Preparation of protected peptide amides using the Fmoc chemical protocol. Comparison of resins for solid phase synthesis.

Different resins were examined for their potential use in the solid phase synthesis of protected peptide amides using the 9-fluorenylmethoxycarbonyl (Fmoc) chemical protocol. The model protected peptide amide BocTyr-Gly-Gly-Phe-Leu-Arg(Pmc)NH2 (1) was synthesized on both the acid-labile 4-(2',4'-dimethoxyphenyl-Fmoc-aminomethyl)phenoxy resin (Rink amide resin) (2) and on resins containing the base-labile linker 4-hydroxymethylbenzoic acid. Of the resins examined only the methylbenzhydrylamine resin containing the 4-hydroxymethylbenzoic acid linkage, which was cleaved by ammonolysis in isopropanol, gave the model peptide 1 in good overall yield (53% including functionalization). Thus the synthesis of protected peptide amides by solid phase synthesis using Fmoc-protected amino acids with t-butyl-type side chain protecting groups is feasible. The choice of peptide-resin linkage and its cleavage conditions, however, are critical to the success of such syntheses. The potential application of this synthetic strategy to the preparation of novel peptide amides is discussed.     

Synthesis of peptide amides by Fmoc-solid-phase peptide synthesis and acid labile anchor groups

The preparation and use of new anchor groups for the synthesis of peptide amides by solid-phase peptide synthesis employing the Fmoc-method is described. Based on the structure of the 4,4'-dimethoxybenzhydryl group (Mbh) handles were developed, which could be cleaved by mild acid treatment to give carboxamides. The syntheses and application of Fmoc-amino-acid-(4-carboxylatomethyloxyphenyl-4'-methoxyphenyl) methyl amide and Fmoc-(4-carboxylatopropyloxyphenyl-4'-methoxyphenyl) methyl amide are described in detail. These handles were coupled to resins and a stepwise elongation of peptide chains proceeded smoothly with N alpha-9-fluorenylmethoxycarbonyl (Fmoc) amino acid derivatives using a carbodiimide/HOBt mediated reaction. The final cleavage of side-chain protecting groups and the release of the C-terminal amide moiety was achieved by the treatment with trifluoroacetic acid, dichloromethane in the presence of scavengers. Various peptides, such as the Leu-enkephalin amide and Leu-Gly-Gly-Gly-Gln-Gly-Lys-Val-Leu-Gly-NH2, which is a good substrate for F XIII, were prepared in high yields and purities.     

An acid-labile anchoring linkage for solid-phase synthesis of C-terminal peptide amides under mild conditions

A series of polymer-supported benzylamides substituted with one to three alkoxy groups in the ring positions were prepared and shown to give carboxamides upon treatment with acid. Based on the initial screening, the bis(o-methoxy)-p-alkoxybenzylamide anchoring linkage was selected for a detailed evaluation of its suitability for solid-phase synthesis of C-terminal peptide amides. The handle derivative 5-[(2' or 4')-Fmoc-aminomethyl-3',5'-dimethoxyphenoxy]valeric acid (1) was prepared in seven facile steps [purification of intermediates unnecessary; overall yield 15% for crystalline product, which is a mixture of positional isomers], and was quantitatively coupled onto amino group-containing supports by use of N,N'-dicyclohexylcarbodiimide plus 1-hydroxybenzotriazole in N,N-dimethylformamide. Stepwise elaboration of peptide chains proceeded smoothly with both N alpha-9-fluorenyl-methyloxycarbonyl (Fmoc) and N alpha-dithiasuccinoyl (Dts) amino acids, and final cleavage of tert.-butyl side-chain protecting groups and of the anchoring linkage occurred readily in trifluoroacetic acid-dichloromethane (7:3) at 25 degrees. The methodology was demonstrated by the syntheses of H-Trp-Asp-Met-Phe-NH2 (tetragastrin) and H-Tyr-Gly-Gly-Phe-Met-NH2 (methionine-enkephalinamide), both with high yields and purities.     

alpha-Chymotrypsin as the catalyst for peptide synthesis.

