Carbonyl, addition transposition

Allylic derivatives are particularly important in the case of boranes, silanes, and stannanes. Allylic boranes effect nucleophilic addition to carbonyl groups via a cyclic TS that involves the Lewis acid character of the borane. 1,3-Allylic transposition occurs through the cyclic TS. 

Ikegami has devised an interesting approach based upon 1,3-cyclooctadiene monoepoxide as starting material (Scheme LX) Transannular cyclization, Sharpless epoxidation, and silylation leads to 638 which is opened with reasonable regioselec-tivity upon reaction with l,3-bis(methylthio)allyllithium. Once aldehyde 639 had been accessed, -amyllithium addition was found to be stereoselective, perhaps because of the location of the te -butyldimethylsilyloxy group. Nevertheless, 640 is ultimately produced in low overall yield. This situation is rectified in part by the initial formation of 641 and eventual decarboxylative elimination of 642 to arrive at 643. An additional improvement has appeared in the form of a 1,2-carbonyl transposition sequence which successfully transforms 641 into 644... 

A recently published full account of another synthesis [69] of the same alkaloid starting from the /rans-cinnamic ester 264 represented a different approach (ACD -> ACDB) to ( )-lycorine (Scheme 42). An intramolecular Diels-Alder reaction of 264 in o-dichlorobenzene furnished the two diastereomeric lactones 265 (86%) and 266 (5%) involving the endo and exo modes of addition respectively. The transposition of the carbonyl group of 265 to 267 was achieved by reduction with lithium aluminium hydride, followed by treatment of the resulting diol with Fetizon s reagent, which selectively oxidised the less substituted alcohol to give isomeric 5-lactone 267. On exposure to iodine in alkaline medium 267 underwent iodolactonisation to afford the iodo-hydroxy y-lactone 268. The derived tetrahydropyranyl ether... 

Nucleophilic addition to a,P-epoxysilanes is part of a reaction sequence which has been used to effect 1,2-transposition of carbonyl groups (Figure Si5.14). 

Carbonyl transposition.1 Tetrafluoroboric acid is the most effective acid for rearrangement of a-hydroxy ketene dithioketals to a,p-unsaturated thiol esters. This rearrangement is particularly useful for rearrangement of the tertiary allylic alcohols formed by addition of organometallic reagents to a-keto ketene dithioketals, which are readily available by reaction of ketone enolates with carbon disulfide followed by alkylation with methyl iodide. 

A carbonyl transposition can be effected via the addition of a vinyl or an alkyl Grignard reagent to an a, 3-unsaturated ketone. Acid-catalyzed rearrangement of the resultant allylic alcohol during oxidation with PCC affords the transposed a,(3-unsaturated carbonyl substrate. This reaction represents a useful alternative when Wittig olefination of the ketone is problematic. 

These examples again have some mechanistic implications in that they appear to rule out cyclization via 5n2 displacement of the halide by a samarium ketyl. However, one cannot distinguish between a mechanism based on allylsamarium addition to the carbonyl versus an electron transfer mechanism as outlined for the alkyl hdide substrates above. Both mechanisms allow for isomerization of the double bond (via 1,3-allylic transposition in the case of an allylmetallic, or configurational instability in an allylic radical in a diradical coupling mechanism) and also provide reasonable routes for generation of butadiene. Further mechanistic work is clearly required in order to provide a more detailed understanding of all of these intramolecular Barbier-type reactions. 

Scheme 8 shows the synthesis of 1 3-dialkylated cyclohexenes from 2-cyclohexenones consisting of 1 4-addition of organo-cupratesy enol phosphorylation and the final alkylation of the sp2 carbon. Scheme 9 provides a novel addition to the technique of 1 2-transposition of a carbonyl moiety accompanied by alkylation in tandem (15). The desulfurization is best performed by Mukaiyama s TiCl4 method (16). 

The a-alkylation of sulfonylhydrazone dianions with disulfides followed by Shapiro reaction has been used to effect the 1,2-transposition of carbonyl groups.19,20 As shown below, treatment of tosylhydrazone 31 with n-BuLi/TMEDA followed by addition of dimethyl disulfide and deprotonation with an additional equivalent of w-BuLi provided vinylsulfide 32.19 Exposure of this compound to mercuric chloride in hot aqueous acetonitrile provided ketone 33 in 75% overall yield. 

Trialkylstannyl-lithium reacts with secondary alkyl halides (substitution) and with a/S-unsaturated carbonyl compounds (conjugate addition) to give alkyl tin derivatives which may be oxidized with chromic anhydride in pyridine to give a saturated ketone. Applying the procedure to a cycloalkenone, an efficient dialkyl-ative enone transposition can be realized (Scheme 68). ... 

Carbonyl Equivalents.—The cyclopropane (17) acts as a linear three-carbon aldehyde equivalent. Addition to ketones and aldehydes, followed by cleavage of the cyclopropane ring with concomitant 1,2-transposition of the oxygen atom, gives /3-sulphido-ketones (18) in 45—70% yields. ... 

Addition of Grignards to the carbonyl group of )3-keto phosphonates gives fi-hydroxyphosphonates with an extended carbon skeleton.Allylmagnesiums add especially with BE3 catalysis, while allylzincs often give higher yields, even without a Lewis acid. AUyllc transpositions follow reactions with crotyl and prenyl organometaUics. 

Several new syntheses of vinylsilanes have been described. Tris(trimethyl-silyl)aluminium undergoes 5yn-addition to alkynes alternatively the same -isomers can be obtained by photochemical isomerisation of Z-1-alkenyl-silanes. Other methods described involve treatment of the lithium salts of hydrazones with trimethylsilyl chloride, Wurtz-type coupling with vinyl bromides, and reaction of acetylenes with a silyl-copper reagent followed by an electrophile. Using the hydrazone method, a route has been devised for 1,2-carbonyl transposition within ketones (Scheme 17). ... 

The first syntheses of dendralenes by C2-C3 bond formation (Scheme 1.25) were reported by Tsuge and coworkers in 1985 and 1986, and proceed via substitution at either a bromide 160 or an epoxide 163, followed by elimination (Scheme 1.26) [116, 117]. Similar addition/elimination sequences to carbonyl groups or epoxides [120], and substitution reactions [121], followed. Such methods have been superseded by cross-coupling techniques that take place between a 2-functionalized 1,3-butadiene and an alkene (each can be either electrophilic or nucleophilic) or a 4-functionalized 1,2-butadiene and alkene, and occur with allylic transposition (Scheme 1.25). No doubt due to the ready availability of alkenyl halides and allenes, and the variety of increasingly mild and selective reaction variants, cross-coupling has provided access to a large number of diversely substituted dendralenes over the past 20 years, some of which have even been part of natural product syntheses [14,122,123]. 

Another way to circumvent the stereoselectivity issues that may arise from olefination or addition/elimination sequences to l,4-dien-3-ones is to switch the polarity of components and olefinate a carbonyl compound with a symmetrical nucleophilic pentadienyl anion equivalent. A seminal contribution was reported by Paul and Tchelitcheff in 1951, who combined trivinylmethane (235) and carbon dioxide to form a [3]dendralene 237 (Scheme 1.40 (a)) [190]. In this instance, the anion of trivinyl methane 236 is indeed a pentadienyl anion, but bond formation occurs with allylic transposition through a vinyl unit. 

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