Sakurai-Hosomi addition

A-Acyl aldimines undergo Hosomi-Sakurai addition of allyltrimethylsilane in up to 98% ee, using chiral Brpnsted acid catalysis. iyn-Diastereoselective crotylations are 0 also reported. 0... 

Allylation of aldehydes or ketones using allylsilanes, known as the Hosomi-Sakurai reaction, is a useful method for obtaining homoallylic alcohols. TiIV compounds have been successfully applied to this reaction (Scheme 21) 80 Besides aldehydes and ketones, acylsilanes, 0,0-acetals, and A-,(7-acetals can be employed.81-83 1,4-Addition of an allyl group to an a,/ -unsaturated ketone has been also reported.84... 

Lewis acid-mediated addition of allylsilanes to carbon nucleophiles. Also known as the Hosomi-Sakurai reaction. The allylsilane will add to the carbonyl compound directly if it is not part of an a,P-unsaturated system (Example 2), giving rise to an alcohol. 

The Hosomi-Sakurai reaction is a powerful method for conjugate allylation of a,fi-unsaturated ketones [425], In the presence of TiCl4 the allylation occurs smoothly at the y-position of allylsilanes and the / -position of a, -unsaturated ketones. This highly regioselective process has been widely used for introduction of functionalized carbon chains and construction of carbocycles in natural product synthesis [6, 426]. When TBAF is used as catalyst, both conjugate addition and 1,2-addition occur competitively [333]. The fluoride ion-catalyzed procedure is, however, effec-... 

The intramolecular version of the Lewis-acid-promoted conjugate addition of allylsilanes to a,/ -unsaturated ketones (Hosomi-Sakurai reaction) has... 

Leighton s synthetic strategy is shown in Scheme 43. Side chain 200 was introduced by the Still-modified (Z)-selective Honer-Emmons reaction forming the C2 -C3 double bond. Macrolactonization leading to 201 was carried out by using the Yamaguchi procedure, and C17 asymmetric carbon was constructed by alkenylzinc addition to an aldehyde in 202. The 2,6-trans-tetrahyderopyran was synthesized by the Hosomi-Sakurai reaction to a lactol. 

The synthetic strategy is based on Yamaguchi macrolactonization, metal alkynylide addition at C17, Mukaiyama-aldol Prins reaction of vinyl ether 219 with aldehyde 218 forming 2,6-d5-tetrahydropyran, Hosomi-Sakurai reaction giving 2,6-tran5-tetrahydropyran, asymmetric center formation via Myers alkylation at C12 and Noyori reduction at C15 and C3 (Scheme 47). 

In 2001, Rychnovsky and co-workers completed the synthesis of the leucascandrolide macrolactone. The key features of the Rychnovsky s synthesis are the Mukayama aldol-Prins cascade reaction of alkyl enol ether with the aldehyde forming 2,6-cij-tetrahydropyran, and Hosomi-Sakurai allysilane addition to generate 2,6-tranj-tetrahydropyran (Schemes 2.12, 2.13). 

Conventional synthetic schemes to produce 1,6-disubstituted products, e.g. reaction of a - with d -synthons, are largely unsuccessful. An exception is the following reaction, which provides a useful alternative when Michael type additions fail, e. g., at angular or other tertiary carbon atoms. In such cases the addition of allylsilanes catalyzed by titanium tetrachloride, the Sakurai reaction, is most appropriate (A. Hosomi, 1977). Isomerization of the double bond with bis(benzonitrile-N)dichloropalladium gives the y-double bond in excellent yield. Subsequent ozonolysis provides a pathway to 1,4-dicarbonyl compounds. Thus 1,6-, 1,5- and 1,4-difunctional compounds are accessible by this reaction. 

Almost 15 years ago Sakurai and Hosomi, in pioneering work, showed that intermolecular addition of an allylsilane to a,j6-unsaturated ketones in the presence of titanium(IV) chloride as the Lewis acid gave the desired 1,4-addition products1 4. In the case of 4,4a,5,6,7,8-hexahy-dro-2(3//)-naphthalenone, reaction was shown to proceed by 1,4-addition with exclusive production of the ris-fused product in high chemical yield. 

