Hydroxylation diastereoselective

Removal of the unsaturated side-chain appendage from C-8 in 22 provides diol lactone 23 and allylic bromide 24 as potential precursors. In the synthetic direction, a diastereoselective alkylation of a hydroxyl-protected lactone enolate derived from 23 with allylic bromide 24 could accomplish the assembly of 22, an intermediate that possesses all of the carbon atoms of PGF2o- It was anticipated that preexisting asymmetry in the lactone enolate would induce the... 

In an effort to make productive use of the undesired C-13 epimer, 100-/ , a process was developed to convert it into the desired isomer 100. To this end, reaction of the lactone enolate derived from 100-) with phenylselenenyl bromide produces an a-selenated lactone which can subsequently be converted to a,) -unsaturated lactone 148 through oxidative syn elimination (91 % overall yield). Interestingly, when 148 is treated sequentially with lithium bis(trimethylsilyl)amide and methanol, the double bond of the unsaturated lactone is shifted, the lactone ring is cleaved, and ) ,y-unsaturated methyl ester alcohol 149 is formed in 94% yield. In light of the constitution of compound 149, we were hopeful that a hydroxyl-directed hydrogenation52 of the trisubstituted double bond might proceed diastereoselectively in the desired direction In the event, however, hydrogenation of 149 in the presence of [Ir(COD)(py)P(Cy)3](PF6)53 produces an equimolar mixture of C-13 epimers in 80 % yield. Sequential methyl ester saponification and lactonization reactions then furnish a separable 1 1 mixture of lactones 100 and 100-) (72% overall yield from 149). 

Optically active Art-butyl 2-(4-methylphenylsulfinyl)propanoate only reacted with aldehydes in the presence of e//-butylmagnesium bromide as a base36. The asymmetric induction for the formation of the hydroxylic center was higher in the case of aliphatic aldehydes (75-80%) than in the case of benzaldehyde (33%). The diastereoselectivity regarding the tertiary center to sulfur was not determined. 

The addition of allylboronates 1 to the chiral oxime 2 results in the formation of a hydroxyl-amine. This is a general method for the subsequent reductive generation of primary homoallyl-amines, but with poor diastereoselectivity in the case of 3 and 4. A diastereomeric ratio of 90 10 is achieved in the addition reaction, using the chiral allylboronate 59 (double stcrcodifferenti-ation). 

Modena and colleagues47 have developed use of some chiral, non-racemic terpene alcohols as directing groups for highly diastereoselective m-chloroperbenzoic oxidation of sulfides into sulfoxides. Specifically the isobornyl vinylic sulfides 8 undergo hydroxyl-directed oxidation to give a 9 1 ratio of diastereomeric sulfoxides (equation 11). 

The aqueous Barbier-Grignard-type reaction has also been used in the synthesis of natural products. Chan and Li used the zinc mediated allylation as a key step in a total synthesis of (+)-muscarine (Scheme 8.5).72 The strategy was based on the observation that the diastereoselectivity of the allylation reaction in water can be reversed through the protection of the a-hydroxyl group. 

In 1991, Whitesides etal. reported the first application of aqueous medium Barbier-Grignard reaction to carbohydrate synthesis through the use of tin in an aqueous/organic solvent mixture (Eq. 8.48).106 These adducts were converted to higher carbon aldoses by ozonolysis of the deprotected polyols followed by suitable derivatization. The reaction showed a higher diastereoselectivity when there was a hydroxyl group present at C-2. However, no reaction was observed under the reaction conditions when there was an /V-acctyl group present at the C-2 position. 

The zirconocene catalysts described above are very oxophilic, which provides several synthetically useful transformations. Oxygen substitution at the al-lylic or homoallylic position of an olefin substrate allows for excellent regio-and diastereocontrol in the ethyl magnesiation reactions of a-olefins and dienes [21]. When 29 is substituted with a hydroxyl group (29a), syn 30a is favored over anti in a 95 5 ratio, while substitution with OCH3 (29b) reversed the diastereoselectivity to 11 89 (Eq. 6). Use of THF in place of diethyl ether as the reaction solvent for the reaction of 29a lowered the overall diastereo-... 

Photocyclization of benzophenone with chiral allylic alcohols, 9 (R = Me, Et, Pri, and Bu1) is hydroxyl group-directed to give regioselectivity and t/zreo-diastereoselectivity in the formation of mainly 10 <00JA2958>. 

An interesting variant involves the use of an allylic alcohol as the alkene component. In this process, re-oxidation of the catalyst is unnecessary since the cyclization occurs with /Uoxygen elimination of the incipient cr-Pd species to effect an SN2 type of ring closure. Both five- and six-membered oxacycles have been prepared in this fashion using enol, hemiacetal, and aliphatic alcohol nucleophiles.439,440 With a chiral allylic alcohol substrate, the initial 7r-complexation may be directed by the hydroxyl group,441 as demonstrated by the diastereoselective cyclization used in the synthesis of (—)-laulimalide (Equation (120)).442 Note that the oxypalladation takes place with syn-selectivity, in analogy with the cyclization of phenol nucleophiles (1vide supra). 

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