Disulfide bond plasticity in epidermal growth factor

Epidermal growth factor (EGF) has a (1-3,2-4,5-6) disulfide-bonding pattern. This pattern is found in nearly all EGF-like domains, despite wide variation in sequences. Biological data from EGF and at least one EGF-like domain show that disulfide bond isomers have significant bioactivity and suggests that the EGF fold can accommodate alternate disulfide-bonding patterns. The disulfide bonds in murine EGF were altered to seven different patterns and structures were calculated incorporating all the restraints from the highest resolution restraint set available (Tejero et al., 1996). Results showed that besides the native (1-3,2-4,5-6), two other disulfide-bonding patterns: (1-2,3-4,5-6) and (1-3,2-5,4-6) satisfied the restraints as well as the native. The results for these two patterns were indistinguishable from the native on the basis of distance and dihedral violations, XPLOR energies, Procheck statistics, and RMSDs of the final set of structures. Two other disulfide bond patterns, (1-2,3-5, 4-6) and (1-4,2-3,5-6) were able to satisfy all the distance restraints but had one or more cysteine dihedral violations. For all seven isomers, the final calculated structures were highly similar to EGF with all-atom RMSD's in the 1. 5-2 A range. These results suggest that the EGF backbone fold has the unique property of accommodating several different disulfide-bonding patterns.     

Thrombin inhibition by cyclic peptides from thrombomodulin.

Peptides corresponding to the loop regions of the fourth, fifth, and sixth epidermal growth factor (EGF)-like domains of thrombomodulin (TM) have been synthesized and assayed for thrombin inhibition, as indicated by both inhibition of thrombin-mediated fibrinogen clotting and inhibition of the association of thrombin with TM that results in protein C activation. Peptides from the fifth EGF-like domain showed significant inhibition of fibrinogen clotting and protein C activation, whereas peptides from the fourth and sixth EGF-like domains were weak inhibitors in both assays. Two structural features were important for inhibitory potency of the peptides from the fifth EGF-like domain: cyclization by a disulfide bond and attachment of the "tail" amino acids C-terminal to the disulfide loop. Linear control peptides did not significantly inhibit clotting or protein C activation. The C-terminal loop alone, the "tail" peptide, or a mixture of the two were at least 10-fold less potent inhibitors of clotting or protein C activation. A more constrained peptide analog was designed by deletion of an isoleucine within the C5-C6 disulfide loop, TM52-1 + 5C. This analog was a better inhibitor in both assay systems, having a Ki for protein C activation of 26 microM.     

Structural elements in glycoprotein 70 from polytropic Friend mink cell focus-inducing virus and glycoprotein 71 from ecotropic Friend murine leukemia virus, as defined by disulfide-bonding pattern and limited proteolysis.

The disulfide-bonding pattern of glycoprotein 70 (gp70), the surface glycoprotein (SU) encoded by the envelope gene of polytropic Friend milk cell focus-inducing virus, was elucidated and compared with that of glycoprotein 71 (gp71), the corresponding glycoprotein of the ecotropic Friend murine leukemia virus, which had previously been determined (M. Linder, D. Linder, J. Hahnen, H.-H. Schott, and Stirm, Eur. J. Biochem. 203:65-73, 1992). In the carboxy-terminal constant domain, in which these glycoproteins have about 97% sequence homology, the location of the four disulfide bonds was found to be analogous. In the amino-terminal differential domain, with about 37% sequence homology, 8 of the 12 cysteine residues of the ecotropic SU are conserved in the polytropic SU. In this domain, a similar clustering of disulfide bonds was detected, which led to the identification of three distinct disulfide-bonded regions in both glycoproteins. However, because of deletions and sequence deviations, the glycoproteins must have significantly different three-dimensional structures in these regions. Since the receptor-binding functions of both glycoproteins have been attributed to their amino-terminal domains and since each binds to a different receptor, these disulfide-bonded structures are likely candidates for receptor-binding functions. Limited proteolysis of both glycoproteins with various endoproteinases led to the identification of preferential proteolytic sites between disulfide-bonded regions, at the beginning of the hypervariable proline-rich region, and between differential and constant domains, further confirming the structural organization of the folded glycoproteins.     

