A convenient method for the synthesis of oligonucleotide-cationic peptide conjugates

A method was developed for the synthesis of oligonucleotide-cationic peptide conjugates in solution phase by disulfide bond formation. Precipitation was avoided by the easily removable triethylammonium trifluoroacetate (TEATFAc) salt which served at the same time as a buffer of the reaction mixture. The fast and high yielding disulfide bond formation was due to the Npys thio protecting and activating group of Cys. A solution of the free 5-thiol modified oligonucleotide obtained from Poly-Pak purification was used for conjugation.     

Stability and structure-forming properties of the two disulfide bonds of alpha-conotoxin GI

alpha-Conotoxin GI is a 13 residue snail toxin peptide cross-linked by Cys2-Cys7 and Cys3-Cys13 disulfide bridges. The formation of the two disulfide bonds by thiol/disulfide exchange with oxidized glutathione (GSSG) has been characterized. To characterize formation of the first disulfide bond in each of the two pathways by which the two disulfide bonds can form, two model peptides were synthesized in which Cys3 and Cys13 (Cono-1) or Cys2 and Cys7 (Cono-2) were replaced by alanines. Equilibrium constants were determined for formation of the single disulfide bonds of Cono-1 and Cono-2, and an overall equilibrium constant was measured for formation of the two disulfide bonds of alpha-conotoxin GI in pH 7.00 buffer and in pH 7. 00 buffer plus 8 M urea using concentrations obtained by HPLC analysis of equilibrium thiol/disulfide exchange reaction mixtures. The results indicate a modest amount of cooperativity in the formation of the second disulfide bond in both of the two-step pathways by which alpha-conotoxin GI folds into its native structure at pH 7.00. However, when considered in terms of the reactive thiolate species, the results indicate substantial cooperativity in formation of the second disulfide bond. The solution conformational and structural properties of Cono-1, Cono-2, and alpha-conotoxin GI were studied by 1H NMR to identify structural features which might facilitate formation of the disulfide bonds or are induced by formation of the disulfide bonds. The NMR data indicate that both Cono-1 and Cono-2 have some secondary structure in solution, including some of the same secondary structure as alpha-conotoxin GI, which facilitates formation of the second disulfide bond by thiol/disulfide exchange. However, both Cono-1 and Cono-2 are considerably less structured than alpha-conotoxin GI, which indicates that formation of the second disulfide bond to give the Cys2-Cys7, Cys3-Cys13 pairing induces considerable structure into the backbone of the peptide.     

Probing the dark state tertiary structure in the cytoplasmic domain of rhodopsin: proximities between amino acids deduced from spontaneous disulfide bond formation between cysteine pairs engineered in cytoplasmic loops 1, 3, and 4

To probe proximities between amino acids in the cytoplasmic domain by using mutants containing engineered cysteine pairs, three sets of rhodopsin mutants have been prepared. In the first two sets, a cysteine was placed, one at a time, at positions 311-314 in helix VIII, while the second cysteine was fixed at position 246 (set I) and at position 250 (set II) at the cytoplasmic end of helix VI. In the third set, one cysteine was fixed at position 65 while the second cysteine was varied between amino acid positions 306 and 321 located at the cytoplasmic end of helix VII and throughout in helix VIII. Rapid disulfide bond formation in the dark was found between the cysteine pairs in mutants A246C/Q312C,A246C/K311C and in mutants H65C/C316, H65C/315C and H65C/312C. Disulfide bond formation at much lower rates was found in mutants A246C/F313C, V250C/Q312C, H65C/N310C, H65C/K311C, H65C/F313C, and H65C/R314C; the remaining mutants showed no significant disulfide bond formation. Comparisons of the results from disulfide bond formation in solution with the distances observed in the rhodopsin crystal structure showed that the rates of disulfide bond formation in most cases were consistent with the amino acid proximities as revealed in crystal structure. However, deviations were also found, in particular, in the set containing fixed cysteine at position Cys246 and cysteines at positions 311-314. The results implicate significant effects of structural dynamics on disulfide bond formation in solution.     

