Towards engineered topogenesis of cytochrome b(5) and P450 for in vivo transformation of xenobiotics.

Nature is endowed with catalysts capable of an unprecedented diversity of biotransformations, beyond the capabilities of synthetic chemistries. In a biotechnological context, there is a growing and emerging need to tap this catalytic potential. CYP (cytochrome P450) represents a superfamily of enzymes capable of a diverse array of catalytic activities. Distinct members are engaged in biosynthetic reactions within many organisms, while others have a role in the detoxification of foreign compounds. The latter substrates include medicines, pollutants, pesticides, carcinogens, perfumes and herbicides, representing considerable applied importance for pharmacology and toxicology. CYPs show a high degree of stereo- and regio-specificity for their reactions, which have wide industrial applications. Recombinant CYPs are commonly expressed as active recombinant cytosolic forms in Escherichia coli. However, selective permeability of E. coli to many substrates and products can cause problems with product recovery when using whole-cell systems. To overcome these problems, we have been developing approaches to facilitate export of functional recombinant haemoproteins to the inner membrane, periplasm and the outer membrane of E. coli. Here, we describe the progress in relation to cytochrome b(5) and CYPs.

Kinetic constants of signal peptidase I using cytochrome b5 as a precursor substrate.

A procedure is described for measuring Escherichia coli signal peptidase I activity which exploits an intact precursor protein composed of the alkaline phosphatase signal peptide fused to the full length mammalian cytochrome b5. This cytochrome b5 precursor protein has been extensively characterised and shown to be processed accurately by purified signal peptidase I [Protein Expr. Purif. 7 (1996) 237]. The amphipathic, chimaeric cytochrome b5 precursor was isolated in mg quantities in a highly homogeneous state under non-denaturing conditions. The processing of the cytochrome b5 precursor by signal peptidase displayed Michaelis-Menten kinetics with K(m)=50 microM and k(cat)=11 s(-1). The K(m) was 20-fold lower than that obtained with signal peptide substrates and 3-fold higher than that reported for pro-OmpA-nuclease A precursor fusion. The corresponding turnover number, k(cat), was four orders of magnitude greater than the peptide substrates but was 2-fold lower than pro-OmpA-nuclease A precursor fusion. These results confirm that both the affinities and the catalytic power of the signal peptidase are significantly higher for macromolecular precursor substrates than for the shorter signal peptide substrates.

Human sterol 14alpha-demethylase activity is enhanced by the membrane-bound state of cytochrome b(5).

Human sterol 14alpha-demethylase (P45051; CYP51) catalyzes the oxidative removal of the C32 methyl group of dihydrolanosterol, an essential step in the cholesterol biosynthetic pathway. The reaction is dependent upon NADPH cytochrome P450 reductase (CPR) that donates the electrons for the catalytic cycle. Here we used a recombinant yeast CPR to investigate the abilities of four different forms of cytochrome b(5) to support sterol demethylation activity of CYP51. The cytochrome b(5) derivatives were genetically engineered forms of the native rat cytochrome b(5) core-tail: the soluble globular b(5) core (core), the core linked at its N-terminus with the secretory signal sequence of alkaline phosphatase (signal-core), and the signal sequence linked to the native b(5) (signal-core-tail). The rat core-tail enzyme greatly stimulated sterol demethylation, whereas the signal-core-tail was only marginally active. In contrast, the core and signal-core constructs were completely inactive in stimulating the demethylation reaction. Additionally, cytochrome b(5) enhanced sterol demethylation by more than threefold by accepting electrons from soluble yeast CPR and in its ability to reduce P450. We show that the nature of transient linkage between the hemoproteins and the redox partners is most likely brought about electrostatically, although productive interaction between cytochrome b(5) and CYP51 is governed by the membrane-insertable hydrophobic region in the cytochrome b(5) which in turn determines the correct spatial orientation of the core. This is the first report showing the stimulation of CYP51 by cytochrome b(5).

Sheep pancreatic microsomes as an alternative to the dog source for studying protein translocation.

A procedure is described for the preparation of rough membrane vesicles of endoplasmic-reticular origin from the pancreas of sheep. These isolated membranes translocate, process and glycosylate in vitro-translated heterologous proteins in a manner comparable with that exhibited by dog pancreatic microsomes.