Carbon stereocontrolled

There are a number of powerful synthetic reactions which join two trigonal carbons to form a CC single bond in a stereocontrolled way under proper reaction conditions. Included in this group are the aldol, Michael, Claisen rearrangement, ene and metalloallyl-carbonyl addition reactions. The corresponding transforms are powerfully stereosimplifying, especially when rendered enantioselective as well as diastereoselective by the use of chiral controller groups. Some examples are listed in Chart 20. 

Erythronolide B, the biosynthetic progenitor of the erythromycin antibiotics, was synthesized for the first time, using as a key step a new method for macrolactone ring closure (double activation) which had been devised specifically for this problem. Retrosynthetic simplification included the clearance of the stereocenters at carbons 10 and 11 and the disconnection of the 9,10-bond, leading to precursors A and B. Cyclic stereocontrol and especially the Baeyer-Villiger and halolactonization transforms played a major role in the retrosynthetic simplification of B which was synthesized starting from 2,4,6-trimethylphenol. 

Enandoselecdve total synthesis of andhingal agent Sch-38516 is reported. Stereocontrolled carbohydrate synthesis is based on the 1,3-dipolar cycloaddidon of chiral nkrone to vinylene carbonate, as shovm in Eq. 8.53. ... 

A salient structural feature of intermediate 18 (Scheme 2b), the retrosynthetic precursor of aldehyde 13, is its y,r5-unsaturated ester moiety. As it turns out, the Johnson ortho ester variant of the Clai-sen rearrangement is an excellent method for the synthesis of y,<5-unsaturated esters.11 In fact, the Claisen rearrangement, its many variants included, is particularly valuable in organic synthesis as a method for the stereocontrolled construction of trans di- and tri-substituted carbon-carbon double bonds.12,13 Thus, it is conceivable that intermediate 18 could be fashioned in one step from allylic alcohol 20 through a Johnson ortho ester Claisen rearrangement. In... 

An important task remaining is the stereocontrolled introduction of a methyl group at C-8. When a cold (-78 °C) solution of 14 in THF is treated successively with LDA and methyl iodide and then warmed to -45 °C, intermediate 24 admixed with minor amounts of the C-8 epimer is formed in a yield of 95 %. The action of LDA on 14 generates a lactone enolate which is alkylated on carbon in a diastereoselective fashion with methyl iodide to give 24. It is of no consequence that 24 is contaminated with small amounts of the unwanted C-8 epimer because hydrolysis of the mixture with lithium hydroxide affords, after Jones oxidation of the secondary alcohol, a single keto acid (13) in an overall yield of 80%. Apparently, the undesired diastereoisomer is epimerized to the desired one under the basic conditions of the saponification step. 

The E. coli enzyme accepts substitution on either cosubstrate propanal, acetone or 1-fluoro-2-propanone can replace the donor and a variety of aldehydes can replace the acceptor moiety 3. Shortcomings are the relatively low conversion rates obtained for any substrate analog and the as yet unidentified level of relative stereocontrol induced upon substitution at the nucleophilic carbon. 

Successful applications of these stereocontrolled conjugate additions have led to asymmetric syntheses of several natural products such as (+ )-cuparenone (39) which involves formation of a quaternary carbon center81, (- )-/ -vetivone (40)8° and steroidal equilenin 4182 the wavy lines in these structures indicate that C—C bond formed stereoselectively under the influence of a temporarily-attached stereogenic sulfoxide auxiliary group. 

Cyclization of an organolithium tethered to a suitably positioned carbon-carbon jt-bond is a thermodynamically favorable process that proceeds in a totally regioselective exo-fashion with a high degree of stereocontrol via a transition state in which the lithium atom is intramolecularly coordinated with the remote rc-bond.9 The stereochemical outcome of the cyclization of a substituted 5-hexenyllithium follows from the preference of the substituent to occupy a pseudoequatorial position in the chair-like transition state depicted below.7... 

Similar catalytic reactions allowed stereocontrol at either of the olefin carbons (Scheme 5-13, Eqs. 2 and 3). As in related catalysis with achiral diphosphine ligands (Scheme 5-7), these reactions proceeded more quickly for smaller phosphine substrates. These processes are not yet synthetically useful, since the enantiomeric excesses (ee s) were low (0-27%) and selectivity for the illustrated phosphine products ranged from 60 to 100%. However, this work demonstrated that asymmetric hydrophosphination can produce non-racemic chiral phosphines [13]. 

In considering the retrosynthetic analysis of juvabione, two factors draw special attention to the bond between C(4) and C(7). First, this bond establishes the stereochemistry of the molecule. The C(4) and C(7) carbons are stereogenic centers and their relative configuration determines the diastereomeric structure. In a stereocontrolled synthesis, it is necessary to establish the desired stereochemistry at C(4) and C(7). The C(4)-C(7) bond also connects the side chain to the cyclohexene ring. As a cyclohexane derivative is a logical candidate for one key intermediate, the C(4)-C(7) bond is a potential bond disconnection. 

The first example of an intermolecular radical addihon/intermolecular trapping domino reactions of an acyclic system in a stereocontrolled fashion to build stereo-genic centers at the a- and 3-carbons was described by Sibi and coworkers [59]. Enantioselective addition of in-sitw-prepared alkyl radical to crotonate or cinnamate,... 

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