Analyses of Native Disulfide Bond Formations in the Early Stage of the Folding Process in Mutant Lysozymes Where the Long-Range Interactions in the Denatured State Were Modulated

In order to clarify whether modulation of long-range interactions in the denatured state affect native disulfide bond (SS bond) formations of hen egg white lysozyme (HEL) containing a pair of cysteine residues, we examined the extent of SS bond formation among 12 variants containing a pair of cysteines. The loss of clusters 5 and 6 in the denatured state affected the formation of Cys30-Cys115 and Cys6-Cys127 respectively.     

Oxidative folding of human lysozyme: effects of the loss of two disulfide bonds and the introduction of a calcium-binding site

Mutant human lysozymes (HLZ) lacking two disulfide bonds were constructed to study the importance of each disulfide bond on oxidative refolding. To avoid destabilization, a calcium-binding site was introduced. Five of the six species of two-disulfide mutants could be obtained with enzymatic activity. Based on the information obtained from refolding and unfolding experiments, the order of importance in oxidative refolding was found to be as follows: SS2(Cys30-Cys116) > SS1(Cys6-Cys128) SS3(Cys65-Cys81) > SS4(Cys77-Cys95). Without SS2, these mutants refolded with low efficiency or did not refold at all. The bond SS2 is located in the interface of B-and D-helices, and a small hydrophobic cluster is formed near SS2. This cluster may play an important role in the folding process and stabilization, and SS2 may act as a stabilizer through its polypeptide linkage. The bond SS2 is the most important disulfide bond for oxidative folding of lysozymes.     

Contribution of disulfide bridging to epitope expression of the dengue type 2 virus envelope glycoprotein

The individual contributions of each of the six conserved disulfide (SS) bonds in the dengue 2 virus envelope (E) glycoprotein (strain 16681) to epitope expression was determined by measuring the reactivities of a panel of well-defined monoclonal antibodies (MAbs) with LLC-MK(2) cells that had been transiently transformed with plasmid vectors expressing E proteins that were mutant in their SS bonds. Three domain I (DI) epitopes (C1, C3, and C4) were affected by elimination of any SS bond and were essentially the only epitopes affected by elimination of the amino-proximal SS1 formed between Cys 3 and Cys 30. The remaining DI epitope (C2) was sensitive to only SS3-bond (Cys 74-Cys 105) and SS6-bond (Cys 302-Cys 333) elimination. Of the four DII epitopes examined, reactivities of three anti-epitope MAbs (A1, A2, and A5) were reduced by elimination of SS2 (Cys 61-Cys 121), SS3, SS4 (Cys 94-Cys 116), SS5 (Cys 185-Cys 285), or SS6. The other DII epitope examined (A3) was sensitive only to SS2- and SS3-bond elimination. The three DIII epitopes tested (B2, B3, and B4) were most sensitive to elimination of SS6. The flavivirus group epitope (A1) was less sensitive to elimination of SS3 and SS6. This result may indicate that the region proximal to the E-protein fusion motif (amino acids 98 to 110) may have important linear components. If this observation can be confirmed, peptide mimics from this region of E protein might be able to interfere with flavivirus replication.     

Glycerol-enhanced detection of a preferential structure latent in unstructured 1SS-variants of lysozyme

Four species of 1SS-varinats of lysozyme were almost unstructured in water, judged from their near-UV CD and (1) H-(15) N-HSQC spectra. Some preferential structure might exist in such a disordered state, but the population of molecules in such a conformation must have been too small to be detected by spectroscopic methods. Indeed, our previous study showed that the addition of 30% glycerol induced the unstructured 2SS-variant of lysozyme to form a native-like structure. To extend this method to more disordered proteins, we attempted to detect some preferential structure latent in unstructured 1SS-variants by the glycerol-enhanced detection. Only in one molecular species of the four 1SS-variants, 1SS[6-127] containing a single disulfide bridge of Cys6-Cys127, a preferential structure was found in the presence of 50% glycerol. It was detected by near-UV CD measurements and the H/D exchange method combined with the NMR spectroscopy. The glycerol-induced structure in 1SS[6-127] was not localized only in the vicinity of Cys6-Cys127, and largely protected regions distributed themselves among A-, B-, and C-helices and Ile55 and Leu56. It was similar to the glycerol-induced structure in 2SS[6-127, 64-80] containing two disulfide bridges of Cys6-Cys127 and Cys64-Cys80, although the former was less rigid than the latter. The role of A-helix (residues 4-15) is proposed as an origin of excellent potential of Cys6-Cys127 for inducing a tertiary structure in the α-domain.     