alpha-Chymotrypsin (EC 3.4.21.1)-catalysed syntheses of peptides were performed with various N-acylated amino acid or peptide esters as donors, and amino acid derivatives, peptides or their derivatives as acceptors. Under optimal conditions the synthesis was almost quantitative. As acceptor nucleophiles, free amino acids or the ester derivatives were inadequate, but amino acid amides or hydrazides, di- or tri-peptides, or the amides, hydrazides and esters of the peptides were useful. The nucleophile specificity for synthesis was markedly similar to the leaving-group specificity in hydrolysis; hydrophobic or bulky amino acid residues were most effecient at both P1' and P2' positions [notation of Schechter & Berger (1967) Biochem. Biophys. Res. Commun. 27, 157-162], but L-proline as well as D-amino acid residues were the worst choices. The synthesis was further dependent on the solubility of the products synthesized; a higher yield of products was expected with lower solubility. As donor esters, good substrates were all useful. Accordingly, fragment condensation was possible by using N-acylated peptide esters and various peptides. The present study suggested that alpha-chymotrypsin may become a useful tool for peptide synthesis.     

A convenient approach to synthesizing peptide C-terminal N-alkyl amides

Peptide C-terminal N-alkyl amides have gained more attention over the past decade due to their biological properties, including improved pharmacokinetic and pharmacodynamic profiles. However, the synthesis of this type of peptide on solid phase by current available methods can be challenging. Here we report a convenient method to synthesize peptide C-terminal N-alkyl amides using the well-known Fukuyama N-alkylation reaction on a standard resin commonly used for the synthesis of peptide C-terminal primary amides, the peptide amide linker-polyethylene glycol-polystyrene (PAL-PEG-PS) resin. The alkylation and oNBS deprotection were conducted under basic conditions and were therefore compatible with this acid labile resin. The alkylation reaction was very efficient on this resin with a number of different alkyl iodides or bromides, and the synthesis of model enkephalin N-alkyl amide analogs using this method gave consistently high yields and purities, demonstrating the applicability of this methodology. The synthesis of N-alkyl amides was more difficult on a Rink amide resin, especially the coupling of the first amino acid to the N-alkyl amine, resulting in lower yields for loading the first amino acid onto the resin. This method can be widely applied in the synthesis of peptide N-alkyl amides.     

Enzymatic peptide synthesis by the recombinant proline-specific endopeptidase from Flavobacterium meningosepticum and its mutationally altered Cys-556 variant

Proline-specific endopeptidase (PSE) (EC 3.4.21.26) was investigated for its potential as a catalyst in peptide synthesis. Using an activated peptide ester or a peptide amide as the acyl component, the enzyme catalyzed kinetically controlled aminolysis and transpeptidation respectively, with various amino acid amides as acyl acceptors. To a certain extent the nucleophile preference reflected the amino acid preference in the S₁-position of the enzyme in peptide hydrolysis: the highest fractions of aminolysis were obtained using amino acid amides with hydrophobic side-chains (e.g. Leu-NH₂, Phe-NH₂). PSE also catalyzed the thermodynamically controlled condensation of short peptides with a free carboxyterminus and various amino acid amides. This enabled us to examine the acceptance of different acyl components in the substrate-binding site of the enzyme with regard to their amino acid composition: In the S₁ position proline was clearly favored, but alanine was also accepted, whereas the S₂ subsite accepted various amino acids rather unspecifically. Since PSE was shown to be extremely sensitive against water-miscible organic solvents, an alternative approach was used to increase yields in enzymatic peptide synthesis: a derivative of PSE in which the catalytic Ser-556 is converted to a Cys was constructed by protein engineering. This mutant (PSE_cys) exhibited a dramatically increased peptide ligase activity in aqueous solution.     

SPPS of protected peptidyl aminoalkyl amides.

Monophthaloyl diamines derived from naturally occurring amino acids were attached through their free amino functions to resins of the trityl type. The phthaloyl groups were removed by hydrazinolysis, and peptide chains were assembled using Fmoc/tBu-amino acids on the liberated amino functions. The peptidyl aminoalkyl amides obtained were cleaved from the resins by mild acidolysis, with the tBu-side chain protection remaining intact.     

