Enynes 1,7-, cycloisomerizations

Compared with cycloisomerization, enyne metathesis as a bond reorganization of an alkene and an alkyne to produce a 1,3-diene is less studied. A recent review by Diver and Giessert highlights some recent advances in synthetic applications, and mechanistic features [60]. 

Yet another palladium-catalyzed transformation leading to 1,2-dialkyl-idenecycloalkanes was established by Trost et al. when investigating a catalytic Alder-ene reaction (path D in Scheme 12). They showed that two different catalyst systems are capable of cycloisomerizing enynes 92 to either cyclic 1,4-dienes 96—the products of regular Alder-ene reactions— or the 1,3-dienes 95 (Scheme 15) [66-68]. Starting from palladium acetate, the reaction presumably occurs by coordination of both unsaturated moieties (intermediate 93) and subsequent cycloisomerization to the ring-... 

Another useful class of palladium-catalyzed cycloisomerizations is based on the general mechanistic pathway shown in Scheme 13. In this chemistry, a hydridopalladium acetate complex is regarded as the catalytically active species.27b-29 According to this pathway, coordination of a generic enyne such as 59 to the palladium metal center facilitates a hydropalladation reaction to give intermediate 60. With a pendant alkene, 60 can then participate in a ring-form-... 

Fiirstner A, Martin R, Majima K (2005) Cycloisomerization of enynes catalyzed by iron (0)—ate complexes. J Am Chem Soc 127 12236-12237... 

Complex 38 also turned out to be an efficient catalyst for cycloisomerization reactions of enynes 41 (Scheme 8) [16, 17]. This seems reasonable if one considers the fact that Fe(0) is isoelectronic to Rh(+1), which is also a catalyst for Alder-ene cycloisomerizations [18, 19]. 

Scheme 9 Enyne cycloisomerization catalyzed by different Fe(0)-ate complexes 38-40 E = COOEt [17]...

With regard to the mechanism of the cycloisomerization, Fiirstner et al. found strong evidence of a metallacyclic intermediate. By labeling the allylic position of enynes 46 and 48, they showed that reactions yielding traws-annulated rings 47 transferred the deuterium atom to the exocychc double bond (eq. 1 in Scheme 10), whereas c -annulated rings 49 formed with complete preservation of the position of the deuterium atom (eq. 2 in Scheme 10). This corresponds well to a metallacycUc... 

One productive facet of Pd-catalyzed domino reactions is the cycloisomerization of enynes and allenes, as shown by Trost and coworkers [19]. Thus, transformation of the dienyne 6/1-10 using Pd(OAc)2 led to 6/1-13 in 72% yield, in which the last step is a Diels-Alder reaction of the intermediate 6/1-12 (Scheme 6/1.2). 

Fiirstner and coworkers developed a new Pt- and Au-catalyzed cycloisomerization of hydroxylated enynes 6/4-141 to give the bicylo[3.1.0]hexanone skeleton 6/4-143, which is found in a large number of terpenes [317]. It can be assumed that, in the case of the Pt-catalysis, a platinum carbene 6/4-142 is formed, which triggers an irreversible 1,2-hydrogen shift. The complexity of the product/substrate relationship can be increased by using a mixture of an alkynal and an allyl silane in the presence of PtCl2 to give 6/4-143 directly, in 55 % yield (Scheme 6/4.36). 

Michael additions of 7r-allyl species to alkynes were employed for the synthesis of elaborated carbocycles as in the ruthenium-catalyzed cycloisomerization of 1,6-enynes (Equation (188)).1... 

It should also be mentioned that very recently, a new cycloisomerization of enynes has been shown to proceed via a rhodium-vinylidene complex,187 which, after [2 + 2]-cycloaddition and ring opening of a rhodacyclobutane, furnishes versatile cyclic dienes (Scheme 47).188 Not only does this constitute a fifth mechanistic pathway, but it also opens new opportunites for C-C bond constructions. 

Recently, Mikami has also obtained high ee s for the cycloisomerization of related 1,6-enynes,220 using Rh(l)... 

Trost has shown some mechanistic dichotomy in the ruthenium(ll)-catalyzed enyne cycloisomerization.233 Thus, as mentioned above, the cyloisomerization of enynes proceeds well for the formation of five- or six-membered ring for a variety of precursors. In sharp contrast, in the case of 1,6-enynoates with a quaternary propargylic position, a seven-membered ring is produced in good yield (Scheme 58). 

The third pathway for the cycloisomerization of l, -enynes is the transformation that involves a vinylmetal intermediate (Scheme 61). 

