64-Oxazolines, aromatization

A -Imidazolines, -oxazolines and -thiazolines (291), and their benzo derivatives (292), are very easily aromatized (292 293), and syntheses which might be expected to yield... 

Aromatic and vinylic sulfides take part in cross-coupling reactions with Grignard reagents in the presence of Ni catalysts.336,337 This reaction has been applied to the enantioselective synthesis of binaphthyls using a standard chiral oxazoline ligand (Equation (25)) 338... 

The use of oxazolines in aromatic substitution is a valuable synthetic tool.2 The o-methoxy- or o-fluorophenyloxazoline reacts readily with a variety of organofithium or Grignard reagents to displace only the ortho substituent. In this fashion a number of ortho-substituted benzoic acids, benzaldehydes, and unsymmetrical biphenyls are accessible. The reaction takes place under very mild conditions, usually at or below room temperature, and thus allows a number of other sensitive groups to be present. 

The photocycloaddition of aliphatic and aromatic aldehydes with 2,4,5-trimethyloxazole (131) gave bicyclic oxetanes 132 in almost quantitative yields hydrolitic cleavage led selectively to erytro a-amino-P-hydroxy methyl ketones 133 <00CC589>. The oxazolium salt 134 was converted to the azomethine ylide 136 via electrocyclic ring opening of the oxazoline 135. Intramolecular cycloaddition afforded 137 in 66% overall yield which was transformed into the aziridinomitosene derivative 138 . 

Preparation of the chiral biphenyls and binaphthyls with high enantiose-lectivity can be achieved via substitution of an aromatic methoxyl group with an aryl Grignard reagent using oxazoline as the chiral auxiliary.38 Schemes 8-10 and 8 11 outline the asymmetric synthesis of such chiral biaryl compounds. 

As shown in Scheme 8-11, nucleophilic entry from the a-face (24a) may be hindered by the sterically bulky substituent R2 on the oxazoline moiety therefore entry from the / -face 24/ predominates. Free rotation of the magnesium methoxy bromide may be responsible for the sense of the axial chirality formed in the biaryl product. If the azaenolate intermediate 25 is re-aromatized with a 2 -methoxy substituent complexed to Mg, (iS )-biphenyl product is obtained. Upon re-aromatization of azaenolate 25B, (R)-product is obtained. 

In an approach to planar chiral ferrocenes, Siegel and Schmalz (85) report that bis(oxazoline)-copper complexes induce efficient aromatic C-H insertion from a... 

From a structural point view, the most explored thionocarbamates in carbohydrate chemistry are five-membered l,3-oxazolidine-2-thiones.27 29 With respect to the synthesis of aromatic analogues of OZTs-1,3 oxazoline-2-thiones (OXTs), only two acyclic D-fructose-derived OXTs were recently reported by Rollin and co-workers.30... 

G. Prakash, G. K. S. Efficient Chemoselective Carboxylation of Aromatics to Arylcarboxylic Acids with Superelectrophilically Activated Carbon Dioxide-Al2CI6/Al System. J. Am. Chem. Soc. 2002, 124, 11379-11391. (d) Klumpp, D. A. Rendy, R. McElrea, A. Superacid Catalyzed Ring-opening Reactions Involving 2-Oxazolines and the Role of Superelectrophilic Intermediates. Tetrahedron Lett. 2004, 45, 7959-7961. 

The oxidation state of thiazolines and oxazolines can be adjusted by additional tailoring enzymes. For instance, oxidation domains (Ox) composed of approximately 250 amino acids utilize the cofactor FMN (flavin mononucleotide) to form aromatic oxazoles and thiazoles from oxazolines and thiazolines, respectively. Such domains are likely utilized in the biosynthesis of the disorazoles, " diazonimides, bleomycin, and epothiolone. The typical domain organization for a synthetase containing an oxidation domain is Cy-A-PCP-Ox however, in myxothiazol biosynthesis one oxidation domain is incorporated into an A domain. Alternatively, NRPSs can utilize NAD(P)H reductase domains to convert thiazolines and oxazolines into thiazolidines and oxazolidines, respectively. For instance, PchC is a reductase domain from the pyochelin biosynthetic pathway that acts in trans to reduce a thiazolyinyl-Y-PCP-bound intermediate to the corresponding thiazolidynyl-Y-PCP. ... 

A note of warning both MOM acetals and methyl ethers ortho to electron-withdrawing groups—particularly oxazolines, aldehydes, imines and amides—are susceptible to nucleophilic aromatic substitution reactions involving loss of the alkoxy substituent ... 

For conversion of functionalized diorganozincs into tertiary amines, aromatic compounds which contain a directed metallation group, such as Af,Af-dialkylbenzamides, methoxymethyl phenyl ether, phenyl oxazolines and phenyl Af,Af-dialkylcarbamates, were ortho-lithiated, transmetallated and then aminated with 2a in good yields, but with a slower reaction rate (Scheme 19). 

A variety of heterocyclic systems containing unsaturated nitrogen can partake in directed aromatic or heteroaromatic lithiations. Pyrazole (II,D), tetrazole (II,G,2), imidazoline (V,B,2), and pyridine (IV,A,4) derivatives were discussed in the sections indicated. In addition, lithio derivatives of 2-oxazoline 178 (76LA183), 4,4-dimethyl-2-oxazoline 179 (790R1 85T837),... 

However, treatment of the precursor 74, where there is no substitution at C(4) (i.e., R = Me) led to a single [3+2] cycloadduct 75 with methyl acrylate. The unstable oxazolines 75, are considered to open spontaneously to their valence bond, 1,3-dipole tautomers 76, which are trapped in situ by the dipolarophile. Use of DMAD led to the formation of the expected 2,5-dihydropyrrole (77), but difficulties in isolation required DDQ aromatization to pyrrole 78 (Scheme 3.19). 

A similar reaction of 70 leads to an amino nitrile ylide synthon (36,37), which reacts with a range of aromatic and heteoaromatic aldehydes to give the 2-oxazolines (71), but which fails to react with ahphatic aldehydes, simple ketones, or activated alkenes. 

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