Cyclopropanes divinyl, Cope rearrangement

The Davies group has described several examples of a rhodium-catalyzed decomposition of a diazo-compound followed by a [2+1] cycloaddition to give divinyl cyclopropanes, which then can undergo a Cope rearrangement. Reaction of the pyrrol derivative 6/2-51 and the diazo compound 6/2-52 led to the tropane nucleus 6/2-54 via the cyclopropane derivative 6/2-53 (Scheme 6/2.11) [201]. Using (S)-lactate and (R)-pari lolaclorie as chiral auxiliaries at the diazo compound, a diastereoselectivity of around 90 10 could be achieved in both cases. 

Figure 12.6. a) Cope rearrangement of 1,5-hexadiene (6) oxy-Cope rearrangement (c) divinyl-cyclopropane rearrangement (d) degenerate rearrangements of bullvalene. 

The intramolecular reaction of the carbene from diazo ester 280, which contains a 1,3-diene moiety in the ester group and a double bond adjacent to the carbene center, leads to the formation of a substituted 1,2-divinyl-cyclopropane, whose CIS isomer then undergoes a Cope rearrangement to give substituted cycloheptadiene. In such a way, bicyclic 281 and tricyclic 282 y-lactones with a neighboring seven-membered carbocycle have been obtained (89JOC930). 

Davies and co-workers [12, 35] have exploited one particular aspect of the asymmetric cyclopropanation of alkenes with vinyl diazoacetates, namely, application to substrates suitable for subsequent Cope rearrangement. Cyclopropanation of dienes with predominant cfs-1,2-divinyl diastereoselection makes possible subsequent facile [3,3]-sigmatropic rearrangement with entry to 1,4-cycloheptadienes or bicyclic dienes. Two such examples employing cyclopenta-diene and penta-l,3-diene as substrates and the rhodium(II) prolinate catalyst, Rh2(2S-TBSP)4 in Fig. 1, are shown in Eq. (6) and Eq. (7),respectively cfs-l,2-di-vinylcyclopropanes are presumed to be intermediates in these annulation reactions. In contrast, ethyl diazoacetate and styrene with the prolinate catalyst (Fig. 

The cyclopropane intermediate results from the rhodium-carbenoid addition to the less-hindered terminal double bond of the diene. This generates the cyclopropane in which both alkenes are cis related, which allows the subsequent Cope rearrangement of the divinyl cyclopropane (see Section 3.6.1). The conformation of the boat-shaped transition state for the rearrangement must have the methyl and acetate groups trans to one another. See W. R. Cantrell and H. M. L. Davies, J. Org. Chem., 56 (1991), 723. 

Scheme 46). The substituted cis-divinylcyclopropanes (321) give no Cope rearrangement but, interestingly, equilibrate cleanly with their trans-isomers upon heating. Co-ordination of the bicyclic cis-divinyl-cyclopropane (322) with Rh also inhibits a Cope rearrangement. ... 

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