TentaGel S RAM

Perloza beaded cellulose was functionalised by a cyanoethylation/reduction procedure to give aminopropyl Perloza. Fmoc-amino acids were anchored to aminopropyl Perloza beaded cellulose via the TFA labile 4-oxymethylphenoxyacetyl (HMPA) linker. Using Fmoc-aminoacyl-4-oxymethylphenoxyacetyl-2,4-dichloro-phenyl esters, all 20 amino acids were anchored at substitution levels ranging from 0.37 to 0.65 mmol/g. Fmoc-amino acids were also anchored using the peptide-amide linker 4-[(R,S)-1-[1-(9H-fluoren-9-yl)-methoxycarbonylamino - (2',4'-dimethoxybenzyl]phenoxyacetic acid. The Fmoc-aminoacyl resins were used for SPPS using Fmoc chemistry. SPPS was carried out using either an LKB Biolynx 4175 low-pressure pumped column continuous-flow peptide synthesiser or an ABI 430A automated vortexing batchwise instrument. Comparison of peptides made using each synthesiser showed little difference in quality of the crude peptides. Different Fmoc-amino acid activation methods (DIC/HOBt/DMF, HBTU, DIC/HOBt/DCM) were found to be equally useful with Perloza. Peptides were cleaved using TFA plus scavengers; however, the TFA-swollen resin was not readily separated from the TFA/peptide solution by simple filtration. Therefore alternative cleavage workup procedures were used with Perloza. Peptides were purified by HPLC and characterised by HPLC and amino acid analysis, and in some cases by FAB-MS. Successful syntheses ranged from 5 to 34 amino acids in length. Some of the peptides were also synthesized using a polystyrene support and standardised (ABI Fastmoc) SPPS protocols. The crude cleaved peptides from each synthesis were compared by HPLC analysis. The overall aim of our work with Perloza is synthesis of resin-bound peptide ligands for affinity chromatography and antibody generation.(ABSTRACT TRUNCATED AT 250 WORDS)

Since the advent of solid-phase peptide synthesis (SPPS) in the late 1950s, numerous advancements in the underlying chemistry (i.e., orthogonal protection strategy, coupling reagents, and solid support matrices) have greatly improved the efficiency of the technique. More recently, application of microwave radiation to SPPS has been found to reduce reaction time and/or increase the initial purity of synthetic peptide products. In this protocol, conditions are described to accomplish rapid peptide coupling and 9-fluorenylmethoxycarbonyl (Fmoc) removal reactions under temperature-controlled conditions in either a manual or automated synthesis format using a microwave reactor. These microwave-assisted peptide synthesis procedures have been used to rapidly prepare a "difficult" peptide sequence from the acyl carrier protein, ACP(65-74), in less than 3 h and the reduced, linear precursor to human hepcidin, in high initial purity.

The use of chitin as a support for solid-phase peptide synthesis is described and illustrated by synthesis of four peptides, varying in length from 10 to 29 residues. Syntheses were performed in a continuous-flow peptide synthesizer, using Fmoc chemistry. A cleavable linker, p-[(R,S)-alpha-[1-(9H-fluoren-9-yl)-methoxyformamido]-2,4-di methoxybenzyl]- phenoxyacetic acid, was attached to chitosan at the desired substitution level, and the complex acetylated to yield a linker substituted chitin. The effects of temperature, solvents and degree of linker substitution on the syntheses were studied. Acyl carrier peptide (ACP) synthesis studies indicated that temperature was the single most important parameter. Increasing the temperature of the synthesis from 20 to 55 degrees C resulted in an enormous improvement of this synthesis, with about 90% of the crude product being the correct peptide. Denaturing solvents, such as DMSO, could be used without significant effect on the flow properties of the support. The synthesis of one peptide was mainly improved by lowering the degree of substitution from 0.3 to 0.1 mmol/g, suggesting peptide aggregation was a problem in this case. The results of three syntheses on chitin were comparable with those obtained with a commonly used commercial support. This work shows that, under appropriate conditions, chitin can be utilized directly as a support for peptide synthesis.