A facile method for the direct synthesis of lanthionine containing cyclic peptides

Summary A series of disulfide bridged peptides were designed as potential inhibitors of protein-protein interactions. Following solid phase synthesis, completely deprotected linear peptides were first oxidized to their disulfide analogs and then transformed into their lanthionine equivalents via a base-assisted reaction in water. Peptides consisting of cystine bridges of lengthi, i+3, with and without discrimination of the chiral centers, were studied for this transformation. Lanthionine peptides were also obtained directly from the reduced linear peptides under mild alkaline treatment, and the reaction proceeded via disulfide bond formation. The extent of conversion of a disulfide bridge into its lanthionine counterpart varied according to the primary sequence. Product characterization revealed diastereomeric lanthionine formation. The presence of D-amino acids, peptide conformation, and/or position of the cystine bridge are among the factors determining the facility of this reaction. Elimination of the backbone proton beta to the sulfur atom followed by intramolecular thiol Michael addition is the most likely mechanism for this transformation.     

Understanding base-assisted desulfurization using a variety of disulfide-bridged peptides

A recently rediscovered reaction of base-assisted lanthionine formation has been applied to several systems of disulfide-bridged peptides. In addition to previously described nonapeptides consisting of i, i+3 cystine linkages, the reaction has now been extended to systems consisting of shorter (i, i+2) and longer (i, i+4) disulfide bridges. The desulfurization reaction is also compatible with disulfide bridges formed through homocysteines and penicillamines, yielding unusual amino acids such as cystathionine and beta,beta-dimethyl lanthionine (referred to as "penthionine") in a peptide chain, respectively. Systematic study of this transformation has provided several new insights into its mechanism. We have observed formation of dehydroalanine and dehydrovaline residues resulting from i, i+2-bridged cysteines and i, i+3-bridged cysteine/penicillamine peptides, respectively, thereby supporting a beta-elimination/Michael-addition mechanism for this transformation. Amino acid analysis and NMR data from total correlation spectroscopy (TOCSY) and (1)H-(13)C heteronuclear single quantum correlation (HSQC) experiments show three diastereomeric lanthionine-bridged peptides in the product mixture. But in the case of desulfurization of a cysteine/homocysteine containing disulfide-bridged peptide, Michael addition appears to be stereoselective, yielding a single stereoisomer of cystathionine within the peptide. According to molecular modeling and CD spectroscopy, constrained peptides such as those containing penicillamine are less likely to undergo facile desulfurization. Flexibility of the torsional angles (C(alpha)H-C(alpha)-C(beta)-S) corresponding to the cysteine residues and temperature appear to be contributing factors determining the extent of desulfurization.     

Thioether side chain cyclization for helical peptide formation: inhibitors of estrogen receptor-coactivator interactions.

Cystine, lanthionine, and cystathionine containing cyclic peptides incorporating the signature nuclear receptor (NR) box (LXXLL) motif have been synthesized and the abilities of these peptides to inhibit estrogen receptor (ER)-coactivator interactions have been determined. We found that helicity of these peptides directly correlated with their bioactivity. Cystathionine proved to be a redox-stable, isosteric replacement for the cystine disulfide. Cystathionine containing peptide 3 showed higher helical character and a lower inhibition constant (Ki, 7 nm) when compared with its cystine counterpart.     

