Synthesis of functionalized carbo- and heterocycles via gold-catalyzed cycloisomerization reactions of enynes

The PPh₃AuCl/AgSbF₆ catalytic system promotes a tandem Friedel-Crafts' type addition of electron-rich aromatic and heteroaromatic derivatives to unactivated alkene followed by a C-C bond cyclization reaction. The efficiency of this system allowed room temperature reactions in a very short time. The scope and limitations of this reaction were investigated. The reaction conditions were compatible with various functional groups on the nucleophiles. Severe limitations were observed when the allylic position of the enyne is substituted by electron-withdrawing groups. The mechanism of the reaction was investigated via the synthesis of a deuterated aromatic ring: we showed that the source of proton involved in the protodemetallation step originates from the acidic activated C-H bond of the nucleophile.     

Carene terpenoids by gold-catalyzed cycloisomerization reactions

Propargyl acetates in the presence of catalytic amounts of AuCl3 constitute synthetic equivalents of alpha-diazoketones as illustrated by a concise entry into the carene family of natural products.     

Platinum-catalyzed cycloisomerization reactions of enynes.

PtCl(2) constitutes an efficient and practical catalyst for a set of different atom economical rearrangement reactions of enynes. This includes (i) a formal enyne metathesis reaction delivering 1,3-dienes, (ii) the formation of polycyclic vinylcyclopropane derivatives, and (iii) an unprecedented O-->C allyl shift reaction if unsaturated ethers are employed. Although these transformations produce significantly different structural motifs, they share a common mechanism comprising a cationic manifold triggered by the pi-complexation of Pt(II) onto the alkyne unit of the substrates. Strong experimental support for the proposed mechanism comes from deuterium-labeling studies, a careful analysis of the product distribution pattern, and the fact that in some cases PtCl(2) can be replaced by simple Lewis or Br?nsted acids as the catalysts.     

Gold-catalyzed cycloisomerization reactions of boronated enynes

Gold (I) complexes generated from a mixture of gold and silver salts were found to be highly reactive for the cycloisomerization reactions of boronated enynes. Both alkynyl pinacol boronates and alkenyl pinacol boronates were tolerated, affording products in moderate to high yields. Interestingly, the ratio of the different endo- and exo-products was heavily dependent on the position of the boronate functionality. Further applications including Suzuki-Miyaura cross coupling and oxidation reactions could be carried out, affording a variety of synthetically useful products.     

Cyclobutenes by platinum-catalyzed cycloisomerization reactions of enynes

1,6-Enynes bearing (electron-rich) aryl substituents on their alkyne moiety rearrange to cyclobutene derivatives in the presence of catalytic amounts of PtCl2 in toluene. The reaction is significantly accelerated when performed under an atmosphere of CO (1 atm), most likely by increasing the electrophilicity of the metal template by temporary coordination to this pi-acidic ligand. This transformation allows the build up of considerable strain in the products as witnessed by the productive formation of tricyclic skeletons, such as 7 or 9. Moreover, these products provide evidence for the mechanistic scenario of platinum-catalyzed cycloisomerization reactions previously proposed, which are thought to proceed via organo-platinum species that mimic the reactivity of metal-complexed "nonclassical" carbocations.     

Alkyne versus allene activation in platinum- and gold-catalyzed cycloisomerization of hydroxylated 1,5-allenynes

Chemo- and stereoselective transformations of 3-hydroxy-1,5-allenynes 1 into a variety of new and potentially useful cyclic compounds have been achieved. Substrates bearing a silyl group at the alkyne moiety undergo purely thermal or Lewis acid catalyzed Alder-ene type transformations into 2-methylene-3-vinylcyclopent-3-enol derivatives 2. When heated in the presence of a catalytic amount of PtCl(2) or PtCl(4), these incipient cyclopentenols could be further transformed into 3-vinylcyclopent-2-enones 3. On the other hand, alkyl-substituted 3-hydroxy-1,5-allenynes proved to be stable under refluxing conditions. Nevertheless, PtCl(2) and PtCl(4) could selectively activate the alkyne moiety of these substrates toward intramolecular nucleophilic attack of the internal allene double bond to yield unprecedented 6-methylenebicyclo[3.1.0]hexan-3-one derivatives 4. With gold-based catalysts, provided that the reaction is carried out in dichloromethane, both Au(I) and Au(III) complexes selectively activate the allene fragment of the substrates toward intramolecular nucleophilic attack of the hydroxyl group to yield 2-ethynyl-3,6-dihydro-2H-pyrans 5. Compounds of type 4 can also be formed with Au(I) and Au(III) complexes if the reaction is carried out in toluene. The reactivity of these new compounds has been partially investigated, and polycyclic ketones were obtained after oxidation under mild conditions or gold-catalyzed cycloisomerization.     

Manganese porphyrin catalyzed cycloisomerization of enynes

Cycloisomerization of 1,6-enynes to five- or six-membered ring systems is successfully carried out in the presence of a cationic manganese(III) catalyst. The use of a structurally rigid tetradentate porphyrin as the equatorial ligand and a weakly coordinating axial ligand is the key to bringing out the catalytic reactivity of manganese for the reaction. The axial ligand of the catalyst has a marked effect on the product and selectively aids the formation of five- or six-membered cyclic products.     