A 3-disulfide mutant of mouse prion protein expression, oxidative folding, reductive unfolding, conformational stability, aggregation and isomerization

The structure of wild-type mouse prion protein mPrP(23-231) consists of two distinctive segments with approximately equal size, a disordered and flexible N-terminal domain encompassing residues 23-124 and a largely structured C-terminal domain containing about 40% of helical structure and stabilized by one disulfide bond (Cys(178)-Cys(213)). We have expressed a mPrP mutant with 4 Ala/Ser-->Cys replacements, two each at the N-(Cys(36), Cys(112)) and C-(Cys(134), Cys(169)) domains. Our specific aims are to study the interaction between N- and C-domains of mPrP during the oxidative folding and to produce stabilized isomers of mPrP for further analysis. Oxidative folding of fully reduced mutant, mPrP(6C), generates one predominant 3-disulfide isomer, designated as N-mPrP(3SS), which comprises the native disulfide (Cys(178)-Cys(213)) and two non-native disulfide bonds (Cys(36)-Cys(134) and Cys(112)-Cys(169)) that covalently connect the N- and C-domains. In comparison to wild-type mPrP(23-231), N-mPrP(3SS) exhibits an indistinguishable CD spectra, a similar conformational stability in the absence of thiol and a reduced ability to aggregate. In the presence of thiol catalyst and denaturant, N-mPrP(3SS) unfolds and generates diverse isomers that are amenable to further isolation, structural and functional analysis.     

Local interactions and the role of the 6-120 disulfide bond in alpha-lactalbumin: implications for formation of the molten globule state

Molten globule states are partially folded states of proteins which are compact and contain a high degree of secondary structure but which lack many of the fixed tertiary interactions associated with the native state. A set of peptides has been prepared in order to probe the role of local interactions in the vicinity of the Cys(6)-Cys(120) disulfide bond in stabilizing the molten globule state of human alpha-lactalbumin. Peptides derived from the N-terminal and C-terminal regions of human alpha-lactalbumin have been analyzed using nuclear magnetic resonance, circular dichroism, fluorescence spectroscopy and sedimentation equilibrium experiments. A peptide corresponding to the first helical region in the native protein, residues 1-13, is only slightly helical in isolation. Extending the peptide to include residues 14-18 results in a modest increase in helicity. A peptide derived from the C-terminal 12 residues, residues 112-123, is predominantly unstructured. Crosslinking the N- and C-terminal peptides by the native disulfide bond results in almost no increase in structure and there is no evidence for any significant cooperative structure formation over the range of pH 2.2-11.7. These results demonstrate that there is very little enhancement of local structure due to the formation of the Cys(6)-Cys(120) disulfide bond. This is in striking contrast to peptides derived from the region of the Cys(28)-Cys(111) disulfide.     

A comparison of folding techniques in the chemical synthesis of the epidermal growth factor-like domain in neu differentiation factor alpha/beta.

The 52-residue alpha/beta chimera of the epidermal growth factor-like domain in neu differentiation factor (NDFealpha/beta) has been synthesized and folded to form a three disulfide bridge (Cys182-Cys196, Cys190-Cys210, Cys212-Cys221) containing peptide. We investigated two general strategies for the formation of the intramolecular disulfide bridges including, the single-step approach, which used fully deprotected and reduced peptide, and a sequential approach that relied on orthogonal cysteine protection in which specific pairs are excluded from the first oxidation step. Because there are 15 possible disulfide bridge arrangements in a peptide with six cysteines, the one-step approach may not always provide the desired disulfide pairing. Here, we compare the single-step approach with a systematic evaluation of the sequential approach. We employed the acetamidomethyl group to protect each pair of cysteines involved in disulfide bridges, i.e. Cys182 to Cys196, Cys190 to Cys210 and Cys212 to Cys221. This reduced the number of possible disulfide patterns from 15 to three in the first folding step. We compared the efficiencies of folding for each protected pair using RP-HPLC, mapped the disulfide connectivity of the predominant product and then formed the final disulfide from the partially folded intermediate via 12 oxidation. Only the peptide having the Cys182-Cys196 pair blocked with acetamidomethyl forms the desired disulfide isomer (Cys190-Cys210/Cys212-Cys221) as a single homogeneous product. By optimizing both approaches, as well as other steps in the synthesis, we can now rapidly provide large-scale syntheses of NDFealpha/beta and other novel EGF-like peptides.     

