Disulfide-linked bovine beta-lactoglobulin dimers fold slowly, navigating a glassy folding landscape

To gain insight into the folding of large proteins, we constructed a bovine beta-lactoglobulin (beta-lg) dimeric mutant, A34C/C121A beta-lg. In the mutant, a free thiol group of wild-type beta-lg at Cys121 was removed and two beta-lg molecules were linked by a disulfide bridge through Cys34 created at the dimer's interface. Under strongly native conditions at low concentrations of urea, the refolding yield of A34C/C121A beta-lg was low when monitored by heteronuclear NMR spectroscopy. However, under marginally native conditions, the yield improved notably, although the refolding was still slow. H-D exchange pulse labeling monitored using heteronuclear NMR spectroscopy indicated that A34C/C121A beta-lg forms a folding intermediate similar to monomeric C121A beta-lg in spite of its slow folding. These results indicate that the rapid formation of folding intermediates driven by local interactions occurs in a manner independent of the molecular size and that, if the non-native interactions are too strong, the kinetic trap is set, leading to a glasslike misfolded state. The results suggest the important roles of marginal stability and pathways in making the folding of large proteins possible.     

Stable monomeric intermediate with exposed Cys-119 is formed during heat denaturation of beta-lactoglobulin

The role of the free sulfhydryl group of beta-lactoglobulin in the formation of a stable non-native monomer during heat-treatment of beta-lactoglobulin solutions was investigated. Two concomitant events occurred at the earlier stage of heating: unfolding of native globular monomer and intramolecular sulfhydryl/disulfide exchange reaction. Thus, two denatured monomeric species were formed: a non-native monomer with exposed Cys-121 (Mcys121) which became reversible after cooling, and a stable non-native monomer with exposed Cys-119 (Mcys119) which exhibited both a larger hydrodynamic conformation than native monomer and low solubility at pH 4.7. The results also show that the formation of these monomeric species throughout heat-induced denaturation of native beta-lg monomers is faster than their subsequent aggregation. A mechanism describing the behavior of beta-lg denaturation/aggregation during heat-treatment under selected conditions (5.8 mg/ml, low ionic strength, pH 6.6, 85 degrees C) is presented.     

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.     

Disulfide bond-coupled folding of bovine pancreatic trypsin inhibitor derivatives missing one or two disulfide bonds.

The disulfide bond-coupled folding and unfolding mechanism (at pH 8.7, 25 degrees C in the presence of oxidized and reduced dithiothreitol) was determined for a bovine pancreatic trypsin inhibitor mutant in which cysteines 30 and 51 were replaced with alanines so that only two disulfides, between cysteines 14 and 38 and cysteines 5 and 55, remain. Similar studies were made on a chemically-modified derivative of the mutant retaining only the 5-55 disulfide. The preferred unfolding mechanism for the Ala30/Ala51 mutant begins with reduction of the 14-38 disulfide. An intramolecular rearrangement via thiol-disulfide exchange, involving the 5-55 disulfide and cysteines 14 and/or 38, then occurs. At least five of six possible one-disulfide bond species accumulate during unfolding. Finally, the disulfide of one or more of the one-disulfide bond intermediates (excluding that with the 5-55 disulfide) is reduced giving unfolded protein. The folding mechanism seems to be the reverse of the unfolding mechanism; the observed folding and unfolding reactions are consistent with a single kinetic scheme. The rate constant for the rate-limiting intramolecular folding step--rearrangements of other one-disulfide bond species to the 5-55 disulfide intermediate--seems to depend primarily on the number of amino acids separating cysteines 5 and 55 in the unfolded chain. The energetics and kinetics of the mutant's folding mechanism are compared to those of wild-type protein [Creighton, T. E., & Goldenberg, D. P. (1984) J. Mol. Biol. 179, 497] and a mutant missing the 14-38 disulfide [Goldenberg, D. P. (1988) Biochemistry 27, 2481]. The most striking effects are destabilization of the native structure and a large increase in the rate of unfolding.     

