromes, but not the holo forms, bind 8-anilino-1-naphthalenesulfonate, indicating that the apoproteins each have an affinity for a hydrophobic ligand. Furthermore, for both apocytochromes c an intramolecular disulfide can form between the cysteines of the CXXCH motif that is characteristic of c-type cytochromes. In vitro reaction of these apocytochromes c with heme to yield holocytochromes c, and the tendency to form a disulfide, have implications for the different systems responsible for cytochrome c maturation in vivo in various organisms.     

The cytochrome c fold can be attained from a compact apo state by occupancy of a nascent heme binding site

NMR techniques and 8-anilino-1-napthalenesulphonate (ANS) binding studies have been used to characterize the apo state of a variant of cytochrome c(552) from Hydrogenobacter thermophilus. In this variant the two cysteines that form covalent thioether linkages to the heme group have been replaced by alanine residues (C11A/C14A). CD studies show that the apo state contains approximately 14% helical secondary structure, and measurements of hydrodynamic radii using pulse field gradient NMR methods show that it is compact (R(h), 16.6 A). The apo state binds 1 mol of ANS/mol of protein, and a linear reduction in fluorescence enhancement is observed on adding aliquots of hemin to a solution of apo C11A/C14A cytochrome c(552) with ANS bound. These results suggest that the bound ANS is located in the heme binding pocket, which would therefore be at least partially formed in the apo state. Consistent with these characteristics, the formation of the holo state of the variant cytochrome c(552) from the apo state on the addition of heme has been demonstrated using NMR techniques. The properties of the apo state of C11A/C14A cytochrome c(552) reported here contrast strongly with those of mitochondrial cytochrome c whose apo state resembles a random coil under similar conditions.     

Oxidation-reduction properties of disulfide-containing proteins of the Rhodobacter capsulatus cytochrome c biogenesis system

Oxidation-reduction titrations for the active-site disulfide/dithiol couples of the helX- and ccl2-encoded proteins involved in cytochrome c biogenesis in the purple non-sulfur bacterium Rhodobacter capsulatus have been carried out. The R. capsulatus HelX and Ccl2 proteins are predicted to function as part of a dithiol/disulfide cascade that reduces a disulfide on the apocytochromes c so that two cysteine thiols are available to form thioether linkages between the heme prosthetic group and the protein. Oxidation-reduction midpoint potential (E(m)) values, at pH 7.0, of -300 +/- 10 and -210 +/- 10 mV were measured for the HelX and Ccl2 (a soluble, truncated form of Ccl2) R. capsulatus proteins, respectively. Titrations of the disulfide/dithiol couple of a peptide designed to serve as a model for R. capsulatus apocytochrome c(2) have also been carried out, and an E(m) value of -170 +/- 10 mV was measured for the model peptide at pH 7.0. E(m) versus pH plots for HelX, Ccl2, and the apocytochrome c(2) model peptide were all linear over the pH range from 5.0 to 8.0, with the -59 mV/pH unit slope expected for a reaction in which two protons are taken up for each disulfide that is reduced. These results provide thermodynamic support for the proposal that HelX reduces Ccl2 and that reduced Ccl2, in turn, serves as the reductant for the production of the two thiols of the CysXxxYyyCysHis heme-binding motif of the apocytochromes.     

Coupling of heme attachment to import of cytochrome c into yeast mitochondria. Studies with heme lyase-deficient mitochondria and altered apocytochromes c

Cytochrome c is synthesized in the cytoplasm as apocytochrome c, lacking heme, and then imported into mitochondria. The relationship between attachment of heme to the apoprotein and its import into mitochondria was examined using an in vitro system. Apocytochrome c transcribed and translated in vitro could be imported with high efficiency into mitochondria isolated from normal yeast strains. However, no import of apocytochrome c occurred with mitochondria isolated from cyc3- strains, which lack cytochrome c heme lyase, the enzyme catalyzing covalent attachment of heme to apocytochrome c. In addition, amino acid substitutions in apocytochrome c at either of the 2 cysteine residues that are the sites of the thioether linkages to heme, or at an immediately adjacent histidine that serves as a ligand of the heme iron, resulted in a substantial reduction in the ability of the precursor to be translocated into mitochondria. Replacement of the methionine serving as the other iron ligand, on the other hand, had no detectable effect on import of apocytochrome c in this system. Thus, covalent heme attachment is a required step for import of cytochrome c into mitochondria. Heme attachment, however, can occur in the absence of mitochondrial import since we have detected CYC3-encoded heme lyase activity in solubilized yeast extracts and in an Escherichia coli expression system. These results suggest that protein folding triggered by heme attachment to apocytochrome c is required for import into mitochondria.     

