Allylic vinylic sulfoxides

A 45-fold increase in the rearrangement rates of allyl vinyl sulfoxides relative to the corresponding sulfides has been observed [235]. The transition state for the former compounds is more polar. 

Sulfoxides occur widely in small concentrations in plant and animal tissues, eg, allyl vinyl sulfoxide [81898-53-5] in garlic oil and 2,2 -sulfinylbisethanol [3085-45-8] as fatty esters in the adrenal cortex (1,2). Homologous methylsulfinylalkyl isothiocyanates, which are represented by the formula CH3SO(CH2)kNCS, where n = 3 [37791-20-1], 4 [4478-93-7], 5 [646-23-1], 8 [75272-81-0], 9 [39036-83-4], or 10 [39036-84-5], have been isolated from a number of mustard oils in which they occur as glucosides (3). Two methylsulfinyl amino acids have also been reported methionine sulfoxide [454-41-1] from cockroaches and the sulfoxide of JT-methylcysteine, 3-(methylsulfinyl)alanine [4740-94-7]. The latter is the dominant sulfur-containing amino acid in turnips and may account in part for their characteristic odor (4). 

To control the stereochemistry of 1,3-dipolar cycloaddition reactions, chiral auxiliaries are introduced into either the dipole-part or dipolarophile. A recent monograph covers this topic extensively 70 therefore, only typical examples are presented here. Alkenes employed in asymmetric 1,3-cycloaddition can be divided into three main groups (1) chiral allylic alcohols, (2) chiral amines, and (3) chiral vinyl sulfoxides or vinylphosphine oxides.63c... 

Entries 8-13 in Table 21.9 illustrate the effect of S-O coordination on the hydrogenation of allyl alcohols. The hydrogenation of (a-hydroxyalkyl)vinyl sul-fones follows the same stereochemical course as the corresponding acrylate via HO coordination (entries 8 and 9). However, the hydrogenation of (a-hydro-xyalkyl)vinyl sulfoxides is directed by S-O coordination, which overrides the HO-participation in the stereochemical course (entries 10-13) [56]. The directing power of S-O may be limited to vinylic examples, as compounds having the S-O and double bond in an allylic relationship failed to reduce under the standard conditions. 

For the addition of ethylene, EtOAc as solvent was particularly advantageous and gave 418 in 60% yield (Scheme 6.86). The monosubstituted ethylenes 1-hexene, vinylcyclohexane, allyltrimethylsilane, allyl alcohol, ethyl vinyl ether, vinyl acetate and N-vinyl-2-pyrrolidone furnished [2 + 2]-cycloadducts of the type 419 in yields of 54—100%. Mixtures of [2 + 2]-cycloadducts of the types 419 and 420 were formed with vinylcyclopropane, styrene and derivatives substituted at the phenyl group, acrylonitrile, methyl acrylate and phenyl vinyl thioether (yields of 56-76%), in which the diastereomers 419 predominated up to a ratio of 2.5 1 except in the case of the styrenes, where this ratio was 1 1. The Hammett p value for the addition of the styrenes to 417 turned out to be -0.54, suggesting that there is little charge separation in the transition state [155]. In the case of 6, the p value was determined as +0.79 (see Section 6.3.1) and indicates a slight polarization in the opposite direction. This astounding variety of substrates for 417 is contrasted by only a few monosubstituted ethylenes whose addition products with 417 could not be observed or were formed in only small amounts phenyl vinyl ether, vinyl bromide, (perfluorobutyl)-ethylene, phenyl vinyl sulfoxide and sulfone, methyl vinyl ketone and the vinylpyri-dines. 

The absence of a-alkylated allylic sulfoxides or the corresponding 2,3-sigmatropically rearranged allylic alcohols as well as of y-alkylated vinylic sulfoxides supports the intermediacy of a vinylic rather than an allylic lithium species. 

Bromination of the enol ether product with two equivalents of bromine followed by dehydrobromination afforded the Z-bromoenol ether (Eq. 79) which could be converted to the zinc reagent and cross-coupled with aryl halides [242]. Dehydrobromination in the presence of thiophenol followed by bromination/dehydrobromination affords an enol thioether [243]. Oxidation to the sulfone, followed by exposure to triethylamine in ether, resulted in dehydrobromination to the unstable alkynyl sulfone which could be trapped with dienes in situ. Alternatively, dehydrobromination of the sulfide in the presence of allylic alcohols results in the formation of allyl vinyl ethers which undergo Claisen rearrangements [244]. Further oxidation followed by sulfoxide elimination results in highly unsaturated trifluoromethyl ketonic products (Eq. 80). 

Copper-mediated 5n2 displacement of enantiomerically pure allylic mesyloxy vinyl sulfoxides occurs with high yields and stereoselectivities.11 The 5n2 reactions of structurally related mesyloxy sulfides and sulfones with organocuprates have also been examined. 

It has been reported that treatment of methyl 1-methylsulfanylvinyl sulfoxides with sodium thiophenolate in methanol affords l-methylsulfanylalk-l-en-3-ols. A sequence has been proposed218 (see Scheme 45) in which the thiophilic base first causes an in situ isomerization of the vinyl sulfoxide moiety into an allylic sulfoxide which then undergoes a [2,3]-sigmatropic rearrangement and subsequent thiophilic cleavage of the intermediate sulfenic ester. 