Structural features and functional domains of amassin-1, a cell-binding olfactomedin protein.

Amassin-1 mediates a rapid cell adhesion that tightly adheres sea urchin coelomocytes (body cavity immunocytes) together. Three major structural regions exist in amassin-1: a short beta region, 3 coiled coils, and an olfactomedin domain. Amassin-1 contains 8 disulfide-bonded cysteines that, upon reduction, render it inactive. Truncated forms of recombinant amassin-1 were expressed and purified from Pichia pastoris and their disulfide bonding and biological activities investigated. Expressed alone, the olfactomedin domain contained 2 intramolecular disulfide bonds, existed in a monomeric state, and inhibited amassin-1-mediated clotting of coelomocytes by a calcium-dependent cell-binding activity. The N-terminal beta region, containing 3 cysteines, was not required for clotting activity. The coiled coils may dimerize amassin-1 in a parallel orientation through a homodimerizing disulfide bond. Neither amassin-1 fragments that were disulfide-linked as dimers or that were engineered to exist as dimers induced coelomocytes clotting. Clotting required higher multimeric states of amassin-1, possibly tetramers, which occurred through the N-terminal beta region and (or) the first segment of coiled coils.     

The folding pathway of alpha-lactalbumin elucidated by the technique of disulfide scrambling. Isolation of on-pathway and off-pathway intermediates

The technique of disulfide scrambling permits reversible conversion of the native and denatured (scrambled) proteins via shuffling and reshuffling of disulfide bonds. Under strong denaturing conditions (e.g. 6 m guanidinium chloride) and in the presence of a thiol initiator, alpha-lactalbumin (alphaLA) denatures by shuffling its four native disulfide bonds and converts to an assembly of 45 species of scrambled isomers. Among them, two predominant isomers, designated as X-alphaLA-a and X-alphaLA-d, account for about 50% of the total denatured structure of alphaLA. X-alphaLA-a and X-alphaLA-d, which adopt the disulfide patterns of (1-2,3-4,5-6,7-8) and (1-2,3-6,4-5,7-8), respectively, represent the most unfolded structures among the 104 possible scrambled isomers (Chang, J.-Y., and Li, L. (2001) J. Biol. Chem. 276, 9705-9712). In this study, X-alphaLA-a and X-alphaLA-d were purified and allowed to refold through disulfide scrambling to form the native alphaLA. Folding intermediates were trapped kinetically by acid quenching and analyzed quantitatively by reversed phase high pressure liquid chromatography. The results revealed two major on-pathway productive intermediates, two major off-pathway kinetic traps, and at least 30 additional minor transient intermediates. Of the two major on-pathway intermediates, one takes on a native-like alpha-helical domain, and the other comprises a structured beta-sheet, calcium binding domain. The two major kinetic traps are apparently stabilized by locally formed non-native-like structures. Overall, the folding mechanism of alphaLA is essentially congruent with the model of "folding funnel" furnished with a rather intricate energy landscape.     

The structure of denatured alpha-lactalbumin elucidated by the technique of disulfide scrambling: fractionation of conformational isomers of alpha-lactalbumin

The structure of denatured alpha-lactalbumin (alpha-LA) has been characterized using the method of disulfide scrambling. Under denaturing conditions (urea, guanidine hydrochloride, guanidine thiocyanate, organic solvent or elevated temperature) and in the presence of thiol initiator, alpha-LA denatures by shuffling its four native disulfide bonds and converts to a mixture of fully oxidized scrambled structures. Analysis by reversed-phase HPLC reveals that the denatured alpha-LA comprises a minimum of 45 fractions of scrambled isomers. Among them, six well populated isomers have been isolated and structurally characterized. Their relative concentrations, which represent the fingerprinting of the denatured alpha-LA, vary substantially under different denaturing conditions. These results permit independent plotting of the denaturation and unfolding curves of alpha-LA. Most importantly, unique isomers of partially unfolded alpha-LA were shown to populate at mild and selected denaturing conditions. Organic solvent disrupts preferentially the hydrophobic alpha-helical domain, generating a predominant isomer containing two native disulfide bonds at the beta-sheet domain and two scrambled disulfide bonds at the alpha-helical region. Thermal denaturation selectively unfolds the beta-sheet domain of alpha-LA, producing a prevalent isomer that exhibits structural characteristics of the molten globule state of alpha-LA.     

