Cystine knot mutations affect the folding of the glycoprotein hormone alpha-subunit. Differential secretion and assembly of partially folded intermediates

The common glycoprotein hormone alpha-subunit (GPH-alpha) contains five intramolecular disulfide bonds, three of which form a cystine knot motif (10-60, 28-82, and 32-84). By converting each pair of cysteine residues of a given disulfide bond to alanine, we have studied the role of individual disulfide bonds in GPH-alpha folding and have related folding ability to secretion and assembly with the human chorionic gonadotropin beta-subunit (hCG-beta). Mutation of non-cystine knot disulfide bond 7-31, bond 59-87, or both (leaving only the cystine knot) resulted in an efficiently secreted folding form that was indistinguishable from wild type. Conversely, the cystine knot mutants were inefficiently secreted (<25%). Furthermore, mutation of the cystine knot disulfide bonds resulted in multiple folding intermediates containing 1, 2, or 4 disulfide bonds. High performance liquid chromatographic separation of intracellular and secreted forms of the folding intermediates demonstrated that the most folded forms were preferentially secreted and combined with hCG-beta. From these studies we conclude that: (i) the cystine knot of GPH-alpha is necessary and sufficient for folding and (ii) there is a direct correlation between the extent of GPH-alpha folding, its ability to be secreted, and its ability to heterodimerize with hCG-beta.     

The nonconsecutive disulfide bond of Escherichia coli phytase (AppA) renders it dependent on the protein-disulfide isomerase, DsbC

The formation of protein disulfide bonds in the Escherichia coli periplasm by the enzyme DsbA is an inaccurate process. Many eukaryotic proteins with nonconsecutive disulfide bonds expressed in E. coli require an additional protein for proper folding, the disulfide bond isomerase DsbC. Here we report studies on a native E. coli periplasmic acid phosphatase, phytase (AppA), which contains three consecutive and one nonconsecutive disulfide bonds. We show that AppA requires DsbC for its folding. However, the activity of an AppA mutant lacking its nonconsecutive disulfide bond is DsbC-independent. An AppA homolog, Agp, a periplasmic acid phosphatase with similar structure, lacks the nonconsecutive disulfide bond but has the three consecutive disulfide bonds found in AppA. The consecutively disulfide-bonded Agp is not dependent on DsbC but is rendered dependent by engineering into it the conserved nonconsecutive disulfide bond of AppA. Taken together, these results provide support for the proposal that proteins with nonconsecutive disulfide bonds require DsbC for full activity and that disulfide bonds are formed predominantly during translocation across the cytoplasmic membrane.     

Effects of disulfide bonds on folding behavior and mechanism of the beta-sheet protein tendamistat

Tendamistat, a small disulfide-bonded beta-sheet protein, and its three single/double-disulfide mutants are investigated by using a modified Gō-like model, aiming to understand the folding mechanism of disulfide-bonded protein as well as the effects of removal of disulfide bond on the folding process. Our simulations show that tendamistat and its two single-disulfide mutants are all two-state folders, consistent with the experimental observations. It is found that the disulfide bonds as well as three hydrogen bonds between the N-terminal loop-0 and strand-6 are of significant importance for the folding of tendamistat. Without these interactions, their two-state behaviors become unstable and the predictions of the model are inconsistent with experiments. In addition, the effect of disulfide bonds on the folding process are studied by comparing the wild-type tendamistat and its two mutants; it is found that the removal of either of the C11-C27 or C45-C73 disulfide bond leads to a large decrease in the thermodynamical stability and loss of structure in the unfolded state, and the effect of the former is stronger than that of the later. These simulation results are in good agreement with experiments and, thus, validate our model. Based on the same model, the detailed folding pathways of the wild-type tendamistat and two mutants are studied, and the effect of disulfide bonds on the folding kinetics are discussed. The obtained results provide a detailed folding picture of these proteins and complement experimental findings. Finally, the folding nuclei predicted to be existent in this protein tendamistat as well as its mutants are firstly identified in this work. The positions of the nucleus are consistent with those argued in experimental studies. Therefore, a nucleation/growth folding mechanism that can explain the two-state folding manner is clearly characterized. Moreover, the effect by the removal of each disulfide bond on the folding thermodynamics and dynamics can also be well interpreted from their influence on the folding nucleus. The implementation of this work indicates that the modified Gō-like model really describes the folding behavior of protein tendamistat and could be used to study the folding of other disulfide-bonded proteins.     