Novel serine penicillocarboxypeptidase CPD-S3 from Penicillium janthinellum IBT 3991: Purification, characterization, and uses in peptide synthesis and modification

A novel carboxypeptidase (CPD-S3) from Penicillium janthinellum IBT 3991 has been isolated in a two-step purification procedure by cation exchange and affinity chromatography. The enzyme is a serine carboxypeptidase with a denatured molecular mass determined by SDS of 62 kDa of which 32% is carbohydrate. The isoelectric point is 5.1. CPD-S3 exhibits a high stability towards organic solvents and elevated temperatures. Besides the carboxypeptidase activity, CPD-S3 exhibits esterase, amidase, and carboxamidohydrolase activities. CPD-S3 favors substrates of -configuration with basic amino acid residues in either P₁ or P_1', and particularly dibasic substrates and medium-sized straight-chain alkyl esters for hydrolysis. In aminolysis of esters, amino acid amides and hydrazines coupled in good yield, but methyl esters poorly, and unlike other carboxypeptidases, free amino acids could not be coupled or transpeptidation effected to form amides. In ester semisynthesis, peptides with neutral, but not basic, residues in P₁ could be esterified. The scope of applicability for enzymatic peptide synthesis is limited.     

Enzymatic reactions in aqueous-organic media. VI. Peptide synthesis by α-chymotrypsin in hydrophilic organic solvents

The peptide synthesis from N-acetyl-L-tyrosine ethyl ester and amino acid amides was realized using α-chymotrypsin as a catalyst in ethanol or acetonitrile containing small amounts of water. In these reaction systems, the precipitates of phosphate salt, which was used as a component of buffer solution, are considered to act as carriers of chymotrypsin. It was found that peptide formation is competitive with hydrolysis of the substrate ester, but the secondary synthesis of the peptide from the hydrolysate was also considered to proceed. The yield of the peptide after 24 h reaction was strongly dependent on the water concentration; maximum yields of the peptide were obtained at water concentrations below 10% (v/v). The addition of tertiary amines, such as triethyl amine, markedly increased the peptide yield, probably due to the increase in the concentration of the nucleophilic amine components by neutralization of hydrohalides of amino acid amides. The effect of reaction temperature and the reactions with CT immobilized on PVA, chitosan, or TEAE-cellulose are also described.     

Peptide bond synthesis by clostridiopeptidase B

Summary Clostridiopeptidase B was used for peptide bond synthesis with Cbz-ARG-OMe as substrate and 17 amino acid amides as nucleophiles. Synthetic yields ranging from 75 to 98% were obtained for most of the amides.N.R.C.C. #26185.     

Synthesis and application of acid labile anchor groups for the synthesis of peptide amides by Fmoc-solid-phase peptide synthesis

The preparation and application of a new linker for the synthesis of peptide amides using a modified Fmoc-method is described. The new anchor group was developed based on our experience with 4,4'-dimethoxybenzhydryl (Mbh)-protecting group for amides. Lability towards acid treatment was increased dramatically and results in an easy cleavage procedure for the preparation of peptide amides. The synthesis of N-9-fluorenylmethoxycarbonyl- ([5-carboxylatoethyl-2.4-dimethoxyphenyl)- 4'-methoxyphenyl]-methylamin is reported in detail. This linker was coupled to a commercially available aminomethyl polystyrene resin. Peptide synthesis proceeded smoothly using HOOBt esters of Fmoc-amino acids. Release of the peptide amide and final cleavage of the side chain protecting groups was accomplished by treatment with trifluoroacetic acid-dichloromethane mixtures in the presence of scavengers. The synthesis of peptide amides such as LHRH and C-terminal hexapeptide of secretin are given as examples.     

Cysteic- and homocysteic acid-S-(aminoiminomethyl) amides: a new class of modified arginines useful in peptide synthesis.

A novel, practical synthesis of the title compounds and their derivatives are described. The protecting groups for amino, guanidino and carboxylic functions of substituted amides of cysteic and homocysteic acid were selected with the aim of making the amino acid derivatives synthons for peptide synthesis both in solution and by the solid phase method. Studying the structure-activity relationship some new kyotorphin, [Leu] kyotorphin and MIF-1 analogues, containing the unusual amino acid cysteic acid-S-(aminoiminomethyl) amide (sArg) in position two, have been prepared. It is a very promising compound, a structural analogue of arginine and an efficient antagonist in its metabolism.     