Interchain disulfide bonds promote protein cross-linking during protein folding

We provide evidence that in vitro protein cross-linking can be accomplished in three concerted steps: (i) a change in protein conformation; (ii) formation of interchain disulfide bonds; and (iii) formation of interchain isopeptide cross-links. Oxidative refolding and thermal unfolding of ribonuclease A, lysozyme, and protein disulfide isomerase led to the formation of cross-linked dimers/oligomers as revealed by SDS-polyacrylamide gel electrophoresis. Chemical modification of free amino groups in these proteins or unfolding at pH < 7.0 resulted in a loss of interchain isopeptide cross-linking without affecting interchain disulfide bond cross-linking. Furthermore, preformed interchain disulfide bonds were pivotal for promoting subsequent interchain isopeptide cross-links; no dimers/oligomers were detected when the refolding and unfolding solution contained the reducing agent dithiothreitol. Similarly, the Cys326Ser point mutation in protein disulfide isomerase abrogated its ability to cross-link into homodimers. Heterogeneous proteins become cross-linked following the formation of heteromolecular interchain disulfide bonds during thermal unfolding of a mixture of of ribonuclease A and lysozyme. The absence of glutathione and glutathione disulfide during the unfolding process attenuated both the interchain disulfide bond cross-links and interchain isopeptide cross-links. No dimers/oligomers were detected when the thermal unfolding temperature was lower than the midpoint of thermal denaturation temperature.     

On the requirement of oxidizing reagent for the formation of a disulfide bond

Cyclization of a peptide through the formation of a disulfide bond between the SH groups of cysteines on the N- and C-terminals of peptide was studied in degassed water solution under vacuum. Cyclization went to completion although the solution was oxygen deficient (the number of oxygen molecules available for the reaction was at least 16 times less than the number of peptide molecules). This result indicates that, contrary to the common assumption, disulfide bond formation does not necessarily require an oxidant (O(2), I(2), etc.) to occur.     

Metallothionein disulfides are present in metallothionein-overexpressing transgenic mouse heart and increase under conditions of oxidative stress

Metallothionein (MT) releases zinc under oxidative stress conditions in cultured cells. The change in the MT molecule after zinc release in vivo is unknown although in vitro studies have identified MT disulfide bond formation. The present study was undertaken to test the hypothesis that MT disulfide bond formation occurs in vivo. A cardiac-specific MT-overexpressing transgenic mouse model was used. Mice were administered saline as a control or doxorubicin (20 mg/kg), which is an effective anticancer drug but with severe cardiac toxicity at least partially because of the generation of reactive oxygen species. A differential alkylation of cysteine residues in MT of the heart extracts was performed. Free and metal-bound cysteines were first trapped by N-ethylmaleimide and the disulfide bonds were reduced by dithiothreitol followed by alkylation with radiolabeled iodoacetamide. Analyses of the differentially alkylated MTs in the heart extract by high performance liquid chromatography, SDS-PAGE, Western blot, and mass spectrometry revealed that disulfide bonds were present in MT in vivo under both physiological and oxidative stress conditions. More disulfide bonds were found in MT under the oxidative stress conditions. The MT disulfide bonds were likely intramolecular and both alpha- and beta-domains were involved in the disulfide bond formation, although the alpha-domain appeared to be more easily oxidized than the beta-domain. The results suggest that under physiological conditions, the formation of MT disulfide bonds is involved in the regulation of zinc homeostasis. Additional zinc release from MT under oxidative stress conditions is accompanied by more MT disulfide bond formation.     

