Preparation of 'side-chain-to-side-chain' cyclic peptides by Allyl and Alloc strategy: potential for library synthesis.

Automated and manual deprotection methods for allyl/allyloxycarbonyl (Allyl/Alloc) were evaluated for the preparation of side-chain-to-side-chain cyclic peptides. Using a standard Allyl/Alloc deprotection method, a small library of cyclic peptides with lactam bridges (with seven amino acids) was prepared on an automatic peptide synthesizer. We demonstrate that the Guibe method for removing Allyl/Alloc protecting groups under specific neutral conditions [Pd(PPh3)4/PhSiH3)/DCM] can be a useful, efficient and reliable method for preparing long cyclic peptides on a resin. We have also manually synthesized a cyclic glucagon analogue containing 24 amino acid residues. These results demonstrated that properly controlled palladium-mediated deprotection of Allyl/Alloc protecting groups can be used to prepare cyclic peptides on the resin using an automated peptide synthesizer and cyclic peptides with a long chain.     

Solid-phase synthesis of peptides containing phosphoserine using phosphate tert.-butyl protecting group

In this paper, we report the solid-phase synthesis of peptides containing O-phosphonoserine using BOP as coupling reagent. Commercially available Fmoc amino-acids linked to p-alkoxybenzyl resin were used in the first step and Alloc amino acids in the following. Alloc group was removed by catalytic hydrostannolytic cleavage. Acid-labile side-chain protecting groups (including phosphate residue) were used. Thus, both removal of side-chain protecting groups and cleavage of the phosphopeptide from the resin were achieved in one step by treatment with TFA. Alloc serine was phosphorylated by the phosphoramidite method. This strategy enables the preparation of peptides with selectively phosphorylated residue and overcomes problems due to repetitive treatments with TFA and final cleavage with HF.     

Studies on deprotection of cysteine and selenocysteine side-chain protecting groups.

We present here a simple method for deprotecting p-methoxybenzyl groups and acetamidomethyl groups from the side-chains of cysteine and selenocysteine. This method uses the highly elecrophilic, aromatic disulfides 2,2'-dithiobis(5-nitropyridine) (DTNP) and 2,2'-dithiodipyridine (DTP) dissolved in TFA to effect removal of these heretofore difficult-to-remove protecting groups. The dissolution of these reagents in TFA, in fact, serves to 'activate' them for the deprotection reaction because protonation of the nitrogen atom of the pyridine ring makes the disulfide bond more electrophilic. Thus, these reagents can be added to any standard cleavage cocktail used in peptide synthesis.The p-methoxybenzyl group of selenocysteine is easily removed by DTNP. Only sub-stoichiometric amounts of DTNP are required to cause full removal of the p-methoxybenzyl group, with as little as 0.2 equivalents necessary to effect 70% removal of the protecting group. In order to remove the p-methoxybenzyl group from cysteine, 2 equivalents of DTNP and the addition of thioanisole was required to effect removal. Thioanisole was absolutely required for the reaction in the case of the sulfur-containing amino acids, while it was not required for selenocysteine. The results were consistent with thioanisole acting as a catalyst. The acetamidomethyl group of cysteine could also be removed using DTNP, but required the addition of > 15 equivalents to be effective. DTP was less robust as a deprotection reagent. We also demonstrate that this chemistry can be used in a simultaneous cyclization/deprotection reaction between selenocysteine and cysteine residues protected by p-methoxybenzyl groups to form a selenylsulfide bond, demonstrating future high utility of the deprotection method.     

Application of arylsulphonyl side-chain protected arginines in solid-phase peptide synthesis based on 9-fluorenylmethoxycarbonyl amino protecting strategy.

One of the main problems still hampering solid-phase peptide synthesis using orthogonal protection strategies based on the 9-fluorenylmethoxycarbonyl amino protecting group is the difficult removal of currently used arginine arylsulphonyl guanidino protecting groups. Poor acid liability of 4-methoxy-2,3,6-trimethylbenzenesulphonyl-protected arginine has led to the popularity of the newer 2,2,5,7,8- pentamethylchroman-6-sulphonyl guanidino protecting group. This group was initially believed to have liability to trifluoroacetic acid, the reagent commonly used to simultaneously deprotect peptides and detach them from the synthesis resin, comparable to tert.-butyl and trityl type protecting groups used for the protection of other peptide side-chain functionalities. In a comparison of three established cleavage/deprotection mixtures we have shown that this is not always the case, particularly in multiple arginine peptides. We have found that only hard-acid deprotection with trimethylsilyl bromide reliably removed both arylsulphonyl guanidino protecting groups from a variety of arginine-containing peptides.     

