Novel approach to improve progesterone hydroxylation selectivity by <scp>CYP</scp>106A2 via rational design of adrenodoxin binding

Sagadin, Tanja; Riehm, Jan L.; Putkaradze, Natalia; Hutter, Michael C.; Bernhardt, Rita

doi:10.1111/febs.14722

Cited by 10 publications

(4 citation statements)

References 43 publications

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“…Such effect is not unusual for the CYP enzyme complex, as recently described for the CYP1A1 enzyme, in which substrate binding was accommodated by minimal perturbation of the α-carbon backbone with subtle adjustments of the side chains (Bart and Scott, 2018). Additionally, a single amino acid change in a redox partner of CYP106A2 induced a considerable increase in substrate conversion by this bacterial CYP, with a minimal conformational perturbation (Sagadin et al, 2019).…”

Section: Mutations Promote Subtle Deviations Within the Fmn-domainsupporting

confidence: 51%

The Role of the FMN-Domain of Human Cytochrome P450 Oxidoreductase in Its Promiscuous Interactions With Structurally Diverse Redox Partners

et al. 2020

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NADPH cytochrome P450 oxidoreductase (CPR) is the obligatory electron supplier that sustains the activity of microsomal cytochrome P450 (CYP) enzymes. The variant nature of the isoform-specific proximal interface of microsomal CYPs indicates that CPR is capable of multiple degenerated interactions with CYPs for electron transfer, through different binding mechanisms, and which are still not well-understood. Recently, we showed that CPR dynamics allows formation of open conformations that can be sampled by its structurally diverse redox partners in a CYP-isoform dependent manner. To further investigate the role of the CPR FMN-domain in effective binding of CPR to its diverse acceptors and to clarify the underlying molecular mechanisms, five different CPR-FMN-domain random mutant libraries were created. These libraries were screened for mutants with increased activity when combined with specific CYP-isoforms. Seven CPR-FMN-domain mutants were identified, supporting a gain in activity for CYP1A2 (P117H, G144C, A229T), 2A6 (P117L/L125V, G175D, H183Y), or 3A4 (N151D). Effects were evaluated using extended enzyme kinetic analysis, cytochrome b 5 competition, ionic strength effect on CYP activity, and structural analysis. Mutated residues were located either in or adjacent to several acidic amino acid stretches-formerly indicated to be involved in CPR:CYP interactions-or close to two tyrosine residues suggested to be involved in FMN binding. Several of the identified positions co-localize with mutations found in naturally occurring CPR variants that were previously shown to cause CYP-isoform-dependent effects. The mutations do not seem to significantly alter the geometry of the FMN-domain but are likely to cause very subtle alterations leading to improved interaction with a specific CYP. Overall, these data suggest that CYPs interact with CPR using an isoform specific combination of several binding motifs of the FMN-domain.

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Section: Mutations Promote Subtle Deviations Within the Fmn-domainsupporting

confidence: 51%

The Role of the FMN-Domain of Human Cytochrome P450 Oxidoreductase in Its Promiscuous Interactions With Structurally Diverse Redox Partners

et al. 2020

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“…The productivities of 1 and 3 was increased up to 18‐fold to yield an absolute productivity up to 5.5 g/L per day [63] (Table 1). In an alternative approach, Adx was optimized by mutation, the distance of the iron‐sulfur cluster and haem diminished significantly, leading to an approximately 2.5‐fold increase in the production of 15β‐hydroxyprogesterone [64] . The stability and activity of CYP106A2 with 24 were also tested under process conditions using the enzyme overexpressed in B. megaterium MS941 and demonstrated the applicability of this system for biotechnological purposes [65] (Table 1).…”

Section: Bacterial Cytochrome P450mentioning

confidence: 99%

Cytochrome P450 Monooxygenases Catalyse Steroid Nucleus Hydroxylation with Regio‐ and Stereo‐Selectivity

et al. 2022

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Steroids are the second largest class of drugs with a wide range of pharmacological properties. Hydroxylation of steroids seriously affects their biological activities and other properties. However, steroids are mostly sp 3 hybridized carbons with numerous CÀ H bonds far from the functional group that can activate them, and achieving regio-and stereo-selective hydroxylation on steroids is a highly challenging task that is almost impossible to achieve using modern organic synthesis techniques. Interestingly, cytochrome P450 monooxygenases possess the ability to catalyse regio-and stereo-selective oxidations of nonactivated CÀ H bonds in complex organic molecules under mild conditions. This review summarizes the P450s identified and engineered in recent years that can catalyse steroid nucleus hydroxylation stereo-and regio-selectively.1.

