Role of the [65-72] disulfide bond in oxidative folding of bovine pancreatic ribonuclease A

To assess the role of the [65-72] disulfide bond in the oxidative folding of RNase A, use has been made of [C65S, C72S], a three-disulfide-containing mutant of RNase A which regenerates from its two-disulfide precursor in an oxidation and conformational folding-coupled rate-determining step. The distribution of disulfide bonds in the one-disulfide-containing ensemble of this mutant has been characterized. In general, the disulfide-bond distribution in its 1S ensemble agrees relatively well with the corresponding distribution in wt-RNase A and with distributions based on calculations of loop entropy, except for the absence of the [65-72] disulfide bond. There is no bias (over the entropic influence) for the three native disulfide bonds, [26-84], [40-95], and [58-110]. Previous oxidative folding results for wt-RNase A indicated the predominance of the des [40-95] intermediate over des [65-72] after the rate-determining step in the regeneration process. Considering that there is no preferential distribution of disulfides in the 1S ensemble of [C65S, C72S], in contrast to the preferential population of the [65-72] disulfide bond in wt-RNase A, these results indicate a critical role for the [65-72] disulfide bond in the regeneration of wt-RNase A. Furthermore, analysis of the disulfide distribution of the 1S intermediates of [C65S, C72S] compared to that of wt-RNase A lends support for a physicochemical basis for the previously observed slow folding rate of this mutant, compared to its analogue (des [65-72]) of wt-RNase A.     

Catalysis of the oxidative folding of bovine pancreatic ribonuclease A by protein disulfide isomerase

The major oxidative folding pathways of bovine pancreatic ribonuclease A at pH 8.0 and 25 degrees C involve a pre-equilibrium steady state among ensembles of intermediates with zero, one, two, three and four disulfide bonds. The rate-determining steps are the reshuffling of the unstructured three-disulfide ensemble to two native-like three-disulfide species, des-[65-72] and des-[40-95], that convert to the native structure during oxidative formation of the fourth disulfide bond. Under the same regeneration conditions, with oxidized and reduced DTT, used previously for kinetic oxidative-folding studies of this protein, the addition of 4 microM protein disulfide isomerase (PDI) was found to lead to catalysis of each disulfide-formation step, including the rate-limiting rearrangement steps in which the native-like intermediates des-[65-72] and des-[40-95] are formed. The changes in the distribution of intermediates were also determined in the presence and absence of PDI at three different temperatures (with the DTT redox system) as well as at 25 degrees C (with the glutathione redox system). The results indicate that the acceleration of the formation of native protein by PDI, which we observed earlier, is due to PDI catalysis of each of the intermediate steps without changing the overall pathways or folding mechanism.     

Mutations in domain a' of protein disulfide isomerase affect the folding pathway of bovine pancreatic ribonuclease A

Protein disulfide isomerase (PDI, EC 5.3.4.1), an enzyme and chaperone, catalyses disulfide bond formation and rearrangements in protein folding. It is also a subunit in two proteins, the enzyme collagen prolyl 4-hydroxylase and the microsomal triglyceride transfer protein. It consists of two catalytically active domains, a and a', and two inactive ones, b and b', all four domains having the thioredoxin fold. Domain b' contains the primary peptide binding site, but a' is also critical for several of the major PDI functions. Mass spectrometry was used here to follow the folding pathway of bovine pancreatic ribonuclease A (RNase A) in the presence of three PDI mutants, F449R, Delta455-457, and abb', and the individual domains a and a'. The first two mutants contained alterations in the last alpha helix of domain a', while the third lacked the entire domain a'. All mutants produced genuine, correctly folded RNase A, but the appearance rate of 50% of the product, as compared to wild-type PDI, was reduced 2.5-fold in the case of PDI Delta455-457, 7.5-fold to eightfold in the cases of PDI F449R and PDI abb', and over 15-fold in the cases of the individual domains a and a'. In addition, PDI F449R and PDI abb' affected the distribution of folding intermediates. Domains a and a' catalyzed the early steps in the folding but no disulfide rearrangements, and therefore the rate observed in the presence of these individual domains was similar to that of the spontaneous process.     

