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Selective protection amino acids

Amino Acids. Chloroformates play a most important role for the protection of the amino group of amino acids (qv) during peptide synthesis (32). The protective carbamate formed by the reaction of benzyl chloroformate and amino acid (33) can be cleaved by hydrogenolysis to free the amine after the carboxyl group has reacted further. The selectivity of the amino groups toward chloroformates results in amino-protected amino acids with the other reactive groups unprotected (34,35). Methods for the preparation of protected amino acids on an industrial scale have been developed (36,37). A wide variety of chloroformates have been used that give various carbamates that are stable or cleaved under different conditions. [Pg.39]

The carboxamidomethyl ester was prepared for use in peptide synthesis. It is formed from the cesium salt of an A-protected amino acid and a-chloroacetamide (60-85% yield). It is cleaved with 0.5 M NaOH or NaHCOa in DMF/H2O. It is stable to the conditions required to remove BOC, Cbz, Fmoc, and r-butyl esters. It cannot be selectively cleaved in the presence of a benzyl ester of aspartic acid. ... [Pg.239]

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. [Pg.1050]

In y-alkoxyfuranones the acetal functionality is ideally suited for the introduction of a chiral auxiliary simultaneously high 71-face selectivity may be obtained due to the relatively rigid structure that is present. With ( + )- or (—(-menthol as auxiliaries it is possible to obtain both (5S)- or (5/ )-y-menthyloxy-2(5//)-furanones in an enantiomerically pure form293. When the auxiliary acts as a bulky substituent, as in the case with the 1-menthyloxy group, the addition of enolates occurs trans to the y-alkoxy substituent. The chiral auxiliary is readily removed by hydrolysis and various optically active lactones, protected amino acids and hydroxy acids are accessible in this way294-29s-400. [Pg.966]

Although these Boc derivatives underwent methylation with poor selectivity (compared to 3-amino-N-benzoyl butanoates [106] and Z-protected methyl 4-phen-yl-3-aminobutanoate [107]), epimers were succesfully separated by preparative HPLC or by flash chromatography. However, saponification of the methyl ester caused partial epimerization of the a-stereocenter and a two-step (epimerization free) procedure involving titanate-mediated transesterification to the corresponding benzyl esters and hydrogenation was used instead to recover the required Boc-y9 -amino acids in enantiomerically pure form [104, 105]. N-Boc-protected amino acids 19 and 20 for incorporation into water-soluble /9-peptides were pre-... [Pg.42]

The imidazolide group at the amino end of an amino acid is as reactive toward nucleophiles as the imidazolide group at the carboxylic end of an amino acid. If an N-protected amino acid is selected as nucleophile, this method can also be used for peptide synthesis. The amino-activated amino acids, for example N-( 1 -imidazolylcarbonyl)-amino acid esters, are prepared from a-isocyanatocarboxylic acids and imidazole. [Pg.157]

Next, we investigated the experimental parameters for hydrogenolysis of Cbz-protected amino acids. It is important to carefully select the experimental parameters so that the reactions are not limited by diffusion of hydrogen to the catalytically active sites. The diffusion of hydrogen can be affected by temperature, agitation speed, as well as the number of catalytically active sites... [Pg.488]

The removal of carbobenzyloxy (Cbz or Z) groups from amines or alcohols is of high interest in the fine chemicals, agricultural and pharmaceutical industry. Palladium on activated carbon is the catalyst of choice for these deprotection reactions. Nitrogen containing modifiers are known to influence the selectivity for certain deprotection reactions. In this paper we show the rate accelerating effect of certain N-containing modifiers on the deprotection of carbobenzyloxy protected amino acids in the presence of palladium on activated carbon catalysts. The experiments show that certain modifiers like pyridine and ethylenediamine increase the reaction rate and therefore shorten the reaction times compared to non-modified palladium catalysts. Triethylamine does not have an influence on the rate of deprotection. [Pg.493]

For a facial selective assembly ofthe stereogenic centers and the introduction of the amino functionality, chiral nitrogen-containing reagents, such as benzyl(2-pheny-lethyl)amine (2-19) and trimethylsilyl RAMP derivative 2-24 were applied. Treatment of diacrylates 2-18, 2-21, and 2-23 with 2-19 and 2-24, respectively, gave the protected amino acids 2-20, 2-22, and 2-25 in good yields as single isomers. [Pg.51]

