Keto-oxazoles

From the same laboratories, a series of heterocyclic ketones were published as HDAC inhibitors [61]. This work is a continuation and further elaboration of the concept of the use of electrophihc ketones as hydroxamic acid replacements. a-Keto oxazole derivatives appeared to act as the most potent HDAC inhibitors in the HDAC1/HDAC2 enzyme assay [60], displaying low micromolar activity (Fig. 9). 

Fig. 9 Keto oxazoles as hydroxamic acid replacements. (Abbott Laboratories)...

Azoleacetic acids with a carboxymethyl group also decarboxylate readily, e.g. all three thiazole isomers, by a mechanism similar to that for the decarboxylation of /3-keto acids cf. Section 4.02.3.1.2. The mechanism has been investigated in the oxazole case, (396) (397) (398) <72JCS(P2)1077). 

Decomposition of the diazoacetic ester (548) to the keto carbene (549) is promoted by copper(II) trifluoromethanesulfonate. In the presence of nitriles, 1,3-dipolar addition to the nitrile occurred giving the oxazole (550) (75JOM(88)ll5) (see also Section 4.03.8.1). 

Treatment of N-benzoyl-L-alanine with oxalyl chloride, followed by methanolic triethylamine, yields methyl 4-methyl-2-phenyloxazole-5-carboxylate 32 <95CC2335>. a-Keto imidoyl chlorides, obtained from acyl chlorides and ethyl isocyanoacetate, cyclise to 5-ethoxyoxazoles by the action of triethylamine (e.g.. Scheme 8) <96SC1149>. The azetidinone 33 is converted into the oxazole 34 when heated with sodium azide and titanium chloride in acetonitrile <95JHC1409>. Another unusual reaction is the cyclisation of compound 35 to the oxazole 36 on sequential treatment with trifluoroacetic anhydride and methanol <95JFC(75)221>. 

Application of the Ritter reaction conditions on y-hydroxy-a,P-alkynoic esters, 102, produced ethyl 5-oxazoleacetates 103 or y-A-acylamino-P-keto ester 104 by reaction with aryl or alkyl nitriles respectively. The y-A-acylamino-P-keto ester 104 can also be transformed into oxazole derivatives using an additional step involving POCI3 <06TL4385>. 

The formation of methyl-oxazole compounds was also described by Wang et al. [34] utilizing an analog of the keto-enol intermediate (22) described in Sect. 2.1.1, Scheme 2. Scheme 11 shows the synthesis of compound 57 which exhibits anti-tubulin activity of 7.7. iM [34], In addition, a range of oxazole COX-2 inhibitors has been reported by Hashimoto et al. [55] employing similar chemistry. 

The meso-ionic 1,3-oxazol-S-ones show an incredible array of cycloaddition reactions. Reference has already been made to the cycloaddition reactions of the derivative 50, which are interpreted as involving cycloaddition to the valence tautomer 51. In addition, an extremely comprehensive study of the 1,3-dipolar cycloaddition reactions of meso-ionic l,3-oxazol-5-ones (66) has been undertaken by Huisgen and his co-workers. The 1,3-dipolarophiles that have been examined include alkenes, alkynes, aldehydes, a-keto esters, a-diketones, thiobenzophenone, thiono esters, carbon oxysulfide, carbon disulfide, nitriles, nitro-, nitroso-, and azo-compounds, and cyclopropane and cyclobutene derivatives. In these reactions the l,3-oxazol-5-ones (66)... 

An oxazole substituted with a complex aminohydantoin side chain is described as a muscle relaxant. Imine formation between glyoxylic acid and aminohydantoin (38-1) results in the imino acid (38-2). Use of that intermediate to acylate the amine on 4-chloro-2 -aminoacetophenone (38-3) leads to the amide (38-4), which now includes a 1,4-dicarbonyl array. Treatment of the keto-amide with phosphorus... 

Oxazoles. Activated isonitriles react with selenol esters in the presence of triethylamine and Cu20 at 25° to form oxazoles, presumably via a j8-keto isonitrile (equation I).1... 

A microwave-assisted one-pot approach towards 2,4,5-trisubstituted oxazoles employed a hypervalent iodine (III) catalyst to bring about the reaction of ketones, 1,3-diketones and /3-keto-carboxylic acid derivatives with amides [75]. Microwave dielectric heating was also successfully utilized in a solid-supported, solvent-free synthesis of 2-phenyl-oxazol-5-ones (azlac-tones) [76] as well as in a solution phase synthesis of isomeric 2-phenyl-oxazol-4-ones (oxalactims) [77]. 

C—C—O—C+N. The formation of oxazoles from a-acyloxy ketones and ammonium salts was discovered in 1937 when it was found that treatment of benzoin benzoate with ammonium acetate in hot acetic acid gave triphenyloxazole in excellent yield. It has been shown that the reaction proceeds by way of intermediate enamines (equation 113). The synthesis is quite general and it is only.limited by the difficulty of obtaining the starting keto esters, particularly formates. The latter are probably intermediates in the preparation of cycloalkenooxazoles from acyloins and formamide in hot sulfuric acid (equation 114). Another variation is to heat a mixture of an a-bromo ketone, the sodium salt of a carboxylic acid and ammonium acetate in acetic acid (equation 115). 

Oxazole IV-oxides cannot be made by oxygenation of oxazoles. The only method of synthesis remains the condensation of monooximes of 1,2-dicarbonyl compounds with aldehydes in the presence of hydrogen chloride (equation 132) (15CB897). The aldehyde may be aromatic or aliphatic (including formaldehyde) and the oxime may be derived from an aromatic diketone or it may be an a-keto aldoxime, leading to a 2,5-disubstituted oxazole IV-oxide. It may also contain an additional carbonyl group as in equation (133). 

A Ph3P0/Tf20-mediated cyclodehydration was utilized in the conversion of -keto-ester 249 to give a key oxazole building block 250 (Scheme 121), which was used in a total synthesis of the marine natural product bistratamide F-I <2005T241, CHEC-III(4.04.9.1)517>. 

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