Cooperative disulfide bond formation in apamin.

Apamin is being studied as a model for the folding mechanism of proteins whose structures are stabilized by disulfide bonds. Apamin consists of 18 amino acid residues and forms a stable structure consisting of a C-terminal alpha-helix and two reverse turns. This structure is stabilized by two disulfide bonds connecting Cys-1 to Cys-11 and Cys-3 to Cys-15. We used glutathione and dithiothreitol as reference thiols to measure the stabilities of the two disulfide bonds as a function of urea concentration and temperature in order to understand what contributes to the stability of the native structure. The results demonstrate modest contributions from secondary structure to the overall stability of the two disulfide bonds. The equilibrium constants for disulfide bond formation between the fully reduced peptide and the native structure with two disulfide bonds at 25 degrees C and pH 7.0 are 0.42 M2 using glutathione and 2.7 x 10(-5) using dithiothreitol. The equilibrium constant decreases by a factor of approximately 4 in 8 M urea and decreases by a factor of 3 between 0 and 60 degrees C. At least three one-disulfide intermediates are found at low concentrations in the equilibrium mixture. Using glutathione, the equilibrium constants for forming the one-disulfide intermediates with respect to the reduced peptide are approximately 0.025 M. The second disulfide bond forms with an equilibrium constant of approximately 17 M. Thus, apamin folding is very cooperative, but the native structure is only modestly stabilized by urea- or temperature-denaturable secondary structure.     

Early events in the disulfide-coupled folding of BPTI.

Recent studies of the refolding of reduced bovine pancreatic trypsin inhibitor (BPTI) have shown that a previously unidentified intermediate with a single disulfide is formed much more rapidly than any other one-disulfide species. This intermediate contains a disulfide that is present in the native protein (between Cys14 and 38), but it is thermodynamically less stable than the other two intermediates with single native disulfides. To characterize the role of the [14-38] intermediate and the factors that favor its formation, detailed kinetic and mutational analyses of the early disulfide-formation steps were carried out. The results of these studies indicate that the formation of [14-38] from the fully reduced protein is favored by both local electrostatic effects, which enhance the reactivities of the Cys14 and 38 thiols, and conformational tendencies that are diminished by the addition of urea and are enhanced at lower temperatures. At 25 degrees C and pH 7.3, approximately 35% of the reduced molecules were found to initially form the 14-38 disulfide, but the majority of these molecules then undergo intramolecular rearrangements to generate non-native disulfides, and subsequently the more stable intermediates with native disulfides. Amino acid replacements, other than those involving Cys residues, were generally found to have only small effects on either the rate of forming [14-38] or its thermodynamic stability, even though many of the same substitutions greatly destabilized the native protein and other disulfide-bonded intermediates. In addition, those replacements that did decrease the steady-state concentration of [14-38] did not adversely affect further folding and disulfide formation. These results suggest that the weak and transient interactions that are often detected in unfolded proteins and early folding intermediates may, in some cases, not persist or promote subsequent folding steps.     

Role of disulfide bonds in folding and activity of leiurotoxin I: just two disulfides suffice

The aim of this study is to investigate the contribution of each disulfide bond in the folding and function of leiurotoxin I, a short scorpion toxin that blocks small conductance K(+) channels. The structure of leiurotoxin I contains a motif conserved in all scorpion toxins, formed by a helix and a double-stranded beta-sheet and stabilized by three disulfide bridges. We synthesized three analogues, each presenting two alpha-aminobutyric acid (Abu) moieties replacing two bridged cysteine residues: LeTx1 ([Abu 3,21] Leiurotoxin I), LeTx2 ([Abu 8,26] Leiurotoxin I), and LeTx3 ([Abu 12,28] Leiurotoxin I). All three analogues fold into a major product containing two native disulfide bonds, while LeTx3 forms an additional isomer, containing non-native disulfides. In denaturing conditions, analogues LeTx2 and LeTx3 yield non-native isomers, while LeTx1 only forms the isomer with native disulfides. All isomers with native disulfides contain nativelike alpha-helical conformations and bind to synaptosomal membranes with affinities within a log of that shown by the native toxin. By contrast, the non-native LeTx3A analogue exhibits a disordered conformation and a decreased biological potency. Our results indicate that the "CxxxC, CxC" cysteine spacing, conserved in all scorpion toxins and preserved in LeTx1, may play an active role in folding, and that only two native disulfide bonds in leiurotoxin I are sufficient to preserve a nativelike and active conformation. Thus, in the scorpion toxin scaffold, modifications of conserved and interior cysteine residues may permit modulation of function, without significantly affecting folding efficiency and structure.     

