Isomerization enyne cycloisomerization

Furthermore, the choice of enyne substrates can lead to cyclized products that contain other functionalities than dienes. Very recently, Muller and Kressierer [148] have shown that yne allyl alcohols 200 can be rapidly cyclo-isomerized by a Pd2dba3-W-acetyl phenyl alanine catalyst system to furnish heterocyclic enals 202 in excellent yields (Scheme 82). The intermediate product of the enyne cycloisomerization in this case is the enol 201, which rapidly tautomerizes to the aldehyde 202. 

Stereoinduction was observed, as in the formation of 74 (Equation (46)) as a single diastereomer 1,3-stereo-induction was not successful. Most substrates contained only methyl-substituted olefins, leading to terminal alkenes. In the case of the cycloisomerization of an //-propyl-substituted enyne, a modicum of selectivity with respect to olefin geometry was exhibited 73 was produced in an isomeric ratio of 1 3.5. The authors do not specify whether the (E)- or (Z)-geometry was preferred. 

The proposed mechanism of the above cycloisomerizations are depicted in Scheme 11.30. The oxidative coupling of a metal to an enyne yields a bicyclic metaUacyclopentene, which is a common intermediate. The reductive elimination and subsequent retro-[2+2] cycloaddition gave vinylcyclopentene derivatives, while the two patterns of P-elimination and subsequent reductive eUmination gave cychc 1,3- and 1,4-dienes, respectively. The existence of a carbene complex intermediate might explain the isomerization of the olefinic moiety. 

Shortly after the discovery of enyne metathesis, Trost began developing cycloisomerization reactions of enynes using Pd(ll) and Pt(ll) metallacyclic catalysts (429-433), which are mechanistically divergent from the metal-carbene reactions. The first of these metal catalyzed cycloisomerization reactions of 1,6-enynes appeared in 1985 (434). The reaction mechanism is proposed to involve initial enyne n complexation of the metal catalyst, which in this case is a cyclometalated Pd(II) cyclopentadiene, followed by oxidative cyclometala-tion of the enyne to form a tetradentate, putative Pd(IV) intermediate [Scheme 42(a)]. Subsequent reductive elimination of the cyclometalated catalyst releases a cyclobutene that rings opens to the 1,3-diene product. Although this scheme represents the fundamental mechanism for enyne metathesis and is useful in the synthesis of complex 1,3-cyclic dienes [Scheme 42(fe)], variations in the reaction pathway due to selective n complexation or alternative cyclobutene reactivity (e.g., isomerization, p-hydride elimination, path 2, Scheme 40) leads to variability in the reaction products. Strong evidence for intermediacy of cyclobutene species derives from the stereospecificity of the reaction. Alkene... 

Okamoto et al. [31] reported an enantioselective Rh-BINAP-catalyzed allyl ether isomerization-cycloisomerization domino sequence of phenol- or naphthol-linked 1,7-enynes 17 to give dihydrobenzofurans and dihydronaphtho-furans 18 (Scheme 12.9). 

There are many examples of preparing cyclopentane structures from enynes by gold-catalyzed carbocyclization reactions. Toste et al. have reported that Au(l)-phosphine complexes act as superior catalysts for isomerization of 1,5-enynes to bicyclo[3.1.0]hexenes [124]. For example, treatment of 1,5-enyne (86) with 1 mol% of PhsP-AuPFfi in dichloromethane at room temperature results in formation of cyclopropane-fused cyclopentene (87) in 99% yield (Scheme 18.30). 1,6-Enynes also undergo similar cycloisomerization to five-membered cyclic compounds under the influence of cationic gold(l) catalysts [125, 126], Hydroxylated enynes are versatile precursors for cyclopentenones by gold-catalyzed cycloisomerization... 

Gold(I)-catalyzed cyclization of 1,8-enynes gives cyclobutene compounds as the main product (Scheme 1.25) [145, 197]. These intermediates can also to give isomerization or fragmentation products after prolonged reaction times or in the presence of traces of acids. Furthermore, cyclobutene compounds can also be synthesized from certain 1,6- and 1,7-enynes [15]. The formation of cyclobutene compounds by gold-catalyzed cycloisomerization of l,n-enynes will be discussed in Chap. 2. 

---