Reductive unfolding and oxidative refolding of a Bowman-Birk inhibitor from horsegram seeds (Dolichos biflorus): evidence for "hyperreactive" disulfide bonds and rate-limiting nature of disulfide isomerization in folding

Horsegram protease inhibitor belongs to the Bowman-Birk class (BBIs) of low molecular weight (8-10 kDa), disulfide-rich, "dual" inhibitors, which can bind and inhibit trypsin and chymotrypsin either independently or simultaneously. They have seven conserved disulfide bonds. Horsegram BBI exhibits remarkable stability against denaturants like urea, guanidine hydrochloride (GdmCl) and heat, which can be attributed to these conserved disulfide bonds. On reductive denaturation, horsegram BBI follows the "two-state" mode of unfolding where all the disulfide bonds are reduced simultaneously resulting in the fully reduced protein without any accumulation of partially reduced intermediates. Reduction with dithiothreitol (DTT) followed apparent first-order kinetics and the rate constants (k(r)) indicated that the disulfide bonds were "hyperreactive" in nature. Oxidative refolding of the fully reduced and denatured inhibitor was possible at very low protein concentration in the presence of "redox" combination of reduced and oxidized glutathiones. Simultaneous recovery of trypsin and chymotryptic inhibitory activities indicated the concomitant folding of both the inhibitory subdomains. Folding efficiency decreased in the absence of the glutathiones and in the presence of denaturants (6 M urea and 4 M GdmCl), indicating the importance of disulfide shuffling and the formation of noncovalent interactions and secondary structural elements, respectively, for folding efficiency. Folding rate was significantly improved in the presence of protein disulfide isomerase (PDI). A 3-fold enhancement of rate was observed in the presence of PDI at molar ratio of 1:20 (PDI/inhibitor), indicating that disulfide bond formation and isomerization to be rate limiting in folding. Peptide prolyl cis-trans isomerase (PPI) did not affect rate at low concentrations, but at molar ratios of 1:1.5 (PPI/inhibitor), there was 1.4-fold enhancement of the folding rate, indicating that the prolyl imidic bond isomerizations may be slowing down the folding reaction but were not rate limiting.     

Domain-dependent protein folding is indicated by the intracellular kinetics of disulfide bond formation of human chorionic gonadotropin beta subunit.

We have measured the intracellular rates of formation of the six disulfide bonds in the human chorionic gonadotropin beta subunit (hCG-beta) to determine whether the folding pathway of this molecule can be described by a simple sequential model. If such a model is correct, the formation of disulfide bonds, which is indicative of tertiary structural changes during protein folding, should occur in a discrete order. The individual rates of disulfide bridging were determined by identifying the extent of disulfide bond formation in hCG-beta intermediates purified from choriocarcinoma cells that had been metabolically labeled for 40 to 120 s and chased for 0 to 25 min. The results of these kinetic studies describe a folding pathway in which the disulfide bonds between cysteines 34-88, 38-57, 9-90 and 23-72 stabilize, in a discrete order, the putative domain(s) involving amino acids 1-90 of hCG-beta. However, the S-S bonds 93-100 and 26-110 begin to form before the complete formation of the disulfide bonds that stabilize the amino acid 1-90 domain(s), and continue to form after complete formation of these disulfide bonds, suggesting that hCG-beta does not fold by a simple sequential pathway. The order of completion of each of the six disulfide bonds of hCG-beta is: 34-88 (t1/2 = 1-2 min), 38-57 (t1/2 = 2-3 min), 9-90 and 23-72, 93-100, and 26-110. Moreover, 60-100% of each of the six disulfide bonds form posttranslationally, and nonnative disulfide bonds do not form in detectable amounts during intracellular folding of hCG-beta.     

The underlying mechanism for the diversity of disulfide folding pathways

The disulfide folding pathway of bovine pancreatic trypsin inhibitor (BPTI) is characterized by the predominance of folding intermediates with native-like structures. Our laboratory has recently analyzed the folding pathway(s) of four 3-disulfide-containing proteins, including hirudin, potato carboxypeptidase inhibitor, epidermal growth factor, and tick anticoagulant peptide. Their folding mechanism(s) differ from that of BPTI by 1) a higher degree of heterogeneity of 1- and 2-disulfide intermediates and 2) the presence of 3-disulfide scrambled isomers as folding intermediates. To search for the underlying causes of these diversities, we conducted kinetic analyses of the reductive unfolding of these five proteins. The experiment of reductive unfolding was designed to evaluate the relative stability and interdependence of disulfide bonds in the native protein. It is demonstrated here that among these five proteins, there exists a striking correlation between the mechanism(s) of reductive unfolding and that of oxidative folding. Those proteins with their native disulfide bonds reduced in a collective and simultaneous manner exhibit both a high degree of heterogeneity of folding intermediates and the accumulation of scrambled isomers along the folding pathway. A sequential reduction of the native disulfide bonds is associated with the presence of predominant intermediates with native- like structures.     