Effect of protein disulfide isomerase on the rate-determining steps of the folding of bovine pancreatic ribonuclease A

To address the effect of an agglutogen on virus infection, we studied the avidin-associated inhibition of infection by biotinylated M13 phages (BIO-phages). Microscopic observation of mixtures of BIO-phages and avidin–fluorescein conjugates revealed many aggregates. Even at low phage concentrations, avidin induced inhibition of infection significantly. Anti-M13 phage antibody also made aggregates and inhibited the infection but in a different manner from avidin. The inhibition by avidin was at ≥2 μg/ml, time dependent and marked until 10 min after the mixing of the BIO-phages and Escherichia coli. On the other hand, antibody inhibited the infection at ≥0.1 μg/ml dose dependently, and the inhibition was time dependent and marked until 45 min after the mixing at moderate and low phage concentrations. These results indicate that avidin against BIO-phages and antibodies are agglutogens, and the inhibition of the BIO-phages by avidin is closely related to the tetramerization of avidin. Agglutogens may be novel alternative antiviral drugs.     

Contribution of individual disulfide bonds to the oxidative folding of ribonuclease A

The eight cysteine residues of ribonuclease A form four disulfide bonds in the native protein. We have analyzed the folding of three double RNase A mutants (C65A/C72A, C58A/C110A, and C26A/C84A, lacking the C65-C72, C58-C110, and C26-C84 disulfide bonds, respectively) and two single mutants (C110A and C26A), in which a single cysteine is replaced with an alanine and the paired cysteine is present in the reduced form. The folding of these mutants was carried out in the presence of oxidized and reduced glutathione, which constitute the main redox agents present within the ER. The use of mass spectrometry in the analysis of the folding processes allowed us (i) to follow the formation of intermediates and thus the pathway of folding of the RNase A mutants, (ii) to quantitate the intermediates that formed, and (iii) to compare the rates of formation of intermediates. By comparison of the folding kinetics of the mutants with that of wild-type RNase A, the contribution of each disulfide bond to the folding process has been evaluated. In particular, we have found that the folding of the C65A/C72A mutant occurs on the same time scale as that of the wild-type protein, thus suggesting that the removal of the C65-C72 disulfide bond has no effect on the kinetics of RNase A folding. Conversely, the C58A/C110A and C26A/C84A mutants fold much more slowly than the wild-type protein. The removal of the C58-C110 and C26-C84 disulfide bonds has a dramatic effect on the kinetics of RNase A folding. Results described in this paper provide specific information about conformational folding events in the regions involving the mutated cysteine residues, thus contributing to a better understanding of the complex mechanism of oxidative folding.     

Significance of the four carboxyl terminal amino acid residues of bovine pancreatic ribonuclease A for structural folding

The C-terminal amino acid residues of bovine pancreatic ribonuclease A (RNase A) form a core structure in the initial stage of the folding process that leads to the formation of the tertiary structure. In this paper, roles of the C-terminal four amino acids in the structure, function, and refolding were studied by use of recombinant mutant enzymes in which these residues were deleted or replaced. Purified mutant enzymes were analyzed for their secondary structure, thermal stability, and ability to regenerate from the denatured and reduced state. The C-terminal deleted mutant enzymes showed lower hydrolytic activity for C>p and nearly identical CD spectra compared with the wild-type enzyme. The rate of recovery of activity was significantly different among the C-terminal deleted mutant enzymes when air oxidation was employed in the absence of GSH and GSSG: the rates decreased in the order of des-124-, des-(123-124)-, and des-(122-124)-RNase A. It is noteworthy that the regeneration rates of mutant RNase A in the presence of GSH and GSSG were nearly the same. Des-(121-124)-RNase A failed to recover activity both in the presence and absence of glutathione, due to the mismatched formation of disulfide bonds. The mutant enzyme in which all of the C-terminal four amino acid residues were replaced by alanine residues showed lower hydrolytic activity and an indistinguishable CD spectrum compared with the wild-type enzyme, and also recovered its activity from the denatured and reduced state by air oxidation. The D121 mutant enzymes showed decreased hydrolytic activity and identical CD spectra compared with the wild type. The recovery rates of activity of D121A and D121K were determined to be lower than that of the wild-type enzyme, while the rate of recovery of D121E was comparable to that of the wild type. The C-terminal amino acids play a significant role in the formation of the correct disulfide bonds during the refolding process, and the interaction of amino acid residues and the existence of the main chain around the C-terminal region are both important for achieving the efficient packing of the RNase A molecule.     

