Cyclopentene, oxidative cycloaddition

A number of examples involving nitrile oxide cycloadditions to cyclic cis-disubstituted olefinic dipolarophiles was presented in the first edition of this treatise, notably to cyclobutene, cyclopentene, and to 2,5-dihydrofuran derivatives (15). The more recent examples discussed here also show, that the selectivity of the cycloaddition to 1,2-cis-disubstituted cyclobutenes depends on the type of substituent group present (Table 6.8 Scheme 6.41). The differences found can be explained in terms of the nonplanarity (i. e., pyramidalization) of the double bond in the transition state (15) and steric effects. In the cycloaddition to cis-3,4-diacetyl-(197) and cis-3,4-dichlorocyclobutene (198), the syn-pyramidalization of the carbon atoms of the double bond and the more facile anti deformability of the olefinic hydrogens have been invoked to rationalize the anti selectivity observed. 

Utilizing an alternate mode of Diels-Alder reactivity, Harman has examined the cycloaddition reactions of 4,5-T -Os(II)pentaammine-3-vinylpyrrole complexes with suitably activated dienophiles <96JA7117>. For instance, cycloaddition of the p-vinylpyrrole complex 58 with 4-cyclopentene-l,3-dione, followed by DDQ oxidation affords 59, possessing the fused-ring indole skeleton of the marine cytotoxic agent, herbindole B. 

The synthesis of new 11-deoxyprostaglandin analogs with a cyclopentane fragment in the oo-chain, prostanoid 418, has been accomplished by a reaction sequence involving nitrile oxide generation from the nitromethyl derivative of 2-(oo-carbomethoxyhexyl)-2-cyclopenten-l-one, its 1,3-cycloaddition to cyclopenten-l-one and reductive transformations of these cycloadducts (459). Diastereoisomers of a new prostanoid precursor 419 with a 4,5,6,6a-tetrahydro-3aH-cyclopent[d isoxazole fragment in the oo-chain have been synthesized. Reduction of 419 gives novel 11-deoxyprostanoids with modified a- and oo-chains (460). 

A total synthesis of the sesquiterpene ( )-illudin C 420 has been described. The tricyclic ring system of the natural product is readily quickly assembled from cyclopropane and cyclopentene precursors via a novel oxime dianion coupling reaction and a subsequent intramolecular nitrile oxide—olefin cycloaddition (463). 

Finally, the LDA deprotonation of amine N-oxides has been reported to generate azomethine ylides that can be trapped in [2 + 3] cycloadditions with simple alkenes.126 For example, N-methylpyrrolidine N-oxide (137) reacts with LDA in the presence of cyclopentene to give adduct (139 Scheme 31). A variety of other N-oxides behave similarly. Interestingly, there are no examples published to date where nonstabilized azomethine ylides generated by the desilylation procedure can be trapped by simple, unactivated alkenes. It is not clear whether these discrepancies are due to some fundamental difference in the reactive intermediate being generated, or whether the differences in environment are responsible for differing behavior. Further work is needed to establish this point. 

Enantioselective total syntheses of (-)-6-epitrehazolin and (+)-trehazolin were achieved by the synthesis of 275, which began with an asymmetric heterocycloaddition between [(benzyloxy)methyl]cyclopentadiene (263),108 prepared from thallous cyclopentadienide, and the acylnitroso compound arising from in situ oxidation of (,S )-mandelohydroxamic acid (264) with tetrabutylammonium periodate. Cycloaddition led to a mixture of 265 and its diastereomer (Scheme 35).109 The inseparable mixture was reduced to afford cyclopentenes 266 and 268 in 40% and 11 % overall yields, respectively, from thallous cyclopentadienide. Catalytic osmylation of 266 favored syn addition, while the osmylation of diacetate 267 was more selective and nearly quantitative, affording, after acetylation, compounds 270 and 269 in >5 1 ratio. 

The first synthesis of this compound to be completed was the result of studies by Smith and co-workers in 1982. The readily available flavor constituent cyclotene (368) (Scheme 2.28) was reduced and isomerized to 2-methyl-2-cyclopenten-l-one (369) in 64% yield. Addition of dimethyl cuprate followed by isomerization and Baeyer-Villiger oxidation gave the racemic 8-lactone 370 (86%). Addition of allyl Grignard reagent followed by formation of the methyl ketal provided a 71% yield of 371, which possesses the expected axial methoxy group. Conversion of the terminal olefin into the functionalized isoxazoline 373 was accomplished in 68% by the 1,3 dipolar cycloaddition of nitrile oxide 372. 

In addition to the trihalo compounds, many other 1,2,4-triazines have been found to react with cyclopentene, cyclohexene, cycloheptene and cyclooctene to give condensed pyridines. In most cases, 1,4-benzoquinone is added to oxidize the initially formed dihydropyridines and to prevent a second [4 I 2] cycloaddition.386 Other 1,2,4-triazines also react with bicyclo[2.2.1]hept-2-ene to give either the condensed pyridines and/or the bisadducts. The ratio of the two products depends on the reaction conditions and the relative proportions of the reactants.386 For a detailed survey, see Houben-Weyl, Vol. E7b, p471ff. 

Silyl nitronates 156, generated from a-halonitro compounds 155, undergo cycloaddition with a variety of olefins 157 such as styrene, acrylate, nor-bornene, cyclopentene etc to afford isoxazoline W-oxides 159 in good to high... 

VCPs have served as valuable five-carbon components in various cycloaddition reactions. Usually, they form six-membered metallacycles upon oxidative cycliza-tion with transition metals. Then, migratory insertion of unsaturated molecules, followed by reductive elimination, furnishes the carbocycles. In particular, intermolecular [5-1-2] annulation of VCPs with alkynes, alkenes, and allenes has been studied extensively (Scheme 2.39) [57]. In addition, VCP-cyclopentene rearrangement has been well documented [56 ]. 

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