Roseocin,a novel two-component lantibiotic from an actinomycete

Lantibiotics are lanthionine ring containing natural products that belong to the class of ribosomally synthesized and posttranslationally modified peptides (RiPPs). Recent expansion in the availability of microbial genome data and in silico analysis tools have accelerated the discovery of these promising alternatives to antibiotics. Following the genome-mining approach, a biosynthetic gene cluster for a putative two-component lantibiotic, roseocin, was identified in the genome of an Actinomycete, Streptomyces roseosporus NRRL 11379. Posttranslationally modified lanthipeptides of this cluster were obtained by heterologous expression of the genes in Escherichia coli, and were in vitro reconstituted to their bioactive form by exploiting commercial proteases like endoproteinase GluC, and proteinase K. The two peptides displayed synergistic antimicrobial activity against Gram-positive bacteria including the WHO high-priority pathogens, MRSA and VRE. Structural characterization confirmed the installation of four (methyl)lanthionine rings with an indispensable disulfide bond in the α-peptide, and six (methyl)lanthionine rings in the β-peptide, by a single promiscuous lanthionine synthetase, RosM. Roseocin is the first two-component lantibiotic from a non-Firmicute, with extensive lanthionine bridging.     

Synthesis of cystine peptides 21-25/70-73 and 35-39/56-59 of the beta-subunit of human choriogonadotropin.

Syntheses of two asymmetrical cystine peptides with the amino acid residues 21-25/70-73 and 35-39/56-59, based on the linear amino acid sequence and the disulfide bond assignment in the beta-subunit of human choriogonadotropin (hCG-beta), are described. S-trityl and S-acetamidomethyl peptide fragments of each cystine peptide were prepared in solution phase and were subjected to oxidation with I2/MeOH to form the disulfide bridge. The cystine peptides were characterized by their amino acid analyses and fast atom bombardment mass spectrometry. Immunological characterization by several homologous radioimmunoassay systems showed that peptide 21-25/70-73 had significant hCG, hCG-beta, and hLH activities while peptide 35-39/56-59 failed to reveal any immunoreactivity.     

Optimization of the Oxidative Folding Reaction and Disulfide Structure Determination of Human α-Defensin 1, 2, 3 and 5

The optimal conditions were determined for oxidative folding of the reduced human α-defensins, HNP1, HNP2, HNP3 and HD5, preferentially into their native disulfide structures. Since the human α-defensin-molecule in both reduced and oxidized forms raised a solubility problem arising from its basic and hydrophobic compositions, buffer concentration had to be lowered and cosolvent, such as CH₃CN, had to be added to the folding medium in the presence of reduced and oxidized gluthathione (GSH/GSSG) to prevent aggregation and also to realize predominant formation of the native conformer. The four synthetic human α-defensins of high homogeneity were confirmed to exhibit the same antimicrobial potencies against E. coli as those reported for the natural products. All these peptides were shown to possess the native disulfide structure by sequence analyses and mass measurements with cystine segments obtained by enzymatic digestion. Edman degradation allowed for disulfide assignment of cystine segments involving adjacent Cys residues composed of three peptide chains, for which two possible disulfide modes could be considered, with the guidance of the cycles detecting diPTH cystine. As for HNP1, HNP2 and HNP3, however, diPTH cystine was expected at the same cycles in both structures, which would have resulted in not being able to distinguish between the two alternative modes. To avoid this, it was necessary to provide an acetyl tag for the specific peptide chain originating from the N-terminus. Edman degradation of cystine segments tagged with the acetyl group would be a practical procedure for analyzing disulfide structures involving adjacent Cys residues.     

Engineering a disulfide bond and free thiols in the lantibiotic nisin Z.

The antimicrobial peptide nisin contains the uncommon amino acid residues lanthionine and methyl-lanthionine, which are post-translationally formed from Ser, Thr and Cys residues. To investigate the importance of these uncommon residues for nisin activity, a mutant was designed in which Thr13 was replaced by a Cys residue, which prevents the formation of the thioether bond of ring C. Instead, Cys13 couples with Cys19 via an intramolecular disulfide bridge, a bond that is very unusual in lantibiotics. NMR analysis of this mutant showed a structure very similar to that of wild-type nisin, except for the configuration of ring C. The modification was accompanied by a dramatic reduction in antimicrobial activity to less than 1% of wild-type activity, indicating that the lanthionine of ring C is very important for this activity. The nisin Z mutants S5C and M17C were also isolated and characterized; they are the first lantibiotics known that contain an additional Cys residue that is not involved in bridge formation but is present as a free thiol. Secretion of these peptides by the lactococcal producer cells, as well as their antimicrobial activity, was found to be strongly dependent on a reducing environment. Their ability to permeabilize lipid vesicles was not thiol-dependent. Labeling of M17C nisin Z with iodoacetamide abolished the thiol-dependence of the peptide. These results show that the presence of a reactive Cys residue in nisin has a strong effect on the antimicrobial properties of the peptide, which is probably the result of interaction of these residues with thiol groups on the outside of bacterial cells.     

