Sigmatropic rearrangements chirality transfer

The transposition of oxygen in allylic esters (R6 = alkyl, phenyl) or carbamates [R6 = N(CH3)2] has the same overall bonding changes as the thermal [3,3] sigmatropic Claisen or Cope rearrangements. Chirality transfer from C-l to C-3 is accompanied by 1,3 oxygen transposition (carbonyl O to allylic O ). 

It may be of interest to note that the stereospecific transformation shown in equation 15 has been cited as the first reported observation of an 1 - 3 chirality transfer. It is evident that on rearrangement of optically active 6d to 7d, the chiral center at C-a is eliminated and a new one created at C-y. The term self-immolative asymmetric synthesis has also been used to describe syntheses of this kind. As pointed out by Hoffmann , quantitative 1 - 3 chirality transfer will follow from the suprafacial - course of rearrangement, provided the reactant has a uniform configuration at the j8, y-double bond. This stereochemical prediction has also been confirmed by the results obtained in several other [2,3]sigmatropic rearrangements, subsequently reported " . 

Uemura and co-workers (91) demonstrated that copper catalysts effectively transfer nitrenoid groups to sulfides generating chiral sulfimides. A complex obtained from CuOTf and 55d catalyzes nitrenoid transfer to prochiral sulfides to afford products such as 139 in moderate to poor enantioselectivities (<71% ee, Eq. 78). Nitrenoid transfer occurs selectively to the sulfur atom of allylic sulfides generating allylic sulfenamide (140) in moderate selectivity, after [2,3] sigmatropic rearrangement of the initial sulfimide 141, Eq. 79. 

This type of stereoselective reaction, in which a chiral unit is created and another destroyed, has been termed self-immolative by Mislow39 and an asymmetric transfer process by Pracejus40. Both terms are in use. but the latter is gaining ground in the mutated form of "chirality transfer 41, which is most often applied to sigmatropic rearrangement reactions such as the following37 ... 

The self-immolative 1,3-chirality transfer from C-5 to C-3 the simple diastereoselection observed in the connection of C-2 with C-3 which results from the enol ester olefin geometry and the chair-like transition state of the [3.3]-sigmatropic rearrangement. 

Review on chirality transfer via sigmatropic rearrangements R. K. Hill in Asymmetric Synthesis, J. D. Mosher, Ed., Vol. 3, p 503, Academic, Orlando 1984. 

Nitrene transfer to selenide is also possible. Catalytic asymmetric induction in this process has been studied with Cu(OTf)/bis(oxazoline) catalyst (Scheme 22). When prochiral selenide 206 and TsN=IPh are allowed to react in the presence of Cu(OTf)/chiral bis(oxazoline) 122b, selenimide 207 is obtained with enantioselectivity of 20-36% ee. When arylcinnamyl selenide 208 is applied to this reaction, corresponding selenimide 209 is produced which undergoes [2,3]-sigmatropic rearrangement to afford chiral allylic amides 211 in up to 30% ee. 

The synthesis of natural products by chirality transfer from carbohydrates has been used for a total synthesis of (-)-(7S)-nonactic acid (199). The furanoid glycal (197) was prepared from D-mannose, which is the appropriate chiral precursor (Scheme 46) (80JOC4259). A [3,3]-sigmatropic rearrangement of the silylated ketene-acetal (198) led to the control of the C-2 configuration. The intermediate furanoid glycal was prepared in ten steps from the carbohydrate precursor. 

The [2,3]- or [3,3]-sigmatropic rearrangements (Scheme 24) provide a means to introduce either the protected amine or the carbon atom which will become the carboxylic acid, while also positioning the double bond in the correct position for the alkene isosteres. Moreover, when starting from homochiral allyl alcohols, a very effective chirality transfer assures the stereospecific construction of the R1 and R2 side-chain stereochemistries. 

The [3,3]-sigmatropic rearrangement of a 1,5-hexanediene is known as the Cope rearrangement and usually proceeds through a chair transition state. Generally, a large substituent at C-3 (or C-A) prefers to adopt an equatorial-like confirmation.303 304 As the reaction is concerted, chirality at C-3 (or C-4) is transferred to the new chiral center at C-l (or C-6). The reaction can be catalyzed by transition metals.305 The use of a palladium catalyst allows for the reaction to be conducted at room temperature instead of extremely high temperatures (Scheme 26. lO).306-307... 

When chiral substrates were employed in the cascade reaction, good transfer of the chiral information was observed (Scheme 7.43).119 Excellent diastereoselectivity was obtained with 152g, containing an allylic methyl group and even 152h, which contained a benzyl ether substituent that would lie outside the chairlike transition state (TS-156), controlled the facial selectivity of the [3,3]-sigmatropic rearrangement. 

R. K. Hill, Chirality Transfer via Sigmatropic Rearrangements, in Asymmetric Synthesis. 

It has long been known that appropriately substituted [2.2]paracyclophanes are chiral, chemically stable and do not racemize under normal reaction conditions. With these seemingly ideal prerequisites for use in chiral synthesis, it is perhaps surprising that only three examples have appeared in the literature, all of them in recent years (Scheme 8). Reich employed [2.2]paracyclo-phane-derived selenides such as 24 to administer chirality transfer in selenoxide [2,3] sigmatropic rearrangements. Using this methodology, he was able to synthesize optically active linalool 25... 

The stereochemical features of the [2,3] sigmatropic rearrangement for C-l monosubstituted allyl sulfoxides with an E or Z double bond are shown. The transfer of chirality from C-l to C-3 is high because of the preference of the transoid transition state6. 

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