Parallel synthesis of peptide libraries using microwave irradiation

The application of microwave irradiation to solid-phase peptide synthesis increases product purity and reduces reaction time. Parallel synthesis in 96-well polypropylene filter plates with microwave irradiation is an efficient method for the rapid generation of combinatorial peptide libraries in sufficient purity to assay the products directly for biological activity without HPLC purification. In this protocol, the solid-phase support is arrayed into each well of a 96-well plate, reagents are delivered using a multichannel pipette and a microwave reactor is used to complete peptide coupling reactions in 6 min and Fmoc-removal reactions in 4 min under temperature-controlled conditions. The microwave-assisted parallel peptide synthesis protocol has been used to generate a library of difficult hexa-beta-peptides in 61% average initial purity (50% yield) and has been applied to the preparation of longer alpha- and beta-peptides. Using this protocol, a library of 96 different hexapeptides can be synthesized in 24 h (excluding characterization).     

Solid-phase synthesis of C-terminally modified peptides.

In this paper, a straightforward and generic protocol is presented to label the C-terminus of a peptide with any desired moiety that is functionalized with a primary amine. Amine-functional molecules included are polymers (useful for hybrid polymers), long alkyl chains (used in peptide amphiphiles and stabilization of peptides), propargyl amine and azido propyl-amine (desirable for 'click' chemistry), dansyl amine (fluorescent labeling of peptides) and crown ethers (peptide switches/hybrids). In the first part of the procedure, the primary amine is attached to an aldehyde-functional resin via reductive amination. To the secondary amine that is produced, an amino acid sequence is coupled via a standard solid-phase peptide synthesis protocol. Since one procedure can be applied for any given amine-functional moiety, a robust method for C-terminal peptide labeling is obtained.     

Application of gel-phase 19F NMR spectroscopy for optimization of solid-phase synthesis of a hydrophobic peptide from the signal sequence of the mucin MUC1.

This paper describes the manual Fmoc/t-Bu solid-phase synthesis of a difficult nine-residue hydrophobic peptide LLLLTVLTV from one of the signal sequences that flank the tandem repeat of the mucin MUC1. Gel-phase 19F NMR spectroscopy was used as a straightforward method for optimization of the solid-phase synthesis. Different approaches were applied for comparative studies. The strategy based on modified solid-phase conditions using DIC/HOAt for coupling, DBU for Fmoc deprotection, and the incorporation of the pseudo proline dipeptide Fmoc-Leu-Thr(psiMe, Me pro)-OH as a backbone-protecting group was found to be superior according to gel-phase 19F NMR spectroscopy. Implementation of the optimized Fmoc protocol enabled an effective synthesis of signal peptide LLLLTVLTV.     

Optimization of solid-phase synthesis of difficult peptide sequences via comparison between different improved approaches

Summary. Different approaches are applied to avoid the strong aggregation of the difficult peptide sequences, which is considered as the main reason for incomplete acylation and deprotection reactions hindering the synthesis of these sequences. Temporary protection of amide nitrogen of peptide bond using 2-hydroxy-4-methoxybenzyl (Hmb) and 2,4,6-timethoxybenzyl (Tmob) amino acid derivatives, introduction of D-Ala or Pro residues in the peptide chain sequences and utilization of microwave energy are proved to be useful methods in the enhancement of solubility and in the hindrance of the aggregation during the solid-phase synthesis of oligoalanine. Oligoalanine is chosen to demonstrate the difficult sequences and to compare the efficiencies of these methods.     

Solid phase synthesis of peptide hydroxamic acids on poly(ethylene glycol)‐based support

A novel resin designed for solid‐phase synthesis of peptide hydroxamic acids (PHA) combining the trityl linker with poly(ethylene glycol)‐based support, ChemMatrix® type, is described. The synthesis of PHA can be performed according to a standard protocol, providing products in excellent purity and reasonable yields. Copyright © 2012 European Peptide Society and John Wiley & Sons, Ltd.     