Elucidation of the disulfide bridge pattern of the recombinant human growth and differentiation factor 5 dimer and the interchain Cys/Ala mutant monomer

Growth and differentiation factor 5 (GDF5) is involved in many developmental processes such as chondrogenesis and joint and bone formation. A recombinant monomeric human GDF5 mutant rGDF5(C84A) is in vitro as potent as the dimeric native form, and clinical investigations of rGDF5(C84A) are in progress. Native homodimeric GDF5 belongs to the transforming growth factor β (TGF-β) superfamily; each monomer contains a cystine knot formed by three intrachain disulfide bridges, and the monomers are connected via an interchain disulfide bridge. The disulfide bridge pattern of recombinant homodimeric rGDF5 was recently elucidated by X-ray diffraction. A combination of proteolytic degradation with thermolysin, separation of the generated fragments by reverse-phase high-performance liquid chromatography (RP–HPLC), and subsequent analyses of the disulfide-linked peptides by electrospray–mass spectrometry and matrix-assisted laser desorption/ionization time-of-flight (MALDI–TOF) mass spectrometry, amino acid analysis, and Edman degradation led to the unambiguous identification of the disulfide bridge pattern of the monomeric mutant rGDF5(C84A) and of the homodimeric rGDF5 in solution. The cystine knot of homodimeric rGDF5 exhibits the pattern Cys1-Cys5, Cys2-Cys6, and Cys3-Cys7 (three intrachain disulfide bonds), and the monomers are connected by a single interchain disulfide bridge (Cys4-Cys4) in accordance with other members of the TGF-β superfamily. The monomeric mutant rGDF5(C84A) exhibits the same cystine knot pattern as homodimeric rGDF5.     

Direct analysis of the disulfide content of proteins: methods for monitoring the stability and refolding process of cystine-containing proteins

So far, the cystine (disulfide) content of proteins has been routinely determined by indirect methods, i.e., cystines are first converted to more stable half-cystines prior to analysis. We present a study which demonstrates that the cystine content can be directly and accurately analyzed at low picomole to femtomole levels. The method involves (a) the employment of a vacuum during sample hydrolysis which permits quantitative recovery of cystine, and (b) the dabsyl chloride precolumn derivatization method which yields stable DABS-cystine that is subsequently analyzed by HPLC. Direct analysis of the cystine residue is important in numerous areas of protein research. It allows, by a single analysis, simultaneous determination of the sulfhydryl (cysteine, as S-carboxymethyl derivative) and disulfide (cystine) contents. The technique can be used to follow the refolding process of fully reduced, cystine-containing proteins. Direct analysis of the cystine content also serves to monitor the extent of inactivation of cystine-containing proteins caused by alkaline pH and heat treatments. In this mode of protein inactivation, cystines are selectively destroyed and converted to lanthionine and lysinoalanine. Both the decrease of cystine and the recoveries of lanthionine and lysinoalanine can be simultaneously evaluated by the proposed method. Examples of these applications are presented here.     

Two Novel Bovine Somatotropin Species Generated from a Common Dehydroalanine Intermediate

Under stressed conditions such as prolonged exposure to high pH, the C-terminal disulfide bridge in bovine somatotropin (bST) is susceptible to a base catalyzed β-elimination reaction. This reaction converts the disulfide bond to a dehydroalanine residue with loss of a sulphur atom. Two altered species were isolated in pure form and determined to be generated from this dehydroalanine intermediate. One is a monomeric lanthionyl bST (L-bST) with a thioether linkage, and the other is an inter-molecular disulfide linked dimer containing a lysinoalanine. These two novel structures were unambiguously determined using various techniques including enzymatic digestion, amino acid sequencing and analysis, and mass spectrometry. The monomeric L-bST was demonstrated to be equipotent to normal bST in a hypox rat assay, thus showing that formation of lanthionine in place of this disulfide bond does not affect it bioactivity.     