Redox conditions for stimulation of in vitro folding and assembly of the glycoprotein hormone chorionic gonadotropin

The formation of native disulfide bonds during in vitro protein folding can be limiting in obtaining biologically active proteins. Thus, optimization of redox conditions can be critical in maximizing the yield of renatured, recombinant proteins. We have employed a folding model, that of the beta subunit of human chorionic gonadotropin (hCG- beta), to investigate in vitro oxidation conditions that facilitate the folding of this protein, and have compared the in vitro rates obtained with the rate of folding that has been observed in intact cells. Two steps in the folding pathway of hCG-beta were investigated: the rate-limiting events in the folding of this protein, and the assembly of hCG-beta with, hCG-alpha. The rates of these folding events were determined with and without protein disulfide isomerase (PDI) using two different types of redox reagents: cysteamine and its oxidized equivalent, cystamine, and reduced and oxidized glutathione. Rates of the rate-limiting folding events were twofold faster in cysteamine/cystamine redox buffers than in glutathione buffers in the absence of PDI. Optimal conditions for hCG-beta folding were attained in a 2 mM glutathione buffer, pH 7.4, that contained 1 mg/mL PDI and in 10muM cysteamine/cystamine, pH 8.7, without PDI. Under these conditions, the half-time of the ratelimiting folding event was 16 to 20 min and approached the rate observed in intact cells (4 to 5 min). Moreover, folding of the beta subunit under these conditions yields a functional protein, based on its ability to assemble with the alpha subunit. The rates of assembly of hCG-beta with hCG-alpha in the cysteamine/cystamine or glutathione/PDI redox buffers were comparable (t(1/2/sb> = 9 to 12 min)). These studies show that rates of folding and assembly events that involve disulfide bond formation can be optimized by a simple buffer system composed of cysteamine and cystamine. (c) 1994 John Wiley & Sons, Inc.     

Disulfide bond formation during the folding of influenza virus hemagglutinin

To study the importance of individual sulfhydryl residues during the folding and assembly in vivo of influenza virus hemagglutinin (HA), we have constructed and expressed a series of mutant HA proteins in which cysteines involved in three disulfide bonds have been substituted by serine residues. Investigations of the structure and intracellular transport of the mutant proteins indicate that (a) cysteine residues in the ectodomain are essential both for efficient folding of HA and for stabilization of the folded molecule; (b) cysteine residues in the globular portion of the ectodomain are likely to form native disulfide bonds rapidly and directly, without involvement of intermediate, nonnative linkages; and (c) cysteine residues in the stalk portion of the ectodomain also appear not to form intermediate disulfide bonds, even though they have the opportunity to do so, being separated from their correct partners by hundreds of amino acids including two or more other sulfhydryl residues. We propose a role for the cellular protein BiP in shielding the cysteine residues of the stalk domain during the folding process, thus preventing them from forming intermediate, nonnative disulfide bonds.     

Characterization and structural role of disulfide bonds in a highly knotted thionin from Pyrularia pubera

Disulfide bonds play a crucial role in the stabilization of the amphipathic folding of the diverse families of cysteine-rich antimicrobial peptides. The determination of cysteine pairings in these peptides has largely depended on sequence homology criteria, since the classical methods of disulfide bond characterization, which usually require proteolysis as a first step, encounter serious drawbacks derived from the tight folding and the presence of vicinal cysteines. We have chosen the Pyrularia pubera thionin, a 47-residue peptide with four internal disulfides and a remarkable resistance to most proteases, as a representative member of this type of cysteine-rich peptides and have shown that a combination of partial reduction and cyanylation readily allows the determination of its disulfide bonds. We have also studied by molecular dynamics and a combination of partial reduction and proteolysis the role of disulfide bonds in the stabilization of the tridimensional structure of this thionin and found a good agreement with our partial reduction data, suggesting that removal of only one disulfide bond is enough to significantly alter the folding of the peptide.     

