Automated ‘X‐Y’ robot for peptide synthesis with microwave heating: application to difficult peptide sequences and protein domains

Precise microwave heating has emerged as a valuable method to aid solid‐phase peptide synthesis (SPPS). New methods and reliable protocols, as well as their embodiment in automated instruments, are required to fully use this potential. Here we describe a new automated robotic instrument for SPPS with microwave heating, report protocols for its reliable use and report the application to the synthesis of long sequences, including the β‐amyloid 1‐42 peptide. The instrument is built around a valve‐free robot originally developed for parallel peptide synthesis, where the robotic arm transports reagents instead of pumping reagents via valves. This is the first example of an ‘X‐Y’ robotic microwave‐assisted synthesizer developed for the assembly of long peptides. Although the instrument maintains its capability for parallel synthesis at room temperature, in this paper, we focus on sequential peptide synthesis with microwave heating. With this valve‐free instrument and the protocols developed for its use, fast and efficient syntheses of long and difficult peptide sequences were achieved. Copyright © 2010 European Peptide Society and John Wiley & Sons, Ltd.     

Synthesis of proteins by native chemical ligation using Fmoc-based chemistry

C-terminal peptide alpha-thioesters are valuable intermediates in the synthesis/semisynthesis of proteins by native chemical ligation. They are prepared either by solid-phase peptide synthesis (SPPS) or biosynthetically by protein splicing techniques. The present paper reviews the different methods available for the chemical synthesis of peptide alpha-thioesters using Fmoc-based SPPS.     

Advances in Fmoc solid‐phase peptide synthesis

Today, Fmoc SPPS is the method of choice for peptide synthesis. Very‐high‐quality Fmoc building blocks are available at low cost because of the economies of scale arising from current multiton production of therapeutic peptides by Fmoc SPPS. Many modified derivatives are commercially available as Fmoc building blocks, making synthetic access to a broad range of peptide derivatives straightforward. The number of synthetic peptides entering clinical trials has grown continuously over the last decade, and recent advances in the Fmoc SPPS technology are a response to the growing demand from medicinal chemistry and pharmacology. Improvements are being continually reported for peptide quality, synthesis time and novel synthetic targets. Topical peptide research has contributed to a continuous improvement and expansion of Fmoc SPPS applications. Copyright © 2015 European Peptide Society and John Wiley & Sons, Ltd.     

Assessing the correlation of microscopy‐based and volumetry‐based measurements for resin swelling in a range of potential greener solvents for SPPS

The degree of resin swelling in a particular solvent system is one of the critical parameters for solid‐phase peptide synthesis (SPPS) and for solid‐phase synthesis in general. Methods used for measuring the degree of resin swelling include microscopy‐based and volumetry‐based methods. This study describes and compares the use of both methods for a number of commercially available resins commonly used in SPPS, with a range of solvents, which have been identified in the literature as ‘greener’ than DCM, DMF and NMP. The results were analysed by statistical methods, and a significant correlation between the two distinct methods has been demonstrated for the first time. The results will likely be used, in conjunction with other literature methods, to help in choosing both the resin and solvent system for greener SPPS, as well as for continuous flow SPPS, which is of growing importance.     

Some Mechanistic Aspects on Fmoc Solid Phase Peptide Synthesis

Peptides are biomolecules that may have several biological activities which makes them important to the environment in which they operate. Sometimes it is necessary for larger amounts of peptides to carry out some studies, like biological tests, NMR structural research or even interaction studies between peptides with other molecules. Expression can be an alternative for that. However, synthesis is specially useful when unnatural modifications or introduction of site specific tags are required. Synthetic peptides have been used for different studies such as cell signaling, development of epitope-specific antibodies, in cell-biology, biomarkers for diseases etc. Many different methodologies for peptide synthesis can be found in the literature. Solid phase peptide synthesis (SPPS) has been largely used and can be an excellent alternative to achieve larger quantities of these biomolecules. In this mini review, we aim to describe the SPPS and explain some of the mechanistic aspects and reagents involved in all phases of the synthesis: the use of resin, the ninhydrin test, some of the protecting groups, coupling reagents for peptide bond formation and the cleavage process.     

Development of a Method for the Solid-Phase Peptide Synthesis in Water

Various organic solvents are routinely used in peptide synthesis, safe disposal of which are now an important environmental problem. To circumvent this problem, during the last few years we focused on developing an organic solvent-free SPPS method using aqueous solvents. For the SPPS in water, we designed protected amino acids that could be used in the aqueous media. Here we described development of several types of water-soluble protected amino acids and their application to the SPPS in water, and a novel technology that uses water-dispersible protected amino acids for in-water peptide synthesis.     