Formation of the cystine between cysteine 225 and cysteine 462 from ribonucleoside diphosphate reductase is kinetically competent

Participation of the formation of the cystine between cysteine 225 and cysteine 462 in the R1 protein to the enzymatic mechanism of aerobic ribonucleoside diphosphate reductase from Escherichia coli has been examined by use of rapid quenching and site-directed immunochemistry. Prereduced ribonucleotide reductase in the presence of ATP was mixed with CDP in a quench flow apparatus. The reaction was terminated with a solution of acetic acid and N-ethylmaleimide. The protein was precipitated and digested with chymotrypsin and the proteinase from Staphylococcus aureus strain V8 in the presence of N-ethylmaleimide to yield the peptide SS[S-(N-ethylsuccinimid-2-yl)cysteinyl]VLIE containing cysteine 225 and the mixed disulfide between the peptide SSCVLIE and the peptide IALCTL containing cysteine 462. These two peptides were retrieved together from the digest by immunoadsorption. The affinity-purified peptides were modified at their amino termini with the fluorescent reagent 6-aminoquinolyl-N-hydroxysuccimidyl carbamate and submitted to high-pressure liquid chromatography. The areas of the respective peaks of fluorescence corresponding to the S-(N-ethylsuccimidyl) peptide, and the mixed disulfide were used to determine the percentage of the cystine that had formed during each interval. The rate constant for the formation of the cystine following the association of free, fully reduced ribonucleotide reductase with the reactant CDP was 8 s(-)(1). Because only 50% of the active sites participated in this pre-steady-state reaction, the maximum steady-state rate consistent with the involvement of this cystine in the enzymatic reaction would be 4 s(-1). Since the turnover number of the enzyme under the same conditions in a steady state assay was only 1 s(-)(1), the formation of the cystine between these two cysteines is kinetically competent.     

Microwave-assisted Boc-solid phase peptide synthesis of cyclic cysteine-rich peptides.

In this study we describe the first protocols for the synthesis of cystine-rich peptides in the presence of microwave radiation with Boc-solid phase peptide synthesis (SPPS). This method is exemplified for macrocyclic peptides known as cyclotides, which comprise approximately 30 amino acids and incorporate a cystine knot arrangement of their three disulfide bonds. However, the method is broadly applicable for a wide range of peptides using Boc-SPPS, especially for SPPS of large peptides via native chemical ligation. Microwave radiation produces peptides in high yield and with high purity, and we were able to reduce the time for the assembly of approximately 30 mer peptide chains to an overnight reaction in the automated microwave-assisted synthesis.     

Complete synthesis of the bicyclic ring of a mutacin analog with orthogonally protected lanthionine via solid‐phase intracyclization

Mutacin 1140 (MU1140) is a naturally occurring lantibiotic derived from posttranslational modifications of a ribosomally synthesized peptide during the fermentation of a bacterium called Streptococcus mutans, the etiological agent of dental cavities. A practical approach for chemically synthesizing lantibiotics would be a valuable tool to expand the MU1140 library with additional semisynthetic analogs. In turn, an expanded library may prove useful to explore additional therapeutic indications for this pipeline of novel compounds. In this work, orthogonally protected lanthionine analogs were synthesized via an aziridine ring opening strategy. This lanthionine was utilized to synthesize a cysteamine (Cya) instead of the (S)‐aminovinyl‐D‐cysteine (AviCys) that is naturally found in MU1140. The Cya containing bicyclic C/D ring of MU1140 was synthesized by Fmoc solid‐phase peptide synthesis (SPPS). The linear peptides were synthesized using OPfp ester derivatives and using various common coupling reagents such as COMU and TCTU. The linear peptide was intracyclized with DEPBT to construct the so‐called bicyclic ring C/D. This is the first report on the complete chemical synthesis of the bicyclic C/D ring of a MU1140 analog using orthogonally protected lanthionines using SPPS.     