Unpaired cysteine-54 interferes with the ability of an engineered disulfide to stabilize T4 lysozyme

We have introduced an intramolecular disulfide bond into T4 lysozyme and have shown this molecule to be significantly more stable than the wild-type molecule to irreversible thermal inactivation [Perry, L.J., & Wetzel, R. (1984) Science (Washington, D.C.) 226, 555-557]. Wild-type T4 lysozyme contains two free cysteines, at positions 54 and 97, and no disulfide bonds. By directed mutagenesis of the cloned T4 lysozyme gene, we replaced Ile-3 with Cys. Oxidation in vitro generated an intramolecular disulfide bond; proteolytic mapping showed this bond to connect Cys-3 to Cys-97. While this molecule exhibited substantially more stability against thermal inactivation than wild type, its stability was further enhanced by additional modification with thiol-specific reagents. This and other evidence suggest that at basic pH and elevated temperatures Cys-54 is involved in intermolecular thiol/disulfide interchange with the engineered disulfide, leading to inactive oligomers. Mutagenic replacement of Cys-54 with Thr or Val in the disulfide-cross-linked variant generated lysozymes exhibiting greatly enhanced stability toward irreversible thermal inactivation.     

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.     

Glutamine deamidation destabilizes human gammaD-crystallin and lowers the kinetic barrier to unfolding

Human eye lens transparency requires life long stability and solubility of the crystallin proteins. Aged crystallins have high levels of covalent damage, including glutamine deamidation. Human gammaD-crystallin (HgammaD-Crys) is a two-domain beta-sheet protein of the lens nucleus. The two domains interact through interdomain side chain contacts, including Gln-54 and Gln-143, which are critical for stability and folding of the N-terminal domain of HgammaD-Crys. To test the effects of interface deamidation on stability and folding, single and double glutamine to glutamate substitutions were constructed. Equilibrium unfolding/refolding experiments of the proteins were performed in guanidine hydrochloride at pH 7.0, 37 degrees C, or urea at pH 3.0, 20 degrees C. Compared with wild type, the deamidation mutants were destabilized at pH 7.0. The proteins populated a partially unfolded intermediate that likely had a structured C-terminal domain and unstructured N-terminal domain. However, at pH 3.0, equilibrium unfolding transitions of wild type and the deamidation mutants were indistinguishable. In contrast, the double alanine mutant Q54A/Q143A was destabilized at both pH 7.0 and 3.0. Thermal stabilities of the deamidation mutants were also reduced at pH 7.0. Similarly, the deamidation mutants lowered the kinetic barrier to unfolding of the N-terminal domain. These data indicate that interface deamidation decreases the thermodynamic stability of HgammaD-Crys and lowers the kinetic barrier to unfolding due to introduction of a negative charge into the domain interface. Such effects may be significant for cataract formation by inducing protein aggregation or insolubility.     

Identification of nonessential disulfide bonds and altered conformations in the v-sis protein, a homolog of the B chain of platelet-derived growth factor.

The protein encoded by v-sis, the oncogene of simian sarcoma virus, is homologous to the B chain of platelet-derived growth factor (PDGF). There are eight conserved Cys residues between PDGF-B and the v-sis protein. Both native PDGF and the v-sis protein occur as disulfide-bonded dimers, probably containing both intramolecular and intermolecular disulfide bonds. Oligonucleotide-directed mutagenesis was used to change the Cys codons to Ser codons in the v-sis gene. Four single mutants lacked detectable biological activity, indicating that Cys-127, Cys-160, Cys-171, and Cys-208 are required for formation of a biologically active v-sis protein. The other four single mutants retained biological activity as determined in transformation assays, indicating that Cys-154, Cys-163, Cys-164, and Cys-210 are dispensable for biological activity. Double and triple mutants containing three of these altered sites were constructed, some of which were transforming as well. The v-sis proteins encoded by biologically active mutants displayed significantly reduced levels of dimeric protein compared with the wild-type v-sis protein, which dimerized very efficiently. Furthermore, a mutant with a termination codon at residue 209 exhibited partial transforming activity. This study thus suggests that the minimal region required for transformation consists of residues 127 to 208. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis indicated that the v-sis proteins encoded by some of the biologically active mutants exhibited an altered conformation when compared with the wild-type v-sis protein, and suggested that Cys-154 and Cys-163 participate in a nonessential disulfide bond.     

Mutational analysis of the cysteine residues in the hepatitis B virus small envelope protein.