Synthetic approaches to multivalent lipopeptide dendrimers containing cyclic disulfide epitopes of foot-and-mouth disease virus

The synthesis of a multiantigenic peptide dendrimer incorporating four copies of a cyclic disulfide epitope has been undertaken. Since standard chemoselective ligation procedures involving thioether formation are inadvisable in the presence of a preformed disulfide, conjugation through a peptide bond between the lipidated branched lysine scaffold and a suitably protected version of the cyclic disulfide has been used instead. Several synthetic approaches to the partially protected cyclic disulfide peptide have been explored. The most effective involves building a minimally protected version of the peptide by Boc solid phase synthesis, using fluorenyl-based anchorings and cysteine protecting groups. Peptide-resin cleavage and cysteine deprotection/oxidation are performed simultaneously by base-promoted elimination. The cyclic disulfide epitope is readily obtained in sufficient amounts by this procedure and subsequently incorporated to the lipidated lysine core by peptide bond formation in solution. A final acid deprotection step in anhydrous HF yields a peptide construction containing a maximum of three copies of the cyclic disulfide epitope, the lower substitution being attributable to steric constraints. This immunogen has been successfully used in an experimental vaccination trial against foot-and-mouth disease virus.     

In vitro catalysis of oxidative folding of disulfide-bonded proteins by the Escherichia coli dsbA (ppfA) gene product.

It was shown previously that the Escherichia coli gene ppfA (dsbA) encodes a periplasmic protein, and its inactivation leads to a deficiency in disulfide bond formation of envelope proteins (Kamitani, S., Akiyama, Y., and Ito, K. (1992) EMBO J. 11, 57-62; Bardwell, J. C. A., McGovern, K., and Beckwith, J. (1991) Cell 67, 581-589). The DsbA/PpfA protein was overproduced, purified, and examined for its activities in vitro. Its abundance in a wild-type cell was estimated to be about 850 molecules which probably exist as homodimers as suggested by size exclusion chromatography. Purified DsbA markedly stimulated disulfide bond formation of E. coli alkaline phosphatase, either in vitro synthesized or purified and denatured, as well as of reduced bovine ribonuclease A. The DsbA-catalyzed rapid disulfide bond formation occurred after a lag period which appeared to be determined by the redox state of the reaction mixture and concentration of DsbA. Inclusion of higher concentrations of oxidized glutathione or DsbA shortened the lag period. We propose that DsbA, which proved to directly catalyze disulfide bond formation, may also have a role in maintaining the bacterial periplasm oxidative.     

Conformational changes necessary for gene regulation by Tet repressor assayed by reversible disulfide bond formation.

We constructed and characterized four Tet repressor (TetR) variants with engineered cysteine residues which can form disulfide bonds and are located in regions where conformational changes during induction by tetracycline (tc) might occur. All TetR mutants show nearly wild-type activities in vivo, and the reduced proteins also show wild-type activities in vitro. Complete and reversible disulfide bond formation was achieved in vitro for all four mutants. The disulfide bond in NC18RC94 immobilizes the DNA reading head with respect to the protein core and prevents operator binding. Formation of this disulfide bond is possible only in the tc-bound, but not in the operator-bound conformation. Thus, these residues must have different conformations when bound to these ligands. The disulfide bonds in DC106PC159' and EC107NC165' immobilize the variable loop between alpha-helices 8 and 9 located near the tc-binding pocket. A faster rate of disulfide formation in the operator-bound conformation and a lack of induction after disulfide formation show that the variable loop is located closer to the protein core in the operator-bound conformation and that a movement is necessary for induction. The disulfide bond in RC195VC199' connects alpha-helices 10 and 10' of the two subunits in the dimer and is only formed in the tc-bound conformation. The oxidized protein shows reduced operator binding. Thus, this bond prevents formation of the operator-bound conformation. The detection of conformational changes in three different regions is the first biochemical evidence for induction-associated global internal movements in TetR.     

Synthesis of peptide substrates for mammalian thioredoxin reductase.