Local interactions favor the native 8-residue disulfide loop in the oxidation of a fragment corresponding to the sequence Ser-50-Met-79 derived from bovine pancreatic ribonuclease A

A 30-residue peptide was obtained from ribonuclease A by chemical cleavage with cyanogen bromide, subsequent sulfitolysis with concomitant S-sulfonation, and finally enzymatic cleavage withStaphylococcus aureus protease. The peptide was converted to the free thiol form by reductive cleavage of the S-sulfo-protecting groups withd,l-dithiothreitol. This peptide consisted of residues 50–79 of the native sequence of ribonuclease A, with the exception that methionine-79 had been converted to homoserine. Included in this sequence are residues cysteine-65 and cysteine-72, which form a disulfide bond in the native enzyme, as well as cysteine-58. This molecule may form one of three possible intramolecular disulfide bonds upon thiol oxidation, viz. one loop of 15 and 2 of 8 residues each. These isomeric peptides were prepared by oxidation with cystamine, 2-aminoethanethiolation of residual thiols, and fractionation by reverse-phase high-performance liquid chromatography. Disulfide pairings were established by mapping the tryptic fragments and confirming their composition by amino acid analysis. After protracted incubation under oxidizing conditions at 25.0°C andp H 8.0, the 26-member ring incorporating the native disulfide bond between residues 65 and 72 is the dominant product. Assuming that equilibrium is established, we infer that local interactions in the sequence of ribonuclease A significantly stabilize the native 8-residue disulfide loop with respect to the non-native 8-residue loop (G°=–1.1±0.1 kcal mole^–1). The implications of this observation for the oxidative folding of the intact protein are discussed.     

Formation of native structure by intermolecular thiol-disulfide exchange reactions without oxidants in the folding of bovine pancreatic ribonuclease A

It has been shown previously that the oxidative folding of bovine pancreatic ribonuclease A proceeds through parallel pathways with two major native-like three-disulfide (3S) intermediates. We show here that, under some conditions, the native disulfide bonds can also be regenerated through disproportionation reactions; in other words, the protein can serve as its own redox reagent. The results also show that disulfide species of the unstructured 3S ensemble have a strong propensity to participate in intermolecular interactions. These interactions are favored at high protein concentration, temperature and pH, and lead to formation of the native structure during disulfide reshuffling in the rate-determining step.     

Crystal structures of two mutants that have implications for the folding of bovine pancreatic ribonuclease A.

The Tyr92-Pro93 peptide group of bovine pancreatic ribonuclease A (RNase A) exists in the cis conformation in the native state. From unfolding/refolding kinetic studies of the disulfide-intact wild-type protein and of a variant in which Pro93 had been replaced by Ala, it had been suggested that the Tyr92-Ala93 peptide group also exists in the cis conformation in the native state. Here, we report the crystal structure of the P93A variant. Although there is disorder in the region of residues 92 and 93, the best structural model contains a cis peptide at this position, lending support to the results of the kinetics experiments. We also report the crystal structure of the C[40, 95]A variant, which is an analog of the major rate-determining three-disulfide intermediate in the oxidative folding of RNase A, missing the 40-95 disulfide bond. As had been detected by NMR spectroscopy, the crystal structure of this analog shows disorder in the region surrounding the missing disulfide. However, the global chain fold of the remainder of the protein, including the disulfide bond between Cys65 and Cys72, appears to be unaffected by the mutation.     

The oxidative folding rate of bovine pancreatic ribonuclease is enhanced by a covalently attached oligosaccharide

Bovine pancreatic ribonuclease B (RNase B) differs from RNase A by the presence of an oligosaccharide moiety covalently attached to Asn 34. Oxidative folding studies of RNase B were carried out at different temperatures using DTT(ox) as the oxidizing agent, and the results were compared with those for RNase A. The oxidative folding rates of RNase B are between 1.7 and 1.3 times faster than those of RNase A at the temperatures that were investigated. The folding pathways of RNase B were determined to be similar to those of RNase A in that two structured intermediates, each lacking one native disulfide bond, were found to populate the regeneration pathways at 25 degrees C and pH 8.3. The thermodynamic stabilities of these two glycosylated intermediates, and their rates of formation from their unstructured precursors in the rate-determining step, were found to be higher than those of their unglycosylated counterparts from RNase A. Thus, the underlying cause for the faster rate of oxidative regeneration of native RNase B appears to be both thermodynamic and kinetic due to the higher stability, and faster rate of formation, of the intermediates of RNase B compared to those of RNase A.     

Acceleration of oxidative folding of bovine pancreatic ribonuclease A by anion-induced stabilization and formation of structured native-like intermediates

Phosphate anions accelerate the oxidative folding of reduced bovine pancreatic ribonuclease A with dithiothreitol at several temperatures and ionic strengths. The addition of 400 mM phosphate at pH 8.1 increased the regeneration rate of native protein 2.5-fold at 15 degrees C, 3.5-fold at 25 degrees C, and 20-fold at 37 degrees C, compared to the rate in the absence of phosphate. In addition, the effects of other ions on the oxidative folding of RNase A were examined. Fluoride was found to accelerate the formation of native protein under the same oxidizing conditions. In contrast, cations of high charge density or ions with low charge density appear to have an opposite effect on the folding of RNase A. The catalysis of oxidative folding results largely from an anion-dependent stabilization and formation of tertiary structure in productive disulfide intermediates (des-species). Phosphate and fluoride also accelerate the initial equilibration of unstructured disulfide ensembles, presumably due to non-specific electrostatic and hydrogen bonding effects on the protein and solvent.     