Efficient solid phase peptide synthesis. Use of methanesulfonic acid alpha-amino deprotecting procedure and new coupling reagent, 2-(benzotriazol-1-yl)oxy-1,3-dimethylimidazolidinium hexafluorophosphate (BOI).

An efficient method for solid phase peptide synthesis was developed, which consists of N alpha-selective deprotection by dilute methanesulfonic acid, in situ neutralization and rapid coupling reaction using benzotriazol-1-yloxytris(dimethylamino)phosphonium hexafluorophosphate (BOP) or 2-(benzotriazol-1-yl)oxy-1,3- dimethylimidazolidinium hexafluorophosphate (BOI) reagent. Selective removal of the N alpha-Boc group by dilute methanesulfonic acid was of more advantage than removal by TFA in terms of stability of semipermanent protecting groups and suppression of undesired side reactions. The use of in situ neutralization and rapid coupling method reduced intramolecular aminolytic cyclization by shortening exposure of the deprotected nucleophilic amino group. A successful synthesis of porcine brain natriuretic peptide (pBNP) has been achieved using this efficient solid phase peptide synthesis scheme.     

A solid-phase synthetic strategy for the preparation of peptide-based affinity labels: synthesis of dynorphin A analogs.

Solid-phase synthetic methodology was developed for the preparation of peptide-based affinity labels. The initial peptides synthesized were dynorphin A (Dyn A) analogs [Phe(p-X)4,D-Pro10]Dyn A(1-11)NH2 containing isothiocyanate (X=-N=C=S) and bromoacetamide (X=-NHCOCH2Br) groups. The peptides were assembled on solid supports using Fmoc-protected amino acids, and the side chain amine to be functionalized, Phe(p-NH2), was protected by the Alloc (allyloxycarbonyl) group. Following removal of the Alloc group by palladium(O), the reactive isothiocyanate and bromoacetamide functionalities were successfully introduced while the peptides were still attached to the resin. Synthesis of these peptides was carried out on polystyrene (PS) and polyethylene glycol-polystyrene (PEG-PS) resins containing the PAL [peptide amide linker, 5-(4-Fmoc-aminomethyl-3,5-dimethoxyphenoxy)valeric acid] linker. Both the rate of Alloc deprotection and the purity of the crude affinity-labeled peptides obtained were found to be dependent on the resin used for peptide assembly.     

On‐resin conversion of Cys(Acm)‐containing peptides to their corresponding Cys(Scm) congeners

The Acm protecting group for the thiol functionality of cysteine is removed under conditions (Hg²⁺) that are orthogonal to the acidic milieu used for global deprotection in Fmoc‐based solid‐phase peptide synthesis. This use of a toxic heavy metal for deprotection has limited the usefulness of Acm in peptide synthesis. The Acm group may be converted to the Scm derivative that can then be used as a reactive intermediate for unsymmetrical disulfide formation. It may also be removed by mild reductive conditions to generate unprotected cysteine. Conversion of Cys(Acm)‐containing peptides to their corresponding Cys(Scm) derivatives in solution is often problematic because the sulfenyl chloride reagent used for this conversion may react with the sensitive amino acids tyrosine and tryptophan. In this protocol, we report a method for on‐resin Acm to Scm conversion that allows the preparation of Cys(Scm)‐containing peptides under conditions that do not modify other amino acids. Copyright © 2010 European Peptide Society and John Wiley & Sons, Ltd.     

Use of the excluded protecting group (EPG) method for peptide synthesis.