Mammalian thioredoxin reductase (TR) catalyzes the reduction of the redox-active disulfide bond of thioredoxin (Trx) and is similar in structure and mechanism to glutathione reductase except for a C-terminal 16-amino acid extension containing a rare vicinal selenylsulfide bond. This vicinal selenylsulfide bond is essentially a substrate for the enzyme's N-terminal redox center. Here we report the synthesis of peptide substrates for the truncated enzyme missing the C-terminal redox center. We developed a procedure for the synthesis of peptides containing cyclic vicinal disulfide/selenylsulfide bonds as well as their corresponding acyclic heterodimers. Vicinal disulfide bonds form eight-membered ring structures and are difficult to synthesize owing to their propensity to dimerize during oxidation. Our procedure makes use of two key improvements for on-resin disulfide bond formation presented previously by Galande and coworkers (Galande AK, Weissleder R, Tung C-H. An effective method of on-resin disulfide bond formation in peptides. J. Comb. Chem. 2005; 7: 174-177). First, the addition of an amine base to the deprotection solution allows the complete removal of the StBu group, allowing it to be replaced with a 5-Npys group. The second enhancement is the direct use of a Cys(Mob) or Sec(Mob) derivative as the nucleophilic partner instead of utilizing a naked sulfhydryl or selenol. These improvements result in the formation of a vicinal disulfide (or selenylsulfide) bond in high purity and yield. A direct comparison with the Galande procedure is presented. We also present a novel strategy for the formation of an acyclic, interchain selenylsulfide-linked peptide (linking H-PTVTGC-OH and H-UG-OH). Cysteine analogs of the cyclic and acyclic peptides were also synthesized. The results show that the ring structure contributes a factor of 52 to the rate, but the presence of selenium in the peptide is more important to catalysis than the presence of the ring.     

Reexamination of the role of interplay between glutathione and protein disulfide isomerase

Protein disulfide isomerase (PDI) has an essential role in the process of disulfide bond formation, where it catalyzes disulfide bond formation, reduction, and isomerization. It is thought that the major route for oxidizing dithiols in folding proteins to disulfides is via Ero1-mediated oxidation of PDI. Since the discovery of Ero1, the role of glutathione in disulfide bond formation has been downplayed. In this study, the role of glutathione in disulfide bond formation was reexamined. Here we have studied in vitro the kinetics of the glutathione-mediated oxidation and reduction of the catalytic a domains of human PDI and yeast Pdi1p. The results obtained from stopped-flow and quenched-flow experiments show that the reactions of PDI and Pdi1p are faster and more complex than previously thought. Our results suggest that the kinetics of oxidation of PDI and Pdi1p by oxidized glutathione are remarkably similar, whereas the kinetics of reduction by reduced glutathione shows clear differences. The data generated here on the rapid reactivity of PDI towards glutathione suggest that reevaluation is required for several aspects of the field of catalyzed disulfide bond formation, including the potential physiological role of glutathione.     

Bombyxin-II and its disulfide bond isomers: synthesis and activity.

Bombyxin-II, an insulin superfamily peptide of the silkmoth Bombyx mori, and its disulfide bond isomers have been synthesized by two ways of stepwise, semi-regioselective disulfide bond formation. The disulfide bond CysA20-CysB22 or CysA7-CysB10 was formed first, and then the two other disulfide bonds were formed by iodine oxidation. The conditions for the iodine oxidation were improved to suppress oxidative degradation of unprotected Trp residues. With these conditions, bombyxin-II was synthesized in high yields (26% and 32%). Its disulfide bond isomers were also obtained. Specific activity of the products indicates that the disulfide bond CysA20-CysB22 is important to the bombyxin activity.     