For this selective addition, the best catalyst precursors were Ru(methallyl)2(dppe) 1 and Ru(methallyl)2(dppb) 2. The choice of the appropriate complex depended on the steric demand of both the alkyne and the carboxylic acid. A large variety of carboxylic acids and alkynes have been used, including N-protected amino acids, a-hydroxy acids, and functionalized alkynes such as enynes, diynes and propargylic ethers [21-23] (Scheme 10.4). The addition took place under mild conditions and carboxylic adds of... [Pg.316]

Chiral titanium complexes with a, a, a, a -tetraaryl-l,3-dioxolane-4,5-dimethanol (TADDOL) ligands are versatile auxiliaries in the Lewis acid catalyzed alcoholysis of racemic 4-(arylmethyl)-2-phenyl-5(477)-oxazolones 234, providing the corresponding enantiomerically enriched N-protected amino acid esters 235 (Scheme 7.73). The enantioselectivity of the reaction is dependent on the solvent, temperature, and chiral ligand. Selected examples of the alcoholysis of saturated 5(477)-oxazolones are shown in Table 7.21 (Fig. 7.23). [Pg.180]

Various more or less efficient methods have been reported for the synthesis of 2-(l-ami-noalkyl)thiazole-4-carboxylic acids and their suitably protected derivatives. 237,539,541,558-568 Optimal conditions must be selected in these syntheses to prevent racemization at the chiral aminoalkyl moiety, e.g. when applying a modified Hantzsch synthesis 559 racemization has been observed to occur at the level of the starting Na-protected amino acid thioamide as well as in the base-mediated dehydration step of the intermediate hydroxydihydrothiazoles. 558 The 2-(aminoalkyl)thiazole-4-carboxylic acids are incorporated into the linear precursors by standard procedures of peptide synthesis, 237,514,529,539,552,555,558,564,569 and cyclization is pref-... [Pg.522]

A method utilizing the Dess-Martin periodinane[12 for the conversion of a peptide a-hy-droxy ester into the corresponding a-oxo ester was reported by Burkhart et al.[8l The final product, peptide a-oxo ester, obtained in this process contains a mixture of enantiomers at C2 in PI of the peptide. The optical impurity arises not from the oxidation reaction but the synthesis of one of the intermediates, 2-hydroxy-3-nitro-4-phenylbutanoic acid, which generates four diastereomers at two adjacent chiral carbons. This procedure is limited to the synthesis of peptide a-oxo esters with the phenylalanine residue at the PI position. A more diversified approach is achieved by using a-hydroxy- 3-amino acids 14 as the key intermediate that permits selective introduction of an amino acid residue at PI of the peptide it can also be coupled to N-protected amino acids or N-protected peptides and further transformations give a-oxo esters 19, a-oxo acids 20, and a-oxoamides 22 (Scheme 4)J3 61... [Pg.248]

In 2001, diazoketones [169, 170] derived from suitably protected amino acids have been reported to be photochemically rearranged in the presence of imines leading exclusively to //c/n.v-substitiited (3-lactams with up to 84% yield [171]. Selectivities were dependent on the steric demand of the amino acid side-chain with dr ranging from 65 35 to 90 10, (Scheme 70). [Pg.142]

Rhodium complexes that contain these ligands have demonstrated moderate to high enantio-selectivities (24-96%) in the reduction of enamides to protected amino acids (cf Scheme 12.1).7-70 Despite the moderate degree of asymmetric induction, ANIC S.p.A. (EniChem) developed an industrial process with this catalyst system for the production of (S)-phenylalanine for the synthesis of aspartame.1145 The process uses cationic Rh-7a for the reduction of 14b at 28 psig H2 and 22°C for 3 hours (S/C = 15,000) to give 15b in 83.3% ee that is enriched to 98.3% by recrystallization.72... [Pg.197]


See other pages where Selective protection amino acids is mentioned: [Pg.451]    [Pg.235]    [Pg.388]    [Pg.74]    [Pg.172]    [Pg.88]    [Pg.184]    [Pg.33]    [Pg.245]    [Pg.2]    [Pg.19]    [Pg.295]    [Pg.262]    [Pg.84]    [Pg.324]    [Pg.234]    [Pg.314]    [Pg.147]    [Pg.240]    [Pg.159]    [Pg.299]    [Pg.250]    [Pg.44]    [Pg.235]    [Pg.576]    [Pg.318]    [Pg.1694]    [Pg.15]    [Pg.148]    [Pg.131]    [Pg.204]    [Pg.367]    [Pg.118]    [Pg.119]   
See also in sourсe #XX -- [ Pg.373 ]

See also in sourсe #XX -- [ Pg.595 ]




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