Role of disulfide bridges in the folding, structure and biological activity of omega-conotoxin GVIA.

Omega-Conotoxin GVIA (GVIA), an N-type calcium channel blocker from the cone shell Conus geographus, is a 27 residue polypeptide cross-linked by three disulfide bonds. Here, we report the synthesis, structural analysis by (1)H NMR and bioassay of analogues of GVIA with disulfide bridge deletions and N- and C-terminal truncations. Two analogues that retain the crucial Lys-2 and Tyr-13 residues in loops constrained by two native disulfide bridges were synthesised using orthogonal protection of cysteine residues. In the first analogue, the Cys-15-Cys-26 disulfide bridge was deleted (by replacing the appropriate Cys residues with Ser), while in the second, this disulfide bridge and the eight C-terminal residues were deleted. No activity was detected for either analogue in a rat vas deferens assay, which measures N-type calcium channel activity in sympathetic nerve, and NMR studies showed that this was due to a gross loss of secondary and tertiary structure. Five inactive analogues that were synthesised without orthogonal protection of Cys residues as part of a previous study (Flinn et al. (1995) J. Pept. Sci. 1, 379-384) were also investigated. Three had single disulfide deletions (via Ser substitutions) and two had N- or C-terminal deletions in addition to the disulfide deletion. Peptide mapping and NMR analyses demonstrated that at least four of these analogues had non-native disulfide pairings, which presumably accounts for their lack of activity. The NMR studies also showed that all five analogues had substantially altered tertiary structures, although the backbone chemical shifts and nuclear Overhauser enhancements (NOEs) implied that native-like turn structures persisted in some of these analogues despite the non-native disulfide pairings. This work demonstrates the importance of the disulfides in omega-conotoxin folding and shows that the Cys-15-Cys-26 disulfide is essential for activity in GVIA. The NMR analyses also emphasise that backbone chemical shifts and short- and medium-range NOEs are dictated largely by local secondary structure elements and are not necessarily reliable monitors of the tertiary fold.     

Urea dependence of thiol-disulfide equilibria in thioredoxin: confirmation of the linkage relationship and a sensitive assay for structure

Thioredoxin contains a single disulfide bond that can be reduced without perturbing significantly the structure of the enzyme. Upon reduction of the disulfide, protein stability decreases. We have experimentally tested the expected linkage relationship between disulfide bond formation and protein stability for thioredoxin. In order to do this, it is necessary to measure the equilibrium constant for disulfide bond formation in both the folded and unfolded states of the protein. Using glutathione as a reference species, we have measured the equilibrium constant for forming the disulfide bond (effective concentration) in thioredoxin as a function of urea concentration. As a control, we show that urea per se does not interfere with our measurements of thiol-disulfide equilibrium constants. Comparison of the values obtained for disulfide bond formation in the folded and unfolded states with the free energies for unfolding oxidized and reduced thioredoxin using circular dichroism confirms the expected linkage relationship. The urea dependence of thiol-disulfide equilibria provides a sensitive assay for folded structure in peptides or proteins. The method should also be useful to evaluate the stabilizing or destabilizing effect of natural or genetically engineered disulfides in proteins. In future work, the effects of amino acid substitutions on disulfide bond formation could be evaluated individually in the native and unfolded states of a protein.     

Structural stability of human alpha-thrombin studied by disulfide reduction and scrambling