Distinct Unfolding and Refolding Pathways of Lipid Transfer Proteins LTP1 and LTP2

Plant non-specific lipid transfer proteins (ns-LTPs) comprise two families, LTP1s and LTP2s, all structurally stabilized by four native disulfide bonds. Solution and crystal structures of both LTP1s and LTP2s from various plants have been determined. Despite the similarities of their biological function and backbone folds, the biophysical properties of LTP1s and LTP2s differ significantly. In this report, the mechanisms of unfolding and refolding of rice LTP1 and LTP2 have been investigated using the technique of disulfide bonds scrambling. LTP1 is shown to unfold and refold via predominant species of partially structured intermediates. Four isomers of partly unfolded and extensively unfolded LTP1 were identified, isolated and their disulfide structures were determined. By contrast, unfolding and refolding of LTP2 adopt a (close to) two-state mechanism, and undergo a reversible conversion between the native and a single extensively unfolded isomer without accumulation of any significant intermediate.     

Complete determination of disulfide bonds localized within the short consensus repeat units of decay accelerating factor (CD55 antigen).

Decay accelerating factor (DAF) has 4 SCR (short consensus repeat) units. Each SCR unit consists of approx. 60 amino acids characterized by having four conserved cysteine residues and several other highly conserved residues which include proline, tryptophan, tyrosine/phenylalanine and glycine. To determine the disulfide-bonding pattern, we used the urine form of DAF. After thermolysin and trypsin digestion, we isolated seven disulfide-linked peptides by HPLC purification. Because all of the cysteine residues are disulfide-bonded, DAF should contain eight disulfide bonds. After subtilisin and trypsin digestion, we isolated the eighth disulfide-bonded peptides by HPLC purification. From sequence analyses of these peptides, we could identify all disulfide bonds in the 4 SCR units of DAF as being between the first and the third and between the second and the fourth half-cystines within each SCR unit.     

Unfolding of human proinsulin. Intermediates and possible role of its C-peptide in folding/unfolding.

We have investigated the in vitro refolding process of human proinsulin (HPI) and an artificial mini-C derivative of HPI (porcine insulin precursor, PIP), and found that they have significantly different disulfide-formation pathways. HPI and PIP differ in their amino acid sequences due to the presence of the C-peptide linker found in HPI, therefore suggesting that the C-peptide linker may be responsible for the observed difference in folding behaviour. However, the manner in which the C-peptide contributes to this difference is still unknown. We have used both the disulfide scrambling method and a redox-equilibrium assay to assess the stability of the disulfide bridges. The results show that disulfide reshuffling is easier to induce in HPI than in PIP by the addition of thiol reagent. Thus, the C-peptide may affect the unique folding pathway of HPI by allowing the disulfide bonds of HPI to be easily accessible. The detailed processes of HPI unfolding by reduction of its disulfide bonds and by disulfide scrambling methods were also investigated. In the reductive unfolding process no accumulation of intermediates was detected. In the process of unfolding by disulfide scrambling, HPI gradually rearranged its disulfide bonds to form three major isomers G1, G2 and G3. The most abundant isomer, G1, contains the B7-B19 disulfide bridge. Based on far-UV CD spectra, native gel analysis and cleavage by endoproteinase V8, the G1 isomer has been shown to resemble the intermediate P4 found in the refolding process of HPI. Finally, the major isomer G1 is allowed to refold to native protein HPI by disulfide rearrangement, which indicates that a similar molecular mechanism may exist for the unfolding and refolding process of HPI.     

