Matthias Kittelmann scite author profile

Cytochrome P450 monooxygenases (CYPs) are important enzymes in the metabolism of xenobiotics. Therefore, several approaches to clone and overexpress the human isoforms have been made. In addition to microsomes or S9 preparations, these recombinant human isoforms have found diverse application in drug development. We discuss and give examples of the use of bacterial whole cell systems with rec. human CYPs for the preparative scale synthesis of drug metabolites.

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A novel cytochrome P450 mono‐oxygenase from Streptomyces platensis resembles activities of human drug metabolizing P450s

Worsch

Eggimann

Girhard

et al. 2018

Biotech & Bioengineering

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Cytochrome P450 mono-oxygenases (P450) are versatile enzymes which play essential roles in C-source assimilation, secondary metabolism, and in degradations of endo- and exogenous xenobiotics. In humans, several P450 isoforms constitute the largest part of phase I metabolizing enzymes and catalyze oxidation reactions which convert lipophilic xenobiotics, including drugs, to more water soluble species. Recombinant human P450s and microorganisms are applied in the pharmaceutical industry for the synthesis of drug metabolites for pharmacokinetics and toxicity studies. Compared to the membrane-bound eukaryotic P450s, prokaryotic ones exhibit some advantageous features, such as high stability and generally easier heterologous expression. Here, we describe a novel P450 from Streptomyces platensis DSM 40041 classified as CYP107L that efficiently converts several commercial drugs of various size and properties. This P450 was identified by screening of actinobacterial strains for amodiaquine and ritonavir metabolizing activities, followed by genome sequencing and expression of the annotated S. platensis P450s in Escherichia coli. Performance of CYP107L in biotransformations of amodiaquine, ritonavir, amitriptyline, and thioridazine resembles activities of the main human metabolizing P450s, namely CYPs 3A4, 2C8, 2C19, and 2D6. For application in the pharmaceutical industry, an E. coli whole-cell biocatalyst expressing CYP107L was developed and evaluated for preparative amodiaquine metabolite production.

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Preparative Enzymatic Synthesis of the Acylglucuronide of Mycophenolic Acid

Kittelmann¹,

Rheinegger²,

Espigat³

et al. 2003

Adv Synth Catal

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The acylglucuronide (3) of mycophenolic acid (1) was enzymatically synthesised on a preparative scale (450 mg substrate) under optimised reaction conditions with 51% conversion. By screening 9 liver homogenates from 8 vertebrate species, it was shown that only with liver homogenate from horse as the catalyst were the acyl-(3) and the O-glucuronide (2) were formed in a ca. 1 : 1 ratio. With homogenates from other sources, the O-glucuronide (2) was produced in high excess. By optimising the concentration of the co-substrate UDP-glucuronic acid and the reaction temperature, the conversion to the acylglucuronide (3) was increased from initially 34 to 55% and the ratio of acyl-(3) to O-glucuronide (2) from 1.5 : 1 to 3.9 : 1. The reaction was also performed continuously in an enzyme membrane reactor, however, with lower conversion yield and therefore, higher specific UDP-glucuronic acid consumption.

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Human FMO2-based microbial whole-cell catalysts for drug metabolite synthesis

et al. 2015

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BackgroundGetting access to authentic human drug metabolites is an important issue during the drug discovery and development process. Employing recombinant microorganisms as whole-cell biocatalysts constitutes an elegant alternative to organic synthesis to produce these compounds. The present work aimed for the generation of an efficient whole-cell catalyst based on the flavin monooxygenase isoform 2 (FMO2), which is part of the human phase I metabolism.ResultsWe show for the first time the functional expression of human FMO2 in E. coli. Truncations of the C-terminal membrane anchor region did not result in soluble FMO2 protein, but had a significant effect on levels of recombinant protein. The FMO2 biocatalysts were employed for substrate screening purposes, revealing trifluoperazine and propranolol as FMO2 substrates. Biomass cultivation on the 100 L scale afforded active catalyst for biotransformations on preparative scale. The whole-cell conversion of trifluoperazine resulted in perfectly selective oxidation to 48 mg (46% yield) of the corresponding N1-oxide with a purity >98%.ConclusionsThe generated FMO2 whole-cell catalysts are not only useful as screening tool for human metabolites of drug molecules but more importantly also for their chemo- and regioselective preparation on the multi-milligram scale.Electronic supplementary materialThe online version of this article (doi:10.1186/s12934-015-0262-0) contains supplementary material, which is available to authorized users.

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