Enzymatic synthesis of peptide in acetonitrile/supercritical carbon dioxide

Summary The peptide synthesis from N-acetyl-L-tyrosine ethyl ester (Ac-Tyr-OEt) and amino acid amides was realized using -chymotrypsin (CT) in acetonitrile (MeCN) or acetonitrile/supercritical carbon dioxide (SCCO₂) containing small amounts of water. In both solvent systems there was an optimum water content for peptide synthesis, above which peptide hydrolysis became more important. After an incubation for 5 hours, the yields of the peptide was 64% in MeCN and 91% in MeCN/SCCO₂, respectively.     

Peptide synthesis using proteases dissolved in organic solvents

Organic solvent-soluble -chymotrypsin (CT) and subtilisin Carlsberg (SC) are effective catalysts for peptide synthesis in homogeneous organic solutions. The soluble enzymes have values of k_cat/K_m for the reaction of N-Bz-L-Tyr-OEt with L-Leu-NH₂ to yield the dipeptide N-Bz-L-Tyr-L-Leu-NH₂ that are over 3 orders of magnitude higher than their suspended counterparts in isooctane (containing 30% (v/v) tetrahydrofuran (THF) to aid in substrate solubility). Both enzymes are substantially more active in hydrophobic organic solvents than hydrophilic solvents. Adding small concentrations of water (<0.2% and 1% (v/v) in isooctane-THF and ethyl acetate, respectively) results in up to a 150-fold activation of -chymotrypsin-catalyzed peptide synthesis. Importantly, added water does not promote hydrolysis in either isooctane-THF or ethyl acetate; thus, -chymotrypsin is highly selective toward peptide synthesis in the nearly anhydrous organic solutions. Unlike CT, the activation of subtilisin Carlsberg upon partial hydration of isooctane-THF or ethyl acetate was not significant and actually resulted in substantial hydrolysis. Using -chymotrypsin, a variety of tripeptides were produced from dipeptide amino acid esters. Reactivity of D-amino acid amides as acyl acceptors and partially unblocked amino acid acyl donors further expands the generality of the use of organic solvent-soluble enzymes as peptide synthesis catalysts.     

Facile SPS of peptides having C-terminal Asn and Gln

Attachment of Fmoc-asparagine or glutamine to p-alkoxybenzyl alcohol type resins has always been difficult and not very effective. A very simple and effective method for the preparation of peptides terminating in asparagine or glutamine is described. The method involves quantitative attachment of Fmoc-Asp-OtBu or Fmoc-Glu-OtBu via their side-chain carboxyl group to a resin functionalized with our TMBPA linker for peptide amides. Peptide synthesis is performed using our standard Fmoc chemistry, and treatment with acid, e.g. TFA/DCM/scavenger mixtures, releases the Asn or Gln peptides.     

Practical approach to solid-phase synthesis of C-terminal peptide amides under mild conditions based on a photolysable anchoring linkage

Several 3-nitro-4-(N-protected aminomethyl)benzoic acids; with protection provided by tert.-butyloxycarbonyl (Boc), 9-fluorenylmethyloxycarbonyl (Fmoc), trifluoroacetyl (Tfa), dithiasuccinoyl (Dts), or phthaloyl (Phth), have been prepared by reproducible routes. Synthesis of Dts-handle 6 illustrates some particularly novel and efficient chemistry, and is preferred over more intricate routes to Boc-handle 3 and Fmoc-handle 4. The five handles were each evaluated for their application to the synthesis of peptide amides. Coupling onto amino-functionalized supports provided a general starting point for peptide chain assembly. The handle amino function was deblocked (Boc, Fmoc, Dts), the C-terminal residue was coupled as its N alpha-protected free acid, and ultimately the ortho-nitrobenzylamide anchorage linkage was cleaved photolytically to give the corresponding amide. Starting with handles 3, 4, and 6, several free and protected peptide amides were synthesized.     

