Amide thioacetals synthesis

A recent total synthesis of tubulysin U and V makes use of a one-pot, three-component reaction to form 2-acyloxymethylthiazoles <06AG(E)7235>. Treatment of isonitrile 25, Boc-protected Z-homovaline aldehyde 26, and thioacetic acid with boron trifluoride etherate gives a 3 1 mixture of two diastereomers 30. The reaction pathway involves transacylation of the initial adduct 27 to give thioamide 28. This amide is in equilibrium with its mercaptoimine tautomer 29, which undergoes intramolecular Michael addition followed by elimination of dimethylamine to afford thiazole 30. The major diastereomer serves as an intermediate in the synthesis of tubulysin U and V. 

Cyclization of benzophenones having an o -thioacetic acid, ester or amide group has been used in structure studies and to synthesize 3-phenylbenzo[6 ]thiophenes with specific substituents. Thus (57) was readily converted to (58 X = OH, OEt or NH2) as precursors to a variety of benzo[6 ]thiophenes (57AC(R)705>, and as precursor to the unequivocal synthesis of 3-phenylbenzo[6 jthiophene, to demonstrate a remarkable sulfur-catalyzed rearrangement (59AJC218). 

Schlessinger has shown that the addition of ester enolates to sulfur stabilized acceptors, e.g. ketene di-thioacetal monoxide (151) and methyl a-(methylthio)acrylate (187), is highly efficient for the synthesis of Y-ketoesters.148 Similarly, Ahlbrecht and Seebach have reported that amide and ester enolate additions to nitrogen stabilized acceptors, e.g. nitroalkenes (40) and 2-(/V-methylanilino)acrylonitrile (59 Scheme 72), are highly efficient.149... 

The liberation of the (3-sulfanyl group of cysteine is achieved by means of PGA-mediated hydrolysis of phenylacetamides.P " °l For this purpose, the thiol group is masked with the phenylacetamidomethyl (Phacm) blocking function. After penicillin acylase catalyzed hydrolysis of the amide incorporated in the acylated thioacetal, the labile 5-aminomethyl compound is formed and immediately liberates the desired thiol. This method has been used in a synthesis of glutathione which is isolated as its disulfide 6 (Scheme 12). 

The Evans asymmetric alkylation [127] and aldol reactions were also effectively applied to the synthesis of the C10-C19 top segment 230 (Scheme 33). The starting chiral unit 223 was synthesized via the Evans asymmetric alkylation of 218a. The subsequent Evans aldol reaction of 223 with 224 followed by trans-amidation yielded 2,3-sy -diol derivative 225 with complete stereoselectivity. Addition of alkyl lithium 226 to the Weinreb amide 225 produced ketone 227, which was stereoselectively reduced and methylated to give dimethyl ether 228. The standard functional group manipulation afforded thioacetal 229, which was converted into phosphine oxide 230. 

The Ru(III)-promoted formation of the amide bond permits the synthesis of amides from azides and thio acids at room temperature, and the reaction is applicable to less-reactive azides. Thus the azide, 119 as a model compound, in methanol solution, was transformed in 80% yield into the corresponding acetamide 240 by the action of thioacetic acid (2.5 eq.) and 2,6-lutidine. ... 

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