Peptide synthesis, polymerization

The structures of these ylide polymers were determined and confirmed by IR and NMR spectra. These were the first stable sulfonium ylide polymers reported in the literature. They are very important for such industrial uses as ion-exchange resins, polymer supports, peptide synthesis, polymeric reagent, and polyelectrolytes. Also in 1977, Hass and Moreau [60] found that when poly(4-vinylpyridine) was quaternized with bromomalonamide, two polymeric quaternary salts resulted. These polyelectrolyte products were subjected to thermal decyana-tion at 7200°C to give isocyanic acid or its isomer, cyanic acid. The addition of base to the solution of polyelectro-lyte in water gave a yellow polymeric ylide. 

H. R. Kricheldorf, a-Aminoacid-N-carboxyanhydrides and Related Heterocycles Synthesis, Properties, Peptide Synthesis, Polymerization. Springer-Verlag, Berlin, 1987. 

Kricheldorf, H., a-Aminoacid-N-Carboxy-anhydrides and Related Heterocycles - Synthesis Properties, Peptide Synthesis, Polymerization, Springer Berlin, (1987) p 3. Leuchs, H. Geiger, W., Ber. Dtsch. Chem. Ges, (1908) 41, 1721. 

Kricheldorf HR (1987) a-aminoacid-Al-carboxy-anhydrides and related heterocycles syntheses, properties, peptide synthesis, polymerization. Springer, Berlin... 

Sulfonium Polymers. Polysulfonium salts have been extensively studied because of the versatile possibilities of their application. They can be used as ion-exchange resins, polymer supports in peptide synthesis, polymeric reagents, and... 

Synthesis of Peptide. There is continual progress ia the improvement of instmments and reagents for peptide synthesis, especially "soHd phase polymerization" (90) (see Proteins). This method is suitable for the synthesis of peptides with 20 30 amino acid units. 

When the polymer was prepared by the suspension polymerization technique, the product was crosslinked beads of unusually uniform size (see Fig. 16 for SEM picture of the beads) with hydrophobic surface characteristics. This shows that cardanyl acrylate/methacry-late can be used as comonomers-cum-cross-linking agents in vinyl polymerizations. This further gives rise to more opportunities to prepare polymer supports for synthesis particularly for experiments in solid-state peptide synthesis. Polymer supports based on activated acrylates have recently been reported to be useful in supported organic reactions, metal ion separation, etc. [198,199]. Copolymers are expected to give better performance and, hence, coplymers of CA and CM A with methyl methacrylate (MMA), styrene (St), and acrylonitrile (AN) were prepared and characterized [196,197]. 

Peptide synthesis requires the use of selective protecting groups. An N-protected amino acid with a free carboxyl group is coupled to an O-protected amino acid with a free amino group in the presence of dicydohexvlcarbodi-imide (DCC). Amide formation occurs, the protecting groups are removed, and the sequence is repeated. Amines are usually protected as their teit-butoxy-carbonyl (Boc) derivatives, and acids are protected as esters. This synthetic sequence is often carried out by the Merrifield solid-phase method, in which the peptide is esterified to an insoluble polymeric support. 

The polymeric resin used for Merrifield solid-phase peptide synthesis (Section 26.8) is prepared by treating polystyrene with iV-(hydroxymethyl) phthalimide and trifluoromethanesulfonic acid, followed by reaction with hydrazine. Propose a mechanism for both steps. 

Peptide synthesis was amenable to solid-phase techniques since the process was repetitive. The C-terminal amino acid is attached to polymeric surface and the peptide chain is assembled via a two-step process coupling of the incoming amino acid that has the alpha-amino group protected... 

The synthesis of some multiblock copolymers was attempted by successive polymerization using this iniferter technique. However, pure tri- or tetrablock copolymers free from homopolymers were not isolated by solvent extraction because no suitable solvent was found for the separation. In 1963, Merrifield reported a brilliant solid-phase peptide synthesis using a reagent attached to the polymer support. If a similar idea can be applied to the iniferter technique, pure block copolymer could be synthesized by radical polymerization. The DC group attached to a polystyrene gel (PSG) through a hydrolyzable ester spacer was prepared and used as a PSG photoiniferter (Eq. 53) [186] ... 

The solid-phase synthesis of dendritic polyamides was explored by Frechet et al. [49]. Inspired by the technique used by Merrifield for peptide synthesis, the same strategy was used to build hyperbranched polyamides onto a polymeric support. The idea was to ensure the preservation of the focal point and to ease the purification between successive steps. The resulting polymers were cleaved from the solid support, allowing ordinary polymer characterization. The reaction was found to be extremely sluggish beyond the fourth generation. 

A distinct group of synthetic depsipeptides comprises of compounds that do not originate from natural product biodiversity several artificial substrates of peptidases and esterases belong to this group, as well as polydepsipeptides that are considered as potentially biodegradable polymeric materials. A specific feature of depsipeptide synthesis is the necessity to acylate a hydroxy acid component, which requires stronger activation of the amino acid component in comparison to normal peptide synthesis. Otherwise, the main principles of depsipeptide synthesis are similar to those of peptides. Frequently, formation of the ester... 

Combustion (elemental) analysis of polymeric supports has mainly been used to determine the amount of halogens, nitrogen, or sulfur present in samples of cross-linked polystyrene (see, e.g., [54]). This information can be used to estimate the loading of a support, or, for example, to verify that the displacement of a halide has proceeded to completion. In solid-phase peptide synthesis, nitrogen determination has been used to estimate the loading of the first amino acid [55]. 

Standard solid-phase peptide synthesis requires the first (C-terminal) amino acid to be esterified with a polymeric alcohol. Partial racemization can occur during the esterification of N-protected amino acids with Wang resin or hydroxymethyl polystyrene [200,201]. /V-Fmoc amino acids are particularly problematic because the bases required to catalyze the acylation of alcohols can also lead to deprotection. A comparative study of various esterification methods for the attachment of Fmoc amino acids to Wang resin [202] showed that the highest loadings with minimal racemization can be achieved under Mitsunobu conditions or by activation with 2,6-dichloroben-zoyl chloride (Experimental Procedure 13.5). iV-Fmoc amino acid fluorides in the presence of DMAP also proved suitable for the racemization-free esterification of Wang resin (Entry 1, Table 13.13). The most extensive racemization was observed when DMF or THF was used as solvent, whereas little or no racemization occurred in toluene or DCM [203]. 

Biosynthesis of bacterial cell wall is remarkable in two respects (1) It entails the synthesis of a regularly cross-linked polymer and (2) Part of the synthesis takes place inside the cell and part outside the cell. The synthesis of cell wall is divided into three stages, which occur at different locations (1) synthesis of UDP-/V-acetylmuramyl-penta-peptide, (2) polymerization of IV-acetylglucosamine and N-acetylmuramyl-pentapeptide to form linear peptidoglycan strands, and (3) cross-linking of the peptidoglycan strands. 

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