Enones addition reactions

Zinc-copper compounds read dy undergo Micliael addition reactions in tlie presence of TMSCl, selectively affording 1,4-adducts [7, 34, 41, 42]. In tlie case of / -disLibstituted enones, tlie 1,4-addltion proceeds well in tlie presence of BF- -OEl2 iSclienie 2.43) [89]. 

The biological activity of calicheamicin 4 (simplified structure) is based on the ability to damage DNA. At the reaction site, initially the distance between the triple bonds is diminished by an addition reaction of a sulfur nucleophile to the enone carbon-carbon double bond, whereupon the Bergman cyclization takes place leading to the benzenoid diradical 5, which is capable of cleaving double-stranded DNA." ... 

The addition of the anions of racemic cyclic allylic sulfoxides to various substituted 2-cyclopentenones gives y-l,4-adducts as single diastereomeric products22. The modest yields were due to competing proton-transfer reactions between the anion and enone. The stereochemical sense of these reactions is identical to that for the 1,4-addition reaction of (Z)-l-(/erf-butylsulfinyl)-2-methyl-2-butene to 2-cyclopentenone described earlier. 

Chiral PTC has been used effectively for making intermediates for drugs. Dolling and coworkers have used 8-R, 9-5, N-(p-trifluoromethylbenzyl) cinchonium bromide to carry out an important asymmetric alkylation, giving 95% ee (Starks, 1987). Nucleophilic epoxidations of enones, Darzens reaction, Michael additions, etc. are some examples of reactions rendered asymmetric through chiral PTCs (Nelson, 1999). 

Another very important method for specific enolate generation is the conjugate addition of organometallic reagents to enones. This reaction, which not only generates a specific enolate, but also adds a carbon substituent, is discussed in Section 8.1.2.3. 

Several examples of conjugate addition of carbanions carried out under aprotic conditions are given in Scheme 2.24. The reactions are typically quenched by addition of a proton source to neutralize the enolate. It is also possible to trap the adduct by silylation or, as we will see in Section 2.6.2, to carry out a tandem alkylation. Lithium enolates preformed by reaction with LDA in THF react with enones to give 1,4-diketones (Entries 1 and 2). Entries 3 and 4 involve addition of ester enolates to enones. The reaction in Entry 3 gives the 1,2-addition product at —78°C but isomerizes to the 1,4-product at 25° C. Esters of 1,5-dicarboxylic acids are obtained by addition of ester enolates to a,(3-unsaturated esters (Entry 5). Entries 6 to 8 show cases of... 

Sml2 has also been used to form cyclooctanols by cyclization of 7,8-enones.262 These alkene addition reactions presumably proceed by addition of the ketyl radical to the double bond, followed by a second electron transfer. 

As discussed in Section 10.4 of Part A, concerted suprafacial [2tt + 2tt] cycloadditions are forbidden by orbital symmetry rules. Two types of [2 + 2] cycloadditions are of synthetic value addition reactions of ketenes and photochemical additions. The latter group includes reactions of alkenes, dienes, enones, and carbonyl compounds, and these additions are discussed in the sections that follow. 

The mechanism of conjugate addition reactions probably involves an initial complex between the cuprate and enone.51 The key intermediate for formation of the new carbon-carbon bond is an adduct formed between the enone and the organocopper reagent. The adduct is formulated as a Cu(III) species, which then undergoes reductive elimination. The lithium ion also plays a key role, presumably by Lewis acid coordination at the carbonyl oxygen.52 Solvent molecules also affect the reactivity of the complex.53 The mechanism can be outlined as occurring in three steps. 

This finding is also in agreement with another three-component Michael/aldol addition reaction reported by Shibasaki and coworkers [14]. Here, as a catalyst the chiral AlLibis[(S)-binaphthoxide] complex (ALB) (2-37) was used. Such hetero-bimetallic compounds show both Bronsted basicity and Lewis acidity, and can catalyze aldol [15] and Michael/aldol [14, 16] processes. Reaction of cyclopentenone 2-29b, aldehyde 2-35, and dibenzyl methylmalonate (2-36) at r.t. in the presence of 5 mol% of 2-37 led to 3-hydroxy ketones 2-38 as a mixture of diastereomers in 84% yield. Transformation of 2-38 by a mesylation/elimination sequence afforded 2-39 with 92 % ee recrystallization gave enantiopure 2-39, which was used in the synthesis of ll-deoxy-PGFla (2-40) (Scheme 2.8). The transition states 2-41 and 2-42 illustrate the stereochemical result (Scheme 2.9). The coordination of the enone to the aluminum not only results in its activation, but also fixes its position for the Michael addition, as demonstrated in TS-2-41. It is of importance that the following aldol reaction of 2-42 is faster than a protonation of the enolate moiety. 

Reactions of highly electron-rich organometalate salts (organocuprates, orga-noborates, Grignard reagents, etc.) and metal hydrides (trialkyltin hydride, triethylsilane, borohydrides, etc.) with cyano-substituted olefins, enones, ketones, carbocations, pyridinium cations, etc. are conventionally formulated as nucleophilic addition reactions. We illustrate the utility of donor/acceptor association and electron-transfer below. 

Ferrocenyl-substituted allenyl cations 28 were generated when 1,3-diferrocenyl-substituted secondary and ferrocenyl-substituted tertiary alcohols 29 were treated with trifluoroacetic acid27. These were rapidly converted into trifluoroacetoxyallylic ions by solvent addition the ions gave ferrocenyl-substituted enones by reaction with water (equation 8). 

Dieter developed a flexible two step synthesis of substituted pyrroles involving initial Beak deprotonation of /ert-butoxycarbonyl (Boc) amines 36 followed by addition of CuX-2LiCl (X = -Cl, -CN) to afford a-aminoalkylcuprates. Such cuprates undergo conjugate addition reactions to a,(3-alkynyl ketones affording a,(3-enones 37, which upon treatment with PhOH/TMSCl undergo carbamate deprotection and intramolecular cyclization to afford the pyrroles 38 . 

The first example of asymmetric rhodium-catalyzed 1,4-addition of organoboron reagents to enones was described in 1998 by Hayashi and Miyaura. Significant progress has been made in the past few years. This asymmetric addition reaction can be carried out in aqueous solvent for a broad range of substrates, such as a,/ -unsaturated ketones, esters, amides, phosphonates, nitroalkenes. The enantioselectivity is always very high (in most cases over 90% ee). This asymmetric transformation provides the best method for the enantioselective introduction of aryl and alkenyl groups to the / -position of these electron-deficient olefins. 

Woodward and co-workers utilized [Gu(MeCN)4]BF4 and (A)-BINOL-derived thiourethane ligand 87 in the addition reaction of trimethylaluminum to acyclic enones. Both yields and enantioselectivities were moderate (Scheme 44).130... 

The application of organostannanes in rhodium-catalyzed 1,4-addition reactions was first studied by Oi and co-workers.137,137a The treatment of enones or enolates with a slight excess of aryltrimethylstannane and catalytic amounts of [Rh(COD)(MeCN)2]BF4 generates the conjugate addition products in good yields. The use of protic additives enhanced the yield of the reaction (Scheme 48).138... 

In the phosphonium salt synthesis, the addition reaction of tertiary phosphines to activated alkenes has been reported (Scheme 3). PPh3 is added to electron-deficient alkenes such as enones or enals at the p-position in the presence of acids.4 The reaction of styrenes with phosphine has recently been reported by Okuma, which gave Markovnikov adducts.5 Although no catalyzed reactions of... 

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