Intramolecular Additions to Cyclopentenones

1 Intramolecular Additions to Cyclopentenones - Irradiation (k 350 nm in THF) of the enone (46) affords a single diastereoisomer identified as (47, 95%). The outcome of the reaction does not seem to be solvent dependent and the same degree of success is obtained with methylene chloride, acetonitrile or methanol as solvents. The corresponding amide also cyclizes efficiently. Crimmins and coworkers have demonstrated that irradiation (X 350 nm) of the enone (48) results in cycloaddition and the formation of the diastereoisomeric adducts (49) and (50) in a ratio of 83 17. A single product (51) is obtained on irradiation of the related enone (52). These adducts are key intermediates in a synthesis of some spirovetivanes. 

The photochemical reactivity of the diastereoisomeric compounds (53) and (54) has been studied. The irradiation of the individual compounds, using perdeuter-ated acetone as the sensitizer, results in the conversion into the cycloadducts (55) and (56), respectively. Direct irradiation of (54), however, affords a mixture of the two cycloadducts while direct irradiation of (53) affords only the cycloadduct 

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Intramolecular Additions to Cyclopentenones and Related Systems. The unsaturated lactones shown in Scheme 5 can undergo photocycloadditions... 

Racemic diquinane enone rac-6 was prepared by Piers and Orellana starting from cyclopentenone (Scheme 6) [11]. After the preparation of the heterocuprate from stannane 20, conjugate addition to cyclopentenone in the presence of BF3 Et20 provided carbonyl compound 21. It was expected that conversion of 21 by intramolecular alkylation and subsequent hydrogenation should provide the desired endo-substituted diquinane rac-13. While other hydrogenation methods proved to be rather unselective, reduction in the presence of Wilkinson s catalyst finally resulted in the formation of rac-13 with good facial diastereoselectivity [11]. 

An intramolecular version of enolate Michael addition to enantiomerically pure vinylic sulfoxides is represented by reaction of a cyclopentenone sulfoxide with dichloroketene (Scheme 5)90 this type of additive Pummerer rearrangement has been developed by Marino and coworkers91 into a highly effective way of constructing variously substituted lactones in very high enantiomeric purity (equation 43). 

In addition to intermolecular cyclization products, Pau-son-Khand reactions can also occur intramolecularly see Intramolecular) to give cyclopentenones. One example of this is the conversion of a cyclic ketone into a functionalized polycyclic system (equation 15). ... 

Ester enolates. Oppolzer showed in 1983 that the Z(Gj-dienolate shown in Scheme 5.30a adds to cyclopentenone with 63% diastereoselectivity [160]. Additionally, the enolate adduct can be allylated selectively, thereby affording (after purification) a single stereoisomer having three contiguous stereocenters in 48% yield. The transition structure illustrated is not analogous to any of those illustrated in Scheme 5.29 because cyclopentenone is an s-trans-Z-enone, whereas the enones in Scheme 5.29 are s-cis-E. In 1985, Corey reported the asymmetric Michael addition of the EfOj-enolate of phenylmenthone propionate to -methyl crotonate as shown in Scheme 5.30b [161]. The product mixture was 90% syn, and the syn adducts were produced in a 95 5 ratio, for an overall selectivity of 86% for the illustrated isomer. The transition structure proposed by the authors to account for the observed selectivity is similar to that shown in Scheme 5.29c, but with the enone illustrated in an s-trans conformation. Intramolecular variations of these reactions were reported by Stork in 1986, as illustrated in Scheme 5.30c and 5.29d [162]. Two features of... 

Whatever the exact mechanism of the conjugate-addition reaction, it seems clear that enolate anions are formed as intermediates and they can be trapped as the silyl enol ether or alkylated with various electrophiles. For example, addition of lithium methylvinyl cuprate (a mixed-cuprate reagent) to cyclopentenone generates the intermediate enolate 166, that can be alkylated with allyl bromide to give the product 167 (1.161). The trans product often predominates, although the transxis ratio depends on the nature of the substrate, the alkyl groups and the conditions and it is possible to obtain the cis isomer as the major product. Examples of intramolecular trapping of the enolate are known, as illustrated in the formation of the ds-decalone 168, an intermediate in the synthesis of the sesquiterpene valerane (1.162). 

Conjugate intramolecular addition of nucleophiles to dienyl diketones can follow two pathways anionic or easily deprotonated nucleophiles in the presence of pyrrolidine afford cyclopentenones while the neutral nucleophile l,4-diazabicyclo[2.2.2]octane (DABCO) promoted a 6n electrocycli-zation to give 2E/-pyrans (Scheme 1) (14JOC10296). 