Evidence for formation of two thioether bonds to link heme to apocytochrome c by partially purified cytochrome c synthetase

Cytochrome c synthetase has been solubilized from yeast mitochondria using Triton X-100 and fractionated with ammonium sulfate. Use of this partially purified enzyme has permitted us to isolate a quantity of iso-1-cytochrome c formed from 125I-labeled apocytochrome c and hemin in the presence of a NADPH-generating system. Visible absorption spectra (pH 8.0 or 5.0) including alpha, beta, and Soret bands and their molar absorption coefficients of this enzymatically synthesized cytochrome c in the oxidized and reduced states are the same, within experimental error, as those of native cytochrome c. Pyridine ferrohemochrome (pH 13) of the synthesized species also exhibits the same alpha and beta bands as those of iso-l-cytochrome c and similar to those reported for heme peptides of cytochrome c. If only one or no thioether bond were formed between the two vinyl side groups of heme and the cysteine residues of apocytochrome c, all these alpha and beta bands would have shifted to red (Pettigrew, G. W., Leaver, J. L., Meyer, T. E., and Ryle, T. E. (1975) Biochem J. 147, 291-302). Thus, two thioether bonds appear to be formed to link heme to apocytochrome c by cytochrome c synthetase, completing information of the three-dimensional structure of cytochrome c.     

Amyloid fibril formation by a helical cytochrome

The substitution of alanines for the two cysteines which form thioether linkages to the haem group in cytochrome c(552) from Hydogenobacter thermophilus destabilises the native protein fold. The holo form of this variant slowly converts into a partially folded apo state that over prolonged periods of time aggregates into fibrillar structures. Characterisation of these structures by electron microscopy and thioflavin-T binding assays shows that they are amyloid fibrils. The data demonstrate that when the native state of this cytochrome is destabilised by loss of haem, even this highly alpha-helical protein can form beta-sheet structures of the type most commonly associated with protein deposition diseases.     

Import of cytochrome c into mitochondria. Cytochrome c heme lyase

The import of cytochrome c into mitochondria can be resolved into a number of discrete steps. Here we report on the covalent attachment of heme to apocytochrome c by the enzyme cytochrome c heme lyase in mitochondria from Neurospora crassa. A new method was developed to measure directly the linkage of heme to apocytochrome c. This method is independent of conformational changes in the protein accompanying heme attachment. Tryptic peptides of [35S]cysteine-labelled apocytochrome c, and of enzymatically formed holocytochrome c, were resolved by reverse-phase HPLC. The cysteine-containing peptide to which heme was attached eluted later than the corresponding peptide from apocytochrome c and could be quantified by counting 35S radioactivity as a measure of holocytochrome c formation. Using this procedure, the covalent attachment of heme to apocytochrome c, which is dependent on the enzyme cytochrome c heme lyase, could be measured. Activity required heme (as hemin) and could be reversibly inhibited by the analogue deuterohemin. Holocytochrome c formation was stimulated 5--10-fold by NADH greater than NADPH greater than glutathione and was independent of a potential across the inner mitochondrial membrane. NADH was not required for the binding of apocytochrome c to mitochondria and was not involved in the reduction of the cysteine thiols prior to heme attachment. Holocytochrome c formation was also dependent on a cytosolic factor that was necessary for the heme attaching step of cytochrome c import. The factor was a heat-stable, protease-insensitive, low-molecular-mass component of unknown function. Cytochrome c heme lyase appeared to be a soluble protein located in the mitochondrial intermembrane space and was distinct from the previously identified apocytochrome c binding protein having a similar location. A model is presented in which the covalent attachment of heme by cytochrome c heme lyase also plays an essential role in the import pathway of cytochrome c.     

