Amino acid deletion products resulting from incomplete deprotection of the Boc group from Npi-benzyloxymethylhistidine residues during solid-phase peptide synthesis.

In peptide synthesis, the use of N(alpha)-tert-butyloxycarbonyl-N(pi)-benzyloxymethylhistidine [Boc-His(pi-Bom)] raises the problem of the Bom group generating formaldehyde during the hydrogen fluoride (HF) cleavage reaction. This can lead to modification of the functional groups on amino acids in the peptide chain. Besides this side reaction, the failure of N(alpha)-Boc deprotection from the His(pi-Bom) residue occurs during TFA treatment for the standard solid-phase peptide synthesis (SPPS) even in the case of a non 'difficult sequence'. This gives amino acid deletion products generated at the N-terminus of the His(pi-Bom) residues. Reviewing the removability of the Boc group on amino acid derivatives showed that the group on the His(pi-Bom) residue was much more resistant under the deprotecting conditions than expected. To circumvent this problem, special precautions, i.e. prolonged deprotection steps and/or increased concentrations of TFA, should be taken for a successful SPPS.     

In situ neutralization in Boc-chemistry solid phase peptide synthesis. Rapid, high yield assembly of difficult sequences.

Simple, effective protocols have been developed for manual and machine-assisted Boc-chemistry solid phase peptide synthesis on polystyrene resins. These use in situ neutralization [i.e. neutralization simultaneous with coupling], high concentrations (> 0.2 M) of Boc-amino acid-OBt esters plus base for rapid coupling, 100% TFA for rapid Boc group removal, and a single short (30 s) DMF flow wash between deprotection/coupling and between coupling/deprotection. Single 10 min coupling times were used throughout. Overall cycle times were 15 min for manual and 19 min for machine-assisted synthesis (75 residues per day). No racemization was detected in the base-catalyzed coupling step. Several side reactions were studied, and eliminated. These included: pyrrolidonecarboxylic acid formation from Gln in hot TFA-DMF; chain-termination by reaction with excess HBTU; and, chain termination by acetylation (from HOAc in commercial Boc-amino acids). The in situ neutralization protocols gave a significant increase in the efficiency of chain assembly, especially for "difficult" sequences arising from sequence-dependent peptide chain aggregation in standard (neutralization prior to coupling) Boc-chemistry SPPS protocols or in Fmoc-chemistry SPPS. Reported syntheses include HIV-1 protease(1-50,Cys.amide), HIV-1 protease(53-99), and the full length HIV-1 protease(1-99).     

多肽固相合成的研究进展

多肽固相化学合成法是蛋白质研究领域非常重要的研究方法之一,主要可以分为Boc方法和Fmoc方法,在生物药物、蛋白质工程、免疫学等研究中得到了广泛的应用。该文论述了多肽固相合成法的原理,比较了两种典型合成方法的优缺点,介绍了适用于该方法的多肽种类,提出了多肽合成过程中存在的问题与解决策略,最后展望了多肽合成法的应用前景,以供相关领域的研究人员参考。     

Comparative studies of Nsc and Fmoc as Nα‐protecting groups for SPPS

2‐(4‐Nitrophenyl)sulfonylethoxycarbonyl (Nsc) is an alternative base‐labile N^α‐protecting group to 9‐fluorenylmethoxycarbonyl (Fmoc) for amino acids. The UV spectrum of the Nsc group exhibits moderate absorption at 380 nm which is excellent for real‐time monitoring of the deprotection process. It also decreases the rearrangement of X‐Asp, which can be a serious problem in SPPS. Copyright © 1999 European Peptide Society and John Wiley & Sons, Ltd.     

