Acylation 2- oxazoles

Trifluoromethyl-l, 3-oxazoles are formed on heating 2-trifluoromethyl-2-acyl-2//-oxazol-5-ones (71CB1408) as well as 3-trifluoromethyl-3-alkox-ycarbonyl-2,2,2-trimethoxy-5-phenyl-2,3-dihydro-l,4,2-oxazaphospholes (89CZ243). Both reaction sequences include a thermally induced [3 + 2] cycloreversion reaction and a 1,5-electrocyclization of the conjugated 1,3-dipolar species initially formed (Scheme 93). 

This formulation is supported by the proton resonance spectrum of the trifluoromethyl compound 101 which shows that it exists in the CH form shownd However, strong electron-withdrawing groups in the 4-position apparently lead to enolization, and compound 102, for example, gives an intense color with ferric chloride, - Other 4-acylated oxazol-5-ones are often formulated as 103 (see, e.g, reference 113). Tautomerism of the type illustrated by the equilibrium 104 103 has been discussed (see reference 115 for further references). 

Jacobi reports using a variant of method A to access the A,B,E-ring system of wortmannin.14 The sequential addition of methyl lithium and acetylenic Grignard reagent followed by triflation proceeds from 7 to the corresponding triflate 8 in 74% yield (Fig. 4.13). Subsequent carbonylation of the alkyne and the phenol produces the acyl oxazole 9, which is smoothly converted into the furanolactone 10 over three more steps. 

Azirine, C-acyl-rearrangement oxazoles from, 6, 223 Azirine, allyl-... 

Oxazol-4(5ff)-one, 5-acetyl-5-methyl-synthesis, 6, 225 Oxazol-4(5ff)-one, 2-phenyl-photorearrangement, 6, 200 synthesis, 6, 225 Oxazol-5(2ff)-one, 2-acyl-2,4-disubstituted pyrolysis, 6, 200 Oxazol-5(2H)-one, allyl-photochemical rearrangement, 6, 200 Oxazol-5(2ff)-one, 2-arylmethylene-synthesis, 6, 227... 

Oxazol-5(2H)-one, 2-benzylidene-4-methyl-tautomerism, 6, 186 Oxazol-5(2ff)-one, 2-methylene-isomerization, 6, 226 Oxazol-5(2H)-one, 2-trifluoromethyl-acylation, 6, 201 Oxazol-5(4ff)-one, 4-allyl-thermal rearrangements, 6, 199 Oxazol-5(4H)-one, 4(arylmethylene)-Friedel-Crafts reactions, 6, 205 geometrical isomerism, 6, 185 Oxazol-5(4ff)-one, 4-benzylidene-2-phenyl-configuration, 6, 185 photorearrangement, 6, 201 Oxazol-5(4ff)-one, 4-benzyl-2-methyl-Friedel-Crafts reactions, 6, 205 Oxazol-5(4ff)-one, 4-methylene-in amino acid synthesis, 6, 203 Oxazol-5(4ff) -one. 2-trifluoromethyl-hydrolysis, 6, 206 Oxazolones... 

Williams and McClymont have observed that acylation reactions of the dianion of 2-(5-oxazolyl)-l,3-dithiane (15) lead to formation of 4,5-disubstituted oxazole products through a Comforth rearrangement pathway under base-induced, low-temperature conditions. For example, deprotonation of 15 with LiHMDS (3.0 equivalents) at -78°C, followed by addition of benzoyl chloride or p-chlorobenzoyl chloride and warming to 0°C, provided 16 in 74% and 47% yield, respectively. 

Since neither direct acylation of the 2-position of oxazole 15 (Ha) nor acylation of the 1,3-dithianyl anion (Hb) was observed, the products were rationalized as arising through selective C-acylation of the ring-opened tautomer 15c. 

Chelated oxo structures were assigned to 5-hydroxy-4-acyl-l,3-oxazoles on the basis of their NMR spectra, the preference being given to the con-former 249a with a six-membered chelate ring (Scheme 86) (75BSB845). 