Next, the cycloisomerization of l, -enynes involving a vinylmetal species originating from the hydro-, hetero-, or carbometallation of the acetylene moiety in the first step is summarized. 

Ruthenium hydride catalysts can also initiate a variety of cycloisomerizations of 1,5- and 1,6-enynes as well as dienes, as exemplified by the RuClH(CO)(PPh3)3-catalyzed reactions shown in Scheme 64.249... 

The skeletal rearrangements are cycloisomerization processes which involve carbon-carbon bond cleavage. These reactions have witnessed a tremendous development in the last decade, and this chemistry has been recently reviewed.283 This section will be devoted to 7T-Lewis acid-catalyzed processes and will not deal, for instance, with genuine enyne metathesis processes involving carbene complex-catalyzed processes pioneered by Katz284 and intensely used nowadays with Ru-based catalysts.285 By the catalysis of 7r-Lewis acids, all these reactions generally start with a metal-promoted electrophilic activation of the alkyne moiety, a process well known for organoplatinum... 

Trost and others have extensively studied the ruthenium-catalyzed intermolecular Alder-ene reaction (see Section 10.12.3) however, conditions developed for the intermolecular coupling of alkenes and alkynes failed to lead to intramolecular cycloisomerization due the sensitivity of the [CpRu(cod)Cl] catalyst system to substitution patterns on the alkene.51 Trost and Toste instead found success using cationic [CpRu(MeCN)3]PF6 41. In contrast to the analogous palladium conditions, this catalyst gives exclusively 1,4-diene cycloisomerization products. The absence of 1,3-dienes supports the suggestion that the ruthenium-catalyzed cycloisomerization of enynes proceeds through a ruthenacycle intermediate (Scheme 11). 

The Alder-ene cyclization of allylic silyl ethers represents a clever use of cycloisomerization chemistry, as the enol ether products can be easily unmasked to yield aldehydes. Palladium-catalyzed cycloisomerization of 1,6- and 1,7-enynes containing an allylic oxygen most often gives rise to 1,3-dienes (see Section 10.12.4.1). However, enynes of type 63 underwent facile Alder-ene cyclization to the corresponding five- or six-membered rings (Equation (40)) using both [CpRu(MeCN)3]PF6 41 and the Cp analog ([Cp Ru(MeCN)3]PF6, 64).53... 

Diastereoselectivity was observed as the result of stereoinduction (Equation (41)), giving preferential formation of the 1,2-trans products. Enhancement of the diastereoselectivity in the cycloisomerization of enyne 65a n= 1) was observed with the use of the catalyst bearing the sterically demanding Cp ligand 64. 

Trost and Toste51 isolated unexpected cycloheptene 69 upon exposing enyne 68 to their optimized ruthenium-based Alder-ene conditions (Equation (42)). Further exploration into the effects of quaternary substitution at the propargylic carbon revealed the ability of ruthenium to catalyze a non-Alder-ene cycloisomerization to form seven-membered rings, presumably via allylic C-H activation (Scheme 15). 

Zhang54 published the first and only account of a non-asymmetric rhodium-catalyzed Alder-ene cycloisomerization of 1,6-enynes.55 The conditions developed by Zhang and co-workers are advantageous in that, similar to the ruthenium conditions developed by Trost, selectivity for 1,4-diene products is exhibited. The rhodium conditions are dissimilar from many other transition metal conditions in that only (Z)-olefins give cycloisomerization products. 

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. 

Incorporation of the carboxylic acid group into the substrate also had an effect on the stereochemistry of the Alder-ene products. Trost and Gelling60 observed diastereoselectivity in the palladium-catalyzed cycloisomerization of 1,7-enynes when the reactions were conducted in the presence of A,A-bis(benzylidene)ethylene diamine (BBEDA, Figure 2). They were able to synthesize substituted cyclohexanes possessing vicinal (Equation (53)) and... 

An intramolecular palladium-catalyzed cycloisomerization of enyne 170 was used to access the antifungal agent, chokol C (Scheme 43).102 The choice of ligand and catalyst was essential to the efficiency of the Alder-ene reaction. Enone 171 was obtained as a single olefinic isomer resulting from migration of only Ha during the cycloisomerization reaction. 

Kibayashi and co-workers103 implemented the palladium-catalyzed cycloisomerization reaction in a stereoselective total synthesis of enantiomerically pure (+)-streptazolin. The cycloisomerization of enyne 172 to provide diene 173 was remarkably selective when performed in the presence of A,Ar -bis(benzylidene)ethylenediamine (BBEDA) as a ligand and water as a proton source (Scheme 44). 

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