Protective groups esters

In each step of the usual C-to-N peptide synthesis the N-protecting group of the newly coupled amino acid must be selectively removed under conditions that leave all side-chain pro-teaing groups of the peptide intact. The most common protecting groups of side-chains (p. 229) are all stable towards 50% trifluoroacetic acid in dichloromethane, and this reagent is most commonly used for N -deprotection. Only /ert-butyl esters and carbamates ( = Boc) are solvolyzed in this mixture. 

Carboxyl groups of ammo acids and peptides are normally protected as esters Methyl and ethyl esters are prepared by Fischer esterification Deprotection of methyl and ethyl esters is accomplished by hydrolysis m base Benzyl esters are a popular choice because they can also be removed by hydrogenolysis Thus a synthetic peptide protected at both... 

Section 27 16 Carboxyl groups are normally protected as benzyl methyl or ethyl esters Hydrolysis m dilute base is normally used to deprotect methyl and ethyl esters Benzyl protecting groups are removed by hydrogenolysis... 

Remove the Z protecting group from the ethyl ester of Z Phe Gly by hydrogenolysis Cou pie with the p mtrophenyl ester of Z Leu then remove the Z group of the ethyl ester of Z Leu Phe Gly... 

Pos twe-Tone Photoresists. The ester, carbonate, and ketal acidolysis reactions which form the basis of most positive tone CA resists are thought to proceed under specific acid catalysis (62). In this mechanism, illustrated in Figure 22 for the hydrolysis of tert-huty acetate (type A l) (63), the first step involves a rapid equihbrium where the proton is transferred between the photogenerated acid and the acid-labile protecting group ... 

Mocimycin has been chemically converted to aurodox by protection of the 4-hydroxy group at the pyridone moiety as the benzoylformate, followed by /V-methylation and hydrolytic removal of the protective group (1,55). Whereas aurodox esters are active growth promotors in animals, goldinamines that are A/-acylated by acids other than goldinonic acid, such as acetic, benzoic, or arylsulfonic acids, lack useful antimicrobial or growth-promoting activity (1). 

Pyrrole Carboxylic Acids and Esters. The acids are considerably less stable than benzoic acid and often decarboxylate readily on heating. However, electron-withdrawing substituents tend to stabilize them toward decarboxylation. The pyrrole esters are important synthetically because they stabilize the ring and may also act as protecting groups. Thus, the esters can be utilized synthetically and then hydrolyzed to the acid, which can be decarboxylated by heating. Often P-esters are hydrolyzed more easily than the a-esters. 

In the synthesis of ceftazidime (40) (Fig. 8), the protected, preassembled arninothiazole side chain [68672-66-2] (60) is coupled to a protected 7-ACA first and the C-3 displacement step carried out last. By way of contrast, in the synthesis of ceftriaxone (39) (Fig. 9), the preformed C-3 substituent is introduced onto the cephalosporin nucleus in the first step and then the acyl-amino side chain is introduced. This last step is noteworthy for two reasons in that it demonstrates the use of an activated thio ester in the coupling step and that no protecting group chemistry is requited (192,193). 

AdeninyUiydroxypropanoic acid alkyl esters [(R,5)-AHPA esters, (30)] represent a new class of broad-spectmm antiviral agents, which are, like (3)-DHPA, targeted at SAH hydrolase (62). The free acid, (R,3)-AHPA, is only weakly active as an antiviral agent. Thus the alkyl moiety merely serves as a protecting group to faciUtate uptake of AHPA by the cells. Within the cells, the AHPA alkyl esters would be hydroly2ed to release the free acid, which should then interact with SAH hydrolase. 

See also Chapter 5, on the preparation of esters as protective groups for carboxylic acids. 

The following miscellaneous esters have been prepared as protective groups, but they have seen little use since publication of the first edition. Therefore they are simply listed for completeness, rather than described in detail. 

Me3SiI, CH3CN, 25-50°, 100% yield. Selective removal of protective groups is possible with this reagent since a carbamate, =NCOOCMe3, is cleaved in 6 min at 25° an aryl benzyl ether is cleaved in 100% yield, with no formation of 3-benzyltyrosine, in 1 h at 50°, at which time a methyl ester begins to be cleaved. 

HCl, Et20, 6 h, 83-88% yield.Acidic deprotection of the BOC group could not be achieved with complete selectivity in the presence of an MTM ester. The trityl and NFS (2-nitrophenylsulfenyl) groups were the preferred nitrogen protective groups. 

The first, and still widely used, polymer-supported ester is formed from an amino acid and a chloromethylated copolymer of styrene-divinylbenzene. Originally it was cleaved by basic hydrolysis (2 N NaOH, FtOH, 25°, 1 h). Subsequently, it has been cleaved by hydrogenolysis (H2/Pd-C, DMF, 40°, 60 psi, 24 h, 71% yield), and by HF, which concurrently removes many amine protective groups. Monoesterification of a symmetrical dicarboxylic acid chloride can be effected by reaction with a hydroxymethyl copolymer of styrene-divinylbenzene to give an ester a mono salt of a diacid was converted into a dibenzyl polymer. ... 

The protective group is removed by mildly alkaline conditions that do not cleave methyl or benzyl esters. The group is stable to CF3COOH, HCl-AcOH, and HBr-AcOH. A polymer-bound version of this group has also been developed. ... 

Reactivity Chart 2. Protection for the Hydroxyl Group Esters... 

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