Ribosomal synthesis of nonstandard peptides.

It is well known that standard peptides, which comprise proteinogenic amino acids, can act as specific chemical probes to target proteins with high affinity. Despite this fact, a number of peptide drug leads have been abandoned because of their poor cell permeability and protease instability. On the other hand, nonstandard peptides isolated as natural products often exhibit remarkable pharmaco-behavior and stability in vivo. Although it is likely that numerous nonstandard therapeutic peptides capable of recognizing various targets could have been synthesized, enzymes for nonribosomal peptide syntheses are complex; therefore, it is difficult to engineer such modular enzymes to build nonstandard peptide libraries. Here we describe an emerging technology for the synthesis of nonstandard peptides that employs an integrated system of reconstituted cell-free translation and flexizymes. We summarize the historical background of this technology and discuss its current and future applications to the synthesis of nonstandard peptides and drug discovery.     

Design and synthesis of chiral peptidic nucleic acids

Summary Due to the increasing interest in the use of oligonucleotide analogues as antisense and antigene drugs, we designed a chiral analogue constituted of a peptidic frame bearing nucleobases in suitable positions (C-PNA). We recently reported the synthesis of four nonnatural α-amino acids with the DNA bases in the lateral chain. In this paper we present an improved synthesis of the Fmoc monomers and their polymerisation to polypeptidic oligonucleotide analogues using a modification of the standard protocol for solid phase peptide synthesis.     

The 'O-acyl isopeptide method' for the synthesis of difficult sequence-containing peptides: application to the synthesis of Alzheimer's disease-related amyloid beta peptide (Abeta) 1-42.

An efficient 'O-acyl isopeptide method' for the synthesis of difficult sequence-containing peptides was applied successfully to the synthesis of amyloid beta peptide (Abeta) 1-42 via a water-soluble O-acyl isopeptide of Abeta1-42, i.e. '26-O-acyl isoAbeta1-42' (6). This paper describes the detailed synthesis of Abeta1-42 focusing on the importance of resin selection and the analysis of side reactions in the O-acyl isopeptide method. Protected '26-O-acyl isoAbeta1-42' peptide resin was synthesized using 2-chlorotrityl chloride resin with minimum side reactions in comparison with other resins and deprotected crude 26-O-acyl isoAbeta1-42 was easily purified by HPLC due to its relatively good purity and narrow elution with reasonable water solubility. This suggests that only one insertion of the isopeptide structure into the sequence of the 42-residue peptide can suppress the unfavourable nature of its difficult sequence. The migration of O-acyl isopeptide to intact Abeta1-42 under physiological conditions (pH 7.4) via O--N intramolecular acyl migration reaction was very rapid and no other by-product formation was observed while 6 was stable under storage conditions. These results concluded that our strategy not only overcomes the solubility problem in the synthesis of Abeta1-42 and can provide intact Abeta1-42 efficiently, but is also applicable in the synthesis of large difficult sequence-containing peptides at least up to 50 amino acids. This synthesis method would provide a biological evaluation system in Alzheimer's disease research, in which 26-O-acyl isoAbeta1-42 can be stored in a solubilized form before use and then rapidly produces intact Abeta1-42 in situ during biological experiments.     

Conventional and microwave‐assisted SPPS approach: a comparative synthesis of PTHrP(1–34)NH2

Attracted by the possibility to optimize time and yield of the synthesis of difficult peptide sequences by MW irradiation, we compared Fmoc/tBu MW‐assisted SPPS of 1–34 N‐terminal fragment of parathyroid hormone‐related peptide (PTHrP) with its conventional SPPS carried out at RT. MWs were applied in both coupling and deprotection steps of SPPS protocol. During the stepwise elongation of the resin‐bound peptide, monitoring was conducted by performing MW‐assisted mini‐cleavages and analyzing them by UPLC‐ESI‐MS. Identification of some deletion sequences was helpful to recognize critical couplings and as such helped to guide the introduction of MW irradiations to these stages. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