Density function studies on the PtCl2‐catalyzed asymmetric cycloisomerization reaction of hydroxylated enynes

The PtCl₂‐catalyzed asymmetric cycloisomerization reaction of hydroxylated enynes was studied using density functional theory (DFT). All structures have been optimized completely at the B3LYP/6‐311G(d,p) level. As shown, the cycloisomerization reaction is exothermic. The cycloisomerization reaction mainly undergoes the formation of catalyst‐hydroxylated enzyme coordination, the asymmetric cyclopropyl platinum carbene, catalyst–cyclopropyl enol coordination, and catalyst–cyclopropyl ketone coordination. The chirality‐limiting step for the asymmetric cycloisomerization reaction is the formation of the asymmetric cyclopropyl platinum carbene, and the rate‐determining step for this reaction is the formation of the catalyst–cyclopropyl ketone coordination. The dominant products predicted theoretically are (R,S) ‐syn_5a, in agreement with the experiment. © 2006 Wiley Periodicals, Inc. Int J Quantum Chem, 2006     

Gold-catalyzed cycloisomerization of siloxy enynes to cyclohexadienes

We have described the first Au-catalyzed cycloisomerization of 1-siloxy-5-en-1-ynes. The reaction is efficiently catalyzed by AuCl (1 mol %) to afford siloxy cyclohexadienes, which can be readily converted to the corresponding 1,2- and 1,3-cyclohexenones. The catalytic process displays a broad substrate scope and exceedingly mild reaction conditions (30 min, 20 degrees C). The presence of a siloxy alkyne moiety is crucial for enabling the skeletal reorganization process, which is postulated to proceed via a novel reaction mechanism involving a cascade of 1,2-alkyl migrations.     

Dicationic platinum porphyrin catalyzed cycloisomerization of enynes

Cycloisomerization of 1,6-enynes is successfully carried out in the presence of a dicationic platinum(IV) catalyst to afford five-membered ring systems. The use of a weakly coordinating axial ligand is the key to bringing out the catalytic activity of platinum porphyrin for the reaction.     

Catalytic cycloisomerization of enynes by using a nickel-zinc-acid system

Catalytic cycloisomerization of enynes has been accomplished in the presence of an Ni0-PPh3-Zn-carboxylic acid or -ZnCl2 system. A nickel(I)-hydride complex, thought to be generated by reduction of the protonated nickel(II) complex with Zn, is proposed as the catalytic species. This cycloisomerization shows reactivity behavior that is different from that of a conventional metal-catalyzed reaction. In particular, in the reaction with (E)-enynes, the catalytic system has a selectivity that favors the formation of the 1,3-diene over the 1,4-diene. In addition, this catalytic system has been applied to the domino cyclization of dienynes for the construction of tricyclic compounds.     

A convenient synthesis of pyrrolopyridines and 2-substituted indoles by gold-catalyzed cycloisomerization

We have developed a gold-catalyzed intramolecular cyclization of variously substituted acetylenic amines under mild conditions, which yields pyrrolopyridines and 2-substituted indoles, quantitatively. The cycloisomerization of acetylenic amines was achieved with AuCl₃ as catalyst without the use of base, acid or N-protecting group.     

Use of ionic liquids in the platinum- and gold-catalyzed cycloisomerization of enyne systems

The platinum- and gold-catalyzed cycloisomerization of enyne systems has been carried out in various ionic liquids (ILs). In some cases, better selectivities and shorter reaction times have been observed compared to conventional conditions.     

Cobalt(I)-mediated cycloisomerization of enynes: mechanistic insights

[CpCo(CO)2] catalyzes the cycloisomerization of 1,n-enynes to afford selectively five- and six-membered ring systems in high yields. The factors governing the cyclization have been explored and we have discovered that the reaction associates two different, but complementary, reactivities of the cobalt(I) complexes. By a judicious choice of the substitution of the enyne, it was also possible to isolate a cyclobutene that arises from a cobaltcyclopentene     

Mechanistic insights into the gold-catalyzed cycloisomerization of bromoallenyl ketones: ligand-controlled regioselectivity

Through computational and experimental studies, the mechanisms of gold-catalyzed cycloisomerization of bromoallenyl ketones in toluene have been elucidated. The divergent 1,2-migrations for the Au(I)- and Au(III)-catalyzed reactions have been investigated, and the results confirmed that the regiochemistry is ligand-dependent in cases of Au(PR3)L (L = Cl, OTf, BF4, and SbF6) catalysts.     

Electrophilic activation and cycloisomerization of enynes: a new route to functional cyclopropanes

Transformations of enynes in the presence of transition-metal catalysts have played an important role in the preparation of a variety of cyclic compounds. Recent developments in the activation of triple carbon-carbon bonds by electrophilic metal centers have provided a new entry to the selective synthesis of cyclopropane derivatives from enynes. The mechanisms of these reactions involve catalytic species with both ionic and cyclopropylcarbenoid character. This type of activation will undoubtedly be further developed for application to other unsaturated hydrocarbons and inspire new catalytic cascade reaction sequences. This Minireview discusses the recent developments in electrophilic activation of enynes and shows that simple catalysts such as [Ru(3)(CO)(12)], PtCl(2), and cationic gold complexes are efficient precursors to promote the formation of functional polyclic compounds.     

A facile and regioselective synthesis of 2,5-disubstituted pyrroles via gold-catalyzed cycloisomerization of acetylenylaziridines

Gold-catalyzed cycloisomerization reaction of acetylenylaziridines provides 2,5-disubstituted pyrroles in high yields. The presence of protic species accelerates the reaction rate and improves the yields of pyrrole products.