Disulfide transfer between two conserved cysteine pairs imparts selectivity to protein oxidation by Ero1

The membrane-associated flavoprotein Ero1p promotes disulfide bond formation in the endoplasmic reticulum (ER) by selectively oxidizing the soluble oxidoreductase protein disulfide isomerase (Pdi1p), which in turn can directly oxidize secretory proteins. Two redox-active disulfide bonds are essential for Ero1p oxidase activity: Cys100-Cys105 and Cys352-Cys355. Genetic and structural data indicate a disulfide bond is transferred from Cys100-Cys105 directly to Pdi1p, whereas a Cys352-Cys355 disulfide bond is used to reoxidize the reduced Cys100-Cys105 pair through an internal thiol-transfer reaction. Electron transfer from Cys352-Cys355 to molecular oxygen, by way of a flavin cofactor, maintains Cys352-Cys355 in an oxidized form. Herein, we identify a mixed disulfide species that confirms the Ero1p intercysteine thiol-transfer relay in vivo and identify Cys105 and Cys352 as the cysteines that mediate thiol-disulfide exchange. Moreover, we describe Ero1p mutants that have the surprising ability to oxidize substrates in the absence of Cys100-Cys105. We show the oxidase activity of these mutants results from structural changes in Ero1p that allow substrates increased access to Cys352-Cys355, which are normally buried beneath the protein surface. The altered activity of these Ero1p mutants toward selected substrates leads us to propose the catalytic mechanism involving transfer between cysteine pairs evolved to impart substrate specificity to Ero1p.     

Striking stabilization of Arc repressor by an engineered disulfide bond

A solvent-exposed Cys11-Cys11' disulfide bond was designed to link the antiparallel strands of the beta sheet both in the Arc repressor dimer and in a single-chain variant in which the Arc subunits are connected by a 15-residue peptide tether. In both proteins, the presence of the disulfide bond increased the T(m) by approximately 40 degrees C. In the single-chain background, the disulfide bond stabilized Arc by 8.5 kcal/mol relative to the reduced form, a significantly larger degree of stabilization than caused by other engineered disulfides and most natural disulfides. This exceptional stabilization arises from a modest effective concentration of the Cys11-Cys11' disulfide in the native state (71 M) and an anomalously low effective concentration in the denatured state (40 microM). Disulfide cross-linking of the two beta strands in the single-chain Arc background accelerated refolding by a factor of 170 into the sub-microsecond time scale. However, the major energetic effect of the disulfide occurs after the transition state for Arc refolding, slowing unfolding by 200 000-fold.     

Identification of the disulfide bonds in human plasma protein SP-40,40 (apolipoprotein-J).

SP-40,40, a human plasma protein, is a modulator of the membrane attack complex formation of the complement system as well as a subcomponent of high-density lipoproteins. In the present study, the positions of the disulfide bonds in SP-40,40 were determined. SP-40,40 was purified from human seminal plasma by affinity chromatography using an anti-SP-40,40 monoclonal antibody and reversed-phase, high-performance liquid chromatography (HPLC). The protein was digested with trypsin and the fragments were separated by reversed-phase HPLC. The peptides containing disulfide bonds were fluorophotometrically detected with 4-(aminosulfonyl)-7-fluoro-2,1,3-benzoxadiazole (ABD-F). The peptides containing more than two disulfide bonds were further digested with Staphylococcus aureus V8 protease and lysylendopeptidase, and the fragments were isolated by HPLC. The amino acid compositions and the amino acid sequences of the peptides containing only a disulfide bond were determined. Disulfide bonds thus determined were between Cys58(alpha)-Cys107(beta), Cys68(alpha)-Cys99(beta), Cys75(alpha)-Cys94(beta), and Cys86(alpha)-Cys80(beta). Since there was no free sulfhydryl groups in the SP-40,40 molecule, Cys78(alpha) and Cys91(beta) should also be linked by a disulfide bond. It is notable that all of the disulfide bonds in SP-40,40 are not only formed by inter-chain pairing, but also appear to form an antiparallel ladder-like structure between the two chains. The unique structure could be related to the functions of SP-40,40.     