Intramolecular hydroacylation of 4-aIkenals is a well-established method for producing cyclopentanones in which a C=C bond inserts into the Rh hydride formed by C-H oxidative addition to Rh(I) with chiral ligands and suitable alkenal substrates, useful asymmetric induction is possible. Extension to cyclopentenone synthesis requires a trans addition of Rh—H across the alkyne (see Section 7.2). ... 

The reactions of the lithium enolates of substituted 2-cyclohexenones and 2-cyclopentenones with ( )-l-nitropropene give a mixture of syn- and ami-products3. The lithium enolate of 3,5,5-trimethyl-2-cyclohexenone gives a mixture of the syn- and //-3.5,5-trimethyl-6-(l-methyl-2-nitroethyl)-2-cyclohexcnoncs in modest diastereoselection when the reaction mixture is quenched with acetic acid after. 30 minutes at —78 =C. When the reaction mixture is heated to reflux, tricyclic products are obtained resulting from intramolecular Michael addition of the intermediate nitronate ion to the enone moiety. 

Another example of a [4S+1C] cycloaddition process is found in the reaction of alkenylcarbene complexes and lithium enolates derived from alkynyl methyl ketones. In Sect. 2.6.4.9 it was described how, in general, lithium enolates react with alkenylcarbene complexes to produce [3C+2S] cycloadducts. However, when the reaction is performed using lithium enolates derived from alkynyl methyl ketones and the temperature is raised to 65 °C, a new formal [4s+lcj cy-clopentenone derivative is formed [79] (Scheme 38). The mechanism proposed for this transformation supposes the formation of the [3C+2S] cycloadducts as depicted in Scheme 32 (see Sect. 2.6.4.9). This intermediate evolves through a retro-aldol-type reaction followed by an intramolecular Michael addition of the allyllithium to the ynone moiety to give the final cyclopentenone derivatives after hydrolysis. The role of the pentacarbonyltungsten fragment seems to be crucial for the outcome of this reaction, as experiments carried out with isolated intermediates in the absence of tungsten complexes do not afford the [4S+1C] cycloadducts (Scheme 38). 

The addition of the 2-substituted 2-cyclopentenone in (4.57) to ethylene affords an intermediate which is converted to tricyclo[4.2.0.01,4]octane 469a). A similar broken window compound was also obtained by an intramolecular photocycloaddition of a 2-cyclopentenone (4.58)469b). 

Stang etal. (94JA93) have developed another alkynyliodonium salt mediated approach for the synthesis of y-lactams including bicyclic systems containing the pyrrole moiety. This method is based on the formation of 2-cyclopentenones 114 via intramolecular 1,5-carbon-hydrogen insertion reactions of [/3-(p-toluenesulfonyl)alkylidene]carbenes 113 derived from Michael addition of sodium p-toluenesulfinate to /3-ketoethynyl(phenyl) iodonium triflates 112 (Scheme 32). Replacing 112 by j8-amidoethynyl (phenyl)iodonium triflates 115-119 provides various y-lactams as outlined in Eqs. (26)-(30). 

However, from the outset of this field, the limitations as well as the potentials of this cycloaddition were also apparent. For instance, the efficiency of this cycloaddition in an intermolecular manner was typically low unless strained olefins were used. Moreover, the use of unsymmetrical alkenes led to a mixture of the cyclopentenone regioisomers. Synthetic utility of this reaction is considerably expanded by the emergency of the intramolecular reaction. Schore introduced the first intramolecular version forming several rings simultaneously, which is now the most popular synthetic strategy in natural product synthesis because of its conceptual and operational simplicity. Additionally, the regiochemistry is no longer the problem in this variation. 

The chiral organocopper compound (186) adds diastereoselectively to 2-methyl-2-cyclopentenone, allowing the preparation of optically active steroid CD-ring building blocks (Scheme 68).202-204 A related method was applied to a synthesis of the steroid skeleton via an intramolecular (transannular) Diels-Alder reaction of a macrocyclic precursor.203 Chiral acetone anion equivalents based on copper azaeno-lates derived from acetone imines were shown to add to cyclic enones with good selectivity (60-80% ee, after hydrolysis).206-208 Even better ee values are obtained with the mixed zincate prepared from (187) and dimethylzinc (Scheme 69). Other highly diastereoselective but synthetically less important 1,4-additions of chiral cuprates to prochiral enones were reported.209-210... 

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