An optimized Boc synthesis of indolicidin

Indolicidin, an antimicrobial peptide from bovine neutrophils containing five tryptophan out of a total of 13 residues, has the highest molar proportion of tryptophan of any known peptide sequence and is thus considered a difficult synthetic target. Conventional Boc chemistry can be applied to the synthesis of indolicidin with an appropriate choice of scavenger mixtures, reaction times and temperatures at the crucial acidolytic cleavage and deprotection step. In particular, treatment with HF/p-cresol/p-thiocresol (90:7:3) for 40 min at –8 °C results in a crude product containing ca. 90% indolicidin, from which the target compound can be isolated in satisfactory yields and purity after reverse-phase purification. The main byproducts arising during the synthesis and cleavage steps have been identified by HPLC with on-line electrospray mass spectrometric detection.     

PNA synthesis using a novel Boc/acyl protecting group strategy.

The synthesis of novel Boc/acyl protected monomers for the synthesis of peptide nucleic acid (PNA) is described. The oligomerization protocol using these new monomers has been optimized with regard to coupling reagents. The use of base-labile acyl protecting groups at the exocyclic amines of the heterocyclic bases (isobutyryl for guanine and benzoyl for adenine and cytosine) and a PAM-linked solid support offers an attractive alternative to the present procedures used in PNA synthesis. This strategy has been applied for the synthesis of a test 17mer PNA on both control pore glass (CPG) and a polystyrene MBHA support and was used in the preparation of PNA-DNA chimeras.     

Spot synthesis: observations and optimizations.

Positionally addressable syntheses of peptides on continuous cellulose membranes (spot synthesis) have often been reported in detail, but important questions dealing with synthesis quality, reproducibility and subsequent binding assays have largely been under-emphasized. In this report we have investigated some of these problems. The most important results were: (i) the signal intensity of ligate binding to cellulose-bound peptides and the affinity of the corresponding soluble peptides show good correlation, illustrated by three different ligate binding assays; (ii) reducing peptide density on the cellulose avoids the 'ring spot' effect, i.e. where less binding is observed in the spot-center compared to the rim. We recommend a peptide density of 10 nmol/cm2 as a reasonable starting point for further optimization; (iii) statistical analysis of binding assay reproducibility with more than 15000 peptides resulted in a mean standard signal deviation of 0.18; and (iv) optimization of side-chain deprotection revealed that a 30-min pretreatment of the cellulose with 90% trifluoroacetic acid followed by the standard deprotection protocol resulted in higher purity of the synthesized products.     

Aqueous microwave-assisted solid-phase peptide synthesis using Fmoc strategy. III: Racemization studies and water-based synthesis of histidine-containing peptides

In this study, we describe the first aqueous microwave-assisted synthesis of histidine-containing peptides in high purity and with low racemization. We have previously shown the effectiveness of our synthesis methodology for peptides including difficult sequences using water-dispersible 9-fluorenylmethoxycarbonyl-amino acid nanoparticles. It is an organic solvent-free, environmentally friendly method for chemical peptide synthesis. Here, we studied the racemization of histidine during an aqueous-based coupling reaction with microwave irradiation. Under our microwave-assisted protocol using 4-(4,6-dimethoxy-1,3,5-triazin-2-yl)-4-methylmorpholinium chloride, the coupling reaction can be efficiently performed with low levels of racemization of histidine. Application of this water-based microwave-assisted protocol with water-dispersible 9-fluorenylmethoxycarbonyl-amino acid nanoparticles led to the successful synthesis of the histidine-containing hexapeptide neuropeptide W-30 (10–15), Tyr-His-Thr-Val-Gly-Arg-NH₂, in high yield and with greatly reduced histidine racemization.     