Cytochrome c(552) from Thermus thermophilus engineered for facile substitution of prosthetic group

The facile replacement of heme c in cytochromes c with non-natural prosthetic groups has been difficult to achieve due to two thioether linkages between cysteine residues and the heme. Fee et al. demonstrated that cytochrome c(552) from Thermus thermophilus, overproduced in the cytosol of E. coli, has a covalent linkage cleavable by heat between the heme and Cys11, as well as possessing the thioether linkage with Cys14 [Fee, J. A. (2004) Biochemistry 43, 12162-12176]. Prompted by this result, we prepared a C14A mutant, anticipating that the heme species in the mutant was bound to the polypeptide solely through the thermally cleavable linkage; therefore, the removal of the heme would be feasible after heating the protein. Contrary to this expectation, C14A immediately after purification (as-purified C14A) possessed no covalent linkage. An attempt to extract the heme using a conventional acid-butanone method was unsuccessful due to rapid linkage formation between the heme and polypeptide. Spectroscopic analyses suggested that the as-purified C14A possessed a heme b derivative where one of two peripheral vinyl groups had been replaced with a group containing a reactive carbonyl. A reaction of the as-purified C14A with [BH(3)CN](-) blocked the linkage formation on the carbonyl group, allowing a quantitative yield of heme-free apo-C14A. Reconstitution of apo-C14A was achieved with ferric and ferrous heme b and zinc protoporphyrin. All reconstituted C14As showed spontaneous covalent linkage formation. We propose that C14A is a potential source for the facile production of an artificial cytochrome c, containing a non-natural prosthetic group.     

Studies on cytochrome c oxidase activity of the cytochrome c1aa3 complex from Thermus thermophilus

Cytochrome oxidase from T. thermophilus is isolated as a noncovalent complex of cytochromes c1 and aa3 in which the four redox components of aa3 appear to be associated with a single approximately 55,000-D subunit while the heme C is associated with a approximately 33,000-D peptide (Yoshida, T., Lorence, R. M., Choc, M. G., Tarr, G. E., Findling, K. L., and Fee, J. A. (1983) J. Biol. Chem. 258, 112-123). We have examined the steady state transfer of electrons from ascorbate to oxygen by cytochrome c1aa3 as mediated by horse heart, Candida krusei, and T. thermophilus (c552) cytochromes c as well as tetramethylphenylenediamine (TMPD). These mediators exhibit simple Michaelis-Menten kinetic behavior yielding Vmax and KM values characteristic of the experimental conditions. Three classes of kinetic behavior were observed and are qualitatively discussed in terms of a reaction scheme. The data show that tetramethylphenyldiamine and cytochromes c react with the enzyme at independent sites; it is suggested that cytochrome c1 may efficiently transfer electrons to cytochrome aa3. When incorporated into phospholipid vesicles, the highly purified cytochrome c1aa3 was found to translocate one proton into the exterior medium for each molecule of cytochrome c552 oxidized. The combined results suggest that this bacterial enzyme functions in a manner generally identical with the more complex eucaryotic enzyme.     

A homolog of prokaryotic thiol disulfide transporter CcdA is required for the assembly of the cytochrome b6f complex in Arabidopsis chloroplasts

The c-type cytochromes are defined by the occurrence of heme covalently linked to the polypeptide via thioether bonds between heme and the cysteine sulfhydryls in the CXXCH motif of apocytochrome. Maintenance of apocytochrome sulfhydryls in a reduced state is a prerequisite for covalent ligation of heme to the CXXCH motif. In bacteria, a thiol disulfide transporter and a thioredoxin are two components in a thio-reduction pathway involved in c-type cytochrome assembly. We have identified in photosynthetic eukaryotes nucleus-encoded homologs of a prokaryotic thiol disulfide transporter, CcdA, which all display an N-terminal extension with respect to their bacterial counterparts. The extension of Arabidopsis CCDA functions as a targeting sequence, suggesting a plastid site of action for CCDA in eukaryotes. Using PhoA and LacZ as topological reporters, we established that Arabidopsis CCDA is a polytopic protein with within-membrane strictly conserved cysteine residues. Insertional mutants in the Arabidopsis CCDA gene were identified, and loss-of-function alleles were shown to impair photosynthesis because of a defect in cytochrome b(6)f accumulation, which we attribute to a block in the maturation of holocytochrome f, whose heme binding domain resides in the thylakoid lumen. We postulate that plastid cytochrome c maturation requires CCDA, thioredoxin HCF164, and other molecules in a membrane-associated trans-thylakoid thiol-reducing pathway.     