Human alpha-thrombin is a very important plasma serine protease, which is involved in physiologically vital processes like hemostasis, thrombosis, and activation of platelets. Knowledge regarding the structural stability of alpha-thrombin is essential for understanding its biological regulation. Here, we investigated the structural and conformational stability of alpha-thrombin using the techniques of disulfide reduction and disulfide scrambling. alpha-Thrombin is composed of a light A-chain (36 residues) and a heavy B-chain (259 residues) linked covalently by an inter-chain disulfide bond (Cys(1)-Cys(122)). The B-chain is stabilized by three intra-chain disulfide bonds (Cys(42)-Cys(58), Cys(168)-Cys(182), and Cys(191)-Cys(220)) (Chymotrypsinogen nomenclature). Upon reduction with dithiothreitol (DTT), alpha-thrombin unfolded in a 'sequential' manner with sequential reduction of Cys(168)-Cys(182) within the B-chain followed by the inter-chain disulfide, generating two distinct partially reduced intermediates, I-1 and I-2, respectively. Conformational stability of alpha-thrombin was investigated by the technique of disulfide scrambling. alpha-Thrombin denatures by scrambling its native disulfide bonds in the presence of denaturant [urea, guanidine hydrochloride (GdmCl) or guanidine thiocyanate (GdmSCN)] and a thiol initiator. During the process, cleavage of the inter-chain disulfide bond and release of the A-chain from B-chain was the foremost event. The three disulfides in the B-chain subsequently scrambled to form three major isomers (designated as X-Ba, X-Bb, and X-Bc). Complete denaturation of alpha-thrombin was observed at low concentrations of denaturants (0.5 M GdmSCN, 1.5 M GdmCl, or 3 M urea) indicating low conformational stability of the protease.     

Factors governing selective formation of specific disulfides in synthetic variants of alpha-conotoxin

alpha-Conotoxin GI is a snail toxin protein consisting of 13 amino acids cross-linked by 2 intramolecular disulfide bridges. This toxin is an antagonist of acetylcholine receptors. The native sequence has been synthesized, along with nine additional variants in which non-cysteine residues are replaced by alanine or the cysteine positions are altered. Each reduced peptide has been oxidized by reaction with oxygen or glutathione both in a folding buffer and in 6 M guanidine hydrochloride. Purified products of oxidation have been characterized with respect to molecular weights and the positions of disulfides. The four cysteines in conotoxin can form two intramolecular disulfides in three different combinations. Relative yields of each of the three isomers have been determined, thereby permitting evaluation of the roles of non-cysteine residues and cysteine placements in the folding of conotoxin. Cysteine positions dominate factors directing formation of the nativelike isomer in a manner that may be predicted from equilibrium constants for loop formation in model peptides containing two cysteines. Alanine substitutions at several positions which are conserved in naturally occurring conotoxins affect the discrimination between the two most favored disulfide arrangements. Substitutions at three nonconserved positions have no structural effect on isomer yields. It therefore is possible to vary these latter three positions in a manner which might help to generate a functional binding surface which is complementary to receptors in the specific prey of a particular species of snail, without affecting the toxin's folding.     

Size-exclusion high performance liquid chromatography of native trypsinogen, the denatured protein, and partially refolded molecules. Further evidence that non-native disulfide bonds are dominant in refolding the completely reduced protein

Size-exclusion high performance liquid chromatography was used to compare the Stokes radius of the mixed disulfide of trypsinogen refolded for 10 min with the Stokes radius of denatured trypsinogen in high concentrations of urea. After folding for 10 min, rechromatography of a collection of sequential fractions of an initial separation showed that the fractions display microheterogeneity as seen in the value of the Stokes radius of each fraction. These intermediate species differed in their Stokes radius, and each had a globular structure cross-linked by disulfide bonds. In contrast, when trypsinogen with the native disulfides intact was equilibrated at different concentrations of urea (0-8 M), a progressive increase in Stokes radius was observed with extent of unfolding. Rechromatography of a series of fractions collected at a specific urea concentration showed that each had the same Stokes radius as the fraction in the initial separation. Urea-denatured trypsinogen and partially refolded trypsinogen must therefore differ in the disulfide pairing that links regions of the polypeptide chain. These observations support the suggestion that non-native disulfide bonds are responsible for the many stable conformations that form early in the folding of the mixed disulfide of trypsinogen (Light, A., and Higaki, J.N. (1987) Biochemistry 26, 5556-5564). These intermediates initially are loose structures (large Stokes radius) that become more compact with time (decreasing Stokes radius). The intermediates must therefore undergo a continuing disulfide interchange until native disulfides form late in the process when the stable conformation of the native molecule is reached.     

