Heterologous coexpression of the benzoate-para-hydroxylase CYP53B1 with different cytochrome P450 reductases in various yeasts.

Cytochrome P450 monooxygenases (P450) are enzymes with high potential as biocatalysts for industrial applications. Their large-scale applications are, however, limited by instability and requirement for coproteins and/or expensive cofactors. These problems are largely overcome when whole cells are used as biocatalysts. We previously screened various yeast species heterologously expressing self-sufficient P450s for their potential as whole-cell biocatalysts. Most P450s are, however, not self-sufficient and consist of two or three protein component systems. Therefore, in the present study, we screened different yeast species for coexpression of P450 and P450-reductase (CPR) partners, using CYP53B1 from Rhodotorula minuta as an exemplary P450. The abilities of three different coexpressed CPR partners to support P450 activity were investigated, two from basidiomycetous origin and one from an ascomycete. The various P450-CPR combinations were cloned into strains of Saccharomyces cerevisiae, Kluyveromyces marxianus, Hansenula polymorpha, Yarrowia lipolytica and Arxula adeninivorans, using a broad-range yeast expression vector. The results obtained supported the previous finding that recombinant A. adeninivorans strains perform excellently as whole-cell biocatalysts. This study also demonstrated for the first time the P450 reductase activity of the CPRs from R. minuta and U. maydis. A very interesting observation was the variation in the supportive activity provided by the different reductase partners tested and demonstrated better P450 activity enhancement by a heterologous CPR compared to its natural partner CPR. This study highlights reductase selection as a critical variable for consideration in the pursuit of optimal P450-based catalytic systems. The usefulness of A. adeninivorans as both a host for recombinant P450s and whole-cell biocatalyst was emphasized, supporting earlier findings.

A benzoate-activated promoter from Aspergillus niger and regulation of its activity.

The filamentous fungus Aspergillus niger is able to use benzoic acid as a sole carbon source by conversion to protocatechuic acid and subsequent metabolism. Synthesis of the first enzyme in this metabolic pathway, benzoate p-hydroxylase, is encoded by the bphA gene and positively regulated at the transcriptional level by benzoic acid. Methyl benzoate and para-aminobenzoate also act as inducers of the bphA gene. We show that bphA expression in A. niger in response to benzoate is confined to a 530-bp fragment from the bphA promoter region from -787 to -509 bp from the transcriptional start site. Electrophoretic mobility-shift assays show that a benzoate-response element, consisting of a single 6-bp sequence (5'-TAGTCA-3') within a 51-bp sequence in this region, is most likely to be involved in binding of one or more proteins that modulate the activity of the promoter in response to benzoic acid. We show through fusion of promoter fragments with the green fluorescent protein that the active sequences are located within a 200-bp sequence containing the TAGTCA benzoate-response element. Identification of the benzoate-response element in the bphA promoter region constitutes the first step in the development of a benzoate-inducible promoter system that could be used to control gene expression in fungi, and possibly in other organisms, such as plant and animal cells.

CYP53A15 of Cochliobolus lunatus, a target for natural antifungal compounds.

A novel cytochrome P450, CYP53A15, was identified in the pathogenic filamentous ascomycete Cochliobolus lunatus. The protein, classified into the CYP53 family, was capable of para hydroxylation of benzoate. Benzoate is a key intermediate in the metabolism of aromatic compounds in fungi and yet basically toxic to the organism. To guide functional analyses, protein structure was predicted by homology modeling. Since many naturally occurring antifungal phenolic compounds are structurally similar to CYP53A15 substrates, we tested their putative binding into the active site of CYP53A15. Some of these compounds inhibited CYP53A15. Increased antifungal activity was observed when tested in the presence of benzoate. Some results suggest that CYP53A15 O-demethylation activity is important in detoxification of other antifungal substances. With the design of potent inhibitors, CYP53 enzymes could serve as alternative antifungal drug targets.

Heterologous expression of the benzoate para-hydroxylase encoding gene (CYP53B1) from Rhodotorula minuta by Yarrowia lipolytica.

There is currently an increasing number of cytochrome P450 (CYP450) monooxygenase encoding genes becoming available from various genome-sequencing projects. These enzymes require association with cytochrome P450 reductase (CPR) to achieve optimal activities. In this study, the CYP53B1 gene, which encodes a benzoate para-hydroxylase, was successfully cloned from Rhodotorula minuta and overexpressed in Yarrowia lipolytica E150. Multiple copies of the CYP53B1 cDNA were cloned under the POX2 promoter, while the Y. lipolytica CPR was cloned under the isocitrate lyase promoter. Whole cell biotransformation of benzoic acid to para-hydroxybenzoic acid (pHBA) was used to analyse the hydroxylase activity of the recombinant Y. lipolytica UOFS Y-2366. Different induction conditions were tested in shake flask cultures. The highest concentration of pHBA produced by UOFS Y-2366 was 1.6 g l(-1) after 200 h when stearic acid was repeatedly added to the media. R. minuta accumulated up to 1.8 g l(-1) of pHBA within only 24 h. Thus, the specific hydroxylase activity of Y. lipolytica UOFS Y-2366 [approximately 0.07 U (g dry wt.)(-1)] was about 30 times lower than the specific hydroxylase activity of R. minuta [2.62 U (g dry wt.)(-1)]. However, the hydroxylation activity obtained with Y. lipolytica was one of the highest hydroxylation activities thus reported for whole cell biotransformation studies carried out with yeasts expressing foreign CYP450s.