Enzymatic kinetic resolution carbonate

Reetz, M.T., W. Wiesenhofer, G. Francio and W. Leitner, Continuous Flow Enzymatic Kinetic Resolution and Enantiomer Separation Using Ionic Liquid/Supercritical Carbon Dioxide Media, Advanced Synthesis Catalysis, 345, 1221-1228 (2003). 

Reetz MT, Wiesenhofer W, Francio G et al (2003) Continuous flow enzymatic kinetic resolution and enantiomer separation using ionic Uquid/supercritical carbon dioxide media. Adv Synth Catal 345 1221-1228... 

Another factor to consider is that the site of enzyme-catalyzed hydrolysis would not be adjacent to the stereocenter but rather /> to it. While there are many examples where reaction enantioselectivity is attenuated by the distance of the stereo-genic carbon from the enzymatic action site [31], resolution of centers up to five bonds distant from the site of enzymatic action is still possible [32]. We hoped that we would be able to reproduce the example of the enzymatic kinetic resolution of 9 but with a thioester, inasmuch as the resolution of 9 had been excellent and the resolved center was located two bonds from the ester. 

Albrycht M, Kielbasinski P, Drabowicz J, Mikolajczyk M, Matsuda T, Harada T, Nakamura K (2005) Supercritical carbon dioxide as a reaction medium for enzymatic kinetic resolution of F-chtral hydroxymethanephosphinates. Tetrahedron Asymmetry 16 2015-2018... 

In the last synthesis from this series,the (5)-conhgured a-hydroxyphosphonate building block 70 was required (Scheme 47.17). In this case, the desired carbonate could be obtained directly from the enzymatic kinetic resolution as it was the unreactive enantiomer. The synthesis involved similar key steps as before, namely, a cross metathesis, followed by a stereospecific intramolecular palladium-catalyzed allylic substitution that furnished the furan ring in 78. In contradistinction to the previous syntheses, the phosphonate group was not removed by ozonolysis, but instead it was employed in the Wittig reaction, to produce fragments 80 and 81 for the synthesis of amphidinolides F and C. 

The classical kinetic resolution of racemic substrate precursors allows only access to a theoretical 50% yield of the chiral ladone product, while the antipodal starting material remains unchanged in enantiomerically pure form. The regioseledivity for the enzymatic oxidation correlates to the chemical readion with preferred and exclusive migration of the more nucleophilic center (usually the higher substituted a-carbon). The majority of cydoketone converting BVMOs (in particular CHMOAdneto)... 

Stereoinversion Stereoinversion can be achieved either using a chemoenzymatic approach or a purely biocatalytic method. As an example of the former case, deracemization of secondary alcohols via enzymatic hydrolysis of their acetates may be mentioned. Thus, after the first step, kinetic resolution of a racemate, the enantiomeric alcohol resulting from hydrolysis of the fast reacting enantiomer of the substrate is chemically transformed into an activated ester, for example, by mesylation. The mixture of both esters is then subjected to basic hydrolysis. Each hydrolysis proceeds with different stereochemistry - the acetate is hydrolyzed with retention of configuration due to the attack of the hydroxy anion on the carbonyl carbon, and the mesylate - with inversion as a result of the attack of the hydroxy anion on the stereogenic carbon atom. As a result, a single enantiomer of the secondary alcohol is obtained (Scheme 5.12) [8, 50a]. 

The above-mentioned facts have important consequences on the stereochemical outcome of the kinetic resolution of asymmetrically substituted epoxides. In the majority of kinetic resolutions of esters (e.g. by ester hydrolysis and synthesis using lipases, esterases and proteases) the absolute configuration at the stereogenic centre(s) always remains the same throughout the reaction. In contrast, the enzymatic hydrolysis of epoxides may take place via attack on either carbon of the oxirane ring (Scheme 7) and it is the structure of the substrate and of the enzyme involved which determine the regioselec-tivity of the attack [53, 58-611. As a consequence, the absolute configuration of both the product and substrate from a kinetic resolution of a racemic... 

For the synthesis of p-lactam antibiotics, the presence of asymmetrical carbon at the 3 and 4 positions is critical to prepare optically active -lactams [197]. Nagai et al. [198] developed enzymatic synthesis of optically active p-lactams by lipase-catalyzed kinetic resolution using the enantioselective hydrolysis of iV-acyloxymethyl p-lactams 108 in an organic solvent (isopropyl ether saturated with water) and the transesterification of N-hydroxymethyl P-lactam 109 in organic solvent (metiiylene chloride) in tiie presence of vinyl acetate as acyl donor (Fig. 37). The reaction yield of 35-50% and e.e. s of 93 to more than 99% were obtained depending on the specific substrate used in the reaction mixture, Lipase B from Pseudomonas fragi and lipase PS-30 from Pseudomonas sp. were used in the reaction mixture. 

Many other methods utilizing a three-carbon-chain segment have been employed in the syntheses of the fluoxetine enantiomers. Chirality has been established by enzymatic reduction,lipase mediated enzymatic resolution, " oxidative kinetic... 

Enantioselective enzymatic transesterifications have been used as a complementary method to enantioselective enzymatic ester hydrolyses. The first example of this particular type of biotransformation is the synthesis of the optically active 2-acetoxy-l-silacyclohexane (5 )-78 (Scheme 19). This compound was obtained by an enantioselective transesterification of the racemic l-silacyclohexan-2-ol rac-43 with triacetin (acetate source) in isooctane, catalyzed by a crude lipase preparation from Candida cylindracea (CCL, E.C. 3.1.1.3)62. After terminating the reaction at 52% conversion (relative to total amount of substrate rac-43), the product (S)-78 was separated from the nonreacted substrate by column chromatography on silica gel and isolated in 92% yield (relative to total amount of converted rac-43) with an enantiomeric purity of 95% ee. The remaining l-silacyclohexan-2-ol (/ )-43 was obtained in 76% yield (relative to total amount of nonconverted rac-43) with an enantiomeric purity of 96% ee. Repeated recrystallization of (R)-43 led to an improvement of enantiomeric purity by up to >98% ee. Compound (R)-43 has already earlier been prepared by an enantioselective microbial reduction of the l-silacyclohexan-2-one 42 (see Scheme 8)53. The l-silacyclohexan-2-ol (R)-43 is the antipode of compound (.S j-43 which was obtained by a kinetic enzymatic resolution of the racemic 2-acetoxy-l-silacyclohexane rac-78 (see Scheme 15)62. For further enantioselective enzymatic transesterifications of racemic organosilicon substrates, with a carbon atom as the center of chirality, see References 64 and 70-72. 

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