P22 tailspike trimer assembly is governed by interchain redox associations

Though disulfide bonds are absent from P22 tailspike protein in its native state, a disulfide-bonded trimeric intermediate has been identified in the tailspike folding and assembly pathway in vitro. The formation of disulfide bonds is critical to efficient assembly of native trimers as mutations at C-terminal cysteines reduce or inhibit trimer formation. We investigated the effect of different redox folding environments on tailspike formation to discover if simple changes in reducing potential would facilitate trimer formation. Expression of tailspike in trxB cell lines with more oxidizing cytoplasms led to lower trimer yields; however, observed assembly rates were unchanged. In vitro, the presence of any redox buffer decreased the overall yield compared to non-redox buffered controls; however, the greatest yields of the native trimer were obtained in reducing rather than oxidizing environments at pH 7. Slightly faster trimer formation rates were observed in the redox samples at pH 7, perhaps by accelerating the reduction of the disulfide-bonded protrimer to the native trimer. These rates and the effects of the redox system were found to depend greatly on the pH of the refolding reaction. Oxidized glutathione (GSSG) trapped a tailspike intermediate, likely as a mixed disulfide. This trapped intermediate was able to form native trimer upon addition of dithiothreitol (DTT), indicating that the trapped intermediate is on the assembly pathway, rather than the aggregation pathway. Thus, the presence of redox agents interfered with the ability of the tailspike monomers to associate, demonstrating that disulfide associations play an important role during the assembly of this cytoplasmic protein.     

Two-step selective formation of three disulfide bridges in the synthesis of the C-terminal epidermal growth factor-like domain in human blood coagulation factor IX.

The 45-residue C-terminal EGF-like domain in human blood coagulation factor IX has been synthesized by a 2-step method to form selectively 3 disulfide bridges. Four out of 6 cysteines are blocked with either trityl or 4-methyl-benzyl, and the remaining 2 cysteines are blocked with acetamidomethyl (Acm). In the first step, 4 free cysteinyl thiols are released concurrently with the removal of all protecting groups except Acm and are oxidized to form 1 of the 3 possible isomers containing 2 pairs of disulfides. In the second step, iodine is used to remove the Acm groups to yield the third disulfide bridge. This approach reduces the number of possible disulfide bridging patterns from 15 to 3. To determine the optimal protecting group strategy, 3 peptides are synthesized, each with Acm blocking 1 of the 3 pairs of cysteines involved in disulfide bridges: Cys5 to Cys16 (Cys 1-3), Cys12 to Cys26 (Cys 2-4), or Cys28 to Cys41 (Cys 5-6). Only the peptide having the Cys 2-4 pair blocked with Acm forms the desired disulfide isomer (Cys 1-3/5-6) in high yield after the first step folding, as identified by proteolytic digestion in conjunction with mass spectrometric peptide mapping. Thus, the choice of which pair of cysteines to block with Acm is critically important. In the case of EGF-like peptides, it is better to place the Acm blocking groups on one of the pairs of cysteines involved in the crossing of disulfide bonds.     

Oxidative protein folding in vitro: a study of the cooperation between quiescin-sulfhydryl oxidase and protein disulfide isomerase

The flavin-dependent quiescin-sulfhydryl oxidase (QSOX) inserts disulfide bridges into unfolded reduced proteins with the reduction of molecular oxygen to form hydrogen peroxide. This work investigates how QSOX and protein disulfide isomerase (PDI) cooperate in vitro to generate native pairings in two unfolded reduced proteins: ribonuclease A (RNase, four disulfide bonds and 105 disulfide isomers of the fully oxidized protein) and avian riboflavin binding protein (RfBP, nine disulfide bonds and more than 34 million corresponding disulfide pairings). Experiments combining avian or human QSOX with up to 200 muM avian or human reduced PDI show that the isomerase is not a significant substrate of QSOX. Both reduced RNase and RfBP can be efficiently refolded in an aerobic solution containing micromolar concentrations of reduced PDI and nanomolar levels of QSOX without any added oxidized PDI or glutathione redox buffer. Refolding of RfBP is followed continuously using the complete quenching of the fluorescence of free riboflavin that occurs on binding to apo-RfBP. The rate of refolding is half-maximal at 30 muM reduced PDI when the reduced client protein (1 muM) is used in the presence of 30 nM QSOX. The use of high concentrations of PDI, in considerable excess over the folding protein client, reflects the concentration prevailing in the lumen of the endoplasmic reticulum and allows the redox poise of these in vitro experiments to be set with oxidized and reduced PDI. In the absence of either QSOX or redox buffer, the fastest refolding of RfBP is accomplished with excess reduced PDI and just enough oxidized PDI to generate nine disulfides in the protein client. These in vitro experiments are discussed in terms of current models for oxidative folding in the endoplasmic reticulum.     

