Thiazole ring synthesis

A-4-Thiazoline-2-ones and ring substituted derivatives are usually prepared by the general ring-closure methods described in Chapter II. Some special methods where the thiazole ring is already formed have been used, however. An original synthesis of 4- 2-carboxyphenyl)-A-4-thiazoline-2-one (18) starting from 2-thiocyanato-2-halophenyl-l-3-indandione (19) has been proposed (Scheme 8) (20, 21). Reaction of bicyclic quaternary salts (20) may provide 3-substituted A-4-thiazoline-2-one derivatives (21) (Scheme 9) (22). Sykes et al. (23) report the formation of A-4-thiazoline-2-ones (24) by treatment ef 2-bromo (22) or 2-dimethylaminothiazole (23) quaternary salts with base (Scheme 10). 

The thiazole ring can be obtained directly by other methods, but they have limited application. An example is the synthesis of Cook and Heilbron using a-aminonitriles or a-aminoamides and carbon disulfide (or thioacid derivatives) as reactants of type II. 

The reaction of phosphorus pentasulfide with a-acylamino carbonyl compounds of type Ilia also yields thiazoles. Even more commonly, a mercaptoketone is condensed with a nitrile of type IVa or a-mercaptoacids or their esters with Schiff bases. This ring closure is limited to the thiazolidines. In the Va ring-closure type, /3-mercaptoalkylamines serve as the principal starting materials, and ethylformate is the reactant that supplies the carbon at the 2-position of the ring. These syntheses constitute the most important route for the preparation of many thiazolidines and 2-thiazohnes. In the Vb t3fpe of synthesis, one of the reactant supplies only the carbon at the 5-position of the resultant thiazole. Then in these latter years new modern synthetic methods of thiazole ring have been developed (see Section 7 also Refs. 515, 758, 807, 812, 822). 

Polymerization of a noncyclic monomer leading to a total synthesis of the ring or the polymerization of a substituent on the thiazole ring, for example, a vinyl group. 

This sequence establishes the correct configuration at C-3, C-6, C-7, and C-8. The thiazole ring, along with C(13)-C(15), is added by esterification at step C. The ring is closed by olefin metathesis, and the synthesis is completed by deprotection and epoxida-tion. 

Before our first report (see Ref 39a), there was only a single example of conversion of a 2-aDcylthiazole into aldehyde. See L. 1. Altman and S. L. Richheimer, An aldehyde synthesis utilizing the thiazole ring system, Tetrahedron Lett. p. 4709 (1971). 

The thiazole ring is assembled on the 5-carbon backbone of 1-deoxyxylulose 5-phosphate, which is also an intermediate in the alternative biosynthetic pathway for terpenes (Fig. 22-2) and in synthesis of vitamin B6 (Fig. 25-21). In E. coli the sulfur atom of the thiazole comes from cysteine and the nitrogen from tyrosine.374 The same is true for chloroplasts,375 whereas in yeast glycine appears to donate the nitrogen.372 The thiamin biosynthetic operon of E. coli contains six genes,372a 376 one of which (ThiS) encodes a protein that serves as a sulfur carrier from cysteine into the thiazole.374 The C-terminal glycine is converted into a thiocarboxylate ... 

Scheme 86 Synthesis of a porphycene containing a thiazole ring and nitrogen in its periphery.

I. Synthesis from Preformed Thiazole Rings or from Other Heterocycles. . 11... 

I. SYNTHESIS FROM PREFORMED THIAZOLE RINGS OR FROM OTHER HETEROCYCLES... 

The thiazole ring is synthesized from a pentulose or deoxypentulose 5-phosphate and either glycine or tryptophan, depending on the organism. Incorporation of sulfur leads to formation of hydroxymethyl thiazole, which is then phosphorylated. The sulfur comes from cysteine and is incorporated by formation of a thiocarboxylate at the carboxyl terminal of the enzyme, unlike biotin synthesis (Section 11.1.1), where an iron-sulfur cluster at the active site of the enzyme is the donor. 

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