Glutathione is required to regulate the formation of native disulfide bonds within proteins entering the secretory pathway

The formation of native disulfide bonds is an essential event in the folding and maturation of proteins entering the secretory pathway. For native disulfides to form efficiently an oxidative pathway is required for disulfide bond formation and a reductive pathway is required to ensure isomerization of non-native disulfide bonds. The oxidative pathway involves the oxidation of substrate proteins by PDI, which in turn is oxidized by endoplasmic reticulum oxidase (Ero1). Here we demonstrate that overexpression of Ero1 results in the acceleration of disulfide bond formation and correct protein folding. In contrast, lowering the levels of glutathione within the cell resulted in acceleration of disulfide bond formation but did not lead to correct protein folding. These results demonstrate that lowering the level of glutathione in the cell compromises the reductive pathway and prevents disulfide bond isomerization from occurring efficiently, highlighting the crucial role played by glutathione in native disulfide bond formation within the mammalian endoplasmic reticulum.     

Disulfide bond formation in secreton component PulK provides a possible explanation for the role of DsbA in pullulanase secretion

When expressed in Escherichia coli, the 15 Klebsiella oxytoca pul genes that encode the so-called Pul secreton or type II secretion machinery promote pullulanase secretion and the assembly of one of the secreton components, PulG, into pili. Besides these pul genes, efficient pullulanase secretion also requires the host dsbA gene, encoding a periplasmic disulfide oxidoreductase, independently of disulfide bond formation in pullulanase itself. Two secreton components, the secretin pilot protein PulS and the minor pseudopilin PulK, were each shown to posses an intramolecular disulfide bond whose formation was catalyzed by DsbA. PulS was apparently destabilized by the absence of its disulfide bond, whereas PulK stability was not dramatically affected either by a dsbA mutation or by the removal of one of its cysteines. The pullulanase secretion defect in a dsbA mutant was rectified by overproduction of PulK, indicating reduced disulfide bond formation in PulK as the major cause of the secretion defect under the conditions tested (in which PulS is probably present in considerable excess of requirements). PulG pilus formation was independent of DsbA, probably because PulK is not needed for piliation.     

Increased production of human proinsulin in the periplasmic space of Escherichia coli by fusion to DsbA

The production of human proinsulin in its disulfide-intact, native form in Escherichia coli requires disulfide bond formation and the periplasmic space is the favourable compartment for oxidative folding. However, the secretory expression of proinsulin is limited by its high susceptibility to proteolysis and by disulfide bond formation, which is rate-limiting for proinsulin folding. In this report we describe a method for the production of high amounts of soluble, native human proinsulin in E. coli. We fused proinsulin to the C-terminus of the periplasmic disulfide oxidoreductase DsbA via a trypsin cleavage site. As DsbA is the main catalyst of disulfide bond formation in E. coli, we expected increased yields of proinsulin by intra- or intermolecular catalysis of disulfide bond formation. In the context of the fusion protein, proinsulin was found to be stabilised, probably due to an increased solubility and faster disulfide bond formation. To increase the yield of DsbA-proinsulin in the periplasm, several parameters were optimised, including host strains and cultivation conditions, and in particular growth medium composition and supplement of low molecular weight additives. We obtained a further, about three-fold increase in the amount of native DsbA-proinsulin by addition of L-arginine or ethanol to the culture medium. The maximum yield of native human proinsulin obtained from the soluble periplasmic fraction after specific cleavage of the fusion protein with trypsin was 9.2 mg g(-1), corresponding to 1.8% of the total cell protein.     

Structural and mutational analysis of a monomeric and dimeric form of a single domain antibody with implications for protein misfolding