Two pairs of conserved cysteines are required for the oxidative activity of Ero1p in protein disulfide bond formation in the endoplasmic reticulum

In the major pathway for protein disulfide-bond formation in the endoplasmic reticulum (ER), oxidizing equivalents flow from the conserved ER-membrane protein Ero1p to secretory proteins via protein disulfide isomerase (PDI). Herein, a mutational analysis of the yeast ERO1 gene identifies two pairs of conserved cysteines likely to form redox-active disulfide bonds in Ero1p. Cys100, Cys105, Cys352, and Cys355 of Ero1p are important for oxidative protein folding and for cell viability, whereas Cys90, Cys208, and Cys349 are dispensable for these functions. Substitution of Cys100 with alanine impedes the capture of Ero1p-Pdi1p mixed-disulfide complexes from yeast, and also blocks oxidation of Pdi1p in vivo. Cys352 and Cys355 are required to maintain the fully oxidized redox state of Ero1p, and also play an auxiliary role in thiol-disulfide exchange with Pdi1p. These results suggest a model for the function of Ero1p wherein Cys100 and Cys105 form a redox-active disulfide bond that engages directly in thiol-disulfide exchange with ER oxidoreductases. The Cys352-Cys355 disulfide could then serve to reoxidize the Cys100-Cys105 cysteine pair, possibly through an intramolecular thiol-disulfide exchange reaction.     

Reversible inactivation of AT(2) angiotensin II receptor from cysteine-disulfide bond exchange

Dithiothreitol (DTT) treatment of angiotensin II (Ang II) type 2 (AT(2)) receptor potentiates ligand binding, but the underlying mechanism is not known. Two disulfide bonds proposed in the extracellular domain were examined in this report. Based on the analysis of ligand affinity of cysteine (Cys, C) to alanine (Ala, A) substitution mutants, we provide evidence that Cys(35)-Cys(290) and Cys(117)-Cys(195) disulfide bonds are formed in the wild-type AT(2) receptor. Disruption of the highly conserved Cys(117)-Cys(195) disulfide bond linking the second and third extracellular segments leads to inactivation of the receptor. The Cys(35)-Cys(290) bond is highly sensitive to DTT. Its breakage results in an increased binding affinity for both Ang II and the AT(2) receptor-specific antagonist PD123319. Surprisingly, in the single Cys mutants, C35A and C290A, a labile population of receptors is produced which can be re-folded to high-affinity state by DTT treatment. These results suggest that the free -SH group of Cys(35) or Cys(290) competes with the disulfide bond formation between Cys(117) and Cys(195). This Cys-disulfide bond exchange results in production of the inactive population of the mutant receptors through formation of a non-native disulfide bond.     

One-Way Allosteric Communication between the Two Disulfide Bonds in Tissue Factor

Tissue factor (TF) is a transmembrane glycoprotein that plays distinct roles in the initiation of extrinsic coagulation cascade and thrombosis. TF contains two disulfide bonds, one each in the N-terminal and C-terminal extracellular domains. The C-domain disulfide, Cys186-Cys209, has a ?RHStaple configuration in crystal structures, suggesting that this disulfide carries high pre-stress. The redox state of this disulfide has been proposed to regulate TF encryption/decryption. Ablating the N-domain Cys49-Cys57 disulfide bond was found to increase the redox potential of the Cys186-Cys209 bond, implying an allosteric communication between the domains. Using molecular dynamics simulations, we observed that the Cys186-Cys209 disulfide bond retained the ?RHStaple configuration, whereas the Cys49-Cys57 disulfide bond fluctuated widely. The Cys186-Cys209 bond featured the typical ?RHStaple disulfide properties, such as a longer S-S bond length, larger C-S-S angles, and higher bonded prestress, in comparison to the Cys49-Cys57 bond. Force distribution analysis was used to sense the subtle structural changes upon ablating the disulfide bonds, and allowed us to identify a one-way allosteric communication mechanism from the N-terminal to the C-terminal domain. We propose a force propagation pathway using a shortest-pathway algorithm, which we suggest is a useful method for searching allosteric signal transduction pathways in proteins. As a possible explanation for the pathway being one-way, we identified a pronounced lower degree of conformational fluctuation, or effectively higher stiffness, in the N-terminal domain. Thus, the changes of the rigid domain (N-terminal domain) can induce mechanical force propagation to the soft domain (C-terminal domain), but not vice versa.     