Analysis of the disulfide bonding pattern between domain sequences of recombinant prochymosin solubilized from inclusion bodies

Prochymosin contains three disulfide bonds linking Cys45 to Cys50, Cys206 to Cys210, and Cys250 to Cys283. To analyze the disulfide bonding pattern between domain sequences in the recombinant prochymosin molecule solubilized from inclusion bodies by 8 M urea (designated as solubilized prochymosin), a simple peptide mapping method was established. This process consists of thiol alkylation, cleavage with cyanogen bromide, diagonal electrophoresis on polyacrylamide gel, and N-terminal sequencing. By using this procedure it was found that Cys45 and Cys50 located in the N-terminal domain are not mispaired with the cysteine residues, located in the C-terminal domain, in the solubilized wild-type prochymosin and its mutants. This result implies that Cys45 and Cys50, the partners of a native disulfide, are restricted in some ordered structures existing in inclusion bodies and remaining after solubilization. These native structural elements act as folding nuclei to initiate and facilitate correct refolding. The strategy of preserving the native-like structures including native disulfide in the solubilized inclusion bodies to enhance renaturation efficiency may be applicable to other recombinant proteins.Both authors contributed equally to this work     

Evidence for intramolecular disulfide bond shuffling in the folding of mutant human lysozyme

Our previous results using the Saccharomyces cerevisiae secretion system suggest that intramolecular exchange of disulfide bonds occurs in the folding pathway of human lysozyme in vivo (Taniyama, Y., Yamamoto, Y., Kuroki, R., and Kikuchi, M. (1990) J. Biol. Chem. 265, 7570-7575). Here we report on the results of introducing an artificial disulfide bond in mutants with 2 cysteine residues substituting for Ala83 and Asp91. The mutant (C83/91) protein was not detected in the culture medium of the yeast, probably because of incorrect folding. Thereupon, 2 cysteine residues Cys77 and Cys95 were replaced with Ala in the mutant C83/91, because a native disulfide bond Cys77-Cys95 was found not necessary for correct folding in vivo (Taniyama, Y., Yamamoto, Y., Nakao, M., Kikuchi, M., and Ikehara, M. (1988) Biochem. Biophys. Res. Commun. 152, 962-967). The resultant mutant (AC83/91) was secreted as two proteins (AC83/91-a and AC83/91-b) with different specific activities. Amino acid and peptide mapping analyses showed that two glutathiones appeared to be attached to the thiol groups of the cysteine residues introduced into AC83/91-a and that four disulfide bonds including an artificial disulfide bond existed in the AC83/91-b molecule. The presence of cysteine residues modified with glutathione may indicate that the non-native disulfide bond Cys83-Cys91 is not so easily formed as a native disulfide bond. These results suggest that the introduction of Cys83 and Cys91 may act to suppress the process of native disulfide bond formation through disulfide bond interchange in the folding of human lysozyme.     

Disulfide bond rearrangement during formation of the chorionic gonadotropin beta-subunit cystine knot in vivo

The intracellular kinetic folding pathway of the human chorionic gonadotropin beta-subunit (hCG-beta) reveals the presence of a disulfide between Cys residues 38-57 that is not detected by X-ray analysis of secreted hCG-beta. This led us to propose that disulfide rearrangement is an essential feature of cystine knot formation during CG-beta folding. To test this, we used disulfide bond formation to monitor progression of intracellular folding intermediates of a previously uncharacterized protein, the CG-beta subunit of cynomolgous macaque (Macaca fascicularis). Like its human counterpart hCG-beta with which it shares 81% identity, macaque (m)CG-beta is a cystine knot-containing subunit that assembles with an alpha-subunit common to all glycoprotein hormone members of its species to form a biologically active heterodimer, mCG, which, like hCG, is required for pregnancy maintenance. An early mCG-beta folding intermediate, mpbeta1, contained two disulfide bonds, one between Cys34 and Cys88 and the other between Cys38 and Cys57. The subsequent folding intermediate, mpbeta2-early, was represented by an ensemble of folding forms that, in addition to the two disulfides mentioned above, included disulfide linkages between Cys9 and Cys57 and between Cys38 and Cys90. These latter two disulfides are those contained within the beta-subunit cystine knot and reveal that a disulfide exchange occurred during the mpbeta2-early folding step leading to formation of the mCG-beta knot. Thus, while defining the intracellular kinetic protein folding pathway of a monkey homologue of CG-beta, we detected the previously predicted disulfide exchange event crucial for CG-beta cystine knot formation and attainment of CG-beta assembly competence.     