Camelid single domain antibodies (sdAb) are known for their thermal stability and reversible refolding. We have characterized an unusually stable sdAb recognizing Staphylococcal enterotoxin B with one of the highest reported melting temperatures (T_m = 85°C). Unexpectedly, ～10?20% of the protein formed a dimer in solution. Three other cases where <20% of the sdAb dimerized have been reported; however, this is the first report of both the monomeric and dimeric X‐ray crystal structures. Concentration of the monomer did not lead to the formation of new dimer suggesting a stable conformationally distinct species in a fraction of the cytoplasmically expressed protein. Comparison of periplasmic and cytoplasmic expression showed that the dimer was associated with cytoplasmic expression. The disulfide bond was partially reduced in the WT protein purified from the cytoplasm and the protein irreversibly unfolded. Periplasmic expression produced monomeric protein with a fully formed disulfide bond and mostly reversible refolding. Crystallization of a disulfide‐bond free variant, C22A/C99V, purified from the periplasm yielded a structure of a monomeric form, while crystallization of C22A/C99V from the cytoplasm produced an asymmetric dimer. In the dimer, a significant conformational asymmetry was found in the loop residues of the edge β‐strands (S50‐Y60) containing the highly variable complementarity determining region, CDR2. Two dimeric assemblies were predicted from the crystal packing. Mutation of a residue at one of the interfaces, Y98A, disrupted the dimer in solution. The pleomorphic homodimer may yield insight into the stability of misfolded states and the importance of the conserved disulfide bond in preventing their formation. Proteins 2014; 82:3101–3116. © 2014 Wiley Periodicals, Inc.     

Production of disulfide-bonded proteins in Escherichia coli

Disulfide bonds are covalent bonds formed post-translationally by the oxidation of a pair of cysteines. A disulfide bond can serve structural, catalytic, and signaling roles. However, there is an inherent problem to the process of disulfide bond formation: mis-pairing of cysteines can cause misfolding, aggregation and ultimately result in low yields during protein production. Recent developments in the understanding of the mechanisms involved in the formation of disulfide bonds have allowed the research community to engineer and develop methods to produce multi-disulfide-bonded proteins to high yields. This review attempts to highlight the mechanisms responsible for disulfide bond formation in Escherichia coli, both in its native periplasmic compartment in wild-type strains and in the genetically modified cytoplasm of engineered strains. The purpose of this review is to familiarize the researcher with the biological principles involved in the formation of disulfide-bonded proteins with the hope of guiding the scientist in choosing the optimum expression system.     

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.     

Analysis of the early stage of the folding process of reduced lysozyme using all lysozyme variants containing a pair of cysteines

Twenty-eight hen lysozyme variants that contained a pair of cysteines were constructed to examine the formation of the individual native and nonnative disulfide bonds. We analyzed the extent of the formation of a disulfide bond in each lysozyme variant using a redox buffer (pH 8) containing 1.0 mM reduced and 0.1 mM oxidized glutathione in the absence or presence of 6 M guanidine hydrochloride. In the presence of 6 M guanidine hydrochloride, the extent of the formation of the disulfide bond in each lysozyme variant was proportional to the distance between cysteine residues, indicating that reduced hen lysozyme under a highly denaturing condition adopted a randomly coiled structure. In aqueous solution, the formations of all disulfide bonds occurred much more easily than under a denatured condition. This finding indicated that reduced lysozyme had a somewhat compact structure. Moreover, the scattering data for the extents of the formation of the disulfide bonds among all lysozyme variants were observed. These results suggested that the nonrandom folding occurred in the early stage of the folding of reduced lysozyme, which should provide new insight into the early-stage events in the folding process of reduced lysozyme.     

Role of primary structure and disulfide bond formation in beta-lactamase secretion

Plasmid pBR322-encoded beta-lactamase was shown to contain a single disulfide bond, which caused the protein to migrate faster in sodium dodecyl sulfate-polyacrylamide gels than the fully reduced form. A similar difference in mobility of the in vitro synthesized precursor before and after reduction indicates that it also contained a disulfide bond. Formation of the disulfide bond in vivo, however, occurred concomitant with processing. In vivo accumulation of the precursor by inhibition of secretion did not allow disulfide bond formation to occur. This result is consistent with post-translational translocation of the precursor. Synthesis of a fragment of beta-lactamase lacking the carboxy terminus was obtained by insertion of a foreign DNA segment into the PstI site of bla. Processing and secretion of the protein did not appear to be greatly affected, indicating that the carboxy terminus is not required for secretion.