Industrial Applications of Solid-Phase Peptide Synthesis – A Status Report

Despite the fact that the structure of peptides has been known for more than a century, it was not until du Vigneaud published the synthesis of oxytocin 50 years later that the field was truly launched and the use of peptides as pharmaceuticals began. Since then, technical progress in the field has been astonishing, and the synthesis of peptides of virtually any size and complexity is now possible, with scale-up to the level of metric tonnes a reality. Perhaps the most important development was Merrifield’s publication of the solid-phase peptide synthesis (SPPS) method, which completely revolutionized the field, both from the perspective of accelerating research and discovery, and also because of its now widespread use for the manufacture of peptides for use as active pharmaceutical ingredients (APIs). The application of the SPPS method to the manufacture of peptide APIs will be reviewed, including both a historical overview and a summary of the current status. Some of the remaining challenges will also be discussed.     

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.     

Tools for investigating peptide-protein interactions: peptide incorporation of environment-sensitive fluorophores via on-resin derivatization

This protocol presents the peptide incorporation of environment-sensitive fluorophores derived from the dimethylaminophthalimide family. The procedure utilizes anhydride precursors of 4-dimethylaminophthalimide (4-DMAP) or 6-dimethylaminonaphthalimide (6-DMN), whose syntheses are described in a related protocol from these authors. In this protocol, the fluorophores are directly incorporated after solid-phase peptide synthesis (SPPS) via on-resin derivatization of peptides prepared using commercially available diamino acids, which are Alloc-protected on the side-chain amino group. The time required to complete the procedure depends on the size and number of peptides targeted. As an alternative to this approach, the corresponding fluorescent amino acids can be obtained in an Fmoc-protected form for convenient use as building blocks in SPPS. This option is described in a related protocol by these authors.     

Tools for investigating peptide-protein interactions: peptide incorporation of environment-sensitive fluorophores through SPPS-based 'building block' approach

This protocol presents the synthesis and peptide incorporation of environment-sensitive fluorescent amino acids derived from the dimethylamino-phthalimide family. The procedure uses anhydride precursors of 4-dimethylaminophthalimide (4-DMAP) or 6-dimethylaminonaphthalimide (6-DMN), whose syntheses are described in a related protocol by these authors. In this study, the corresponding fluorescent amino acids can be readily obtained in Fmoc-protected form for convenient use as building blocks in solid phase peptide synthesis (SPPS). The time required to complete the procedure depends on the size and the number of peptides targeted. Alternatively, the chromophores can be incorporated directly after SPPS via on-resin derivatization of peptides, which is an option described in a related protocol by these authors.     

Improved Fmoc‐based solid‐phase synthesis of homologous peptide fragments of human and mouse prion proteins

The synthesis of difficult peptide sequences has been a challenge since the very beginning of SPPS. The self‐assembly of the growing peptide chains has been proposed as one of the causes of this synthetic problem. However, there is an increasing need to obtain peptides and proteins that are prone to aggregate. These peptides and proteins are generally associated with diseases known as amyloidoses. We present an efficient SPPS of two homologous peptide fragments of HuPrP (106–126) and MoPrP105–125 based on the use of the PEGA resin combined with proper coupling approaches. These peptide fragments were also studied by CD and TEM to determine their ability to aggregate. On the basis of these results, we support PEG‐based resins as an efficient synthetic tool to prepare peptide sequences prone to aggregate on‐resin. Copyright © 2010 European Peptide Society and John Wiley & Sons, Ltd.     

Efficient methodology for the cyclization of linear peptide libraries via intramolecular S-alkylation using Multipin solid phase peptide synthesis.

Methodology is described here for the efficient parallel synthesis and cyclization of linear peptide libraries using intramolecular S-alkylation chemistry in combination with Multipin solid phase peptide synthesis (Multipin SPPS). The effective use of this methodology was demonstrated with the synthesis of a 72-member combinatorial library of cyclic thioether peptide derivatives of the conserved four-residue structural motif DD/EXK found in the active sites of the five crystallographically defined orthodox type II restriction endonucleases, EcoRV, EcoRI, PvuII, BamHI and BglI.     

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.     

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.     

Synthesis of phosphotyrosyl-containing phosphopeptides by solid-phase peptide synthesis.