Features of a Spatially Constrained Cystine Loop in the p10 FAST Protein Ectodomain Define a New Class of Viral Fusion Peptides

The reovirus fusion-associated small transmembrane (FAST) proteins are the smallest known viral membrane fusion proteins. With ectodomains of only ∼20–40 residues, it is unclear how such diminutive fusion proteins can mediate cell-cell fusion and syncytium formation. Contained within the 40-residue ectodomain of the p10 FAST protein resides an 11-residue sequence of moderately apolar residues, termed the hydrophobic patch (HP). Previous studies indicate the p10 HP shares operational features with the fusion peptide motifs found within the enveloped virus membrane fusion proteins. Using biotinylation assays, we now report that two highly conserved cysteine residues flanking the p10 HP form an essential intramolecular disulfide bond to create a cystine loop. Mutagenic analyses revealed that both formation of the cystine loop and p10 membrane fusion activity are highly sensitive to changes in the size and spatial arrangement of amino acids within the loop. The p10 cystine loop may therefore function as a cystine noose, where fusion peptide activity is dependent on structural constraints within the noose that force solvent exposure of key hydrophobic residues. Moreover, inhibitors of cell surface thioreductase activity indicate that disruption of the disulfide bridge is important for p10-mediated membrane fusion. This is the first example of a viral fusion peptide composed of a small, spatially constrained cystine loop whose function is dependent on altered loop formation, and it suggests the p10 cystine loop represents a new class of viral fusion peptides.     

Determination of interchain crosslinkages in insulin B-chain dimers by fast atom bombardment mass spectrometry

New methodology for identifying and locating crosslinkages in peptides is described. Pepsin is used to cleave insulin and B-chain dimers of insulin into fragments under conditions which retain the original peptide crosslinkages. After partial separation by HPLC, the peptides are analyzed by fast atom bombardment mass spectrometry (FABMS) to determine their molecular weights. The molecular weights of peptide fragments expected from the pepsin digests of human insulin and related model compounds are calculated from the amino acid sequence of the intact peptide. Digestion products are identified by matching their molecular weights, as determined by FABMS, with calculated molecular weights. Locations of interchain crosslinkages are deduced after the peptide fragments have been assigned to specific segments of the parent peptide. The validity of the method has been established by correctly identifying structurally important products in the pepsin digests of model compounds such as human, bovine, and porcine insulins. Procedures developed with the model compounds were used to identify crosslinkages in peptides of unknown structure isolated from an insulin A-chain/B-chain combination reaction mixture. Evidence is presented for formation of three different types of crosslinkages, disulfide, lanthionine, and sulfoxide.     

Conformation-dependent side reactions in interstrand-disulfide bridging of trimeric collagenous peptides by regioselective cysteine chemistry.

Conversion of single-chain or disulfide-bridged dimeric collagenous peptides into Cys(Npys) derivatives as activated species for subsequent regioselective thiol/disulfide exchange reactions leads to side products whose origin and nature was determined by HPLC and ESI-MS. In both cases the high tendency of the educts to self-associate into triple-helical homotrimers, as assessed by their dichroic properties in the reaction media, is responsible for the failure of this well established cysteine chemistry. Only by optimizing the synthetic strategy or by exploiting a kinetic control of the reaction, could these conformation-dependent limitations be more or less efficiently bypassed for the regioselective assembly of heterotrimeric collagen model peptides crosslinked with artificial cystine knots.     

