Rearrangement allylic sulfoxide

If our proposal that allylic sulfoxides rearrange reversibly to sulfenate esters is correct, then, if we make the sulfenate ester by another route, it too should rearrange to an allylic sulfoxide—and indeed it does. The sulfenate ester arising from reaction of allylic alcohols with PhSCl (phenylsulfenyl chloride) cannot be isolated instead, the allylic sulfoxide is obtained, usually in very good yield, and this method is often used to make allylic sulfoxides. 

Allyl Sulfoxide Rearrangements with a Stereogenic Center at C-l (1,3-Chirality Transfer)... 

Highly diastereoselective allylic sulfoxide rearrangements in larger ring systems were used in syntheses of the natural products ( + )-desmethylcytochalasin D34 and cadinanes35. 

The allylic sulfoxide rearrangement has been used for epimerization of allylic tertiary alcohols in sterically biased systems such as steroids and norbornanes. Racemic c do-2-vinylbicy-clo[2.2.1]heptan-2-ol, prepared by nucleophilic exo attack of vinylmagnesium bromide on... 

In the case of steroidal propargylic alcohols the first rearrangement produced a mixture of allenyl sulfoxides, epimeric at the sulfur atom, which reacted with an added nucleophile to produce substituted allylic sulfoxides. Rearrangement of the sulfoxide resulted in the exclusive formation of a-hydroxy derivatives. This reaction sequence has been applied in a synthesis of hydrocortisone acetate74 (Nu = OCH3) from androstene-3,17-dione and in a transformation of mesantrol75 (Nu = malonate) to a spirolactone. 

Like allyl sulfoxides, allylic selenoxides rearrange via a highly ordered five-membered transition state. The arguments, already presented for the allyl sulfoxide rearrangement (Section 4.11.2.1.2.), apply for the rationalization of the high E selectivity of double-bond formation. Table 7 shows some examples7,8,12-15 for the strong preference for E double bonds (see also reference 2, Table V-2, p 148). Trisubstituted (A)-allyl alcohols are also obtained from allyl selenides with a substituent at C-2 of the allylic moiety (entries 8-10)7,8. 

In 2002 the same author demonstrated the usefulness of this method in a rather demanding context including an intramolecular cycloaddition with an W-sulfinyl urea as a new type of N-sulfinyl dienophile (Scheme 60) [144]. As key steps in the total synthesis of freshwater cyanobacterial hepatotoxins, ( , )-diene 238 was transformed into N-sulfinyl urea 239 which immediately cycloadds intramolecularly yielding tricycle 240 as a single isomer in excellent yield. After reaction with phenylmagnesium bromide the intermediate allylic sulfoxide rearranges cleanly to diastereomerically pure allylic alcohol... 

The reaction is analogous to the allyl sulfenate-allyl sulfoxide rearrangement and is also known in the selenium case. ° As sulfur and selenium functionalities are conunon activating groups in organic synthesis, this highly stereocontrolled transformation can sometimes be very useful. 

Owing to the reversible nature of the allylic sulfenate/allylic sulfoxide interconversion, the stereochemical outcome of both processes is treated below in an integrated manner. However, before beginning the discussion of this subject it is important to point out that although the allylic sulfoxide-sulfenate rearrangement is reversible, and although the sulfenate ester is usually in low equilibrium concentration with the isomeric sulfoxide, desulfurization of the sulfenate by thiophilic interception using various nucleophiles, such as thiophenoxide or secondary amines, removes it from equilibrium, and provides a useful route to allylic alcohols (equation 11). 

One of the first uses of the allylic sulfoxide-sulfenate interconversion was made by Jones and coworkers64, who reported exclusive suprafacial rearrangement of the allyl group in the steroidal sulfoxide 17 shown in equation 13. Two other examples are shown in equations 1465 and 1566. Evans and coworkers have demonstrated the utility of the suprafacial allylic sulfoxide-sulfenate rearrangement in a new synthesis of the tetracyclic alcohol 24 (equation 16)67, as well as in a synthesis of prostaglandin intermediates as shown in equation 1768. The stereospecific rearrangement of the unstable sulfenate intermediate obtained from the cis diol 25 indicates the suprafacial nature of this process. 

In contrast to these results, a preference for rearrangement through an exo-transition state has been detected in the rearrangement of several cyclic allylic sulfoxides. For example, while sulfoxide 36 rearranged to alcohol 37 with 60% ee, introduction of bulky substituents at the (i position of the ring enhanced the optical purity to 90%, as a result of further destabilization of the endo conformation (equation 21)82,84. 

The data presented demonstrate that allylic sulfoxides can provide an easy and highly stereoselective route to allylic alcohols taking advantage of the facility of the allylic sulfoxide-sulfenate [2,3]-sigmatropic rearrangement. This is of considerable synthetic utility, since a number of stereoselective and useful transformations of allylic alcohols and their derivatives have become available in recent years107-109. 

In addition to the synthetic applications related to the stereoselective or stereospecific syntheses of various systems, especially natural products, described in the previous subsection, a number of general synthetic uses of the reversible [2,3]-sigmatropic rearrangement of allylic sulfoxides are presented below. Several investigators110-113 have employed the allylic sulfenate-to-sulfoxide equilibrium in combination with the syn elimination of the latter as a method for the synthesis of conjugated dienes. For example, Reich and coworkers110,111 have reported a detailed study on the conversion of allylic alcohols to 1,3-dienes by sequential sulfenate sulfoxide rearrangement and syn elimination of the sulfoxide. This method of mild and efficient 1,4-dehydration of allylic alcohols has also been shown to proceed with overall cis stereochemistry in cyclic systems, as illustrated by equation 25. The reaction of trans-46 proceeds almost instantaneously at room temperature, while that of the cis-alcohol is much slower. This method has been subsequently applied for the synthesis of several natural products, such as the stereoselective transformation of the allylic alcohol 48 into the sex pheromone of the Red Bollworm Moth (49)112 and the conversion of isocodeine (50) into 6-demethoxythebaine (51)113. 

Recently, a simple and general synthetic method for the preparation of N-alkylisothioazolidines involving [2,3]-sigmatropic rearrangement of appropriately substituted allylic sulfoxides to corresponding sulfenates, followed by intramolecular substitution of the latter, has been described (equation 28)126. 

Further examples of the utility of the allylic sulfoxide-sulfenate interconversion in the construction of various biologically active natural products include intermediates such as the /Miydroxy-a-methylene-y-butyrolactones (e.g. 63)128 and tetrahydrochromanone derivative 64129. Interestingly, the facility and efficiency of this rearrangement has also attracted attention beyond the conventional boundaries of organic chemistry. Thus, a study on mechanism-based enzyme inactivation using an allyl sulfoxide-sulfenate rearrangement has also been published130 131. 

Apparently, the first report of a double [2,3]-sigmatropic rearrangement of an allylic sulfoxide was published by Gaoni132. This author observed that the 1,4-pentadienyl... 

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