In Situ Neutralization in Boc-chemistry Solid Phase Peptide Synthesis

Simple, effective protocols have been developed for manual and machine-assisted Boc-chemistry solid phase peptide synthesis on polystyrene resins. These use in situ neutralization [i.e. neutralization simultaneous with coupling], high concentrations (>0.2 m) of Boc-amino acid-OBt esters plus base for rapid coupling, 100% TFA for rapid Boc group removal, and a single short (30 s) DMF flow wash between deprotection/coupling and between coupling/deprotection. Single 10 min coupling times were used throughout. Overall cycle times were 15 min for manual and 19 min for machine-assisted synthesis (75 residues per day). No racemization was detected in the _.base-catalyzed coupling step. Several side reactions were studied, and eliminated. These included: pyrrolidonecarboxylic acid formation from Gln in hot TFA-DMF; chain-termination by reaction with excess HBTU; and, chain termination by acetylation (from HOAc in commercial Boc-amino acids). The in situ neutralization protocols gave a significant increase in the efficiency of chain assembly, especially for “difficult” sequences arising from sequence-dependent peptide chain aggregation in standard (neutralization prior to coupling) Boc-chemistry SPPS protocols or in Fmoc-chemistry SPPS. Reported syntheses include HIV-1 protease(1–50,Cys.amide), HIV-1 protease(53–99), and the full length HIV-l protease(1–99). Republished with the permission of Blackwell Publishing from International Journal of Peptide Protein Research, volume 40, pp. 180–193, 1992. A preliminary account of this work was presented at the 12th American Peptide Symposium, Cambridge, MA, July 16–21, 1991 (ref. 43). Dedicated to Professor Bruce Merrifield on the occasion of his 70th birthday.     

Making Ends Meet: Microwave-Accelerated Synthesis of Cyclic and Disulfide Rich Proteins Via In Situ Thioesterification and Native Chemical Ligation

The development of synthetic methodologies for cyclic peptides is driven by the discovery of cyclic peptide drug scaffolds such as the plant-derived cyclotides, sunflower trypsin inhibitor 1 (SFTI-1) and the development of cyclized conotoxins. Currently, the native chemical ligation reaction between an N-terminal cysteine and C-terminal thioester group remains the most robust method to obtain a head-to-tail cyclized peptide. Peptidyl thioesters are effectively generated by Boc SPPS. However, their generation is challenging using Fmoc SPPS because thioester linkers are not stable to repeated piperidine exposure during deprotection. Herein we describe a Fmoc-based protocol for synthesizing cyclic peptides adapted for microwave assisted solid phase peptide synthesis. The protocol relies on the linker Di-Fmoc-3,4-diaminobenzoic acid, and we demonstrate the use of Gly, Ser, Arg and Ile as C-terminal amino acids (using HBTU and HATU as coupling reagents). Following synthesis, an N-acylurea moiety is generated at the C-terminal of the peptide; the resin bound acylurea peptide is then deprotected and cleaved from the resin. The fully deprotected peptide undergoes thiolysis in aqueous buffer, generating the thioester in situ. Ultimately, the head-to-tail cyclized peptide is obtained via native chemical ligation. Two naturally occurring cyclic peptides, the prototypical Möbius cyclotide kalata B1 and SFTI-1 were synthesized efficiently, avoiding potential branching at the diamino linker, using the optimized protocol. In addition, we demonstrate the possibility to use the approach for the synthesis of long and synthetically challenging linear sequences, by the ligation of two truncated fragments of a 50-residue long plant defensin.     

N(3)-protection of thymidine with Boc for an easy synthetic access to sugar-alkylated nucleoside analogs

The use of Boc as a nucleobase-protecting group in the synthesis of sugar-modified thymidine analogs is reported. Boc was easily inserted at N(3) by a simple and high-yielding reaction and found to be stable to standard treatments for the removal of Ac and (t) BuMe(2) Si (TBDMS) groups, as well as to ZnBr(2) -mediated 4,4'-dimethoxytrityl (DMTr) deprotection. Boc Protection proved to be completely resistant to the strong basic conditions required to regioselectively achieve O-alkylation, therefore, providing synthetic access to a variety of sugar-alkylated nucleoside analogs. To demonstrate the feasibility of this approach, two 3'-O-alkylated thymidine analogs have been synthesized in high overall yields and fully characterized.     