Distribution of disulfide bonds in the two-disulfide intermediates in the regeneration of bovine pancreatic ribonuclease A: further insights into the folding process.

The distribution of one-disulfide bonds in the two-disulfide intermediates in the oxidative refolding of bovine pancreatic ribonuclease A has been characterized. These two-disulfide intermediates were formed from the fully reduced denatured protein by oxidation with dithiothreitol, then blocked with AEMTS, purified by cation-exchange chromatography, enzymatically digested, and analyzed by reversed-phase high-performance liquid chromatography and mass spectrometry. The relative concentration of each of the 28 possible one-disulfide bonds in the two-disulfide ensemble was determined. Comparison with a statistical mechanical treatment of loop formation shows that the two-disulfide intermediates are probably compact. All 28 disulfide bonds were observed, demonstrating the absence of specific long-range interactions in these intermediates. Thermodynamic arguments suggest that the absence of such specific long-range interactions in the two-disulfide species may elevate the concentration of kinetically important three-disulfide intermediates and thereby increase the folding rate. Bond [65-72] was found to make up approximately 27% of the disulfide bonds of the two-disulfide species, significantly more than all other disulfides, because of stabilization by loop entropy factors and an energetically favorable beta-turn. This turn may be one of several chain-folding initiation sites, accelerating folding by decreasing the dimensionality of the conformational space that has to be searched.     

Further experimental studies of the disulfide folding transition of ribonuclease A

Two very different mechanisms of folding have been proposed from experimental studies of disulfide formation in reduced ribonuclease A. (1) A pathway in which the rate-limiting step separates fully folded protein from all other disulfide intermediates and occurs solely in three-disulfide intermediates. (2) A multiple pathway mechanism with different rate-limiting steps for each pathway. The various rate-limiting steps involve disulfide breakage, formation, and rearrangement in intermediates with one, two, three, and four protein disulfides. To distinguish between these two mechanisms, we have carried out further studies of both unfolding and refolding. Refolding of reduced ribonuclease A requires three-disulfide intermediates to accumulate; negligible refolding occurs when only the nearly random one- and two-disulfide intermediate species are populated. Therefore, no rate-limiting steps of the type postulated in mechanism (2) occur in intermediates with one and two protein disulfides. Unfolding and disulfide reduction is an all-or-none process; no disulfide intermediates accumulate to detectable levels or precede the rate-limiting step. Mechanism (2) requires that such intermediates precede the rate-limiting step and accumulate to substantial levels. The different proposals were shown not to result from the use of different solution conditions or disulfide reagents; the two sets of data are not inconsistent. Instead, the inappropriate mechanism (2) resulted from an incorrect kinetic analysis and misinterpretation of the kinetics of disulfide formation and breakage.     

Structural studies of a folding intermediate of bovine pancreatic ribonuclease A by continuous recycled flow

A new technique, continuous recycled flow (CRF) spectroscopy, has been developed for observing intermediates of any thermally induced, reversible reaction with a half-life of 10 s or longer. The structure can be probed by any spectroscopic method which does not perturb the system. Prolonged signal acquisitions of 8 h for ribonuclease A are possible. CRF was used to investigate the structure of the slow-folding intermediates of chemically intact ribonuclease A (RNase A) during thermal unfolding/folding under acidic conditions. The following conclusions were reached on the basis of the proton nuclear magnetic resonance and far-ultraviolet circular dichroism spectra of a folding intermediate(s): (A) The conformation of the detected folding intermediate(s) is similar to that of the heat-denatured protein. There is only limited formation of new structures. (B) The N-terminal alpha-helix is partially stable under these conditions and is in rapid (less than 10 ms) equilibrium with the denatured conformation. (C) There are long-range interactions between the hydrophobic residues of the N-terminal alpha-helix and the rest of the protein. These interactions persist well above the melting point. (D) An aliphatic methyl group reports on the formation of a new structure(s) that lie(s) outside of the N-terminal region. (E) The structures detected in chemically modified, nonfolding forms of the RNase A are also present in the folding intermediate(s). There are, however, additional interactions that are unique to chemically intact RNase A.     