Low yields of 5-acyl-2,3-dihydropyrrolo[2,l-Z ]oxazoles (37) were obtained by treatment of 2-acyl-5-nitropyrrole (35) with ethylene oxide. Better yields are reported starting from hydroxy derivative 36a or its acetate 36b using sodium hydride in THE The presence of an acyl group at the position 2 was found necessary for the cyclization (Scheme 5) (71JCS(C)2554). 

Pyridino-oxazoles 198 were obtained in an analogous way starting from o-bromoaminopyridine 196, which was first acylated and then cyclized imder microwave irradiation at 165 °C in DMA via an aromatic nucleophilic substitution (Scheme 71) [126]. 

Oxazole formation can be envisaged as proceeding by three possible pathways 1,3-dipolar cycloaddition of a free ketocarbene to the nitiile (Path A), the formation and subsequent 1,5-cyclisation of a nitrile ylide (Path B) or the formation and subsequent rearrangement of a 2-acyl-2//-azirine (Path C) (Scheme 9). 

Although 2-acyl-2//-azirines are known to give oxazoles upon irradiation, the reaction is wavelength dependent, and isoxazoles are formed at some wavelengths, as they are in the thermal rearrangement of 2-acyl-2//-azirines.<74TL29,75JA4682> Since the thermal reaction of diazocarbonyl compounds with nitriles leads to oxazole formation, it would seem that mechanistic path C is unlikely in these reactions. 

The base-catalysed reaction of a-bromo-a,P-unsaturated ketones with aliphatic nitro compounds leads to 2-isoxazoline A-oxides by tandem conjugate addition-ring closure (Scheme 5) <95JOC6624>. A -Acyl-3-isoxazolin-5-ones are transformed into oxazoles by photolysis or by flash vacuum pyrolysis (Scheme 6) <96TL675>. 

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>. 

The mechanism of the condensation in Part D probably involves thioformylation of the metallated isocyanoacetate followed by intramolecular 1,1-addition of the tautomeric enethiol to the isonitrile. This thi2izole synthesis is analogous to the formation of oxazoles from acylation of metallated isonitriles with acid chlorides or anhydrides. " Interestingly, ethyl formate does not react with isocyanoacetate under the conditions of this procedure. Ethyl and methyl isocyanoacetate have been prepared in a similar manner by dehydration of the corresponding N-formylglycine esters with phosgene and trichloromethyl chloroformate, respectively. The phosphoryl chloride method described here was provided to the submitters by Professor U. Schollkopf and is based on the procedure of Bohme and Fuchs. The preparation of O-ethyl thioformate in Part C was developed from a report by Ohno, Koi/.uma, and Tsuchihaski. " ... 

Oxazoles (191) are producedwhen triphenylphosphine is treated simultaneously with an a-azidocarbonyl compound and an acyl halide. The intermediate iminophosphoranes (189) react with the acyl halide before they can react with themselves to give pyrazines. Elimination of phosphine oxide from the resulting salts may give the intermediate halo-genoimines (190), or the oxazoles may be formed via the betaines (192). 

The mass spectra of azolides are not very specific, since they depend to a large extent on the structures of the respective acyl groups. Flash vacuum pyrolyses of azolides has been studied for 1-acyl-1,2,4-triazoles and benzotriazolides by tandem mass spectrometry (MS/MS). 461 Rearrangements of triazolides resulted in the formation of oxazoles. 471... 

A different synthesis of oxazoles based on azolides is the flash-vacuum pyrolysis of 1,2,4-triazolides, which includes a shift of the acyl group and elimination of nitrogen 1371... 

The preparation of 3-vinylpyrroles was investigated utilizing the Horner-Wads worth-Emmons reaction with 3-formyl-lV-tosylpyrrole <06S1494>. The intramolecular acylation of pyrrole-2-Weinreb amides provided access to novel indolizinone derivatives <06T6182>. The amidation of pyrrole-2-carbonyl chloride was utilized as a key step in the preparation of pyrrole-oxazole analogue 90 of the insecticide Pirate <06S1975>. 