The small envelope protein of hepatitis B virus is the major component of the viral coat and is also secreted from cells as a 20-nm subviral particle, even in the absence of other viral proteins. Such empty envelope particles are composed of approximately 100 copies of this polypeptide and host-derived lipids and are stabilized by extensive intermolecular disulfide cross-linking. To study the contribution of disulfide bonds to assembly and secretion of the viral envelope, single and multiple mutants involving all 14 cysteines in HepG2 and COS-7 cells were analyzed. Of the six cysteines located outside the region carrying the surface antigen, Cys-48, Cys-65, and Cys-69 were each found to be essential for secretion of 20-nm particles, whereas Cys-76, Cys-90, and Cys-221 were dispensable. By introduction of an additional cysteine substituting serine 58, the yield of secreted particles was increased. Of four mutants involving the eight cysteines located in the antigenic region, only the double mutant lacking Cys-121 and Cys-124 was secreted with wild-type efficiency. Secretion-competent envelope proteins were intracellularly retained by secretion-deficient cysteine mutants. According to alkylation studies, both intracellular and secreted envelope proteins contained free sulfhydryl groups. Disulfide-linked oligomers were studied by gel electrophoresis under nonreducing conditions.     

Kinetic analysis of the folding and unfolding of a mutant form of bovine pancreatic trypsin inhibitor lacking the cysteine-14 and -38 thiols

The kinetics of the disulfide-coupled unfolding-refolding transition of a mutant form of bovine pancreatic trypsin inhibitor (BPTI) lacking Cys-14 and -38 were measured and compared to previous results for the wild-type protein and other modified forms. The altered cysteines, which were changed to serine in the mutant protein, are normally paired in a disulfide in the native protein but from disulfides with Cys-5 in two-disulfide kinetic intermediates during folding. Although the mutant protein could fold efficiently, the kinetics of both folding and unfolding were altered, reflecting the roles of these cysteines in the two-disulfide intermediates with "wrong" disulfides. The intramolecular rate constant for the formation of the second disulfide of the native mutant protein was more than 10(3)-fold lower than that for the formation of a second disulfide during the refolding of the wild-type protein. The observed rate of unfolding of the mutant protein was also lower than that of the wild-type protein, demonstrating that the altered cysteines are involved in the intramolecular rearrangements that are the rate-determining step in the unfolding of the wild-type protein. These results confirm the previous conclusion [Creighton, T.E. (1977) J. Mol. Biol. 113, 275-293] that the energetically preferred pathway for folding and unfolding of BPTI includes intramolecular rearrangements of intermediates in which Cys-14 and -38 are paired in disulfides not present in the native protein. The present results are also consistent with other, less detailed, studies with similar mutants lacking Cys-14 and -38 [Marks, C.B., Naderi, H., Kosen, P.A., Kuntz, I.D., & Anderson, S. (1987) Science (Washington, D.C.) 235, 1370-1371].     

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.     

Detection of disulfide bonds in bovine brain tubulin and their role in protein folding and microtubule assembly in vitro: a novel disulfide detection approach

Cysteine residues in tubulin are actively involved in regulating ligand interactions and microtubule formation both in vivo and in vitro. These cysteine residues are sensitive reporters in determining the conformation of tubulin. Although some of the cysteines are critical in modulating drug binding and microtubule assembly, it is not clear how many of these normally exist as disulfides. The controversy regarding the disulfide bonds led us to develop a disulfide detection assay to reexamine the presence of the disulfide linkages in purified alphabeta tubulin and explore their possible biological functions in vitro. The accessible cysteine residues in alphabeta tubulin were alkylated with an excess of iodoacetamide to prevent artifactual generation of disulfide linkages in tubulin. After removal of excess iodoacetamide, tubulin was unfolded in 8 M urea. Half of the unfolded tubulin was treated with dithiothreitol to reduce any disulfide bonds present. The aliquots were then treated with iodo[(14)C]acetamide and the incorporation of radioactivity was measured. We also used the same approach to detect the disulfide linkages in the tubulin in a whole-cell extract. We found in both cases that the samples which were not treated with dithiothreitol had little or no incorporation of iodo[(14)C]acetamide, while the others that were treated with dithiothreitol had significant amounts of (14)C incorporation into tubulin. Moreover, the reduction of the disulfide linkages in tubulin resulted in inhibition of microtubule assembly (29-54%) and markedly affected refolding of the tubulin from both an intermediate and a completely unfolded state. All these data therefore suggest that tubulin has intrachain disulfide bonds in the alpha- and beta-subunits and that these disulfides assist in correct refolding of tubulin from the intermediate unfolded state or help to recover the hydrophobic domains from the completely unfolded state. These disulfides also regulate microtubule assembly and the stability of tubulin in vitro. Our results suggest that tubulin disulfides may play a role in tubulin folding and that thiol-disulfide exchange in tubulin could be a key regulator in microtubule assembly and dynamics of tubulin in vivo.     