Stabilities of disulfide bond intermediates in the folding of apamin.

Apamin is an 18-residue bee venom peptide with the sequence CNCKAPETALCARRCQQH-amide and contains 2 disulfide bonds connecting C-1 to C-11 and C-3 to C-15. In the folding of reduced, unfolded apamin to native apamin with two disulfide bonds, the one-disulfide folding intermediate states are not populated to significant levels. To study the properties of the one-disulfide intermediates, we have synthesized two peptide models to mimic the one-disulfide intermediates, Apa-1 and Apa-2, in which two cysteines in the sequence have been replaced by alanines. These peptides can form only one of the native disulfide bonds, C-1 to C-11 in the case of Apa-1 and C-3 to C-15 in the case of Apa-2. The stabilities of these disulfide bonds have been measured as a function of pH, concentration of urea, and temperature, in order to understand which contributions stabilize the disulfide-bonded structures. Using oxidized and reduced glutathione, the equilibrium constants for forming the disulfide bonds at 25 degrees C and pH 7.0 are 0.018 M for Apa-1 and 0.033 M for Apa-2 and show little dependence on pH or temperature. Both disulfide bonds are destabilized slightly (by approximately a factor of 2) between 0 and 8 M urea. Circular dichroism spectra indicate that although both Apa-1 and Apa-2 exhibit some structure, Apa-2 exhibits more than Apa-1. The results suggest that in the folding of apamin, the one-disulfide intermediate containing the C-3 to C-15 disulfide bond, as in Apa-2, is favored slightly. Secondary structure provides modest stabilization to this intermediate.     

Stability and structure-forming properties of the two disulfide bonds of alpha-conotoxin GI

alpha-Conotoxin GI is a 13 residue snail toxin peptide cross-linked by Cys2-Cys7 and Cys3-Cys13 disulfide bridges. The formation of the two disulfide bonds by thiol/disulfide exchange with oxidized glutathione (GSSG) has been characterized. To characterize formation of the first disulfide bond in each of the two pathways by which the two disulfide bonds can form, two model peptides were synthesized in which Cys3 and Cys13 (Cono-1) or Cys2 and Cys7 (Cono-2) were replaced by alanines. Equilibrium constants were determined for formation of the single disulfide bonds of Cono-1 and Cono-2, and an overall equilibrium constant was measured for formation of the two disulfide bonds of alpha-conotoxin GI in pH 7.00 buffer and in pH 7. 00 buffer plus 8 M urea using concentrations obtained by HPLC analysis of equilibrium thiol/disulfide exchange reaction mixtures. The results indicate a modest amount of cooperativity in the formation of the second disulfide bond in both of the two-step pathways by which alpha-conotoxin GI folds into its native structure at pH 7.00. However, when considered in terms of the reactive thiolate species, the results indicate substantial cooperativity in formation of the second disulfide bond. The solution conformational and structural properties of Cono-1, Cono-2, and alpha-conotoxin GI were studied by 1H NMR to identify structural features which might facilitate formation of the disulfide bonds or are induced by formation of the disulfide bonds. The NMR data indicate that both Cono-1 and Cono-2 have some secondary structure in solution, including some of the same secondary structure as alpha-conotoxin GI, which facilitates formation of the second disulfide bond by thiol/disulfide exchange. However, both Cono-1 and Cono-2 are considerably less structured than alpha-conotoxin GI, which indicates that formation of the second disulfide bond to give the Cys2-Cys7, Cys3-Cys13 pairing induces considerable structure into the backbone of the peptide.     