DsbA and DsbC-catalyzed oxidative folding of proteins with complex disulfide bridge patterns in vitro and in vivo

Oxidative protein folding in the periplasm of Escherichia coli is catalyzed by the thiol-disulfide oxidoreductases DsbA and DsbC. We investigated the catalytic efficiency of these enzymes during folding of proteins with a very complex disulfide pattern in vivo and in vitro, using the Ragi bifunctional inhibitor (RBI) as model substrate. RBI is a 13.1 kDa protein with five overlapping disulfide bonds. We show that reduced RBI can be refolded quantitatively in glutathione redox buffers in vitro and spontaneously adopts the single correct conformation out of 750 possible species with five disulfide bonds. Under oxidizing redox conditions, however, RBI folding is hampered by accumulation of a large number of intermediates with non-native disulfide bonds, while a surprisingly low number of intermediates accumulates under optimal or reducing redox conditions. DsbC catalyzes folding of RBI under all redox conditions in vitro, but is particularly efficient in rearranging buried, non-native disulfide bonds formed under oxidizing conditions. In contrast, the influence of DsbA on the refolding reaction is essentially restricted to reducing redox conditions where disulfide formation is rate limiting. The effects of DsbA and DsbC on folding of RBI in E.coli are very similar to those observed in vitro. Whereas overexpression of DsbA has no effect on the amount of correctly folded RBI, co-expression of DsbC enhanced the efficiency of RBI folding in the periplasm of E.coli about 14-fold. Addition of reduced glutathione to the growth medium together with DsbC overexpression further increased the folding yield of RBI in vivo to 26-fold. This shows that DsbC is the bacterial enzyme of choice for improving the periplasmic folding yields of proteins with very complex disulfide bond patterns.     

Evidence for the underlying cause of diversity of the disulfide folding pathway

The pathways of oxidative folding of disulfide proteins exhibit a high degree of diversity, which is illustrated by the varied extent of (a) the heterogeneity of folding intermediates, (b) the predominance of intermediates containing native disulfide bonds, and (c) the level of accumulation of fully oxidized scrambled isomers as intermediates. BPTI and hirudin exemplify two extreme cases of such divergent folding pathways. We previously proposed that the underlying cause of this diversity is associated with the degree of stability of protein subdomains. Here we present compelling evidence that substantiates this hypothesis by studying the folding pathway of alphaLA-IIA. alphaLA-IIA is a partially folded intermediate of alpha-lactalbumin (alphaLA). It comprises a structured beta-sheet (calcium-binding) domain linked by two native disulfide bonds (Cys(61)-Cys(77) and Cys(73)-Cys(91)) and a disordered alpha-helical domain with four free cysteines (Cys(6), Cys(28), Cys(111), and Cys(120)). Purified alphaLA-IIA was allowed to refold without and with stabilization of its structured beta-sheet domain by calcium. In the absence of calcium, the folding pathway of alphaLA-IIA resembles that of hirudin, displaying a highly heterogeneous population of folding intermediates, including fully oxidized scrambled species. Upon stabilization of its beta-sheet domain by bound calcium, oxidative folding of alphaLA-IIA undergoes a pathway conspicuously similar to that of BPTI, exhibiting limited species of folding intermediates containing mostly native disulfide bonds.     

Intracellular folding pathway of the cystine knot-containing glycoprotein hormone alpha-subunit

Three of the five disulfide bonds in the glycoprotein hormone alpha-subunit (GPH-alpha) form a cystine knot motif that stabilizes a three-loop antiparallel structure. Previously, we described a mutant (alpha(k)) that contained only the three knot disulfide bonds and demonstrated that the cystine knot was necessary and sufficient for efficient GPH-alpha folding and secretion. In this study, we used alpha(k) as a model to study the intracellular GPH-alpha folding pathway. Cystine knot formation proceeded through a 1-disulfide intermediate that contained the 28-82 disulfide bond. Formation of disulfide bond 10-60, then disulfide bond 32-84, followed the formation of 28-82. Whether the two non-cystine knot bonds 7-31 and 59-87 could form independent of the knot was also tested. Disulfide bond 7-31 formed rapidly, whereas 59-87 did not form when all cysteine residues of the cystine knot were converted to alanine, suggesting that 7-31 forms early in the folding pathway and that 59-87 forms during or after cystine knot formation. Finally, loop 2 of GPH-alpha has been shown to be very flexible, suggesting that loop 2 does not actively drive GPH-alpha folding. To test this, we replaced residues 36-55 in the flexible loop 2 with an artificially flexible glycine chain. Consistent with our hypothesis, folding and secretion were unaffected when loop 2 was replaced with the glycine chain. Based on these findings, we describe a model for the intracellular folding pathway of GPH-alpha and discuss how these findings may provide insight into the folding mechanisms of other cystine knot-containing proteins.     