A recombinant C121S mutant of bovine beta-lactoglobulin is more susceptible to peptic digestion and to denaturation by reducing agents and heating

The lipocalin beta-lactoglobulin (BLG) is the major whey protein of bovine milk and is homodimeric at physiological conditions. Each monomer contains two disulfide bonds and one cysteine at position 121 (C121). This free thiol plays an important role in the heat-induced aggregation of BLG and, possibly, in its conformational stability. We describe here the expression in the yeast Pichia pastoris of a mutant bovine BLG, in which C121 was changed into Ser (C121S). Circular dichroism and high-performance liquid chromatography experiments, together with the X-ray crystal structure, show that the C121S mutant retains a nativelike fold at both neutral and acid pH. The mutation completely blocks the irreversible aggregation induced by heat treatment at 90 degrees C. Compared to the recombinant wild-type protein, the mutant is less stable to temperature and disulfide reducing agents and is much more sensitive to peptic digestion. Moreover, its affinity for 1-anilino-8-naphthalenesulfonate is increased at neutral and acid pH. We suggest that the stability of the protein arising from the hydrophobic effect is reduced by the C121S mutation so that unfolded or partially unfolded states are more favored.     

Characterization of two active site mutations of thioredoxin reductase from Escherichia coli

Thioredoxin reductase (TRR), a member of the pyridine nucleotide-disulfide oxidoreductase family of flavoenzymes, undergoes two sequential thiol-disulfide interchange reactions with thioredoxin during catalysis. In order to assess the catalytic role of each nascent thiol of the active site disulfide of thioredoxin reductase, the 2 cysteines (Cys-136 and Cys-139) forming this disulfide have been individually changed to serines by site-directed mutageneses of the cloned trxB gene of Escherichia coli. Spectral analyses of TRR(Ser-136,Cys-139) as a function of pH and ionic strength have revealed two pKa values associated with the epsilon 456, one of which increases from 7.0 to 8.3 as the ionic strength is increased, and a second at 4.4 which is seen only at high ionic strength. epsilon 458 of wild type TRR(Cys-136,Cys-139) and epsilon 453 of TRR(Cys-136,Ser-139) are pH-independent. A charge transfer complex (epsilon 530 = 1300 M-1 cm-1), unique to TRR(Ser-136,Cys-139), has been observed under conditions of high ammonium cation concentration (apparent Kd = 54 microM) at pH 7.6. These results suggest the assignment of Cys-139 as the FAD-interacting thiol in the reduction of thioredoxin by NADPH via thioredoxin reductase. If, as with other members of this enzyme family, the two distinct catalytic functions are each carried out by a different nascent thiol, then Cys-136 would perform the initial thiol-disulfide interchange with thioredoxin. Steady state kinetic analyses of the proteins have revealed turnover numbers of 10 and 50% of the value of the wild type enzyme for TRR(Ser-136,Cys-139) and TRR(Cys-136,Ser-139), respectively, and no changes in the apparent Km values of TR(S2) or NADPH. The finding of activity in the mutants indicates that the remaining thiol can carry out interchange with the disulfide of thioredoxin, and the resulting mixed disulfide can be reduced by NADPH via the flavin.     

Maturation of Pseudomonas aeruginosa elastase. Formation of the disulfide bonds

Elastase of Pseudomonas aeruginosa is synthesized as a preproenzyme. After propeptide-mediated folding in the periplasm, the proenzyme is autoproteolytically processed, prior to translocation of both the mature enzyme and the propeptide across the outer membrane. The formation of the two disulfide bonds present in the mature enzyme was examined by studying the expression of the wild-type enzyme and of alanine for cysteine mutant derivatives in the authentic host and in dsb mutants of Escherichia coli. It appeared that the two disulfide bonds are formed successively. First, DsbA catalyzes the formation of the disulfide bond between Cys-270 and Cys-297 within the proenzyme. This step is essential for the subsequent autoproteolytic processing to occur. The second disulfide bond between Cys-30 and Cys-57 is formed more slowly and appears to be formed after processing of the proenzyme, and its formation is catalyzed by DsbA as well. This second disulfide bond appeared to be required for the full proteolytic activity of the enzyme and contributes to its stability.     