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“…The same approach has been used for microbial enzymes, especially to reduce the number of separate components in the electron transfer pathway (Bakkes et al, 2017) including fusing with: the reductase domain of P450 BM3 (Ugalde et al, 2018); mitochondrial adrenodoxin plus an E. coli ferredoxin reductase (Ringle et al, 2013); E. coli flavodoxin and flavodoxin reductase (Bakkes et al, 2015); the reductase domain of P450RhF (RhFRed) (Nodate et al, 2006;Li et al, 2007a;Sabbadin et al, 2010); and the reductase domain of CYP102D1 (Choi et al, 2014). The linker joining the two domains is often tweaked (Zuo et al, 2017) and in some studies, the redox partners interaction face has also been engineered (Sagadin et al, 2019). Fusions have also been explored with cofactor recycling systems e.g., phosphite dehydrogenase (Beyer et al, 2018).…”

Section: Engineering Coupling To Electron Transfer Partnersmentioning

confidence: 99%

Opportunities for Accelerating Drug Discovery and Development by Using Engineered Drug-Metabolizing Enzymes

Gillam

Kramlinger

2022

Drug Metab Dispos

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The study of drug metabolism is fundamental to drug discovery and development (DDD) since by mediating the clearance of most drugs, metabolic enzymes influence their bioavailability and duration of action. Biotransformation can also produce pharmacologically active or toxic products, which complicates the evaluation of the therapeutic benefit vs. liability of potential drugs, but also provides opportunities to explore the chemical space around a lead. The structures and relative abundance of metabolites are determined by the substrate and reaction specificity of biotransformation enzymes and their catalytic efficiency.Preclinical drug biotransformation studies are done to quantify in vitro intrinsic clearance to estimate likely in vivo pharmacokinetic parameters, to predict an appropriate dose, and to anticipate interindividual variability in response, including from drug-drug-interactions. Such studies need to be done rapidly and cheaply, but native enzymes, especially in microsomes or hepatocytes, do not always produce the full complement of metabolites seen in extrahepatic tissues or preclinical test species. Furthermore, yields of metabolites are usually limiting.Engineered recombinant enzymes can make DDD more comprehensive and systematic.Additionally, as renewable, sustainable and scalable resources, they can also be used for elegant chemoenzymatic, synthetic approaches to optimize or synthesize candidates as well as metabolites. Here we will explore how these new tools can be used to enhance the speed and efficiency of DDD pipelines, and provide a perspective on what will be possible in the future. The focus will be on cytochrome P450 enzymes to illustrate paradigms that can be extended in due course to other drug-metabolizing enzymes. Significance statementProtein engineering can generate enhanced versions of drug-metabolizing enzymes that are more stable, better suited to industrial conditions and have altered catalytic activities,

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Novel approach to improve progesterone hydroxylation selectivity by CYP106A2 via rational design of adrenodoxin binding

Cited by 10 publications

References 43 publications

The Role of the FMN-Domain of Human Cytochrome P450 Oxidoreductase in Its Promiscuous Interactions With Structurally Diverse Redox Partners

The Role of the FMN-Domain of Human Cytochrome P450 Oxidoreductase in Its Promiscuous Interactions With Structurally Diverse Redox Partners

Cytochrome P450 Monooxygenases Catalyse Steroid Nucleus Hydroxylation with Regio‐ and Stereo‐Selectivity

Opportunities for Accelerating Drug Discovery and Development by Using Engineered Drug-Metabolizing Enzymes

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