Enynes cyclopropanation

The enyne cross metathesis was first developed in 1997 [170,171]. Compared to CM it benefits from its inherent cross-selectivity and in theory it is atom economical, though in reality the aUcene cross-partner is usually added in excess. The inabihty to control product stereochemistry of ECM reactions is the main weakness of the method. ECM reactions are often directly combined with other transformations like cyclopropanation [172], Diels-Alder reactions [173], cychsations [174] or ring closing metathesis [175]. 

The substituent effects on the alkene were investigated in the reaction of enyne 12 and chromium carbene complex 2c [8]. In the reaction of enyne -12a having a phenyl group on the alkene with Fischer chromium carbene complex 2c, metathesis product 13a was obtained as a main product along with cyclopropane 14 and cyclobutanone 15 (Eq.4). The reaction of Z-12a with 2c gave only... 

The reaction course is shown in Scheme 4. Enyne 12 reacts with 2 to give vinyl carbene complex 17, which is in a state of equilibrium with vinyl ketene complex 21. [2+2] Cycloaddition of the ketene moiety and alkene part in 21 gives cyclob-utanone 22. On the other hand, the vinyl carbene complex 17 reacts with the alkene intramolecularly to produce metalacyclobutane 18. From metalacyclob-utane 18, reductive elimination occurs to give cyclopropane derivative 23. Ret-... 

Bicyclic cyclopropanes.1 Reaction of the Fisher carbene 1 with the 1,6-enyne 2 results in the bicyclic cyclopropane 3 (a bicyclo[3.1.0]hexane) in 69% yield. The 1,7-enyne homolog of 2 reacts with 1 in the same way to form a bicyclo[4.1.0]-... 

For synthetic purpose, the selective preparation of tetrasubstituted enynes was also investigated in the reactions of l-cydopropyl-2-propyn-l-ols bearing a substituent at the a-position in a cyclopropane ring with anilines (Scheme 7.37). As expected, the corresponding tetrasubstituted enynes were obtained in high yields with almost complete selectivity. 

Phase transfer-catalyzed reactions have recently been employed to dehydro-halogenate gem-dihalocyclopropanes [156, 157]. Thus, 1-methylene-2-vinylcyclo-propane has been prepared from l,l-dichloro-2-ethyl-3-methylcyclopropane in 60 % yield. Under the reactipn conditions (solid KOH, DMSO in the presence of dibenzo-18-crown-6, 100-130 °C) further transformations may take place, however. For example, monoalkylated cyclopropanes have been converted to mixtures of acyclic enynes and conjugated trienes. And 7,7-dichloronorcarane is converted to toluene under these conditions. 

A mechanism proposed for the skeletal rearrangement of enynes involved the presence of gold carbenes [161]. This proposed mechanism was supported by the capture of intermediate gold carbenoids trapped by reactive alkenes in intermolecu-lar cyclopropanation reactions [162]. 

The same authors have demonstrated that 1,3-diynes behave in predictable yet distinctive manners compared to simple enynes under electrophilic transition metal-mediated reaction conditions. This characteristic behaviour of 1,3-diynes is presumably caused by the slightly electron-withdrawing nature of the alkynyl substituent, which not only renders preferentially the formation of 5-exotype alkylidenes but also allows for the subsequent [l,3]-metallotropic shift. Several salient features of reactions with this functionality include the following (a) an acetate is more reactive than the tethered alkene as an initiator, generating [l,2]-acetate migrated alkylidene intermediate, whereas an alkene is a better terminator than an acetate/bromide to generate the cyclopropane moiety (b) allene products are not formed at all under current reaction conditions (c) 5-exo/6-endo-type alkylidene formation depends on the heteroatom substituent in the tether (d) facile metallotropic [1,3]-shift of the intermediate alkylidenes occurred whenever possible. 

Up to this point Pd, Pt and Ru-catalysed enyne metatheses have been explained without involvement of metal-carbenes. However, carbenoid species seem to play a key role in these metatheses (or cycloarrangements) based on the following polycyclization involving cyclopropanation. Polycyclic ring systems are constructed by the cycloisomerization of dienynes catalysed by Ru, Pt, Rh, Ir and Re complexes... 

When the double bond of the enyne possesses a cyclopropyl substituent, an intramolecular [5+2] cycloaddition of alkyne and vinylcyclopropane takes place [75, 76]. The ruthenacycle does not undergo /l-hydride elimination but a rearrangement of the cyclopropane to produce a ruthenacyclooctadiene. Thus, a variety of bicyclic and tricyclic cycloheptadienes were obtained in good yields [75] (Eq. 55). 

Diver has recently reported new entries for the assembly of tetracyclic derivatives [89]. Interestingly, ruthenium metathesis-type catalysts have also given birth to tricyclic derivatives incorporating a cyclopropane from di-enynes [90]. Cationic gold-based catalysts have proven to be even more reactive promotors of various reactions resulting from a preliminary electrophilic activation [91]. They also allow the formation of tetracyclic derivatives 140 from acyclic precursors 139 at low temperature and as single diastereomers. In one case, the minor metathesis diene 141 was isolated. Tetracyclic products... 

PtCh is also a catalyst of choice to perform the electrophilic activation of enynes towards the formation of cyclopropane derivatives [103,104], The sequence ruthenium-catalyzed C - C bond formation/platinum-catalyzed cycloisomerization has been successfully carried out in one pot at 60 °C to form... 

A catalytic tandem cyclopropanation-ring-closing metathesis of dienyne 80 led to derivative 81 in good yield (Scheme 30 <2004JA9524>). For internal alkynes, carbene-mediated ring-closing enyne metathesis was observed. Less favorable alkyne binding leads to preferential reactions of the metal carbene with the 1-alkene moiety. 

Pt(II) to the alkyne of the substrate likely triggers all these events. The cycloisomerization might undergo a metallacyclic intermediate that proceeds to eliminate /3-H. The formation of cyclopropanes is presumably succeeded via alkenyl platinum carbene followed by platina(IV)cyclobutane intermediates. The extension using formal metathesis of the enynes includes two transformations, the formation of 1,3-diene moieties and the stereoselective tetrasubstituted aUcene derivatives via O C allyl shift, both leading to diverse structural motifs and serving as the key step in the total synthesis of bioactive targets (Scheme 83). 

Alkenes act as nucleophiles with alkynes in the presence of gold catalysts. In the most simple version of the reaction, enynes are converted with gold complexes or salts, and in the absence of nucleophiles, into rearranged dienes, cyclopropanated carbocycles, and/or bicyclic cyclobutenes. Depending on the length of the tether and the nature of the substituents, the olefin attack to the alkyne occurs in an endo or an exo fashion (equation 33). Besides, substitution at the alkene plays an important role on the regioselectivity of the nucleophilic attack. ... 

In this 3-phcnylalkyne system the triple bond becomes incorporated into a cyclo-propene ring, whereas from the enynes 10 and 11 there is no sign of a vinylcyclo-propene product. The preference for reaction to take place at the alkene unit rather than at the alkyne unit in the photochemistry of enynes is seen again in the photochemistry of enepoly-yne chlorides, where only cyclopropyl chlorides are produced (equation 18). This preference is probably a reflection of the lower strain energy in a cyclopropane than in a cyclopropene ring. 

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