Human gene 2 relaxin chain combination and folding

Relaxin is a small 6 kD two-chain peptide member of the insulin superfamily that is principally produced in the corpus luteum of the ovary and which plays a key role in connective tissue remodeling during parturition. Like insulin, it is produced on the ribosome as preprohormone that undergoes oxidative folding and subsequent proteolytic processing to yield the mature insulin-like peptide. In contrast to the now considerable insight into insulin chain folding and oxidation, comparatively little is known about the folding pathway of relaxin. A series of synthetic pairwise serine substituted relaxin A-chain cysteine analogues was prepared, and their oxidation behavior was studied both on their own and in the presence of native relaxin B-chain. It was observed that native S-reduced A-chain oxidized rapidly to a bicyclic product, whereas individual formation of each of the intramolecular disulfide bonds between Cys11 and Cys24 and the native Cys10 and Cys15 was considerably slower. Curiously, the non-native, isomeric Cys11-Cys15 disulfide bond formed most rapidly, although circular dichroism spectroscopy analysis showed this product to be devoid of secondary structure. This suggested that it may in fact be an intermediate in the subsequent formation of the native Cys10-Cys15 intramolecular disulfide. Combination of the native A-chain with the B-chain proceeded rapidly as compared with the A-chain analogue that lacked the intramolecular disulfide bond suggesting that this latter element is required as a first step in the folding process. It is therefore probable that relaxin is generated from its constituent A- and B-chains in a stepwise organization manner similar to that of insulin chain combination and folding. Further studies showed that the efficiency of combination of A-chain to B-chain was not markedly influenced by reaction temperature and that a reasonable yield of relaxin could be obtained on combination of the preoxidized A-chain with the S-reduced B-chain.     

Study of a major intermediate in the oxidative folding of leech carboxypeptidase inhibitor: contribution of the fourth disulfide bond

The oxidative folding pathway of leech carboxypeptidase inhibitor (LCI; four disulfide bonds) proceeds through the formation of two major intermediates (III-A and III-B) that contain three native disulfide bonds and act as strong kinetic traps in the folding process. The III-B intermediate lacks the Cys19-Cys43 disulfide bond that links the beta-sheet core with the alpha-helix in wild-type LCI. Here, an analog of this intermediate was constructed by replacing Cys19 and Cys43 with alanine residues. Its oxidative folding follows a rapid sequential flow through one, two, and three disulfide species to reach the native form; the low accumulation of two disulfide intermediates and three disulfide (scrambled) isomers accounts for a highly efficient reaction. The three-dimensional structure of this analog, alone and in complex with carboxypeptidase A (CPA), was determined by X-ray crystallography at 2.2A resolution. Its overall structure is very similar to that of wild-type LCI, although the residues in the region adjacent to the mutation sites show an increased flexibility, which is strongly reduced upon binding to CPA. The structure of the complex also demonstrates that the analog and the wild-type LCI bind to the enzyme in the same manner, as expected by their inhibitory capabilities, which were similar for all enzymes tested. Equilibrium unfolding experiments showed that this mutant is destabilized by approximately 1.5 kcal mol(-1) (40%) relative to the wild-type protein. Together, the data indicate that the fourth disulfide bond provides LCI with both high stability and structural specificity.     

Thioredoxins and glutaredoxins as facilitators of protein folding

Thiol-disulfide oxidoreductase systems of bacterial cytoplasm and eukaryotic cytosol favor reducing conditions and protein thiol groups, while bacterial periplasm and eukaryotic endoplasmatic reticulum provide oxidizing conditions and a machinery for disulfide bond formation in the secretory pathway. Oxidoreductases of the thioredoxin fold superfamily catalyze steps in oxidative protein folding via protein-protein interactions and covalent catalysis to act as chaperones and isomerases of disulfides to generate a native fold. The active site dithiol/disulfide of thioredoxin fold proteins is CXXC where variations of the residues inside the disulfide ring are known to increase the redox potential like in protein disulfide isomerases. In the catalytic mechanism thioredoxin fold proteins bind to target proteins through conserved backbone-backbone hydrogen bonds and induce conformational changes of the target disulfide followed by nucleophilic attack by the N-terminally located low pK(a) Cys residue. This generates a mixed disulfide covalent bond which subsequently is resolved by attack from the C-terminally located Cys residue. This review will focus on two members of the thioredoxin superfamily of proteins known to be crucial for maintaining a reduced intracellular redox state, thioredoxin and glutaredoxin, and their potential functions as facilitators and regulators of protein folding and chaperone activity.     