Solid-phase synthesis of pseudo-complementary peptide nucleic acids

Pseudo-complementary peptide nucleic acid (pcPNA) is a DNA analog in which modified DNA bases 2,6-diaminopurine (D) and 2-thiouracil (U(s)) 'decorate' a poly[N-(2-aminoethyl)glycine] backbone, together with guanine (G) and cytosine (C). One of the most significant characteristics of pcPNA is its ability to effect double-duplex invasion of predetermined DNA sites inducing various changes in the biological and the physicochemical properties of the DNA. This protocol describes solid-phase synthesis of pcPNA. The monomers for G and C are commercially available, but the monomers for D and U(s) need to be synthesized (or can be ordered to custom synthesis companies). Otherwise, the procedure is the same as that employed for Boc-strategy synthesis of conventional PNA. This protocol, if the synthesis of D and U(s) monomers is not factored in, takes approximately 7 d to complete.     

Rapid solid-phase synthesis of a calmodulin-binding peptide using controlled microwave irradiation

A rapid and efficient microwave-assisted solid-phase synthesis method for the preparation of a nonapeptide using conventional Fmoc/Bu(t) orthogonal protection strategy is described. In this protocol, the coupling steps are performed within 5 min at 60 degrees C and the Fmoc-deprotection steps are completed within 3 min at 60 degrees C using a dedicated single-mode microwave peptide synthesizer utilizing temperature-controlled conditions. It is demonstrated that the model nonapeptide (containing the calmodulin-binding octapeptide sequence) is synthesized in a shorter time (approximately 3.5 h) and with high purity (>95%) under microwave irradiation conditions in comparison with a reference peptide that is obtained by standard methods at room temperature (within 11 h).     

An optimized Boc synthesis of indolicidin

Summary Indolicidin, an antimicrobial peptide from bovine neutrophils containing five tryptophan out of a total of 13 residues, has the highest molar proportion of tryptophan of any known peptide sequence and is thus considered a difficult synthetic target. Conventional Boc chemistry can be applied to the synthesis of indolicidin with an appropriate choice of scavenger mixtures, reaction times and temperatures at the crucial acidolytic cleavage and deprotection step. In particular, treatment with HF/p-cresol/p-thiocresol (90:7:3) for 40 min at −8°C results in a crude product containing ca. 90% indolicidin, from which the target compound can be isolated in satisfactory yields and purity after reverse-phase purification. The main byproducts arising during the synthesis and cleavage steps have been identified by HPLC with on-line electrospray mass spectrometric detection.     

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.     

An efficient Fmoc strategy for the rapid synthesis of peptide para-nitroanilides

A new strategy has been developed for the rapid synthesis ofpeptide para-nitroanilides (pNA). The method involves derivatization of commercially available tritylchloride resin(TCP-resin) with 1,4-phenylenediamine, subsequent coupling withdesired amino acids by the standard Fmoc protocol, and oxidationof the intermediate para-aminoanilides (pAA) with Oxone®. This procedure allows easy assembly of the desired para-aminoanilides (pAA) on standard resin and efficient oxidation and purification of the corresponding para-nitroanilides (pNA). The method allows easy access to any desired peptide para-nitroanilides, which are useful substrates for the characterization and study of proteolytic enzymes.     

An efficient Fmoc strategy for the rapid synthesis of peptide para-nitroanilides

A new strategy has been developed for the rapid synthesis ofpeptide para-nitroanilides (pNA). The method involves derivatization of commercially available tritylchloride resin(TCP-resin) with 1,4-phenylenediamine, subsequent coupling withdesired amino acids by the standard Fmoc protocol, and oxidationof the intermediate para-aminoanilides (pAA) with Oxone®. This procedure allows easy assembly of the desired para-aminoanilides (pAA) on standard resin and efficient oxidation and purification of the corresponding para-nitroanilides (pNA). The method allows easy access to any desired peptide para-nitroanilides, which are useful substrates for the characterization and study of proteolytic enzymes.