The excluded protecting group (EPG) method has been used for the solution synthesis of several peptides including Merrifield's Model Tetrapeptide, linear antamanide and an analogue of magainin-1, [Ala(19), Asn(22)]magainin-1. In the approach reported, the C-terminal amino acid is esterified to the 2-position of cholestane as the [2s,3s]iodohydrin ester and the penultimate amino acid added to the aminoacyl-steroid as the Fmoc-pentafluorophenyl-ester. The Fmoc group is removed with Et(2)NH/DMF ( approximately 15% v/v) and, after evaporation to approximately 10 mL, the solution chromatographed on Sephadex LH-20 in DMF. The dipeptidyl-steroid elutes as the free amine well separated from other reaction mixture components. Fractions containing the dipeptide, as determined by counting and TLC, are pooled and reacted with the next Fmoc-amino acid-pentafluorophenyl ester in the sequence. Repetition of the deprotection/purification/reaction cycle yields the fully protected peptide.On completion of the synthesis, the cholestane iodohydrin ester is selectively removed by treatment with Zn degrees /AcOH to yield the peptide with intact alpha-amino and side chain protecting groups. Global deprotection is achieved with HF. All intermediates from the syntheses reported were characterized. The magainin analogue was shown to have full biologic activity. The Fmoc iodohydrin esters of 16 of the 20 proteogenic amino acids have been prepared and characterized for use as the C-terminal amino acids in other EPG syntheses.     

Two-step hard acid deprotection/cleavage procedure for solid phase peptide synthesis

A new two-step deprotection/cleavage procedure for t-butoxycarbonyl (Boc) based solid phase peptide synthesis is reported. First the protective groups are removed from 4-(oxymethyl)-phenylacetamidomethyl (PAM) resin attached peptide with the weak hard acid, trimethylsilyl bromide-thioanisole/trifluoroacetic acid (TFA). In the second step, the peptide is cleaved from the resin with a stronger hard acid such as trimethylsilyl trifluoromethanesulfonate in TFA or with HF. The method is also shown to deformylate Nin-formyltryptophan moiety efficiently. The usefulness of this procedure for practical solid phase peptide synthesis is demonstrated by comparison with other deprotection methods in the synthesis of urotensin II and human endothelin.     

A Dde resin based strategy for inverse solid-phase synthesis of amino terminated peptides, peptide mimetics and protected peptide intermediates.

This report describes a Dde resin based attachment strategy for inverse solid-phase peptide synthesis (ISPPS). This attachment strategy can be used for the synthesis of amino terminated peptides with side chains and the carboxyl terminus either protected or deprotected. Amino acid t-butyl esters were attached through their free amino group to the Dde resin. The t-butyl carboxyl protecting group was removed by 50% TFA, and inverse peptide synthesis cycles performed using an HATU/TMP based coupling method. Protected peptides were cleaved from the resin with dilute hydrazine. Side chain protecting groups could then be removed by treatment with TFMSA/TFA. The potential of this approach was demonstrated by the synthesis of several short protected and unprotected peptides in good yield and with low epimerization. Its potential for peptide mimetic synthesis was demonstrated by the synthesis of two peptide trifluoromethylketones.     

Synthesis of cyclic penta- and hexapeptides: A general synthetic strategy on DAS resin

The active part or receptor-binding sequence of peptide hormones can usually be defined by a span of 4–8 amino acids. Cyclic penta- and hexapeptides are excellent model systems for performing conformational and structure-function studies on this class of bioactive molecules. A synthetic scheme has been devised comprising solid-phase Fmoc chemistry followed by resin cleavage, cyclization in solution, and, finally, side-chain deprotection. A new resin, DAS, cleaved under weak acid conditions, is an excellent solid-phase synthesis support, and HBTU or PyBOP are the activation reagents of choice, not only during synthesis, but also for the cyclization reaction. Three cyclic peptides were synthesized using this method, one requiring extensive side-chain protection, and this method has general applicability for any cyclic pentapeptide or hexapeptide, giving good yields and high purity.     