Respiratory chain strongly oxidizes the CXXC motif of DsbB in the Escherichia coli disulfide bond formation pathway

Escherichia coli DsbB has four essential cysteine residues, among which Cys41 and Cys44 form a CXXC redox active site motif and the Cys104-Cys130 disulfide bond oxidizes the active site cysteines of DsbA, the disulfide bond formation factor in the periplasm. Functional respiratory chain is required for the cell to keep DsbA oxidized. In this study, we characterized the roles of essential cysteines of DsbB in the coupling with the respiratory chain. Cys104 was found to form the inactive complex with DsbA under respiration-defective conditions. While DsbB, under normal aerobic conditions, is in the oxidized state, having two intramolecular disulfide bonds, oxidation of Cys104 and Cys130 requires the presence of Cys41-Cys44. Remarkably, the Cys41-Cys44 disulfide bond is refractory to reduction by a high concentration of dithiothreitol, unless the membrane is solubilized with a detergent. This reductant resistance requires both the respiratory function and oxygen, since Cys41-Cys44 became sensitive to the reducing agent when membrane was prepared from quinone- or heme-depleted cells or when a membrane sample was deaerated. Thus, the Cys41-Val-Leu-Cys44 motif of DsbB is kept both strongly oxidized and strongly oxidizing when DsbB is integrated into the membrane with the normal set of respiratory components.     

Contribution of disulfide bonds to the conformational stability and catalytic activity of ribonuclease A.

Disulfide bonds between the side chains of cysteine residues are the only common crosslinks in proteins. Bovine pancreatic ribonuclease A (RNase A) is a 124-residue enzyme that contains four interweaving disulfide bonds (Cys26-Cys84, Cys40-Cys95, Cys58-Cys110, and Cys65-Cys72) and catalyzes the cleavage of RNA. The contribution of each disulfide bond to the conformational stability and catalytic activity of RNase A has been determined by using variants in which each cystine is replaced independently with a pair of alanine residues. Thermal unfolding experiments monitored by ultraviolet spectroscopy and differential scanning calorimetry reveal that wild-type RNase A and each disulfide variant unfold in a two-state process and that each disulfide bond contributes substantially to conformational stability. The two terminal disulfide bonds in the amino-acid sequence (Cys26-Cys84 and Cys58-Cys110) enhance stability more than do the two embedded ones (Cys40-Cys95 and Cys65-Cys72). Removing either one of the terminal disulfide bonds liberates a similar number of residues and has a similar effect on conformational stability, decreasing the midpoint of the thermal transition by almost 40 degrees C. The disulfide variants catalyze the cleavage of poly(cytidylic acid) with values of kcat/Km that are 2- to 40-fold less than that of wild-type RNase A. The two embedded disulfide bonds, which are least important to conformational stability, are most important to catalytic activity. These embedded disulfide bonds likely contribute to the proper alignment of residues (such as Lys41 and Lys66) that are necessary for efficient catalysis of RNA cleavage.     

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.     

Direct identification of disulfide bond linkages in human insulin-like growth factor I (IGF-I) by chemical synthesis

The primary structure of human IGF-I, except for the disulfide bond system, has been reported by Rinderknecht and Humbel. IGF-I afforded the corresponding characteristic peptide fragment on V8 protease digestion, which contained Cys6, Cys47, Cys48, and Cys52. Two possible fragments, Type I with Cys6-Cys47 and Cys48-Cys52, and Type II with Cys6-Cys48 and Cys47-Cys52, were synthesized. The disulfide bond system of IGF-I was unequivocally determined to be the Type II form along with Cys18-Cys61. Interestingly, the Type I system was included in the disulfide bond isomer produced as the main by-product in the refolding step on IGF-I synthesis by the recombinant DNA method.     

