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Recent Desymmetrization Reactions By CALB

International Journal of Applied Chemistry
© 2020 by SSRG - IJAC Journal
Volume 7 Issue 3
Year of Publication : 2020
Authors : Satomi Niwayama
10.14445/23939133/IJAC-V7I3P109
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How to Cite?

Satomi Niwayama, "Recent Desymmetrization Reactions By CALB," SSRG International Journal of Applied Chemistry, vol. 7,  no. 3, pp. 46-48, 2020. Crossref, https://doi.org/10.14445/23939133/IJAC-V7I3P109

Abstract:

Enzyme reactions are among the most environmentally friendly and important asymmetric reactions for organic synthesis. Candida Antarctica lipase B (CALB) is one of the most extensively utilized enzymes for various asymmetric reactions. It catalyzes a variety of asymmetric reactions, such as hydrolysis, esterification, and amidation. However, as the studies of desymmetrization reactions of symmetric compounds catalyzed by CALB is rather limited, this commentary focuses on some recent examples of desymmetrization reactions mediated by CALB.

Keywords:

enzyme, desymmetrization, CALB, building block, organic synthesis.

References:

[1] For example, (a) R. Kumar, V. Kumar, D. Mathur, R. Kumar, A. Kumar and A. K. Prasad. Biocatalyst CAL-B catalyzed synthesis of modified nucleosides: an overview. Synth. Commun. 2019, 49, pp 1659-1678 (b) Y. Cen, W. Singh, M. Arkin, T. S. Moody, M. Huang, J. Zhou, Q. Wu and M. T. Reetz. Artificial cysteine-lipases with high activity and altered catalytic mechanism created by laboratory evolution. Nat. Commun. 10: (2019), 3198 (c) Q. Wu, P. Soni and M. T. Reetz. Laboratory evolution of enantio complementary Candida Antarctica lipase B mutants with broad substrate scope. J. Am. Chem. Soc, 135, (2013) 1872-1881. and references cited therein.
[2] A.-B. L. Fransson, Y. Xu, K. Leijondahl and J.-E. Bäckvall. The enzymatic resolution, desymmetrization, and dynamic kinetic asymmetric transformation of 1,3-cycloalkanediols. J. Org. Chem., 71 (2006) 6309-6316.
[3] Y. Saito, T. Shinkai, Y. Yoshimura and H. Takahata. A straightforward stereoselective synthesis of meso-, (S, S)- and (R, R)-2,6-diaminopimelic acids from cis-1,4-diacetoxycyclohept-2-ene. Bioorg. Med. Chem. Lett, 17 (2007) 5894-5896.
[4] (a) K. Leijondahl, L. Borén, R. Brau and J.-E. Bäckvall. Enantiopure 1,5-diols from dynamic kinetic asymmetric transformation. Useful synthetic intermediates for the preparation of chiral heterocycles. Org. Lett. 10, (2008) 2027-2030. (b) L. Borén, K. Leijondahl and J.-E. Bäckvall. Dynamic kinetic asymmetric transformation of 1,4-diols and the preparation o trans-2,5-disubstituted pyrrolidines. Tetrahedron Lett. 50 (2009) 3237-3240.
[5] R. Kolodziejska, A. Karczmarska-Wódzka, A. Wolan and M. Draminski. Candida antarctica lipase B catalyzed enantioselective acylation of pyrimidine acylnucleoside. Biocatal. Biotranformation, 2, 30 (012) 426-430.
[6] A. Hamber, A. O. Magnusson and F. J. Hu. Selective monoacylation of diols by substrate assisted catalysis in T40A Candida Antarctica lipase B. ChemCatChem, 5 (2013) 743-747.
[7] N. Guajardo, C. Bernal, L. Wilson and Z. Cabrera. The selectivity of R--monobenzenoate glycerol synthesis catalyzed by Candida Antarctica lipase B immobilized on heterobifunctional supports. Process Biochem. 50 (2015) 1870-1877.
[8] M. J. Homann, R. Vail, B. Morgan, V. Sabesan, C. Levy, D. R. Dodds and A. Zaks. Enzymatic hydrolysis of a prochiral 3-substituted glutarate ester, an intermediate in the synthesis of an NK1/NK2 dual antagonist. Adv. Synth. Catal., 343 744-749.
[9] J.-H. Jung, D.-H. Yoon, P. Kang, W. K. Lee, H. Eum and H.-J. Ha. CAL-B catalyzed desymmetrization of 3-alkylglutarate: "olefin effect" and asymmetric synthesis of pregabalin. Org. Biomol. Chem., 11 (2013) 3635-3641.
[10] Z. Cabrera, G. Fernandez-Lorente, R. Fernandez-lafuente, J. M. Palomo and J. M. Guisan. Novozym 435 displays very different selectivity compared to lipase from Candida Antarctica B absorbed on other hydrophobic supports. J. Mol. Cat. B. Enzymatic, 57(2009) 171-176.
[11] J. Wu, H. Wang, B. Yang, W. Song, C. Liang and L. Liu. Efficient production of (R)-3-TBDMSO glutaric acid methyl monoester by manipulating the substrate pocket of Pseudozyma Antarctica lipase B. RSC Adv. 7 (2017) 38264-38272.
[12] H. Wang, Z. Li, X. Yu, X. Chen, and L. Liu. Green synthesis of (R)-3-TBDMSO glutaric acid methyl monoester using Novozym 435 in nonaqueous media. RSC Adv.5 (2015) 75160-75166.
[13] A. Fryszkowska, M. Komar, D. Koszelewski and R. Ostaszewski. Tetrahedron: Asymmetry, 17 (2006) 961-966.
[14] M. López-García, I. Alfonso and V. Gotor. Tetrahedron: Asymmetry, 14 (2003) 603-609.
[15] M. López-García, I. Alfonso and V. Gotor. Synthesis of (R)-3,4-diaminobutanoic acid by desymmetrization of dimethyl 3-(benzylamino)glutarate through enzymatic ammonolysis. J. Org. Chem. 68 (2003) 648-651.