Novel method for the synthesis of urea backbone cyclic peptides using new Alloc‐protected glycine building units

Cyclization of bioactive peptides, utilizing functional groups serving as natural pharmacophors, is often accompanied with loss of activity. The backbone cyclization approach was developed to overcome this limitation and enhance pharmacological properties. Backbone cyclic peptides are prepared by the incorporation of special building units, capable of forming amide, disulfide and coordinative bonds. Urea bridge is often used for the preparation of cyclic peptides by connecting two amine functionalized side chains. Here we present urea backbone cyclization as an additional method for the preparation of backbone cyclic peptide libraries. A straightforward method for the synthesis of crystalline Fmoc‐N^α [ω‐amino(Alloc)‐alkyl] glycine building units is presented. A set of urea backbone cyclic Glycogen Synthase Kinase 3 analogs was prepared and assessed for protein kinase B inhibition as anticancer leads. Copyright © 2010 European Peptide Society and John Wiley & Sons, Ltd.     

Solid-phase tuftsin (Thr-Lys-Pro-Arg) synthesis: deprotection and resin cleavage with trifluoromethane sulfonic acid.

A method is described for the synthesis of the naturally occurring tetrapeptide tuftsin (Thr-Lys-Pro-Arg). This stimulates phagocytosis of granulocytes and macrophages. Trifluoromethanesulfonic acid is used to cleave the tetrapeptide from its supporting resin in solid-phase synthesis. This reagent also causes deprotection of several protecting groups in bifunctional residues. The most significant is the complete removal of the tosyl group from N^G-tosyl-arginine-resin ester.     

A New Protecting Group Strategy for Amino Groups in Oligonucleotide Chemistry: CEOC Group

Abstract

A new protecting group, 2-cyanoethyloxycarbonyl, or CEOC, has been developed for amino groups and utilized in synthesizing modified oligonucleotides. (CEOC)-oxy-succinimide reagent has been synthesized to introduce this protecting group. The protecting group is removed by standard oligonucleotide deprotection protocols. Using this approach, oligonucleotides have been synthesized with various types of alkylamine substituents.     

Rapid semi-on-line monitoring of Fmoc solid-phase peptide synthesis by matrix-assisted laser desorption/ionization mass spectrometry

Summary A simple yet highly effective application of matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) for the rapid monitoring of Fmoc solid-phase peptide synthesis is described. A few beads of the resin are removed at any desired step during synthesis, the fully protected peptide is cleaved from the resin and an MS spectrum of the analytes present is produced. Some standard side-chain protecting groups may be cleaved off during sample preparation for MS analysis; however, these cleavages are readily identified. Using this approach, incomplete amino acid acylations are readily detected in approximately the same time as by traditional tests such as ninhydrin. The semi-on-line method also lends itself to ready optimization of synthesis protocols and to the examination of resin-bound peptide side reactions which may not be detectable by chemical means.     

Removal of acid-labile protecting or anchoring groups in the presence of polyfluorinated alcohol: Application to solid-phase peptide synthesis

We describe herein a new method for cleaving from resin and removing acid-labile protecting groups in solid-phase peptide synthesis in the presence of a polyfluorinated alcohol (either trifluoroethanol, TFE, or hexafluoroisopropanol, HFIP). It was shown that 0.1 M HCl in hexafluoroisopropanol or trifluoroethanol removes the acid-labile protecting groups commonly used in Fmoc SPPS for the protection of amino acid side-chains, such as t-butyl ester and ether, Boc, trityl, and Pbf groups including the most acid-resistant p-hydroxymethylphenoxyacetyl group (HMPA), p-benzyloxy benzyl ester (Wang resin), Rink amide, and peptide amide linker (PAL). The addition of 5–10% of a hydrogen-bonding solvent was shown to considerably retard or even fully inhibit the reaction. However, nonhydrogen-bonding solvents, such as dichloromethane, do not slow down the reaction.     

Solid phase synthesis of the protected 27--42 hexadecapeptide of the heavy chain from myeloma immunoglobulin M603. Elimination of side reactions associated with glycyl-2-oxypropionyl-resin.

A fully protected 27--42 hexadecapeptide of the variable region of myeloma immunoglobulin M603 was synthesized on a 2-bromopropionyl-resin by the solid phase method. Side reactions due to cyclization of glycyl-2-oxypropionyl-resin were studied under different reaction conditions. The loss of peptide chains at the dipeptide and tripeptide stages due to diketopeperazine formation was also examined. These side reactions were circumvented by using a combination of fragment and stepwise coupling methods. The synthesized protected peptide was removed from the resin in 85% yield by photolysis, and purified by crystallization and by chromatography on a Sephadex LH-60 column.     