Acetaldehyde-ethanol exchange in vivo during ethanol oxidation.

Bovine thrombin was immobilized on sepharose 4B through an oxidized sialic acid group on its B chain. The immobilized thrombin was reduced with β-mercaptoethanol in 8 m urea under conditions that were shown to be sufficient to reduce the disulfide bond connecting the A and B chains. The immobilized B chain that remained after the A chain was washed away was allowed to refold, and the disulfide bonds were reoxidized with a mixture of oxidized and reduced glutathione under anaerobic conditions. The refolded immobilized B chain exhibited 15–25% of the tosyl-l-arginine methyl ester esterase activity of the immobilized thrombin and a significant amount of fibrinogen clotting activity. The immobilized B chain behaved qualitatively like immobilized thrombin towards two oligopeptide fibrinogen-like substrates and showed no activity towards lysine or arginine peptide bonds in a fragment of ribonuclease.Since the recovered activity was greater than that computed for a random refolding of seven -SH groups to form three SS bonds, it is concluded that the B chain retains a sufficient number of interacting groups to refold correctly, and it is suggested that prothrombin might fold in localized domains with only weak interactions between domains. The behavior of the B chain towards the substrates tested suggests that the A chain does not play a significant role in determining the catalytic specificity of thrombin or in distinguishing its specificity from that of trypsin.     

Prediction of the disulfide-bonding state of cysteine in proteins

The bonding states of cysteine play important functional and structural roles in proteins. In particular, disulfide bond formation is one of the most important factors influencing the three-dimensional fold of proteins. Proteins of known structure were used to teach computer-simulated neural networks rules for predicting the disulfide-bonding state of a cysteine given only its flanking amino acid sequence. Resulting networks make accurate predictions on sequences different from those used in training, suggesting that local sequence greatly influences cysteines in disulfide bond formation. The average prediction rate after seven independent network experiments is 81.4% for disulfide-bonded and 80.0% for non-disulfide-bonded scenarios. Predictive accuracy is related to the strength of network output activities. Network weights reveal interesting position-dependent amino acid preferences and provide a physical basis for understanding the correlation between the flanking sequence and a cysteine's disulfide-bonding state. Network predictions may be used to increase or decrease the stability of existing disulfide bonds or to aid the search for potential sites to introduce new disulfide bonds.     

Synthesis and conformational analysis of the insulin-like 4 gene product.

Insulin-like 4 (INSL-4) is a protein expressed in the early placenta. Its primary structure is insulin-like with reference to the distribution of cysteine residues and the single chain pro-form. Insulin-like 4 was generated by solid-phase peptide synthesis of the two chains followed by the sequential synthesis of the three disulfide bonds. Two disulfide isomers were produced, one with an insulin-like disulfide bonding pattern and the other with a reversed chain orientation. The CD spectra of the two disulfide isomers were indistinguishable without any features produced by periodic structures. In addition, the hydrodynamic properties of the two isomers were identical which implied a very open structure of the disulfide-bonded two-chain molecules. It appears that insulin-likeness cannot be defined solely on the basis of the primary structure of cDNA.     