Evidence for difference in the roles of two cysteine residues involved in disulfide bond formation in the folding of human lysozyme

Human lysozyme is made up of 130 amino acid residues and has four disulfide bonds at Cys6-Cys128, Cys30-Cys116, Cys65-Cys81, and Cys77-Cys95. Our previous results using the Saccharomyces cerevisiae secretion system indicate that the individual disulfide bonds of human lysozyme have different functions in the correct in vivo folding and enzymatic activity of the protein (Taniyama, Y., Yamamoto, Y., Nakao, M., Kikuchi, M., and Ikehara, M. (1988) Biochem. Biophys. Res. Commun. 152, 962-967). In this paper, we report the results of experiments that were focused on the roles of Cys65 and Cys81 in the folding of human lysozyme protein in yeast. A mutant protein (C81A), in which Cys81 was replaced with Ala, had almost the same enzymatic activity and conformation as those of the native enzyme. On the other hand, another mutant (C65A), in which Cys65 was replaced with Ala, was not found to fold correctly. These results indicate that Cys81 is not a requisite for both correct folding and activity, whereas Cys65 is indispensable. The mutant protein C81A is seen to contain a new, non-native disulfide bond at Cys65-Cys77. The possible occurrence of disulfide bond interchange during our mapping experiments cannot be ruled out by the experimental techniques presently available, but characterization of other mutant proteins and computer analysis suggest that the intramolecular exchange of disulfide bonds is present in the folding pathway of human lysozyme in vivo.     

Tertiary interactions between transmembrane segments 3 and 5 near the cytoplasmic side of rhodopsin.

Previous studies [Yu, H., Kono, M., and Oprian, D. D. (1999) Biochemistry 38, xxxx-xxxx] using split receptors and disulfide cross-linking have shown that native cysteines 140 and 222 on the cytoplasmic side of transmembrane segments (TM) 3 and 5 of rhodopsin, respectively, can cross-link to each other upon treatment with the oxidant Cu(phen)3(2+). In this paper we show that although the 140-222 cross-link does not affect the spectral properties of rhodopsin, it completely and reversibly inactivates the ability of the receptor to activate transducin. Following on this lead we further investigate the cytoplasmic region of TM3 and TM5 and identify three additional pairs of residues that when changed to Cys are capable of forming disulfide cross-links in the protein: 140/225, 136/222, and 136/225. These disulfides are able to form without addition of the Cu(phen)3(2+) oxidant. Similar to the 140-222 cross-link, none of the additional disulfides affect the spectral properties of rhodopsin. Also like the 140-222 bond, the 136-222 disulfide completely and reversibly inactivates the light-dependent activation of transducin by the receptor. In contrast, the 140-225 and 136-225 disulfides have no effect on the ability of rhodopsin to activate transducin. The pattern of cross-linking observed in Cys and disulfide scans of the protein is consistent with helical secondary structure in TM3 from 130 to 142 and in TM5 from 218 to 225.     

Isomers of epidermal growth factor with Ser --> Cys mutation at the N-terminal sequence: isomerization, stability, unfolding, refolding, and structure

The structure of human epidermal growth factor (EGF, 53 amino acids) comprises three distinct loops (A, B, and C) connected correspondingly by the three native disulfide bonds, Cys(6)-Cys(20), Cys(14)-Cys(31), and Cys(33)-Cys(42). The connection of Cys(6) and Cys(20) forming the N-terminal A loop is essential for the biological activity of EGF [Barnham et al. (1998) Protein Sci. 7, 1738-1749] and has also been shown to represent a major kinetic trap in the oxidative folding of EGF [Chang et al. (2001) J. Biol. Chem. 276, 4845-4852]. To further understand the chemical nature of this kinetic trap, we have prepared three EGF mutants each with a single Ser --> Cys mutation at Ser residues (Ser(2), Ser(4), and Ser(9)) flanking Cys(6). This allows competition between Cys(6) and mutated Cys(2), Cys(4), and Cys(9) to link with Cys(20) and to form EGF isomers containing different sizes of the A loop. The results show that, in the cases of EGF(S2C) and EGF(S4C), native Cys(6)-Cys(20) is favored over Cys(2)-Cys(20) and Cys(4)-Cys(20) by 4.5- and 9-fold, respectively, in the state of equilibrium. However, in the case of EGF(S9C), a non-native Cys(9)-Cys(20) is thermodynamically more stable than the native Cys(6)-Cys(20) by a free-energy difference (DeltaG degrees ) of 1.12 kcal/mol. Implications of these data in the formation of kinetic trap of EGF folding are discussed. Stabilized isomers of EGF were further generated from denaturation of wild-type and mutant EGF via the method of disulfide scrambling. Properties of these diverse isomers of EGF, including their isomerization, stability, unfolding, refolding, and disulfide structures, are described in this paper.