Michael-aldol reaction as an alternative to the Morita-Baylis-Hillman reaction 14 recent results in conjugate addition of nitroalkanes to electron-poor alkenes 15 asymmetric cyclopropanation of chiral (l-phosphoryl)vinyl sulfoxides 16 synthetic methodology using tertiary phosphines as nucleophilic catalysts in combination with allenoates or 2-alkynoates 17 recent advances in the transition metal-catalysed asymmetric hydrosilylation of ketones, imines, and electrophilic C=C bonds 18 Michael additions catalysed by transition metals and lanthanide species 19 recent progress in asymmetric organocatalysis, including the aldol reaction, Mannich reaction, Michael addition, cycloadditions, allylation, epoxidation, and phase-transfer catalysis 20 and nucleophilic phosphine organocatalysis.21... 

Addition to allylic mesylates.6 Conjugate addition of organocyanocuprates to acyclic allylic mesylates substituted at the P-position with a chiral sulfoxide group involves an SN2 -substitution with high Z/E stereoselectivity and high asymmetric induction. This reaction provides a route to chiral trisubstituted vinyl sulfoxides. 

Reactions of 3,5-dichloro-2,4,6-trimethyl benzonitrile oxide 241 with fluoro-methyl substituted alkenes 242, bearing a chiral sulfinyl group at -position of the double bond, afford diastereoisomeric 4,5-dihydroisoxazoles 243 and 244 [180] with a stereoselectivity lower than 2 1 (Scheme 110). The authors conclude that the efficiency of allyl sulfoxides to control diastereoselectivity of 1,3-dipolar cycloadditions with nitrile oxides is lower than that of vinyl sulfoxides. 

Along the same lines, the influence of the sulfinyl group on a sigmatrop-ic shift, Hwu and Anderson [204] have reported on the kinetics of an allyl vinyl sulfide and its analogous sulfoxide. They have observed a 45-fold... 

Acyclic stereocontrol remains a challenging problem in synthesis. While enan-tiomerically pure sulfoxides are valuable synthetic intermediates for enantiocon-trolled carbon-carbon bond formation by conjugate addition in cyclic cases, their usefulness for such alkylations in acyclic cases has not been firmly established. Moreover, most sulfoxide directed alkylation protocols utilize the valuable sulfur auxiliary just once, which limits the synthetic versatility of the process. Marino et al. have recently reported SN2 displacements of acyclic allylic mesyloxy vinyl sulfoxides with organocopper reagents (Scheme 10).33 In addition to the excellent observed stereoselectivities, the newly created chiral center is adjacent to a vinyl sulfoxide which should allow for subsequent chirality transfer operations. On treatment with organocopper nucleophiles, both sulfoxide diastereoisomers 40b and 43b underwent SN2 displacements with high Z selectivity to yield products 42b and 45b, respectively (Table 2). The oxidation state on the sulfur was varied... 

Asymmetric synthesis of a chroman. Solladie and Moine have effected an en-antiospecific synthesis of the chroman-2-carboxaldehyde 7, a key intermediate in the synthesis of a-tocopherol, from (R)-( +)-l. The phosphonate 2, derived from 1, undergoes a Wittig-Horner reaction with the dimethyl ketal of pyruvaldehyde to afford the optically active vinyl sulfoxide 3. Condensation of the aldehyde 4 with the lithio derivative of 3 affords, after silyl deprotection, the allylic alcohol 5 as the only diastereoisomer. This... 

The sulfoxide moiety is an excellent anion stabilizing group, i.e., allyl sulfoxides or vinyl sulfoxides with a hydrogen in a y-position are easily deprotonated (see Section D. 1.1.1.5.3.). Therefore, a-substituted allylic sulfoxides can either be obtained by alkylation of an unsubstituted allylic sulfoxide or by deprotonation-a-protonation of vinyl sulfoxides. 

As a means to generate allylic sulfoxides, the isomerization of vinyl sulfoxides was foimd to be an interesting alternative. As an example featuring this method, its application in efforts directed toward the total synthesis of gua-nacastepene A will be presented (Scheme 51) [ 125]. 

In a recent pubhcation the nitrile (EWG = CN) variant [ 126] of this chemistry was performed in water by applying N,N-diethylaminopropylated sihca gel as heterogeneous catalyst [ 128]. Another variant of this reaction sequence, leading to chiral sulfinylated enones, has been developed by Llera [ 129] employing the enantiomerically pure geminal bis(sulfoxide) 208 (Scheme 54). This bis(sulfoxide) was prepared from (-)-p-toluenesulfinic acid menthyl ester [100], as described by Kunieda [130]. Later this procedure was improved to increase the yield from 35 to 91% [13,131]. Treatment of 208 with enolizable aldehydes or ketones, in the presence of piperidine as a base and thiophile, initiated a reaction cascade involving a condensation step (to 210), a proton shift to allylic sulfoxide 211, and a [2,3]-0-shift followed by a piperidine-mediated desulfuration delivering the alcohols 212 as isomeric mixtures. Oxidation of the latter compounds (one of the R = H) led to enantiomerically pure E-y-oxo vinyl sulfoxides 213. 

The addition of an allyl alcohol to racemic allenyl sulfoxides results in vinyl ethers with the sulfinyl moiety at C-1 that undergo sigmatropic rearrangements upon distillation to produce 2,4-dienones after ehmination of sulfenic acid. In one example, an isomeric vinyl ether was obtained with a sulfinyl methyl substituent at C-2 that gave rise to a sulfinyl enone upon rearrangement [138]. In related work, the addition-elimination of an allyl alkoxide to a functionalized vinyl sulfoxide results in a sulfinyl enol ether that rearranges with loss of sulfenic acid to the unsaturated ester [139-141] (Scheme 21). 

---