(S)-2-(Fmoc-amino)-4-iodobutanoic acid

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)

Aromatic short peptide derivatives, i.e. peptides modified with aromatic groups such as 9-fluorenylmethoxycarbonyl (Fmoc), can self-assemble into self-supporting hydrogels. These hydrogels have some similarities to extracellular matrices due to their high hydration, relative stiffness and nanofibrous architecture. We previously demonstrated that Fmoc-diphenylalanine (Fmoc-F(2)) provides a suitable matrix for two-dimensional (2D) or three-dimensional (3D) culture of primary bovine chondrocytes. In this paper we investigate whether the introduction of chemical functionality, such as NH(2), COOH or OH, enhances compatibility with different cell types. A series of hydrogel compositions consisting of combinations of Fmoc-F(2) and n-protected Fmoc amino acids, lysine (K, with side chain R=(CH(2))(4)NH(2)), glutamic acid (D, with side chain R=CH(2)COOH), and serine (S, with side chain R=CH(2)OH) were studied. All compositions produced fibrous scaffolds with fibre diameters in the range of 32-65 nm as assessed by cryo-scanning electron microscopy and atomic force microscopy. Fourier transform infrared spectroscopy analysis suggested that peptide segments adopt a predominantly antiparallel beta-sheet conformation. Oscillatory rheology results show that all four hydrogels have mechanical profiles of soft viscoelastic materials with elastic moduli dependent on the chemical composition, ranging from 502 Pa (Fmoc-F(2)/D) to 21.2 KPa (Fmoc-F(2)). All gels supported the viability of bovine chondrocytes as assessed by a live-dead staining assay. Fmoc-F(2)/S and Fmoc-F(2)/D hydrogels in addition supported viability for human dermal fibroblasts (HDF) while Fmoc-F(2)/S hydrogel was the only gel type that supported viability for all three cell types tested. Fmoc-F(2)/S was therefore investigated further by studying cell proliferation, cytoskeletal organization and histological analysis in 2D culture. In addition, the Fmoc-F(2)/S gel was shown to support retention of cell morphology in 3D culture of bovine chondrocytes. These results demonstrate that introduction of chemical functionality into Fmoc-peptide scaffolds may provide gels with tunable chemical and mechanical properties for in vitro cell culture.

Circular economy and aqueous synthesis are attractive concepts for sustainable chemistry. Here it is reported that the two can be combined in the universal method for peptide chemistry, fluorenylmethoxycarbonyl(Fmoc)/t-Bu solid-phase peptide synthesis (SPPS). It was demonstrated that Fmoc/t-Bu SPPS could be performed under aqueous conditions using standard Fmoc amino acids (AAs) employing TentaGel S as resin and 4 : 1 mixture of water with inexpensive green solvent PolarClean. This resin/solvent combination played a crucial dual role by virtue of improving resin swelling and solubility of starting materials. In a model coupling, TCFH and 2,4,6-collidine afforded a full conversion at only 1.3 equiv. AA, and these conditions were used in SPPS of Leu enkephaline amide affording the model peptide in 85 % yield and 86 % purity. A method to recycle the waste by filtration through a mixed ion exchange resin was developed, allowing reusing the waste without affecting quality of the peptide. The method herein obviates the use of unconventional or processed AAs in aqueous SPPS while using lower amounts of starting materials. By recycling/reusing SPPS waste the hazardous dipolar aprotic solvents used in SPPS were not only replaced with an aqueous medium, solvent use was also significantly reduced. This opens up a new direction in aqueous peptide chemistry in which efficient use of inexpensive starting materials and waste minimization is coupled with the universal Fmoc/t-Bu SPPS.