Several new methods for the synthesis of the oxazole nucleus were published. A new consecutive three-component oxazole synthesis by an amidation-coupling-cycloisomerisation sequence was developed. The synthesis started from propargylamine 92 and acyl chlorides. To extend this process, a four component sequence involving a carbonylative arylation by substitution of one acyl chloride with an aryl iodide and a CO atmosphere was also performed <06CC4817>. 

Heterocyclic ring systems are also used to connect two anthraquinone groups. Typical examples include Cl Vat Red 10 (6.106), which is an oxazole derivative obtained from 2-amino-3-hydroxyanthraquinone and the appropriate acyl chloride, the similar thiazole derivative Cl Vat Blue 31 (6.107) and the oxadiazole derivative Cl Vat Blue 64 (6.108). 

The reaction of acylsilanes with acid chlorides in the presence of A1C13 leads to furans (Table 9.41) [45]. In these reactions an acyl cation initiates the addition with ensuing silyl migration yielding an intermediate vinyl cation. Attack of the carbonyl oxygen followed by proton loss affords the observed products (Scheme 9.16). An analogous reaction with nitrosyl fluoroborate provides a route to oxazoles (Table 9.42) [65]. The nitrosyl cation serves as the electrophile in this application. 

Trapping of the intermediate acyl nitrile ylide with dimethyl acetylenedicar-boxylate leads to pyrroles in low yields (< 18%) [1250]. Representative examples of the preparation of oxazoles with carbene complexes are listed in Table 4.18. 

From Nocardia strains several closely related compounds (nocobactins, formo-bactin, amamistatins) were isolated that contain three typically Fe " binding sites, two hydroxamate units, and ahydroxyphenyloxazole stmcture (cf. Sect. 3.2 below). The C-terminus is A-hydroxy-cyc/o-Lys bound to a long chain 3-hydroxy fatty acid, whose hydroxy group is esterified by A -acyl-A -hydroxy-Lys, the a-amino group of which is bound to 2-o-hydroxyphenyl-5-methyl-oxazole-4-carboxylic acid (Table 4). For the amamistatins the configuration of the cyclic lysine was determined as L, the open one as d, and that of C-3 of the fatty acid as (S). The involvement in the iron metabolism was not investigated. 

In general, acyl azides are too unstable to survive at the temperatures required for addition to acetylenes, although benzoyl azide adds readily to ynamines in toluene. Ethoxycarbonyl azide also gives triazoles in good yield with ynamines. The azide adds to propargylic alcohols in boiling ethanol, and to acetylene at 100° under pressure. Addition to phenylacetylene and to electron-deficient acetylenes has been carried out at 130°. Oxazoles are also formed at this temperature by competing thermal decomposition of the azide, and addition of ethoxycarbonylnitrene to the acetylenes. The triazole obtained from phenylacetylene is 2-ethoxycarbonyl-4-phenyltriazole the two 1-ethoxycarbonyltriazoles can be isolated if the addition is carried out at 50° over several weeks. Since the IH- to -triazole isomerization takes place readily in these systems, a IH-structure cannot be assumed for a triazole formed by addition of these azides. 

As shown in previous sections, NHCs promote acyl transfer in transesterification reactions. In a similar manner, O C acyl transfer can be achieved with substrates such as 351 in the presence of 0.9 mol% of triazolium pre-catalyst 353 and KHMDS (Scheme 53). Moderate yields are obtained by varying substitution of the oxazole from R = Me, Ph, t-Bu, and t-Pr [171], Deprotonation of the triazolium salt followed by nucleophilic addition to the carbonate moiety of the oxazole results in enolate intermediate LXXXIII and activated carboxylate LXXXIV. Enolate addition and regeneration of the active catalyst provides quaternary stereocenters 352. 

New methods for the synthesis of 2,4-disubstitued oxazoles are summarized in a recent review. 2-Alkyl-1,3-oxazoles bearing alkyl, aryl, or acyl substitution at C4 are common substructures in natural products. Examples include macrolides such as rhizoxin (4), hennoxazole A (5), and phorboxazole A (6), ° as well as many cyclic peptides that incorporate an oxazole subunit presumably derived from serine. ... 

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