Stabilization mechanism of cytochrome c552 from a moderately thermophilic bacterium, Hydrogenophilus thermoluteolus

Cytochrome c(552) (PH c(552)) from moderately thermophilic Hydrogenophilus thermoluteolus exhibits stability intermediate between those of cytochrome c(552) (HT c(552)) from thermophilic Hydrogenobacter thermophilus and cytochrome c(551) (PA c(551)) from mesophilic Pseudomonas aeruginosa. To understand the mechanism of stabilization of PH c(552), we introduced mutations into PH c(552) at five sites, which, in HT c(552), are occupied by the amino acids responsible for stability higher than the less stable PA c(551). When PH c(552) Val-78 was mutated to Ile, as found in HT c(552), the resulting variant showed increased stability. Mutation of Ala-7, Met-13, and Tyr-34 to the corresponding residues in PA c(551) (Phe, Val, and Phe, respectively) resulted in destabilization. We also found that PH c(552) Lys-43 contributed to stability through the formation of an attractive electrostatic interaction with Asp-39. These results suggest that the intermediate stability of PH c(552) is due to the amino acids at these five sites.     

The reactivity of thiols and disulfides with different redox states of myoglobin. Redox and addition reactions and formation of thiyl radical intermediates.

The reactivity of several thiols, including glutathione, dihydrolipoic acid, cysteine, N-acetyl cysteine, and ergothioneine, as well as several disulfides, toward different redox states of myoglobin, mainly met-myoglobin (HX-FeIII) and ferrylmyoglobin (HX-FeIV=O), was evaluated by optical spectral analysis, product formation, and thiyl free radical generation. Only dihydrolipoic acid reduced met-myoglobin to oxy-myoglobin, whereas all the other thiols tested did not interact with met-myoglobin. Although the redox transitions involved in the former reduction were expected to yield the dihydrolipoate thiyl radical, the reaction was EPR silent. Conversely, all thiols interacted to different extent with the high oxidation state of myoglobin, i.e. ferrylmyoglobin, via two processes. First, direct electron transfer to heme iron in ferrylmyoglobin (HX-FeIV=O) with formation of met-myoglobin (HX-FeIII) or oxymyoglobin (HX-FeIIO2); the former transition was effected by all thiols except dihydrolipoate, which facilitated the latter, i.e. the formation of the two-electron reduction product of ferrylmyoglobin. Second, nucleophilic addition onto a pyrrole in ferrylmyoglobin with subsequent formation of sulfmyoglobin. The contribution of either direct electron transfer to the heme iron or nucleophilic addition depended on the physicochemical properties of the thiol involved and on the availability of H2O2 to reoxidize met-myoglobin to ferrylmyoglobin. The thiyl radicals of glutathione, cysteine, and N-acetylcysteine were formed during the interaction of the corresponding thiols with ferrylmyoglobin and detected by EPR in conjunction with the spin trap 5,5'-dimethyl-1-pyroline-N-oxide. The intensity of the EPR signal was insensitive to superoxide dismutase and it was decreased, but not suppressed, by catalase. The disulfides of glutathione and cysteine did not react with ferrylmyoglobin, but the disulfide bridge in lipoic acid interacted efficiently with the ferryl species by either reducing directly the heme iron to form met-myoglobin or adding onto a pyrrole ring to form sulfmyoglobin; either process depended on the presence or absence of catalase (to eliminate the excess of H2O2) in the reaction mixture, respectively. The biological significance of the above results is discussed in terms of the occurrence and distribution of high oxidation states of myoglobin, its specific participation in cellular injury, and its potential interaction with biologically important thiols leading to either recovery of myoglobin or generation of nonfunctional forms of the hemoprotein as sulfmyoglobin.     

Cytochrome c maturation system on the negative side of bioenergetic membranes: CCB or System IV

Cytochromes of the c-type contain hemes covalently attached via one or, more generally, two thioether bonds between the vinyls of heme b and the thiols of cysteine residues of apocytochromes. This post-translational modification relies on membrane-associated specific biogenesis proteins, referred to as cytochrome c maturation systems. At least three different versions (i.e. Systems I-III) are found on the positive side of bioenergetic membranes in different organisms and compartments. The present minireview is concerned with systems on the negative side of the membranes. It describes System IV, also referred to as cofactor assembly on complex C subunit B, for heme binding on cytochrome b(6) through one thioether bond; this covalent heme is usually called c(i) . This system is found in all organisms with oxygenic photosynthesis but not in Firmicutes, although they also have a cytochrome b protein with an additional heme c(i) covalently attached via a single thioether bond.     

