Chiral calanolide

Synthesis of Optically Active Calanolide A (1) and Calanolide B (2) (-l-)-Calanolide A (1) and (—)-calanolide B (15) have been shown to be potent inhibitors of HIV-1 RT. Synthesis of both optically active calanolide A and calanolide B have been accomplished by Deshpande et al. (Scheme 8-7)." ° They reported on the first enantioselective total synthesis of (-l-)-calanolide A (1) and (-l-)-calanolide B (2) and their (—)enantiomers, (—)-calanolide A (a new compound) and (—)-cala-nolide B (15), using a process that generated all three contiguous chiral centers (the (—)-calanolide B is also known as costatolide), respectively. 

Synthesis of (-I-) calanolide A (Scheme 8-11) was achieved by enzyme catalyzed resolution of the aldol products ( )-53. Compound 7 with acetaldehyde by aldol reaction in the presence of LDA/TiCU stereoselectively produced a mixmre of ( )-53 and ( )-54 (94% yield), the ratio of which was 96 4. ( )-53 was then resolved by lipase AK-catalyzed acylation reaction in the presence of tert-butyl methyl ether and vinyl acetate at 40 °C to obtain 41% yield of (+)-55 and 54% yield of the acetate (—)-56. Mitsunobu cyclization of (+)-55 in the presence of tri-phenylphosphine and dielthyl azodicarboxylate afforded 63% yield of (-l-)-43 with 94% ee as determined by chiral HPLC. Luche reaction on (+)-43 with CeCla 7H2O and triphenyl phosphine oxide and NaBH4 in the presence of ethanol at 30 °C gave the crude product. It was purified by column chromatography on silica gel to give 78% yield of a mixture containing 90% of (+)-calanolide A and 10% (+)-calanohde B, which were further separated by HPLC. 

The synthetic ( )-calanolide A was resolved into its enantiomers, (+)-calanolide A (1) and ( )-calanolide A, by using a semipreparative chiral HPLC column packed with amylose carbamate eluting with hexane/ethnol (95 5). The ultraviolet detection was set at a wavelength of 254 nm. (+)-calanolide A and its enantiomer (—)-calanohde A were collected, and their chemical structures were identified based on their optical rotations and spectroscopic data, as compared with the corresponding natural and synthesis compounds. 

Quite recently, the use of natural cinchona alkaloids as catalysts for the intramolecular oxo-Michael addition of o-tigloylphenol (3), furnishing chiral ris-2,3-dimethyl-4-chromanone 4, which is a valuable intermediate for the synthesis of the anti-HIV-1 active coumarins, (+ )-calanolide A (5a), and (+ )-inophyllum B (5b), was reexamined by Ishikawa and coworkers (Scheme 9.2) [2], The parent cinchona alkaloids,... 

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