Microwave‐assisted solid‐phase peptide synthesis at 60 °C: alternative conditions with low enantiomerization

Several conditions have been used in the coupling reaction of stepwise SPPS at elevated temperature (SPPS‐ET), but we have elected the following as our first choice: 2.5‐fold molar excess of 0.04–0.08 M Boc or Fmoc‐amino acid derivative, equimolar amount of DIC/HOBt (1:1) or TBTU/DIPEA (1:3), 25% DMSO/toluene, 60 °C, conventional heating. In this study, aimed to further examine enantiomerization under such condition and study the applicability of our protocols to microwave‐SPPS, peptides containing L ‐Ser, L ‐His, L ‐Cys and/or L ‐Met were manually synthesized traditionally, at 60 °C using conventional heating and at 60 °C using microwave heating. Detailed assessment of all crude peptides (in their intact and/or fully hydrolyzed forms) revealed that, except for the microwave‐assisted coupling of L ‐Cys, all other reactions occurred with low levels of amino acid enantiomerization (<2%). Therefore, herein we (i) provide new evidences that our protocols for SPPS at 60 °C using conventional heating are suitable for routine use, (ii) demonstrate their appropriateness for microwave‐assisted SPPS by Boc and Fmoc chemistries, (iii) disclose advantages and limitations of the three synthetic approaches employed. Thus, this study complements our past research on SPPS‐ET and suggests alternative conditions for microwave‐assisted SPPS. Copyright © 2009 European Peptide Society and John Wiley & Sons, Ltd.     

Limiting racemization and aspartimide formation in microwave-enhanced Fmoc solid phase peptide synthesis.

Microwave energy represents an efficient manner to accelerate both the deprotection and coupling reactions in 9-fluorenylmethyloxycarbonyl (Fmoc) solid phase peptide synthesis (SPPS). Typical SPPS side reactions including racemization and aspartimide formation can occur with microwave energy but can easily be controlled by routine use of optimized methods. Cysteine, histidine, and aspartic acid were susceptible to racemization during microwave SPPS of a model 20mer peptide containing all 20 natural amino acids. Lowering the microwave coupling temperature from 80 degrees C to 50 degrees C limited racemization of histidine and cysteine. Additionally, coupling of both histidine and cysteine can be performed conventionally while the rest of the peptide is synthesized using microwave without any deleterious effect, as racemization during the coupling reaction was limited to the activated ester state of the amino acids up to 80 degrees C. Use of the hindered amine, collidine, in the coupling reaction also minimized formation of D-cysteine. Aspartimide formation and subsequent racemization of aspartic acid was reduced by the addition of HOBt to the deprotection solution and/or use of piperazine in place of piperidine.     

Facile preparation of the N‐acetyl‐glucosaminylated asparagine derivative with TFA‐sensitive protecting groups useful for solid‐phase glycopeptide synthesis

In this study, a novel N‐acetyl‐glucosaminylated asparagine derivative was developed. This derivative carried TFA‐sensitive protecting groups and was derived from commercially available compounds only in three steps. It was applicable to the ordinary 9‐fluorenylmethoxycarbonyl (Fmoc)‐based solid‐phase peptide synthesis (SPPS) method, and the protecting groups on the carbohydrate moiety could be removed by a single step of TFA cocktail treatment generally used for the final deprotection step in Fmoc‐SPPS. Copyright © 2015 European Peptide Society and John Wiley & Sons, Ltd.     