Snake inhibitors of phospholipase A(2) enzymes

Fragment 53--103 of bovine alpha-lactalbumin, prepared by limited peptic digestion of the protein at low pH, is a 51-residue polypeptide chain crosslinked by two disulfide bonds encompassing helix C (residues 86--98) of the native protein. Refolding of the fully reduced fragment (four--SH groups) is expected to lead to three fully oxidized isomers, the native (61--77, 73--91) and the two misfolded species named ribbon (61--91, 73--77) and beads (61--73, 77--91) isomers. The fragment with correct disulfide bonds was formed in approx. 30% yield when refolding was conducted in aqueous solution at neutral pH in the presence of the redox system constituted by reduced and oxidized glutathione. On the other hand, when the reaction was conducted in 30% (v/v) trifluoroethanol (TFE), the oxidative refolding to the native isomer was almost quantitative. To provide an explanation of the beneficial effect of TFE in promoting the correct oxidative folding, the conformational features of the various fragment species were analyzed by far-UV circular dichroism measurements. The fully reduced fragment is largely unfolded in water, but it becomes helical in aqueous TFE. Correctly refolded fragment is produced most when the helical contents of the reduced and oxidized fragment in aqueous TFE are roughly equal. It is proposed that 30% TFE promotes a native-like format of the fragment and thus an efficient and correct pairing of disulfides. Higher concentrations of TFE, instead, promote some non-native helical secondary structure in the fragment species, thus hampering correct folding.     

A novel approach to the synthesis of EGF-like domains: a method for the one-pot regioselective formation of the three disulfide bonds of a human blood coagulation factor VII EGF-1 analogue.

The study of EGF-like domains is of great general interest in protein science because of their participation in a multitude of protein-protein interactions. A common structural feature of EGF-like modules is the presence of three disulfide bonds, the regioselective formation of which still remains a challenge to peptide chemists. We report here on a method for the one-pot regioselective synthesis of an analogue of the EGF-1 domain of human coagulation Factor VII (residues 45-83) comprising an Asn57beta-Asp substitution. The cysteine protecting groups trityl, t-butyl and acetamidomethyl were chosen for the three disulfide bond pairings. All three disulfide bridges were prepared directly from the crude starting product, obviating the need for the timely and costly purification of the intermediate folded products. The fully folded product was purified by preparative high-pressure liquid chromatography prior to evaluation of its biological activity in an assay to detect inhibition of FVII/TF complex formation. In addition circular dichroism spectroscopy was employed to elucidate the main structural similarities between this peptide analogue and the native human Factor VII EGF-1 domain.     

Putative disulfide-forming pathway of porcine insulin precursor during its refolding in vitro

Although the structure of insulin has been well studied, the formation pathway of the three disulfide bridges during the refolding of insulin precursor is ambiguous. Here, we reported the in vitro disulfide-forming pathway of a recombinant porcine insulin precursor (PIP). In redox buffer containing L-arginine, the yield of native PIP from fully reduced/denatured PIP can reach 85%. The refolding process was quenched at different time points, and three distinct intermediates, including one with one disulfide linkage and two with two disulfide bridges, have been captured and characterized. An intra-A disulfide bridge was found in the former but not in the latter. The two intermediates with two disulfide bridges contain the common A20-B19 disulfide linkage and another inter-AB one. Based on the time-dependent formation and distribution of disulfide pairs in the trapped intermediates, two different forming pathways of disulfide bonds in the refolding process of PIP in vitro have been proposed. The first one involves the rapid formation of the intra-A disulfide bond, followed by the slower formation of one of the inter-AB disulfide bonds and then the pairing of the remaining cysteines to complete the refolding of PIP. The second pathway begins first with the formation of the A20-B19 disulfide bridge, followed immediately by another inter-AB one, possibly nonnative. The nonnative two-disulfide intermediates may then slowly rearrange between CysA6, CysA7, CysA11, and CysB7, until the native disulfide bond A6-A11 or A7-B7 is formed to complete the refolding of PIP. The proposed refolding behavior of PIP is compared with that of IGF-I and discussed.     

Determination of in vivo disulfide-bonded proteins in Arabidopsis

Protein thiol-disulfide oxidoreduction plays an important role in redox regulation of cellular processes. Here we present a proteomic approach to visualize and map in vivo disulfide-bonded proteins in plants. A proteomic map of the disulfide-bonded proteins was achieved using 2D gel electrophoresis of Arabidopsis protein extract. Along with novel proteins identified as potentially redox regulated, we have also shown the feasibility of mapping some of the cysteines involved in the formation of disulfide bonds. This study presents an important tool for characterizing redox-regulated proteins.