Peptide synthesis in aqueous-organic solvent mixtures with alpha-chymotrypsin immobilized to tresyl chloride-activated agarose

alpha-Chymotrypsin was immobilized with a high coupling yield (up to 80%) to tresyl chloride activated Sepharose CL-4B.The immobilized enzyme was tested for its ability to synthesize soluble peptides from N-acetylated amino acid esters as acyl donors and amino acid amides as acceptor amines in water-water-miscible organic solvent mixtures. It was found that the yield of peptide increased with increasing concentration of organic cosolvent. Almost complete synthesis (97%) of Ac-Phe-Ala-NH(2) was obtained from Ac-Phe-OMe using a sixfold excess of Ala-NH(2). The rate of peptide formation in aqueous-organic solvent mixtures was good. Thus, 0.1M peptide was formed in less than 2 h in 50 vol% DMF with 0.1 mg immobilized chymotrypsin/mL reaction mixture. The immobilized enzyme distinguished between the L and D configurations of acceptor amino acid amides even in high concentration of nonaqueous component (90% 1,4-butanediol). The effect of temperature was studied. It was found that both the yield of peptide and the stability of immobilized enzyme increased when the temperature was lowered. Experiments could be performed at subzero temperatures in the aqueous-organic solvent mixtures resulting in very high yield of peptide. After three weeks continuous operation at 4 degrees C in 50% DMF, the immobilized enzyme retained 66%of its original synthetic activity. The activity of the immobilized enzyme was better conserved with a preparation made from agarose with a higher tresyl group content compared to a preparation made from a lower activated agarose, indicating that multiple point of attachment has a favorable effect on the stability of the enzyme in aqueous-organic solvent mixtures. The major advantage of using water-miscible instead of water-immiscible organic solvents to promote peptide syntheses appears to be the increased solubility of substrates and products, making continuous operation possible.     

Tetrazine-Containing Amino Acid for Peptide Modification and Live Cell Labeling

A novel amino acid derivative 3-(4-(1, 2, 4, 5-tetrazine-3-yl) phenyl)-2-aminopropanoic acid was synthesized in this study. The compound possessed better water-solubility and was synthesized more easily compared with the well-known and commercially available 3-(p-benzylamino)-1, 2, 4, 5-tetrazine. Tetrazine-containing amino acid showed excellent stability in biological media and might be used for cancer cell labeling. Moreover, the compound remained relatively stable in 50% TFA/DCM with little decomposition after prolonged exposure at room temperature. The compound could be utilized as phenylalanine or tyrosine analogue in peptide modification, and the tetrazine-containing peptide demonstrated more significant biological activity than that of the parent peptide. The combination of tetrazine group and amino acid offered broad development prospects of the bioorthogonal labeling and peptide synthesis.     

Peptide synthesis catalyzed by papain at alkaline pH values

The synthesis of peptides in the presence of papain at pH 8-9.5 is described. Starting substances are acylamino acid alkyl esters (the carboxyl component) and amides or tert.-butylesters of amino acids, as well as peptide (the amino component). Under such conditions secondary hydrolysis is not essential, making the synthesis of peptides soluble in aqueous medium. The yield of peptides is 50-94%. The effect of different factors (temperature, solvents, reagent concentrations) on the result of the reaction has been studied. It has been found that an excess of the carboxyl component is expedient to increase the yield of peptides.     

Contributions to the S'-subsite specificity of papain.

The product ratio was analyzed for the papain-catalyzed acyl transfer from the specific acyl donor Mal-Phe-Ala-OEtCl to various nucleophilic amino components, ranging from amino acid amides to tripeptide amides. The data obtained are discussed in terms of binding specificity. From the structure-activity relationships for the S'1-P'1 interaction it follows that only three methyl(ene) groups can be accommodated in the S'1 subsite. Hydrophilic side chains are bound better to S'1 than indicated by their hydrophobicities. Negatively charged amino components are inefficient deacylating agents. However, there was no evidence for electrostatic contributions to the nucleophile binding. Amino components with bulky hydrophobic amino acid residues in the P'2 and in the P'3 position, respectively, are preferentially bound to Mal-Phe-Ala-papain. The results of this study can be applied to the planning of papain-catalyzed peptide synthesis reactions.