Improving the stability of thiol–maleimide bioconjugates via the formation of a thiazine structure

Linker stability is critically important for the efficacy and safety of peptide and protein conjugates used for biological applications. One common conjugation strategy, thiol–maleimide coupling, generates a succinimidyl thioether linker with limited stability under physiological conditions. We have shown in previous work that when a peptide with an N-terminal cysteine is conjugated to a maleimide reagent, a thiazine structure is formed via a chemical rearrangement. Our preliminary work indicated that the thiazine linker has favorable stability. Here, we report the evaluation of a thiazine linker as an alternative to the widely used succinimidyl thioether linker for thiol–maleimide bioconjugation. The stability of the thiazine conjugate in comparison to the thioether conjugate was assessed across a broad pH range. Additionally, the propensity for retro-Michael reaction and cross-reactivity with other thiols was evaluated by treating conjugates in the presence of glutathione. The studies indicated that the thiazine linker degrades markedly slower than the thioether conjugate. In addition, the thiazine linker is over 20 times less susceptible to glutathione adduct formation. The NMR study of the thiazine structure confirmed that the formation of the thiazine linker is a stereoselective process that yields a single diastereomer. In summary, we propose the use of the thiazine linker obtained by conjugation of maleimide-containing reagents with peptides or proteins presenting an N-terminal cysteine as a novel approach for bioconjugation. The advantages of this approach are the formation of a linker with a well-defined stereochemical configuration, increased stability at physiological pH, and a strongly reduced propensity for thiol exchange.     

Mechanistic studies of rat protein farnesyltransferase indicate an associative transition state

Protein farnesyltransferase is a zinc metalloenzyme that catalyzes the transfer of a 15-carbon farnesyl group to a conserved cysteine residue of a protein substrate. Both electrophilic and nucleophilic mechanisms have been proposed for this enzyme. In this work, we investigate the detailed catalytic mechanism of mammalian protein farnesyltransferase by measuring the effect of metal substitution and/or substrate alterations on the rate constant of the chemical step. Substitution of cadmium for the active site zinc enhances peptide affinity approximately 5-fold and decreases the rate constant for the formation of the thioether product approximately 6-fold, indicating changes in the metal-thiolate coordination in the catalytic transition state. In addition, the observed rate constant for product formation decreases for C3 fluoromethyl farnesyl pyrophosphate substrates, paralleling the number of fluorines at the C3 methyl position and indicating that a rate-contributing transition state has carbocation character. Magnesium ions do not affect the affinity of either the peptide or the isoprenoid substrate but specifically enhance the observed rate constant for product formation 700-fold, suggesting that magnesium coordinates and activates the diphosphate leaving group. These data suggest that FTase catalyzes protein farnesylation by an associative mechanism with an "exploded" transition state where the metal-bound peptide/protein sulfur has a partial negative charge, the C1 of FPP has a partial positive charge, and the bridge oxygen between C1 and the alpha phosphate of FPP has a partial negative charge. This proposed transition state suggests that stabilization of the developing charge on the carbocation and pyrophosphate oxygens is an important catalytic feature.     

Different redox states of metallothionein/thionein in biological tissue

Mammalian metallothioneins are redox-active metalloproteins. In the case of zinc metallothioneins, the redox activity resides in the cysteine sulfur ligands of zinc. Oxidation releases zinc, whereas reduction re-generates zinc-binding capacity. Attempts to demonstrate the presence of the apoprotein (thionein) and the oxidized protein (thionin) in tissues posed tremendous analytical challenges. One emerging strategy is differential chemical modification of cysteine residues in the protein. Chemical modification distinguishes three states of the cysteine ligands (reduced, oxidized and metal-bound) based on (i) quenched reactivity of the thiolates when bound to metal ions and restoration of thiol reactivity in the presence of metal-ion-chelating agents, and (ii) modification of free thiols with alkylating agents and subsequent reduction of disulfides to yield reactive thiols. Under normal physiological conditions, metallothionein exists in three states in rat liver and in cell lines. Ras-mediated oncogenic transformation of normal HOSE (human ovarian surface epithelial) cells induces oxidative stress and increases the amount of thionin and the availability of cellular zinc. These experiments support the notion that metallothionein is a dynamic protein in terms of its redox state and metal content and functions at a juncture of redox and zinc metabolism. Thus redox control of zinc availability from this protein establishes multiple methods of zinc-dependent cellular regulation, while the presence of both oxidized and reduced states of the apoprotein suggest that they serve as a redox couple, the generation of which is controlled by metal ion release from metallothionein.