Secretion incompetence of bovine pancreatic trypsin inhibitor expressed in Escherichia coli.

There is increasing evidence that protein folding and protein export are competing processes in prokaryotic cells. Virtually all secretion studies reported to date, however, have employed proteins that are relatively uncharacterized in terms of their folding behavior and three-dimensional structure. In contrast, the structural and biochemical parameters governing the folding of bovine pancreatic trypsin inhibitor (BPTI) and several of its mutants have been studied intensively. We therefore undertook a study of the secretion behavior in Escherichia coli of recombinant BPTI and its mutants. Wild-type BPTI and two well-characterized folding mutants (C14A, C38A)BPTI and (C30A, C51A)BPTI (missing the 14-38 and 30-51 disulfide bonds, respectively), were investigated by analyzing their expression fused to an E. coli signal sequence or to two synthetic IgG-binding domains of staphylococcal protein A. Both disulfide mutants are destabilized relative to wild-type BPTI and exhibit markedly altered folding kinetics: one (C14A, C38A) folds more slowly than wild-type BPTI and the other (C30A, C51A) unfolds more rapidly. Both mutants were observed to be exported 3-10 times more efficiently than the wild-type molecule. Moreover, the levels of unprocessed preprotein in the cytoplasm were severalfold higher for the wild-type fusion than for the fusion to the two folding mutants. Intracellular degradation of the BPTI moiety was also observed. These results are consistent with traffic of intracellular BPTI preproteins on at least three routes along the secretory pathway: (a) facile secretion of unfolded material, (b) intracellular folding leading to secretion blockage, and (c) degradation followed by export of truncated molecules. A novel feature of these findings is the implication that disulfide bonds can form in the bacterial cytoplasm and lead to secretion incompetence.     

Protein disulfide isomerase isomerizes non-native disulfide bonds in human proinsulin independent of its peptide-binding activity

Protein disulfide isomerase (PDI) supports proinsulin folding as chaperone and isomerase. Here, we focus on how the two PDI functions influence individual steps in the complex folding process of proinsulin. We generated a PDI mutant (PDI-aba'c) where the b' domain was partially deleted, thus abolishing peptide binding but maintaining a PDI-like redox potential. PDI-aba'c catalyzes the folding of human proinsulin by increasing the rate of formation and the final yield of native proinsulin. Importantly, PDI-aba'c isomerizes non-native disulfide bonds in completely oxidized folding intermediates, thereby accelerating the formation of native disulfide bonds. We conclude that peptide binding to PDI is not essential for disulfide isomerization in fully oxidized proinsulin folding intermediates.     

Identification of a protein required for disulfide bond formation in vivo

We describe a mutation (dsbA) that renders Escherichia coli severely defective in disulfide bond formation. In dsbA mutant cells, pulse-labeled beta-lactamase, alkaline phosphatase, and OmpA are secreted but largely lack disulfide bonds. These disulfideless proteins may represent in vivo folding intermediates, since they are protease sensitive and chase slowly into stable oxidized forms. The dsbA gene codes for a 21,000 Mr periplasmic protein containing the sequence cys-pro-his-cys, which resembles the active sites of certain disulfide oxidoreductases. The purified DsbA protein is capable of reducing the disulfide bonds of insulin, an activity that it shares with these disulfide oxidoreductases. Our results suggest that disulfide bond formation is facilitated by DsbA in vivo.     