A general method for preparation of peptides biotinylated at the carboxy terminus.

A method for the preparation of a biotinylated resin that can be elongated by standard methods of solid-phase peptide synthesis to give peptides biotinylated at the carboxy terminus is described. This methodology is particularly important for the preparation of biotinylated peptides in which a free amino terminus is required. Coupling of N epsilon-9-fluorenylmethoxycarbonyl-(Fmoc)-N alpha-tert-butyloxycarbonyl(Boc)-L- lysine to p-methylbenzhydrylamine resin, followed by removal of the Fmoc protecting group and reaction with (+)-biotin-4-nitrophenyl ester yielded N alpha-Boc-biocytin-p-methyl-benzhydrylamine resin. The utility of this resin was tested by the synthesis of a biotinylated peptide, Gly-Asn-Ala-Ala-Ala-Ala-Arg-Arg-biocytin-NH2, for use as an in vitro substrate for myristoyl-CoA:protein N-myristoyltransferase (NMT), the enzyme that catalyzes protein N-myristoylation. Analysis of the peptide derivative by HPLC and mass spectrometry revealed a single major product of the expected mass, indicating that the biotin group survived cleavage and deprotection with HF. The biotinylated peptide served as a substrate for NMT, and the resulting myristoylated peptide could be quantitatively recovered by adsorption to immobilized avidin.     

p‐Methoxyphenol: A potent and effective scavenger for solid‐phase peptide synthesis

During the final step of t‐Boc/Bzl, solid‐phase peptide synthesis (SPPS)‐protecting groups from amino acids (aa) side chains must be removed from the target peptides during cleavage from the solid support . These reaction steps involve hydrolysis with hydrogen fluoride (HF) in the presence of a nucleophile (scavenger), whose function is to trap the carbocations produced during S_N1‐type reactions. Five peptide sequences were synthesised for evaluating p‐methoxyphenol effectiveness as a potent scavenger. After the synthesis, the resin–peptide was then separated into two equal parts to be cleaved using two scavengers: conventional reactive p‐cresol (reported in the literature as an effective acyl ion eliminator) and p‐methoxyphenol (hypothesised as fulfilling the same functions as the routinely used scavenger). Detailed analysis of the electrostatic potential map (EPM) revealed similarities between these two nucleophiles, regarding net atomic charge, electron density distribution, and similar pKa values. Good scavenger efficacy was observed by chromatography and mass spectrometry results for the synthesised molecules, which revealed that p‐methoxyphenol can be used as a potent scavenger during SPPS by t‐Boc/Bzl strategy, as similar results were obtained using the conventional scavenger.     

2,2′‐Dithiobis(5‐nitropyridine) (DTNP) as an effective and gentle deprotectant for common cysteine protecting groups

Of all the commercially available amino acid derivatives for solid phase peptide synthesis, none has a greater abundance of side‐chain protection diversity than cysteine. The high reactivity of the cysteine thiol necessitates its attenuation during peptide construction. Moreover, the propensity of cysteine residues within a peptide or protein sequence to form disulfide connectivity allows the opportunity for the peptide chemist to install these disulfides iteratively as a post‐synthetic manipulation through the judicious placement of orthogonal pairs of cysteine S‐protection within the peptide's architecture. It is important to continuously discover new vectors of deprotection for these different blocking protocols in order to achieve the highest degree of orthogonality between the removal of one species in the presence of another. We report here a complete investigation of the scope and limitations of the deprotective potential of 2,2′‐dithiobis(5‐nitropyridine) (DTNP) on a selection of commercially available Cys S‐protecting groups. The gentle conditions of DTNP in a TFA solvent system show a remarkable ability to deprotect some cysteine blocking functionality traditionally removable only by more harsh or forcing conditions. Beyond illustrating the deprotective ability of this reagent cocktail within a cysteine‐containing peptide sequence, the utility of this method was further demonstrated through iterative disulfide formation in oxytocin and apamin test peptides. It is shown that this methodology has high potential as a stand‐alone cysteine deprotection technique or in further manipulation of disulfide architecture within a more complex cysteine‐containing peptide template. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.