Conformations of disulfide bridges in proteins

The conformational characteristics of disulfide bridges in proteins have been analyzed using a dataset of 22 protein structures, available at a resolution of less than or equal to 2.0 A, containing a total of 72 disulfide crosslinks. The parameters used in the analysis include (phi, psi) values at Cys residues, bridge dihedral angles chi ss, chi i1, chi j1, chi i2, and chi j2, the distances C alpha i-C alpha j and C beta i-C beta j between the C alpha and C beta atoms of Cys(i) and Cys(j). Eight families of bridge conformations with three or more occurrences have been identified on the basis of these stereochemical parameters. The most populated family corresponds to the "left handed spiral" identified earlier by Richardson [1981) Adv. Protein Chem. 34, 167-330). Disulfide bridging across antiparallel extended strands is observed in alpha-lytic protease, crambin, and beta-trypsin and this structure is shown to be very similar to those obtained in small cystine peptides. Solvent accessible surface area calculations show that the overwhelming majority of disulfide bridges are inaccessible to solvent.     

Chemical Synthesis of Human β-Defensin (hBD)-1, -2, -3 and -4: Optimization of the Oxidative Folding Reaction

Reduced human β-defensin (hBD)-1, -2, -3 and -4 synthesized by Boc chemistry were subjected to oxidative folding reaction under optimal conditions. Among the factors affecting the oxidative folding in the presence of reduced and oxidized glutathione (GSH/GSSG), the buffer concentration and reaction temperature were essential for the predominant formation of the native disulfide structure. The homogeneity of the four synthetic hBDs was confirmed by analytical procedures using RP-HPLC, IEX-HPLC, capillary zone electrophoresis (CZE) and MALDI-TOF MS as well as sequencing, although high temperature (70 °C) was used for the RP-HPLC analysis of hBD-3 and hBD-4 to exclude the influence of equilibrium with the respective conformers having native disulfide pairing. All synthetic hBDs were shown to possess the native disulfide structure by sequential analyses and mass measurements with cystine segments obtained by enzymatic digestion. Upon digestion of hBD-1 and hBD-4 with proline specific endopeptidase, the Cys-X bond was found to be reproducibly cleaved together with the Pro-X bond although the cleavage of Cys-X afforded the appropriate cystine segments for determining the disulfide structure of hBD-1 and hBD-4. With respect to antimicrobial activity against E. coli, the four synthetic hBDs of high homogeneity possessed the same potencies as those reported previously.Australian Peptide Conference Issue     

Synthesis of single- and multiple-stranded cystine-rich peptides

The large abundance of bioactive single- and multiple-stranded cystine-rich peptides in nature has fostered the development of orthogonal thiol-protection schemes and of efficient chemistries for regioselective disulfide formation in synthetic replica for decades. In parallel to these entirely synthetic strategies, an increased knowledge of oxidative refolding mechanisms of proteins has been accumulated, and the collective experience with air oxidation of cysteine-rich peptides into their native disulfide frameworks have largely confirmed Anfinsen's principle of the self-assembly of polypeptide chains. In fact, a continuously growing number of cysteine-rich bioactive peptides from the most diverse sources and with differing cysteine patterns were found to retain the critical sequence-encoded structural information for correct oxidative folding into the native structures as dominant isomers, although in the biosynthetic pathways the mature peptide forms are mostly generated by posttranslational processing of folded precursors. Such self-assembly processes can be optimized by opportune manipulation of the experimental conditions or by induction of productive intermediates. But there are also numerous cases where folding and disulfide formation are thermodynamically not coupled and where the application of a defined succession of regioselective cysteine pairings still represents the method of choice to install the desired native or non-native cystine frameworks. Among our contributions to the state of the art in the synthesis of cystine-rich peptides, we have mainly addressed the induction of correct oxidative refolding of single-stranded cysteine-rich peptides into their native structures by the use of selenocysteine and suitable strategies for disulfide-mediated assembly of monomers into defined oligomers as mimics of homo- and heterotrimeric collagens as a synthetic approach for the development of new biomaterials.