Your search keyword '"Oscar Alvizo"' showing total 3 results

1. Chemoenzymatic conversion of amides to enantioenriched alcohols in aqueous medium

Author

Sophie Racine, Oscar Alvizo, David Entwistle, Evan R. Darzi, Neil K. Garg, Maude Giroud, and Jacob E. Dander

Subjects

Aqueous medium, 010405 organic chemistry, Chemistry, General Chemistry, 010402 general chemistry, 01 natural sciences, Biochemistry, Chemical synthesis, Combinatorial chemistry, Article, 0104 chemical sciences, Stereocenter, lcsh:Chemistry, Enzyme binding, lcsh:QD1-999, Materials Chemistry, Environmental Chemistry, Stereoselectivity, Enantiomer

Abstract

One-pot reactions that combine non-enzymatic and biocatalytic transformations represent an emerging strategy in chemical synthesis. Some of the most powerful chemoenzymatic methodologies, although uncommon, are those that form a carbon–carbon (C–C) bond and a stereocenter at one of the reacting carbons, thereby streamlining traditional retrosynthetic disconnections. Here we report the one-pot, chemoenzymatic conversion of amides to enantioenriched alcohols. This transformation combines a nickel-catalyzed Suzuki–Miyaura coupling of amides in aqueous medium with an asymmetric, biocatalytic reduction to provide diarylmethanol derivatives in high yields and enantiomeric excesses. The synthetic utility of this platform is underscored by the formal syntheses of both antipodes of the pharmaceutical orphenadrine, which rely on ketoreductase enzymes that instill complementary stereoselectivities. We provide an explanation for the origins of stereoselectivity based on an analysis of the enzyme binding pockets.

Published

2020

2. Synthesis of the GPR40 Partial Agonist MK-8666 through a Kinetically Controlled Dynamic Enzymatic Ketone Reduction

Author

Birgit Kosjek, Oscar Alvizo, Nobuyoshi Yasuda, Mark A. Huffman, John Limanto, Eric R. Ashley, Zhijian Liu, Artis Klapars, Alan M. Hyde, Xiuyan Gu, Guiquan Liu, Yong-Li Zhong, Nicholas J. Agard, Lushi Tan, and David M. Tschaen

Subjects

chemistry.chemical_classification, Ketone, 010405 organic chemistry, Stereochemistry, Chemistry, Organic Chemistry, Diastereomer, 010402 general chemistry, Ring (chemistry), 01 natural sciences, Biochemistry, 0104 chemical sciences, Cyclopropane, chemistry.chemical_compound, Yield (chemistry), Intramolecular force, Pyridine, Physical and Theoretical Chemistry, Selectivity

Abstract

A scalable and efficient synthesis of the GPR40 agonist MK-8666 was developed from a simple pyridine building block. The key step to set the stereochemistry at two centers relied on an enzymatic dynamic kinetic reduction of an unactivated ketone. Directed evolution was leveraged to generate an optimized ketoreductase that provided the desired trans alcohol in >30:1 dr and >99% ee. Further, it was demonstrated that all four diastereomers of this hydroxy-ester could be prepared in high yield and selectivity. Subsequently, a challenging intramolecular displacement was carried out to form the cyclopropane ring system with perfect control of endo/exo selectivity. The endgame coupling strategy relied on a Pd-catalyzed C–O coupling to join the headpiece chloropyridine with the benzylic alcohol tailpiece.

Published

2016

3. Structural, kinetic, and thermodynamic studies of specificity designed HIV-1 protease

Author

Stephen L. Mayo, Oscar Alvizo, Celia A. Schiffer, and Seema Mittal

Subjects

Proteases, Protease, medicine.medical_treatment, Substrate (chemistry), Isothermal titration calorimetry, Protein engineering, Biology, Biochemistry, Protein structure, HIV-1 protease, medicine, biology.protein, Molecular Biology, Binding selectivity

Abstract

HIV-1 protease recognizes and cleaves more than 12 different substrates leading to viral maturation. While these substrates share no conserved motif, they are specifically selected for and cleaved by protease during viral life cycle. Drug resistant mutations evolve within the protease that compromise inhibitor binding but allow the continued recognition of all these substrates. While the substrate envelope defines a general shape for substrate recognition, successfully predicting the determinants of substrate binding specificity would provide additional insights into the mechanism of altered molecular recognition in resistant proteases. We designed a variant of HIV protease with altered specificity using positive computational design methods and validated the design using X-ray crystallography and enzyme biochemistry. The engineered variant, Pr3 (A28S/D30F/G48R), was designed to preferentially bind to one out of three of HIV protease's natural substrates; RT–RH over p2-NC and CA-p2. In kinetic assays, RT–RH binding specificity for Pr3 increased threefold compared to the wild-type (WT), which was further confirmed by isothermal titration calorimetry. Crystal structures of WT protease and the designed variant in complex with RT–RH, CA-p2, and p2-NC were determined. Structural analysis of the designed complexes revealed that one of the engineered substitutions (G48R) potentially stabilized heterogeneous flap conformations, thereby facilitating alternate modes of substrate binding. Our results demonstrate that while substrate specificity could be engineered in HIV protease, the structural pliability of protease restricted the propagation of interactions as predicted. These results offer new insights into the plasticity and structural determinants of substrate binding specificity of the HIV-1 protease.

Published

2012