Desymmetrization substitutional

NOL-based systems for addition of (substituted) anilines to meso epoxides. Hou found that a ytterbium-BI NO L complex catalyzed desymmetrization of cyclohexene oxide in up to 80% ee [15], Shibasaki demonstrated that a praseodymium-BINOL complex could promote addition of p-anisidine to several epoxides in moderate yields with modest enantioselectivities (Scheme 7.7) [16]. 

In contrast, Cozzi and Umani-Ronchi found the (salen)Cr-Cl complex 2 to be very effective for the desymmetrization of meso-slilbene oxide with use of substituted indoles as nucleophiles (Scheme 7.25) [49]. The reaction is high-yielding, highly enantioselective, and takes place exclusively at sp2-hybridized C3, independently of the indole substitution pattern at positions 1 and 2. The successful use of N-alkyl substrates (Scheme 7.25, entries 2 and 4) suggests that nucleophile activation does not occur in this reaction, in stark contrast with the highly enantioselective cooperative bimetallic mechanism of the (salen)Cr-Cl-catalyzed asymmetric azidolysis reaction (Scheme 7.5). However, no kinetic studies on this reaction were reported. 

The initial results of an early directed evolution study are all the more significant, because no X-ray data or homology models were available then to serve as a possible guide [89]. In a model study using whole E. coU cells containing the CHMO from Adnetohacter sp. NCIM B9871,4-hydroxy-cydohexanone (3 5) was used as the substrate. The WT leads to the preferential formation of the primary product (i )-36, which spontaneously rearranges to the thermodynamically more stable lactone (R)-37. The enantiomeric excess of this desymmetrization is only 9%, and the sense of enantioselectivity (R) is opposite to the usually observed (S)-preference displayed by simple 4-alkyl-substituted cydohexanone derivatives (see Scheme 2.10) [84—87]. 

The catalytic enantioselective desymmetrization of meso compounds is a powerful tool for the construction of enantiomerically enriched functionalized products." Meso cyclic allylic diol derivatives are challenging substrates for the asymmetric allylic substitution reaction owing to the potential competition of several reaction pathways. In particular, S 2 and 5n2 substitutions can occur, and both with either retention or inversion of the stereochemistry. In the... 

Desymmetrization of cyclic allyl acetals such as 2-substituted 4,7-hydrodioxepins or 5-methylene-1,3-dioxanes was investigated using ruthenium or nickel catalysts. The isomerization of the dioxanes was accomplished using Ru2Cl4(DIOP)/LiBHEt3 in high yield with up to 38% ee (Equation (22)).81... 

Nitrogen substituted porphyrazines were the second type of heteroatom-deriva-tized pz macrocycle reported and were prepared from the readily derivatized diami-nomalconitrilc (DAMN) (7). Octakis(dimethylamino)porphyrazines are extremely electron-rich systems and have been used to prepare charge-transfer complexes with Cgo, as well as to peripherally chelate metals or convert to crown appended systems (38, 39). The unsymmetrical dimethylaminoporphyrazine analogues have also been reported (29), as well as the first example of the desymmetrized seco-pz from the dimethylaminoporphyrazine (8, 40). The nitrogen substituted porphyrazines are discussed in Section V. 

Cyclohexadienones 61 and 64 are readily available from monoprotected hydro-quinones or para-substituted phenols, respectively. Conjugate additions to these symmetrical dienones result in desymmetrization of the prochiral dienone moieties, providing access to multifunctional chiral synthons in two steps from the aromatic precursors (Scheme 7.17) [72]. 

The Ir-tolBINAP catalyst also functions well in the desymmetrization of dienynes, where a highly enantioselective and diastereoselective Pauson-Khand-type reaction proceeded to give vinyl-substituted bicyclic cyclopentenones with two chiral centers (Scheme 11.19) [31]. 

Verma and Ghosh [72] desymmetrized a a-symmetric 3-dimethyl(phe-nyl)silyl substituted glutaric anhydride (127) with Evans oxazolidinone 128 (Scheme 32) as one of the key steps in their synthesis of (+)-preussin. 

Jeong and coworkers have executed a desymmetrization of a dienyne by asymmetric Pauson-Khand-type reaction. Intriguingly, the use of a Rh catalyst resulted in preferential formation of one diastereomer, while a switch to the analogous Ir system provided the other diastereomer in excellent selectivity [Eq. (10.62)] the system has been shown to be tolerant of oxygen in the linker as well as modest substitution on the alkyne (Ph) ... 

Landais has extended his desymmetrization of dienes from dihydroxylation approaches to a cyclopropanation reaction. A Cu-pybox complex provides the highest enantioselectivities and good diastereoselectivity in the asymmetric cyclopropanation of the silyl-substituted cyclopentadiene 210 ... 

The desymmetrization works also well with higher substituted meio-epoxides such as ewdo-norbornene oxide (130) , cis-5,6- and 4,7-difunctionalized cyclooctene oxides 132 and 134, giving the alcohols 131, 133 and 135, respectively but for the diastereomer 136, the rearrangement to form the allylic alcohol 138 beside 137 cannot be completely suppressed (equation 29 best results are given). ... 

