Benzyl ester, preparation acid synthesis

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. ... 

In subsequent studies,22 Sheehan et al. demonstrated that the action of diisopropylcarbodiimide on penicilloate 24, prepared by protection of the free primary amino group in 23 with trityl chloride (see Scheme 6b), results in the formation of the desired -lactam 25 in a very respectable yield of 67 %. In this most successful transformation, the competing azlactonization reaction is prevented by the use of a trityl group (Ph3C) to protect the C-6 amino function. Hydrogenolysis of the benzyl ester function in 25, followed by removal of the trityl protecting group with dilute aqueous HC1, furnishes 6-aminopenicillanic acid (26), a versatile intermediate for the synthesis of natural and unnatural penicillins. 

A similar series of reactions was performed by Paulsen and Hdlck141 for the preparation of the T-antigenic, unprotected, amino acid-disaccha-rides 200 and 201, starting from the 4,6-0-benzylidene-N-(benzyloxy-carbonyl) benzyl esters 198 and 199, respectively, by condensation with 110 in the presence of mercury dicyanide-mercury dichloride and molecular sieves 4A, and deprotection of the product. Sinay and co-workers148 also reported the synthesis of hexa-O-acetyl derivatives of 200 and 201 by application of the sequence of azido-nitration-bromination. 

The same basic strategy was applied to the synthesis of the smaller fragment benzyl ester 28 as well (Scheme 4). In this case, aldehyde 22 prepared from (S)-2-hydroxypentanoic acid [9] was allylated with ent-10 and tin(IV) chloride, and the resulting alcohol 23 was converted to epimer 24 via Mitsunobu inversion prior to phenylselenenyl-induced tetrahydrofuran formation. Reductive cleavage of the phenylselanyl group, hydrogenolysis of the benzyl ether, oxidation, carboxylate benzylation, and desilylation then furnished ester 28. 

This convenient three-step synthesis allowed amino acids 186a-e to be prepared in overall yields ranging from 48 (186f, cleonin) to 90% (186b) [9]. Since deprotection of benzyl esters maybe achieved simultaneously with hydrogenolytic reduction of an azido group, amino acids 186c,f were prepared from Michael adducts 87c-Bn and 94b in only two step reaction sequences (Scheme 55). 

Because O-glycosylation can also be accomplished with active esters (e.g., penta-fluorophenyl esters) [11] of Fmoc serine and threonine, the Fmoc technique provides a general method for the synthesis of glycopeptides. Thomsen-Friedenreich antigen glycopeptides and neoglycoproteins have been obtained by this method in preparative amounts [12], In combination with acid-labile polymeric benzyl ester anchors, this Fmoc technique was applied to solid-phase syntheses of glycopeptides [11,13,14]. 

The key intermediate in the preparation of derivatives suitable for peptide synthesis (Table 3) is the benzyl (25)-7V-tritylaziridine-2-carboxylate, since it is smoothly converted into the N-protected imino acid by catalytic hydrogenolysis.[47] Similarly, the related methyl ester is saponified by lithium hydroxide to produce A-tritylaziridine-2-carboxylateJ83 84 Detrit-ylation to benzyl (2S)-aziridine-2-carboxylate is more difficult, but the dibenzosulfimide salt is found to be perfectly stable on storage as a solid for longer periods of time (see Section 9.2.1.1) J47l In solution, upon addition of bases the benzyl ester is sufficiently stable to allow for peptide syntheses.[47]... 

Although the racemization of the a-carbon can now be considered a potential problem, the synthesis of 32-peptides has been achieved in the same way as seen for 33-peptides. As the 32-amino acids cannot be prepared from the analogous a-amino acids, Seebach and co-workers 5,7 opted to use Evans oxazolidinone chemistry to produce enantiomerically pure 32-amino acids. Alkylation of 3-acyloxazolidin-2-ones 17 with A-(chloromethyl)benzamide yielded the products 18 with diastereomeric ratios between 93 7 and 99 1 (Scheme 8). Removal of the chiral auxiliary (Li0H/H202) and debenzoylation (refluxing acid) was followed by ion-exchange chromatography to yield the free 32-amino acids 20 which were converted by standard means into Boc 21 or benzyl ester 22 derivatives for peptide synthesis. 

Acid-labile linkers are the oldest and still the most commonly used linkers for carboxylic acids. Most are based on the acidolysis of benzylic C-O bonds. Benzyl esters cleavable under acidic conditions were the first type of linker to be investigated in detail. The reason for this was probably the initial choice of polystyrene as an insoluble support for solid-phase synthesis [13]. Polystyrene-derived benzyl esters were initially prepared by the treatment of partially chloromethylated polystyrene with salts of carboxylic acids (Figure 3.3). 

Seeberger and coworkers prepared synthetically useful amounts of P-peptides (0.2-0.6mmol) by using a microreactor (reactor volume = 78.3 pi). The reaction of add fluoride and the TFA salt of amino acid benzyl ester in the presence of N-methylmorpholine (NMM) at 90 °C (3 min residence time) gave the dipeptide in 92% yield (Scheme 4.19). A fluorous tag method was used for an effident synthesis of tetrapeptides. Amino acid esters having fluorous tags were used to facilitate purification by fluorous solid-phase extraction (FSPE) (Scheme 4.20). 

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