Since allylsilane can be considered as a very soft nucleophile because of the involvement of o-7i conjugation between the -electrons of the double bond and the o-electrons in the carbon-silicon bond, the addition of allylsilanes to ,/3-unsaturated enone moiety occurs exclusively via 1,4-addition19,20. A typical Sakurai-Hosomi reaction is illustrated in the reaction of allylsilane 66 with enone 67 in the presence of TiCU to give 68 which is used for the synthesis of a cyclic enediyne (equation 45)108. A similar reaction has been used for the synthesis of ewf-herbasolide 70 from enone 69 (equation 46)109. Prenylsilane undergoes 1,4-addition with squaric acid chloride 71 followed by dechlorosilylation to give 72 as the predominant product (equation 47). Interestingly, other simple allylsilanes react in a 1,2-addition fashion to yield 73110. 

Benzaldehyde (entry 3) and the hindered iso-butyraldehyde (entry 2) give the lowest yields. Sakurai and Hosomi next extended the addition of allylsilane 1 to enones 8 [7]. In the presence of TiCU, the 1,4-adduct 9 is obtained in good yields (Scheme 13.3). It is interesting to note that allylcuprates are less selective than allylsilanes and that / ,/ -disubstituted enones react efficiently, leading to ketones bearing a quaternary carbon center at the / position (entry 3). 

Most desirable, however, would be chiral catalysts for the addition of the more readily available and less toxic allyl silanes, but so far the efforts towards an enantioselective variant of the Sakurai-Hosomi reaction have been less successful. Some time ago Ketter and Herrmann [3a] obtained 24 % ee for the addition of allyl silane to aldehydes catalyzed by the dichlorotitanate 1. 

Better results (80 % ee) have been reported by Mikami, Nakai and co-workers [3c] for the addition of crotyl silane also catalyzed by complex 1. Yamamoto and co-workers [3b] used chiral acyl-oxy boranes to catalyze the Sakurai-Hosomi-reac-tion. While an excellent 96 % ee was obtained for the addition of 2,3 -disubstituted allyl groups, the conversion with parent allyl silane was low (46 %) and the asymmetric induction mediocre (55 % ee). Gauthier and Carreira [5] then made a big leap forward by using the difluorotita-nium-binaphthol complex 3. The catalyst 3 is prepared in situ via the TiF4-binaphthol adduct 4 and formal HF elimination mediated by allyl silane 5. The addition of 5 to aldehydes 6 ( 7) catalyzed by 10 % of 3 proceeds with 61 - 94 % < e and good yields (69-93 %), the best results being observed for aldehydes with tertiary alkyl residues (Scheme 1). 

Conjugate addition to acyclic Michael acceptors. Sakurai and Hosomi (9, 445-446) reported one example of the fluoride ion-catalyzed reaction of allyltrimethylsilane with an acyclic enone. In that case (reaction with C6H5CH=CHCOCH,). 1.2- and 1,4-adducts are obtained in the ratio 2 1.1,4-Addition is enhanced by use of DMF and HMPT as solvent and by increase in the size of the group adjacent to the carbonyl group. 1,4-Addition is the main or predominant reaction with a,3-unsaturated esters or nitriles. In this case, it is superior to or competitive with allylation with lithium diallylcuprate. Yields in 1,4-additions to a,p-enones can compare favorably with those obtained with reactions catalyzed by TiC. ... 

The required highly carbon-substituted enynes, such as (7) and (8), are conveniently prepared by the Sakurai-Hosomi allylsilane conjugate addition, followed by conversion of methyl ketones into silyl-ated alkynes, as shown in equation (10)."... 

Hosomi, A., Sakurai, H. Chemistry of organosilicon compounds. 99. Conjugate addition of allylsilanes to a,(3-enones. A New method of stereoselective introduction of the angular allyl group in fused cyclic a,p-enones. J. Am. Chem. Soc. 1977, 99, 1673-1675. 

Stable pentacoordinated allylsiliconates have been employed in aldehyde addition reactions. These reagents require no activation by Lewis acids or Lewis bases, but have found only limited applications in synthesis to date. The use of these agents in addition to aldehydes was first described in 1987 by Corriu [59] and Hosomi [60] and by Kira and Sakurai [61] in 1988. In these reactions, the addition of a catechol or 2,2 -biphenol-derived allylsiliconate to an achiral aldehyde led to the highly regio- and stereoselective formation of homoallylic alcohols. For example, the addition of the catechol-derived 2-butenylsiliconate 81 (90/10 E Z) provided a diastereomeric mixture of homoallylic alcohols 74 and 75 in a 90/10 ratio (Scheme 10-33) [60c]. 

---