In 2000, Tanaka, Sakai, and Suemune expanded the scope of these desymmetrization reactions to more highly substituted substrates (Eq. 16) [19], The high selectivity of Rh(I)/BINAP for addition to one of the enantiotopic olefins leads to the generation of adjacent quaternary and tertiary stereocenters with excellent stereoselection. Unfortunately, for these more sterically demanding substrates, neutral Rh(l)/BINAP complexes furnish a poor yield of the desired cyclopentanone. 

Jeong described desymmetrization of dienynes, such as iV-propargyl-jY-(penta-l,4-dien-3-yl) tosylamides, by the asymmetric Ir(i)-based PK-type reaction. The corresponding vinyl-substituted bicyclo[3,3,0]-octenones were obtained with high diastereoselectivity and enantioselectivity (Equation (36)). ... 

A-Boc-leucinal may react with allyl- and alkenyhnagnesium hahdes giving syn- and awf/-products in ca 9 1 ratio. This method was used for the asymmetric synthesis of important amino acids like statine and norstatine. An enantioselective desymmetrization of anhydrides was reported. Arylmagnesium chlorides react in toluene in the presence of (—)-sparteine (1 equiv.) with 3-substituted glutaric anhydrides 215, giving aryl ketones with 87-92% ee (equation 145). ... 

Scheme 7.16 Desymmetrization of 2-substituted 1,3-propanediol to (S)-monoacetate by enzymatic hydrolysis in 80% organic solvent.

A similar sequence was reported where the asymmetry was introduced by the reaction of weio-3-substituted glutanc anhydrides and (S)-methylbenzylamines to give diastereomeric hemiamides that could be separated by recrystallization The asymmetnc desymmetrization of certain 4-aryl substituted glutanmides has also been accomplished with high levels of selectivity (up to 97% ee) by enolization with a chiral bis-lithium amide base. The selectivity of the reaction was shown to be the result of asymmetric enolization, followed by a kinetic resolution." ... 

SE.3.1.2. Desymmetrization of gem-Dwarboxylates An equivalent of asymmetric carbonyl addition can be achieved by the alkylation of gem-dicarboxylates (Scheme 8E.17). The alkylation of gem-dicarboxylates, which are easily prepared by the Lewis acid-catalyzed addition of acid anhydrides to an aldehyde, converts the problem of differentiating the two enantiotopic 7t-faces of a carbonyl group into that of asymmetric substitution of either enantiotopic C-O bond of the gem-dicarboxylate. Although asymmetric induction may be derived from enantio-discrimination in the ionization step or in the alkene coordination step, the fast and reversible nature of alkene coordination suggests that the ionization step is more likely to be the source of enantio-discrimination. 

In another development, the statin side chain en route to Atorvastatin (Lipitor , Pfizer) is synthesized via the key intermediate alkyl 3-hydroxy-4-cyanobutyrate (Figure 13.17). Instead of the currently practiced six-step route, a much more concise three-step route starts from epichlorohydrin via Cl chain length enhancement by both nucleophilic substitution of chloride and nucleophilic ring opening of the epoxide with cyanide to yield symmetric dicyanoisopropanol. Nitrilase action desymmetrizes the dinitrile intermediate with the creation of a chiral center in C3 to yield (R)-3-hydroxy-4-cyanobutyrate, which is esterified to the key intermediate ethyl (R)-3-hydroxy-4-cyanobutyrate. 

The desymmetrization of dicarbonate 206 was initiated by the addition of one equivalent of N-(3-butenyl) nosylamide 207 under palladium catalysis in the presence of Trost s chiral diphosphine ligand 205. When the first allylic substitution was completed, the reaction was warmed and the resulting intermediate 208 was treated in situ with one equivalent of a second nosylamide 209. Product 210 resulting from this double substitution reaction was submitted to a tandem intramolecular ROM/RCM to furnish key precursor 211, which was engaged in the final cyc-lization step by the reduction of the double bonds, followed by the HCl-promoted domino deprotection of the acetal and aminal formation. 

The desymmetrization of meso-e poxides such as cyclohexene epoxide (55, Scheme 13.27) has been achieved both by enantioselective isomerization, e.g. to allylic alcohols (56, path A, Scheme 13.27) or by enantiotopos-differentiating opening by nucleophiles, affording trans-/ -substituted alcohols and derivatives (57, path B, Scheme 13.27). As indicated in Scheme 13.27, the allylic alcohols 56 can also be prepared from the ring-opening products 57 by subsequent elimination of the nucleophile. 

Giblin, G. M. P. Kirk, D. T. Mitchell, L. Simpkins, N. S. Bridgehead enolates substitution and asymmetric desymmetrization of small bridged carbonyl compounds by lithium amide bases. Org. Lett. 2003, 5, 1673-1675. 

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