Suppression of Side Reactions During Final Deprotection Employing a Strong Acid in Boc Chemistry: Regeneration of Methionyl Residues from Their Sulfonium Salts

During global deprotection using a strong acid in Boc chemistry, the electrophilic alkylating species, i.e. carbocations, and formaldehyde generated from the side-chain protecting groups and the benzyloxymethyl group on the His residue, respectively, can cause alkylation of susceptible residues. To reduce these side reactions, a deprotection procedure using a strong acid such as HF or trifuloromethanesulfonic acid must always be carried out in the presence of scavengers. We found that addition of hydroxylamine derivatives could efficiently suppress the side reactions associated with formaldehyde and that addition of 2-mercaptopyridine could not only specifically circumvent alkylation of the Met residue but also convert its sulfonium salt to the Met residue regardless of the substituent species.     

Racemisation of N‐Fmoc phenylglycine under mild microwave‐SPPS and conventional stepwise SPPS conditions: attempts to develop strategies for overcoming this

We have been engaged in the microwave‐solid phase peptide synthesis (SPPS) synthesis of the phenylglycine (Phg)‐containing pentapeptide H‐Ala‐Val‐Pro‐Phg‐Tyr‐NH₂ (1) previously demonstrated to bind to the so‐called BIR3 domain of the anti‐apoptotic protein XIAP. Analysis of the target peptide by a combination of RP‐HPLC, ESI‐MS, and NMR revealed the presence of two diastereoisomers arising out of the racemisation of the Phg residue, with the percentage of the LLLDL component assessed as 49%. We performed the synthesis of peptide (1) using different microwave and conventional stepwise SPPS conditions in attempts to reduce the level of racemisation of the Phg residue and to determine at which part of the synthetic cycle the epimerization had occurred. We determined that racemisation occurred mainly during the Fmoc‐group removal and, to a much lesser extent, during activation/coupling of the Fmoc‐Phg‐OH residue. We were able to obtain the desired peptide with a 71% diastereomeric purity (29% LLLDL as impurity) by utilizing microwave‐assisted SPPS at 50 °C and power 22 Watts, when the triazine‐derived coupling reagent DMTMM‐BF₄ was used, together with NMM as an activator base, for the incorporation of this residue and 20% piperidine as an Fmoc‐deprotection base. In contrast, the phenylalanine analogue of the above peptide, H‐Ala‐Val‐Pro‐Phe‐Tyr‐NH₂ (2), was always obtained as a single diastereoisomer by using a range of standard coupling and deprotection conditions. Our findings suggest that the racemisation of Fmoc‐Phg‐OH, under both microwave‐SPPS and stepwise conventional SPPS syntheses conditions, is very facile but can be limited through the use of the above stated conditions. Copyright © 2012 European Peptide Society and John Wiley & Sons, Ltd.     

生长激素释放肽的合成及促生长活性

用固相多肽合成法合成了生长激素释放肽(GHRP),这是一种含D-型氨基酸的外源性激素,具有促进脑下垂体分泌生长激素功能的人工合成六肽,其氨基酸序列为His-D-Trp-Ala-Trp-D-Phe-Lys-NH₂.观察了使用不同剂量的GHRP对不同日龄小鼠的促生长效应,当使用最佳剂量(1000μg/kg)时,可使25日龄小鼠体重较对照组增加14.8%,同时发现鼠龄越小对GHRP越敏感,当使用剂量高达10mg/kg时仍然安全无毒.     

Regeneration of aged DMF for use in solid‐phase peptide synthesis

Dimethylformamide (DMF), which is still the most commonly used solvent for Fmoc‐SPPS, has the potential for degradation over time on exposure to air (and water vapour) and storage, to give dimethylamine and formic acid impurities. In particular, dimethylamine can lead to unwanted deprotection of the fluorenylmethyloxycarbonyl (Fmoc) group during, for example, the initial loading of Fmoc amino acids in SPPS, which leads reduced calculated loading values. We have found that treatment of such aged DMF by simple sparging with an inert gas (N₂), or vacuum sonication, can regenerate the DMF in order to restore loading levels back to those found for newer, fresh, DMF samples.     