Both PDI and PDIp can attack the native disulfide bonds in thermally-unfolded RNase and form stable disulfide-linked complexes

Protein disulfide isomerase (PDI) and its pancreatic homolog (PDIp) are folding catalysts for the formation, reduction, and/or isomerization of disulfide bonds in substrate proteins. However, the question as to whether PDI and PDIp can directly attack the native disulfide bonds in substrate proteins is still not answered, which is the subject of the present study. We found that RNase can be thermally unfolded at 65°C under non-reductive conditions while its native disulfide bonds remain intact, and the unfolded RNase can refold and reactivate during cooling. Co-incubation of RNase with PDI or PDIp during thermal unfolding can inactivate RNase in a PDI/PDIp concentration-dependent manner. The alkylated PDI and PDIp, which are devoid of enzymatic activities, cannot inactivate RNase, suggesting that the inactivation of RNase results from the disruption of its native disulfide bonds catalyzed by the enzymatic activities of PDI/PDIp. In support of this suggestion, we show that both PDI and PDIp form stable disulfide-linked complexes only with thermally-unfolded RNase, and RNase in the complexes can be released and reactivated dependently of the redox conditions used. The N-terminal active site of PDIp is essential for the inactivation of RNase. These data indicate that PDI and PDIp can perform thiol-disulfide exchange reactions with native disulfide bonds in unfolded RNase via formation of stable disulfide-linked complexes, and from these complexes RNase is further released.     

Catalysis of creatine kinase refolding by protein disulfide isomerase involves disulfide cross-link and dimer to tetramer switch

Protein disulfide isomerase (PDI) functions as an isomerase to catalyze thiol:disulfide exchange, as a chaperone to assist protein folding, and as a subunit of prolyl-4-hydroxylase and microsomal triglyceride transfer protein. At a lower concentration of 0.2 microm, PDI facilitated the aggregation of unfolded rabbit muscle creatine kinase (CK) and exhibited anti-chaperone activity, which was shown to be mainly due to the hydrophobic interactions between PDI and CK and was independent of the cross-linking of disulfide bonds. At concentrations above 1 microm, PDI acted as a protector against aggregation but an inhibitor of reactivation during CK refolding. The inhibition effect of PDI on CK reactivation was further characterized as due to the formation of PDI-CK complexes through intermolecular disulfide bonds, a process involving Cys-36 and Cys-295 of PDI. Two disulfide-linked complexes containing both PDI and CK were obtained, and the large, soluble aggregates around 400 kDa were composed of 1 molecule of tetrameric PDI and 2 molecules of inactive intermediate dimeric CK, whereas the smaller one, around 200 kDa, was formed by 1 dimeric PDI and 1 dimeric CK. To our knowledge this is the first study revealing that PDI could switch its conformation from dimer to tetramer in its functions as a foldase. According to the observations in this research and our previous study of the folding pathways of CK, a working model was proposed for the molecular mechanism of CK refolding catalyzed by PDI.     

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.     

Impact of an easily reducible disulfide bond on the oxidative folding rate of multi-disulfide-containing proteins.

The burial of native disulfide bonds, formed within stable structure in the regeneration of multi-disulfide-containing proteins from their fully reduced states, is a key step in the folding process, as the burial greatly accelerates the oxidative folding rate of the protein by sequestering the native disulfide bonds from thiol-disulfide exchange reactions. Nevertheless, several proteins retain solvent-exposed disulfide bonds in their native structures. Here, we have examined the impact of an easily reducible native disulfide bond on the oxidative folding rate of a protein. Our studies reveal that the susceptibility of the (40-95) disulfide bond of Y92G bovine pancreatic ribonuclease A (RNase A) to reduction results in a reduced rate of oxidative regeneration, compared with wild-type RNase A. In the native state of RNase A, Tyr 92 lies atop its (40-95) disulfide bond, effectively shielding this bond from the reducing agent, thereby promoting protein oxidative regeneration. Our work sheds light on the unique contribution of a local structural element in promoting the oxidative folding of a multi-disulfide-containing protein.