The synthesis of phosphotyrosine-containing phosphopeptides using solid-phase peptide synthesis (SPPS) techniques is described. We present the synthesis of a Boc-phosphotyrosine derivative, which when used with modifications of the conventional SPPS protocol permits the incorporation of phosphotyrosine into synthetic peptides. The resulting phosphopeptides were authenticated by fast atom bombardment mass spectrometry, amino acid analysis, and phosphate assay. Alkaline phosphatase was found to dephosphorylate synthetic phosphopeptides at different rates, supporting the potential use of these synthetic substrates for studies of phosphoprotein phosphatases. Synthesis of a phosphopeptide using the described protocol has several advantages over the preparation of phosphopeptides via enzymatic phosphorylation.     

Fmoc-based synthesis of the human CC chemokine CCL14/HCC-1 by SPPS and native chemical ligation

Summary The CC chemokine CCL14/HCC-1(9–74), a 66-residue polypeptide containing two disulfide bonds, was recently discovered from a human hemofiltrate peptide library as a high-affinity ligand of the chemokine receptors CCR1 and CCR5. It has been shown to inhibit HIV infection by blocking CCR5. Using Fmoc methodology, we, report the chemical synthesis of CCL14/HCC-1 by conventional stepwise solid-phase peptide synthesis (SPPS) and, alternatively, native chemical ligation. To optimize SPPS of CCL14/HCC-1, difficult sequence regions were identified by mass spectrometry, in order to obtain a crude tetrathiol precursor suitable for oxidative disulfide formation. For synthesis of CCL14/HCC-1 by native chemical ligation, the peptide was divided into two segments, CCL14/HCC-1(9–39) and CCL14/HCC-1(40–74), the latter containing a cysteine residue at the amino-terminus. The synthesis of the thioester segment was carried out comparing a thiol linker with a sulfonamide safety-catch linker. While the use of the thiol linker led to very low overall yields of the desired thioester, the sulfonamide linker was efficient in obtaining the 31-residue thioester of CCL14/HCC-1(9–39), suggesting a superior suitability of this linker in generating larger thioesters using Fmoc chemistry. The thioester of CCL14/HCC-1 was subsequently ligated with the cysteinyl segment to the full-length chemokine. Disulfides were introduced in the presence of the redox buffer cysteine/cystine. The products of both SPPS and native chemical ligation were identical. The use of a sulfonamide safety-catch linker enables the Fmoc synthesis of larger peptide thioesters, and is thus useful to generate arrays of larger polypeptides.     

Bradykinin in Solid-phase Peptide Synthesis

Bradykinin (Arg-Pro-Pro-Gly-Phe-Ser-Pro-Phe-Arg; BK) occupies a special place in the history of the development of solid-phase peptide synthesis (SPPS). It was the first biologically-active peptide to be synthesized by Merrifield using the new method. Since that time many hundreds of BK analogs have been synthesized by SPPS. Certain of these analogs show potential as drug candidates. Dedicated to the memory of Bruce Merrifield. John Stewart (left) and RB Merrifield (right) with the first automatic peptide synthesizer.      

Fmoc-based synthesis of the human CC chemokine CCL14/HCC-1 by SPPS and native chemical ligation

The CC chemokine CCL14/HCC-1(9-74), a 66-residue polypeptide containing two disulfide bonds, was recently discovered from a human hemofiltrate peptide library as a high-affinity ligand of the chemokine receptors CCR1 and CCR5. It has been shown to inhibit HIV infection by blocking CCR5. Using Fmoc methodology, we report the chemical synthesis of CCL14/HCC-1 by conventional stepwise solid-phase peptide synthesis (SPPS) and, alternatively, native chemical ligation. To optimize SPPS of CCL14/HCC-1, difficult sequence regions were identified by mass spectrometry, in order to obtain a crude tetrathiol precursor suitable for oxidative disulfide formation. For synthesis of CCL14/HCC-1 by native chemical ligation, the peptide was divided into two segments, CCL14/HCC-1(9-39) and CCL14/HCC-1(40-74), the latter containing a cysteine residue at the amino-terminus. The synthesis of the thioester segment was carried out comparing a thiol linker with a sulfonamide safety-catch linker. While the use of the thiol linker led to very low overall yields of the desired thioester, the sulfonamide linker was efficient in obtaining the 31-residue thioester of CCL14/HCC-1(9-39), suggesting a superior suitability of this linker in generating larger thioesters using Fmoc chemistry. The thioester of CCL14/HCC-1 was subsequently ligated with the cysteinyl segment to the full-length chemokine. Disulfides were introduced in the presence of the redox buffer cysteine/cystine. The products of both SPPS and native chemical ligation were identical. The use of a sulfonamide safety-catch linker enables the Fmoc synthesis of larger peptide thioesters, and is thus useful to generate arrays of larger polypeptides.     

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.     

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.