Selectivity of tryptophan residues in mediating photolysis of disulfide bridges in goat alpha-lactalbumin

Goat alpha-lactalbumin (GLA) contains four tryptophan (Trp) residues and four disulfide bonds. Illumination with near-UV light results in the cleavage of disulfide bridges and in the formation of free thiols. To obtain information about the reaction products, the illuminated protein was carbamidomethylated and digested with trypsin and the peptides were analyzed by mass spectrometry. Peptides containing Cys120Cam, Cys61Cam, or Cys91Cam were detected, as well as two peptides containing a new Cys-Lys cross-link. In one, Cys6 was cross-linked to Lys122, while the cross-link in the second was either a Cys91-Lys79 or Cys73-Lys93 cross-link; however, the exact linkage could not be defined. The results demonstrate photolytic cleavage of the Cys6-Cys120, Cys61-Cys77, and Cys73-Cys91 disulfide bonds. While photolysis of Cys6-Cys120 and Cys73-Cys91 disulfide bonds in GLA has been reported, cleavage of the Cys61-Cys77 disulfide bonds has not been previously detected. To examine the contribution of the individual Trp residues, we constructed the GLA mutants, W26F, W60F, W104F, and W118F, by replacing single Trp residues with phenylalanine (Phe). The substitution of each Trp residue led to less thiol production compared to that for wild-type GLA, showing that each Trp residue in GLA contributed to the photolytic cleavage of disulfide bridges. The specificity was expressed by the nature of the reaction products. No cleavage of the Cys6-Cys120 disulfide bridge was detected when the W26F mutant was illuminated, and no cleavage of the Cys73-Cys91 disulfide bridge was seen following illumination of W26F or W104F. In contrast, Cys61Cam, resulting from the cleavage of the Cys61-Cys77 disulfide bridge, was found following illumination of any of the mutants.     

Pairs of Vp1 cysteine residues essential for simian virus 40 infection

Transient disulfide bonding occurs during the intracellular folding and pentamerization of simian virus 40 (SV40) major capsid protein Vp1 (P. P. Li, A. Nakanishi, S. W. Clark, and H. Kasamatsu, Proc. Natl. Acad. Sci. USA 99:1353-1358, 2002). We investigated the requirement for Vp1 cysteine pairs during SV40 infection. Our analysis identified three Vp1 double-cysteine mutant combinations that abolished viability as assayed by plaque formation. Mutating the Cys49-Cys87 pair or the Cys87-Cys254 pair led to ineffective nuclear localization and diminished accumulation of the mutant Vp1s, and the defect extended in a dominant-negative manner to the wild-type minor capsid proteins Vp2/3 and an affinity-tagged recombinant Vp1 expressed in the same cells. Mutating the Cys87-Cys207 pair preserved the nuclear localization and normal accumulation of the capsid proteins but diminished the production of virus-like particles. Our results are consistent with a role for Cys49, Cys87, and Cys254 in the folding and cytoplasmic-nuclear trafficking of Vp1 and with a role for Cys87 and Cys207 in the assembly of infectious particles. These findings suggest that transient disulfide bond formation between certain Vp1 cysteine residues functions at two stages of SV40 infection: during Vp1 folding and oligomerization in the cytoplasm and during virion assembly in the nucleus.     

Determination of the disulfide bond arrangement of Newcastle disease virus hemagglutinin neuraminidase. Correlation with a beta-sheet propeller structural fold predicted for paramyxoviridae attachment proteins

Disulfide bonds stabilize the structure and functions of the hemagglutinin neuraminidase attachment glycoprotein (HN) of Newcastle disease virus. Until this study, the disulfide linkages of this HN and structurally similar attachment proteins of other members of the paramyxoviridae family were undefined. To define these linkages, disulfide-linked peptides were produced by peptic digestion of purified HN ectodomains of the Queensland strain of Newcastle disease virus, isolated by reverse phase high performance liquid chromatography, and analyzed by mass spectrometry. Analysis of peptides containing a single disulfide bond revealed Cys(531)-Cys(542) and Cys(172)-Cys(196) linkages and that HN ectodomains dimerize via Cys(123). Another peptide, with a chain containing Cys(186) linked to a chain containing Cys(238), Cys(247), and Cys(251), was cleaved at Met(249) with cyanogen bromide. Subsequent tandem mass spectrometry established Cys(186)-Cys(247) and Cys(238)-Cys(251) linkages. A glycopeptide with a chain containing Cys(344) linked to a chain containing Cys(455), Cys(461), and Cys(465) was treated sequentially with peptide-N-glycosidase F and trypsin. Further treatment of this peptide by one round of manual Edman degradation or tandem mass spectrometry established Cys(344)-Cys(461) and Cys(455)-Cys(465) linkages. These data, establishing the disulfide linkages of all thirteen cysteines of this protein, are consistent with published predictions that the paramyxoviridae HN forms a beta-propeller structural fold.