Synthesis and cardioprotective properties of apelin-12 and its structural analogs

The apelin-12 and a number of its analogs, resistant to degradation of proteases, were synthesized by Fmoc- method of SPPS. By-products of synthesis were examined. It was found that serine hydroxyl group was sulfating during the final deprotection of apelin-12 (I) and its analogs. Sulfate moiety of Arg-protecting group transfer into hydroxyl group of Ser. Amount of by-product depends on presence of water in cleavage mixture. Furthermore, the final deprotection of amide analogs of apelin-12 (III, IV) is closed with formation of by-product--4-hydroxybenzylamide, its amount range on 20-8% on reaction mixture accordance HPLC data and also depend on composition of cleavage mixture. Effects of the synthesized peptides on recovery of cardiac function after ischemia were examined in a model of isolated perfused rat heart. Infusions of any of the peptides (I-V) before ischemia resulted in a significant improvement of contractile and pump function recovery compared to the control. Cardioptotective efficacy of the peptides increased in the following rank (I) < (II) = (III) < (IV) = (V).     

Methods and protocols of modern solid phase peptide synthesis

The purpose of this article is to delineate strategic considerations and provide practical procedures to enable non-experts to synthesize peptides with a reasonable chance of success. This article is not encyclopedic but rather devoted to the Fmoc/tBu approach of solid phase peptide synthesis (SPPS), which is now the most commonly used methodology for the production of peptides. The principles of SPPS with a review of linkers and supports currently employed are presented. Basic concepts for the different steps of SPPS such as anchoring, deprotection, coupling reaction and cleavage are all discussed along with the possible problem of aggregation and side-reactions. Essential protocols for the synthesis of fully deprotected peptides are presented including resin handling, coupling, capping, Fmoc-deprotection, final cleavage and disulfide bridge formation.     

N(3)‐Protection of Thymidine with Boc for an Easy Synthetic Access to Sugar‐Alkylated Nucleoside Analogs

The use of Boc as a nucleobase‐protecting group in the synthesis of sugar‐modified thymidine analogs is reported. Boc was easily inserted at N(3) by a simple and high‐yielding reaction and found to be stable to standard treatments for the removal of Ac and ^tBuMe₂Si (TBDMS) groups, as well as to ZnBr₂‐mediated 4,4′‐dimethoxytrityl (DMTr) deprotection. Boc Protection proved to be completely resistant to the strong basic conditions required to regioselectively achieve O‐alkylation, therefore, providing synthetic access to a variety of sugar‐alkylated nucleoside analogs. To demonstrate the feasibility of this approach, two 3′‐O‐alkylated thymidine analogs have been synthesized in high overall yields and fully characterized.     

Synthesis and application of Fmoc-His(3-Bum)-OH.

This paper presents a reevaluation of the synthesis and properties of Fmoc-His(3-Bum)-OH regarding its application in SPPS with minimal racemization of histidine residues during coupling and esterification reactions. By-product formation during the deprotection of the test peptides could be significantly reduced by scavenging the concomitantly formed HCHO, e.g. with methoxyamine.     

Use of the Npys thiol protection in solid phase peptide synthesis. Application to direct peptide-protein conjugation through cysteine residues

The protection of the thiol function of cysteine with the 3-nitro-2-pyridylsulfenyl (Npys) group has been successfully applied in the solid phase synthesis of nine peptides. A reexamination of the chemical stability of the protecting group has shown that, while Npys is essentially suitable for standard Boc/benzyl synthesis conditions, it is inadequate for the Fmoc strategy. Its proven stability to "high" HF acidolysis can not be extended to "low-high" conditions without significant thiol deprotection. On the other hand, the Npys group is quite compatible with standard photolytical cleavage conditions. The stability of Npys to HF and its thiol-activating character allow its application in peptide-carrier protein conjugation reactions by specific coupling through cysteine residues in the peptide.     

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.