Abstract
Cytochrome P450 monooxygenases (P450) are heme-containing enzymes that oxidize a broad range of substrates in the presence of molecular oxygen and NAD(P)H. For their activity, most P450s rely on one or two redox proteins responsible for the transfer of electrons from the cofactor NAD(P)H to the heme. One of the challenges when using P450s in vitro, especially when non-physiological redox proteins are applied, is the inefficient transfer of electrons between the individual proteins resulting in non-productive consumption of NAD(P)H – referred to as uncoupling. Herein, we describe the improvement of the coupling efficiency between a P450 and its redox partner – diflavin reductase – by fusing both enzymes individually to the hydrophobin HFBI – a small self-assembling protein of the fungus Trichoderma reesei. The separated monooxygenase (BMO) and reductase (BMR) domains of P450 BM3 from Bacillus megaterium were chosen as a P450-reductase model system and individually fused to HFBI. The fusion proteins could be expressed in soluble form in Escherichia coli. When HFBI-fused BMO and BMR were mixed in vitro, substantially higher coupling efficiencies were measured as compared with the respective non-fused enzymes. Consequently, myristic acid conversion increased up to 20-fold (after 6 h) and 5-fold (after 24 h). Size exclusion chromatography demonstrated that in vitro the hydrophobin-fused enzymes build multimeric protein assemblies. Thus, the higher activity is hypothesized to be due to HFBI-mediated self-assembly arranging BMO and BMR in close spatial proximity in aqueous solution.
Highlights
Cytochromes P450 are heme-containing monooxygenases that catalyze selective oxidations of a vast variety of organic molecules
Fusion proteins were constructed using the mature form of hydrophobin HFBI lacking its N-terminal 22 amino acids-long secretion signal sequence
Due to the large differences in molecular weights of HFBI (7.5 kDa) and BMO or BMR (54 and 64 kDa, respectively), a flexible but not too long linker was considered suitable to retain the functional integrity of both domains; especially the selfassembling capability of the rather small HFBI domain should not be superposed by the larger BMO or BMR domains
Summary
Cytochromes P450 are heme-containing monooxygenases that catalyze selective oxidations of a vast variety of organic molecules. Among the substrates of P450s are fatty acids, alkanes, steroids, terpenes, and antibiotics (Bernhardt, 1996; Bernhardt and Urlacher, 2014) The significance of these enzymes in biological, pharmacological, and biotechnological processes has been demonstrated in a large number of publications and emphasized in many reviews (Wong, 1998; Guengerich, 2008; Julsing et al, 2008; Jung et al, 2011; Podust and Sherman, 2012; Urlacher and Girhard, 2012; Bernhardt, 2013; Munro et al, 2013). P450s can generally be considered as multi-protein systems composed of a hemecontaining monooxygenase component and either two redox proteins (a ferredoxin or flavodoxin, and a flavin-dependent reductase) or a diflavin cytochrome P450 reductase (Hannemann et al, 2007; McLean et al, 2015) Due to this multi-component nature of P450 systems, their biotechnological applications are mainly restricted to whole-cell processes
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