Two critical cysteine residues implicated in disulfide bond formation and proper folding of Kir2.1

Inwardly rectifying potassium channels are important in cellular repolarization of many excitable tissues. Amino acid sequence alignment of different mammalian inward rectifier K(+) channels revealed two absolutely conserved cysteine residues in the putative extracellular face, suggesting a possible disulfide bond. Replacement of these cysteine residues in the Kir2.1 channel (i.e., C122 and C154) with either alanine or serine abolished current in Xenopus laevis oocytes although Western blotting established that the channels were fully expressed. The digestion pattern of channels treated with V8 protease combined with Western blotting under reducing and nonreducing conditions confirmed intrasubunit cross-linking of C122 and C154. Whole-cell and single channel current recordings of oocytes expressing tandem tetrameric constructs with one or two of the mutant subunits suggested that insertion of one mutant subunit is sufficient to eliminate channel function. Coexpression studies confirmed that the cysteine mutant channels eliminate wild-type Kir2.1 currents in a dominant-negative manner. Despite these results, sulfhydryl reduction did not alter the functional properties of Kir2.1 currents. Molecular modeling of Kir2.1 with the two cysteines cross-linked predicted that the extracellular loop between the first transmembrane domain and the pore helix contains a beta-hairpin structure. Distinct from the KcsA structure, the disulfide bond together with the beta-hairpin structure is expected to constrain and stabilize the P-loop and selectivity filter. Taken together, these results suggest that intramolecular disulfide bond exists between C122 and C154 of Kir2.1 channel and this cross-link might be required for proper channel folding.     

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.     

Effect of mutation of proline 93 on redox unfolding/folding of bovine pancreatic ribonuclease A.

Both the reductive unfolding and oxidative regeneration of a P93A mutant and wild-type RNase A have been studied at 15 degrees C and pH 8.0. The rate of reduction of the 40--95 disulfide bond is accelerated about 120-fold by the P93A mutation, while the reduction of the 65--72 disulfide bond is not accelerated by this mutation (within the experimental error). Moreover, the reduction of native P93A to des[40--95] is about 10 times faster than the further reduction of the same des[40--95] species. These results demonstrate that the reduction of the mutant proceeds through a local unfolding event and provides strong support for our model in which the reduction of wild-type RNase A to the des species proceeds through two independent local conformational unfolding events. The oxidative regeneration rate of the P93A mutant is comparable to that of wild-type RNase A, suggesting that a cis 92--93 peptide group that is present in native wild-type RNase A and in native des[40--95], is not obligatory for the formation of the third (final) native disulfide bond of des[40--95] by reshuffling from an unstructured 3S precursor. Thus, the trans to cis isomerization of the Tyr92-Pro93 peptide group during the regeneration of wild-type RNase A may occur after the formation of the third native disulfide bond.     

Expression of bovine pancreatic ribonuclease A in Escherichia coli

A synthetic gene for bovine pancreatic ribonuclease A (RNase A) has been expressed in Escherichia coli as a fusion protein with beta-galactosidase linked by the tetrapeptide Ile-Glu-Gly-Arg. RNase A was cleaved from the fusion using factor Xa, and the resulting product purified and reconstituted. The isolated RNase A was chromatographically, catalytically, and immunologically identical with authentic RNase A. This work argues that the method suggested by Nagai and Thogersen [Nagai, K. & Thogersen, H. C. (1984) Nature (Lond.) 309, 810-812] for releasing fusion proteins is quite general, even when applied to particularly complicated expression problem. The procedure here makes RNase A available for the first time as a model for studying structure-function relationships in proteins using site-directed mutagenesis.     

Oxidative folding of bovine pancreatic ribonuclease A: insight into the overall catalysis of the refolding pathway by phosphate

The effects of the strong stabilizing anion, phosphate, on the oxidative folding of bovine pancreatic ribonuclease A were examined. Phosphate was found to catalyze several steps involved in the oxidative folding process at pH 8.0 and 25°C, resulting in an increase in the rate of pre-equilibration of unstructured species on the folding pathway. In the presence of 400 mM phosphate, the overall increase in the rate of regeneration of native protein was caused primarily by the increased formation and stabilization of tertiary structure in the nativelike intermediates, des-[40-95] and des-[65-72], involved in the rate-determining step. Based on the regeneration of native protein and the stability of Cys Ala substituted mutant analogs of the des-species, (C40A, C95A) and (C65A, C72A), it is suggested that the primary role of phosphate is to catalyze the overall regeneration of native protein through nonspecific electrostatic and hydrogen-bonding effects on the protein and solvent.