In vivo substrate specificity of periplasmic disulfide oxidoreductases

In Escherichia coli, a family of periplasmic disulfide oxidoreductases catalyzes correct disulfide bond formation in periplasmic and secreted proteins. Despite the importance of native disulfide bonds in the folding and function of many proteins, a systematic investigation of the in vivo substrates of E. coli periplasmic disulfide oxidoreductases, including the well characterized oxidase DsbA, has not yet been performed. We combined a modified osmotic shock periplasmic extract and two-dimensional gel electrophoresis to identify substrates of the periplasmic oxidoreductases DsbA, DsbC, and DsbG. We found 10 cysteine-containing periplasmic proteins that are substrates of the disulfide oxidase DsbA, including PhoA and FlgI, previously established DsbA substrates. This technique did not detect any in vivo substrates of DsbG, but did identify two substrates of DsbC, RNase I and MepA. We confirmed that RNase I is a substrate of DsbC both in vivo and in vitro. This is the first time that DsbC has been shown to affect the in vivo function of a native E. coli protein, and the results strongly suggest that DsbC acts as a disulfide isomerase in vivo. We also demonstrate that DsbC, but not DsbG, is critical for the in vivo activity of RNase I, indicating that DsbC and DsbG do not function identically in vivo. The absence of substrates for DsbG suggests either that the in vivo substrate specificity of DsbG is more limited than that of DsbC or that DsbG is not active under the growth conditions tested. Our work represents one of the first times the in vivo substrate specificity of a folding catalyst system has been systematically investigated. Because our methodology is based on the simple assumption that the absence of a folding catalyst should cause its substrates to be present at decreased steady-state levels, this technique should be useful in analyzing the substrate specificity of any folding catalyst or chaperone for which mutations are available.     

Identification of protein disulfide isomerase 1 as a key isomerase for disulfide bond formation in apolipoprotein B100

Apolipoprotein (apo) B is an obligatory component of very low density lipoprotein (VLDL), and its cotranslational and posttranslational modifications are important in VLDL synthesis, secretion, and hepatic lipid homeostasis. ApoB100 contains 25 cysteine residues and eight disulfide bonds. Although these disulfide bonds were suggested to be important in maintaining apoB100 function, neither the specific oxidoreductase involved nor the direct role of these disulfide bonds in apoB100-lipidation is known. Here we used RNA knockdown to evaluate both MTP-dependent and -independent roles of PDI1 in apoB100 synthesis and lipidation in McA-RH7777 cells. Pdi1 knockdown did not elicit any discernible detrimental effect under normal, unstressed conditions. However, it decreased apoB100 synthesis with attenuated MTP activity, delayed apoB100 oxidative folding, and reduced apoB100 lipidation, leading to defective VLDL secretion. The oxidative folding–impaired apoB100 was secreted mainly associated with LDL instead of VLDL particles from PDI1-deficient cells, a phenotype that was fully rescued by overexpression of wild-type but not a catalytically inactive PDI1 that fully restored MTP activity. Further, we demonstrate that PDI1 directly interacts with apoB100 via its redox-active CXXC motifs and assists in the oxidative folding of apoB100. Taken together, these findings reveal an unsuspected, yet key role for PDI1 in oxidative folding of apoB100 and VLDL assembly.     

Expression, folding, and characterization of small proteins with increasing disulfide complexity by a pT7-7-derived phagemid

The expression, folding, and characterization of a series of small proteins with increasingly complex disulfide bond patterns were characterized. A phagemid was prepared from the pT7-7 plasmid to facilitate mutagenic studies with these proteins. cDNAs coding for bovine, rat, and human prolactin; human growth hormone; and bovine alpha-lactalbumin were amplified by PCR using primers that inserted restriction sites at the 5' and 3' ends and reduced the coding sequence to the mature methionyl protein with bacterially preferred codons in the 5' region. The expressed proteins were folded and oxidized by methods that allowed disulfide bond formation to occur either during or following folding. The effectiveness of the folding procedures was determined for each protein by electrophoresis, absorption spectroscopy, and functional studies. The redox conditions required for folding functional proteins varied as the number of disulfide bonds per unit molecular weight increased. Human growth hormone, 22 kDa; human prolactin, 23 kDa; and bovine prolactin, 23 kDa, contain two, three, and three disulfides, respectively, and are folded correctly by air oxidation performed during renaturation under alkaline conditions. Proper disulfide bond formation of rat prolactin, 23 kDa, containing three disulfide bonds required the addition of a reducing agent at the initiation of renaturation. Bovine alpha-lactalbumin, 14 kDa with four disulfide bonds, required complete renaturation prior to the removal of a reducing agent. SDS-gel electrophoresis under nonreducing conditions provided information regarding the proper folding of these proteins. The absorption of 250-nm light by disulfide bonds also provided information regarding the proper folding of rat prolactin and bovine alpha-lactalbumin.     

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.