Threonine protection

The phenolic hydroxyl group of tyrosine, the imidazole moiety of histidine, and the amide groups of asparagine and glutamine are often not protected in peptide synthesis, since it is usually unnecessary. The protection of the hydroxyl group in serine and threonine (O-acetylation or O-benzylation) is not needed in the azide condensation procedure but may become important when other activation methods are used. 

A second, conceptually distinct chiral synthesis of monobactams was developed from P-hydroxy amino acids. As shown in Figure 2, cycli2ation of the acylsulfamate of an amino-protected 0-mesylserine derivative (14, R = H) leads directiy to the monobactam (15). This methodology was also appHed to the synthesis of 4a- (15, R = CH ) and 4P-methyl monobactams from L-threonine and aHothreonine, respectively (17). The... 

This active ester was used for carboxyl protection of Fmoc-serine and Fmoc-threonine during glycosylation. The esters are then used as active esters in peptide synthesis. 

Extension of this strategy enables syntheses of both protected c-threonine and t-allo-threonine, in which reagent-controlled stereoselecdve epoxidadon of a common intermediate is the key step fScheme 4.8. " ... 

For this class of reactions, only a few examples which proceed with reasonable diastereoselectivity are known. Allylation of a-methoxycarbamate 1, easily obtained as a 1 1 mixture of isomers by anodic oxidation of protected threonine, produces an 83 17 mixture of enantiomers on treatment with trimethyl(2-propcnyl)silanel03. Cyanation with trimcthylsilyl cyanide proceeds less stereoselectively (67 33 93 % yield). 

High-pressure [4 + 2] cycloaddition of 1-methoxy-1,3-butadiene to A/,0-protected D-threoninals and D-allo-threoninals [91]... 

Chiral tricyclic fused pyrrolidines 29a-c and piperidines 29d-g have been synthesized starting from L-serine, L-threonine, and L-cysteine taking advantage of the INOC strategy (Scheme 4) [19]. L-Serine (23 a) and L-threonine (23 b) were protected as stable oxazolidin-2-ones 24a and 24b, respectively. Analogously, L-cysteine 23 c was converted to thiazolidin-2-one 24 c. Subsequent N-allylation or homoallylation, DIBALH reduction, and oximation afforded the ene-oximes, 27a-g. Conversion of ene-oximes 27a-g to the desired key intermediates, nitrile oxides 28 a-g, provided the isoxazolines 29 a-g. While fused pyrrolidines 29a-c were formed in poor yield (due to dimerization of nitrile oxides) and with moderate stereoselectivity (as a mixture of cis (major) and trans (minor) isomers), corresponding piperidines 29d-g were formed in good yield and excellent stereoselectivity (as exclusively trans isomers, see Table 3). 

While in the uncatalyzed reaction of l-ethyleneimino-2-hydroxy-3-butene in THF, refluxing for four hours was necessary to produce 70% of the ester, in the presence of NaNH2 a 90% yield was achieved at room temperature after only five minutes.[13 14] An especially interesting example of the use of the imidazolide method for ester synthesis is illustrated by the total synthesis of actinomycin C3.[15],[16] Working with N-protected L-TV-methylvaline and CDI, esterification of the hydroxyl group on the threonine residue proved successful whereas this could not be accomplished by any of the conventional methods. 

Scheme 1 summarizes our synthetic approach. By protecting the carboxyl groups using a suitable protecting group, the three hydroxy amino acids, serine, threonine and tyrosine were conveniently coupled with Boc-Phe-OH to obtain the corresponding peptides (1-4) in good yields. 

A new method for the solid phase synthesis of oxazole-containing peptides 105 was developed, based on cyclodehydration followed or preceded by oxidation in a biomimetic fashion. The oxazole nucleus was obtained starting from threonine or serine and the method is compatible with most protecting groups <06OL2417>. 

To overcome these difficulties in the selective deprotection and chain extension, several carboxyl-protecting groups, namely, allyl (16,32), benzyl (43,44), tert-butyl (42), 2-bromoethyl (45), 2-chloroethyl (45), heptyl (46), 4-nitrophenyl (47,48), and pentafluorophenyl (49) for L-serine/L-threonine have been introduced or applied. Similarly, amino-protecting groups for L-serine/L-threonine that have proved useful for the synthesis of glycopeptides are tm-butyloxycarbonyl (50), 9-fluorenylmethoxycarbonyl (43,44,48), 2-(2-pyridyl)ethoxycarbonyl (51), 2-(4-pyridyl)ethoxycarbonyl (44,52), and 2-triphenylphosphonioethoxycarbonyl (53). Some applications of these groups have been discussed in earlier reviews (7-11). 

Paulsen and associates (58) synthesized mono- and di-D-galactopyranosyl derivatives of L-serine/L-threonine. Condensation of the 2-azido-2-deoxy-glycosyl halides 61 and 62 with the benzyl or tert-butyl esters of iV-benzyl-oxycarbonyl (Z)-protected L-serine, L-threonine, and L-leucyl-L-serine (63 -65) in the presence of silver carbonate, silver perchlorate, Drierite, and molecular sieves gave (59) the corresponding O-glycopeptides 67-69. The free glycopeptides were obtained after total deprotection. 

Different Amino and Carboxyl Protecting-Group Combinations of L-Serine/L-Threonine Used for Glycopeptide Chain-Lengthening... 

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