Exploration of Natural and Artificial Sequence Spaces: Towards a Functional Remodeling of Membrane-bound Cytochrome P450

Engineering and assaying of cytochrome P450 biocatalysts

Cytochrome P450s constitute a highly fascinating superfamily of enzymes which catalyze a broad range of reactions. They are essential for drug metabolism and promise industrial applications in biotechnology and biosensing. The constant search for cytochrome P450 enzymes with enhanced catalytic performances has generated a large body of research. This review will concentrate on two key aspects related to the identification and improvement of cytochrome P450 biocatalysts, namely the engineering and assaying of these enzymes. To this end, recent advances in cytochrome P450 development are reported and commonly used screening methods are surveyed.

A shuffled CYP2C library with a high degree of structural integrity and functional versatility

Cytochrome P450 (CYP) enzymes involved in mammalian xenobiotic metabolism are attractive targets for the engineering of biocatalysts since they have broad and overlapping substrate and reaction substrate specificities. In this report, a library of chimeric mutants was prepared from CYP2C8, CYP2C9, CYP2C18 and CYP2C19 by DNA family shuffling. Twelve randomly selected clones were fully sequenced and showed 9+/-2 crossovers and 1.5+/-0.5 spontaneous mutations per approximately 1.5kbp open reading frame. CYP hemoprotein expression was observed in 50% (microaerobic culture) to 54% (aerobic culture) of clones. The functional diversity of the library was assessed using three luminogenic substrates, diclofenac and indole as probe substrates. A random sample of 26 clones revealed two clones with activity towards luciferin ME, one towards luciferin H and five towards diclofenac 4'-hydroxylation. One mutant showed activity towards all three substrates. Of 96 clones screened on solid media, one showed elevated indigo production compared to the parental forms. Turnover rates for luciferin ME and H metabolism by CYP2C9 and mutants were at least one order of magnitude higher in experiments with membranes compared to whole cells, consistent with impaired product egress from cells. Apparent K(m) values were increased in whole cell incubations with luciferin H suggesting impaired access of the substrate to the active site of the enzymes in whole cells. Finally screening with a panel of CYP2C ligands using CYP2C9 or active mutants revealed different patterns of inhibition and heteroactivation of metabolism of luciferin analogs.

Extending the capabilities of nature's most versatile catalysts: directed evolution of mammalian xenobiotic-metabolizing P450s

Cytochrome P450 enzymes are amongst the most versatile enzymatic catalysts known. The ability to introduce a single atom of oxygen into an organic substrate has led to the diversification and exploitation of these enzymes throughout nature. Nowhere is this versatility more apparent than in the mammalian liver, where P450 monooxygenases catalyze the metabolic clearance of innumerate drugs and other environmental chemicals. In addition to the aromatic and aliphatic hydroxylations, N- and O-dealkylations, and heteroatom oxidations that are common in drug metabolism, many more unusual reactions catalyzed by P450s have been discovered, including reductions, group transfers and other biotransformations not typically associated with monooxygenases. A research area that shows great potential for development over the next few decades is the directed evolution of P450s as biocatalysts. Mammalian xenobiotic-metabolizing P450s are especially well suited to such protein engineering due to their ability to interact with relatively wide ranges of substrates with marked differences in structure and physicochemical properties. Typical characteristics, such as the low turnover rates and poor coupling seen during the metabolism of xenobiotics, as well as the enzyme specificity towards particular substrates and reactions, can be improved by directed evolution. This mini-review will cover the fundamental enabling technologies required to successfully engineer P450s, examine the work done to date on the directed evolution of mammalian forms, and provide a perspective on what will be required for the successful implementation of engineered enzymes.