Faculty Expert
Brent Feske
Associate Professor
- Statesboro GA UNITED STATES
- Biochemistry
Professor Feske specializes in biocatalysis (catalysis using enzymes) and asymmetric synthesis towards pharmaceuticals
Contact More Open optionsSpotlight
April 21, 2020
2 min
April 30, 2019
1 min
Biography
Professor Feske specializes in biocatalysis (catalysis using enzymes) and asymmetric synthesis towards pharmaceuticals or pharmaceutical precursors
Areas of Expertise
Education
University of Florida
Ph.D.
Organic Chemistry
Southeastern Louisiana University
B.S.
Chemistry
Links
Articles
Synthesis, stereochemical characterization, and antimicrobial evaluation of a potential non-nephrotoxic 3'-C-acethydrazide puromycin analog
Journal of Nucleosides, Nucleotides and Nucleic AcidsCarter, J.; Weaver, B.A.; Chiacchio, M.A.; Messersmith, A.R.; Lynch, W.E.; Feske, B.D.; Gumina, G.
2017
Synthetic Strategy toward γ-Keto Nitriles and Their Biocatalytic Conversion to Asymmetric γ-Lactones
SynthesisFranz, S.E., Watkins, R.R.; Wright, L.A.; Weaver, B.A.; Hartage, R.C.; Ghiviriga, I.; Gumina, G.; Feske, B.D.
2013
Asymmetric synthesis of (-)-fosfomycin and its trans-(1S,2S)-diastereomer using a biocatalytic reduction as the key step
Tetrahedron AsymmetryMarocco, C.P.; Davis, E.V.; Finnell, J.E.; Nguyen, H.; Mateer, S.C.; Ghiviriga, I.; Padgett, C.W.; Feske, B.D
2011
Biocatalytic synthesis towards both antipodes of 3-hydroxy-3-phenylpropanitrile a precursor to fluoxetine, atomoxetine and nisoxetine
Tetrahedron LettersRJ Hammond, BW Poston, I Ghiviriga, BD Feske
2007 The bakers’ yeast reduction of 3-oxo-3-phenylpropanenitrile (1) has been difficult to achieve due to a dominant alkylating mechanism. A library of 20 bakers’ yeast reductases, that are overexpressed in Escherichia coli, were screened against (1). Four enzymes were found to reduce this substrate and by varying the enzyme both enantiomers of 3-hydroxy-3-phenylpropanitrile (2) could be prepared with a high enantiomeric excess. In addition, the Escherichia coli whole-cell system can be optimized to nearly eliminate the competing alkylating mechanism. By using this system, a formal biocatalytic synthesis of both antipodes of fluoxetine, atomoxetine and nisoxetine has been demonstrated...
Enantiodivergent, Biocatalytic Routes to Both Taxol Side Chain Antipodes
The Journal of Organic ChemistryBD Feske, IA Kaluzna, JD Stewart, et al.
2005 Two enantiocomplementary bakers' yeast enzymes reduced an α-chloro-β-keto ester to yield precursors for both enantiomers of the N-benzoyl phenylisoserine Taxol side chain. After base-mediated ring closure of the chlorohydrin enantiomers, the epoxides were converted directly to the oxazoline form of the target molecules using a Ritter reaction with benzonitrile. These were hydrolyzed to the ethyl ester form of the Taxol side chain enantiomers under acidic conditions...
Stereoselective, Biocatalytic Reductions of α-Chloro-β-keto Esters
The Journal of Organic ChemistryIA Kaluzna, BD Feske, W Wittayanan, et al.
2004 Eighteen known and putative reductases from baker's yeast (Saccharomyces cerevisiae) were tested for the ability to reduce a series of α-chloro-β-keto esters. In nearly all cases, it was possible to produce at least two of the four possible α-chloro-β-hydroxy ester diastereomers with high optical purities. The utility of this approach was demonstrated by reducing ethyl 2-chloroacetoacetate to the corresponding syn-(2R,3S)-alcohol on a multigram scale using whole cells of an Escherichia coli strain overexpressing a single yeast reductase identified from the screening studies...
Last updated: 1/9/2024
