Use of transposon Tn5367 mutagenesis and a nitroimidazopyran-based selection system to demonstrate a requirement for fbiA and fbiB in coenzyme F(420) biosynthesis by Mycobacterium bovis BCG.

Three transposon Tn5367 mutagenesis vectors (phAE94, pPR28, and pPR29) were used to create a collection of insertion mutants of Mycobacterium bovis strain BCG. A strategy to select for transposon-generated mutants that cannot make coenzyme F(420) was developed using the nitroimidazopyran-based antituberculosis drug PA-824. One-third of 134 PA-824-resistant mutants were defective in F(420) accumulation. Two mutants that could not make F(420)-5,6 but which made the biosynthesis intermediate FO were examined more closely. These mutants contained transposons inserted in two adjacent homologues of Mycobacterium tuberculosis genes, which we have named fbiA and fbiB for F(420) biosynthesis. Homologues of fbiA were found in all seven microorganisms that have been fully sequenced and annotated and that are known to make F(420). fbiB homologues were found in all but one such organism. Complementation of the fbiA mutant with fbiAB and complementation of the fbiB mutant with fbiB both restored the F(420)-5,6 phenotype. Complementation of the fbiA mutant with fbiA or fbiB alone did not restore the F(420)-5,6 phenotype, but the fbiA mutant complemented with fbiA produced F(420)-2,3,4 at levels similar to F(420)-5,6 made by the wild-type strain, but produced much less F(420)-5. These data demonstrate that both genes are essential for normal F(420)-5,6 production and suggest that the fbiA mutation has a partial polar effect on fbiB. Reverse transcription-PCR data demonstrated that fbiA and fbiB constitute an operon. However, very low levels of fbiB mRNA are produced by the fbiA mutant, suggesting that a low-level alternative start site is located upstream of fbiB. The specific reactions catalyzed by FbiA and FbiB are unknown, but both function between FO and F(420)-5,6, since FO is made by both mutants.

Secretory overproduction of Arthrobacter simplex 3-ketosteroid delta 1-dehydrogenase by Streptomyces lividans with a multi-copy shuttle vector.

The gene for 3-ketosteroid delta 1-dehydrogenase (ksdD) of Arthrobacter simplex was expressed in Streptomyces lividans and the secreted enzyme was overproduced by using a multi-copy shuttle vector composed of pIJ702 and pUC19. Deletional analysis of the recombinant plasmid showed that the entire coding sequence of the ksdD gene was located within a 7-kb segment of the chromosomal DNA obtained from the enzyme-producing strain of A. simplex. When S. lividans carrying the recombinant plasmid was grown in an appropriate medium, the cells produced about 100-fold more 3-ketosteroid delta 1-dehydrogenase than the original strain. Although the percentage of enzyme secreted was changed during cultivation, a maximum 55% of the enzyme was secreted into the cultured medium of S. lividans, while A. simplex did not produce the enzyme extracellularly. Secretory overproduction of 3-ketosteroid delta 1-dehydrogenase in S. lividans was also identified by sodium dodecyl sulfate/polyacrylamide gel electrophoresis and on native gel, and the enzyme reaction was confirmed by reverse-phase HPLC using 4-androstene-3,17-dione as a substrate.

Purification and characterization of the 3-ketosteroid-delta 1-dehydrogenase of Arthrobacter simplex produced in Streptomyces lividans.

The 3-ketosteroid-delta 1-dehydrogenase (KS1DH) gene of Arthrobacter simplex IFO12069 cloned in Streptomyces lividans was overexpressed, resulting in production of the enzyme both extracellularly and intracellularly. The enzyme was purified by ammonium sulfate fractionation and chromatographies using DEAE-Toyopearl, Butyl-Toyopearl and Toyopearl HW55S from the supernatant of culture broth and cell-free extracts of S. lividans, and both preparations showed the same characteristics. The N-terminal amino acid sequence of both KS1DHs was M-D-W-A-E-E-Y-D, which coincided with the amino acid sequence deduced from the nucleotide sequence. Thus, the extracellular enzyme may derived from leakage of S. lividans cells during cultivation rather than secretion by processing of the signal sequence. The molecular weight of the enzyme was about 55,000, identical with the size deduced from the nucleotide sequence (M(r) 54,329). The optimum conditions for its activity were pH 10.0 and 40 degrees C. The enzyme catalyzed the conversion of several 3-keto-steroids, but those containing 11 alpha- or 11 beta-hydroxyl group were converted at low rates. The amino acid sequence of KS1DH from A. simplex is similar to those of KS1DH of Pseudomonas testosteroni and fumarate reductase from Shewanella putrefaciens.

Molecular cloning, expression in Streptomyces lividans, and analysis of a gene cluster from Arthrobacter simplex encoding 3-ketosteroid-delta 1-dehydrogenase, 3-ketosteroid-delta 5-isomerase and a hypothetical regulatory protein.

The Arthrobacter simplex gene coding for 3-ketosteroid-delta 1-dehydrogenase, a key enzyme in the degradation of the steroid nucleus, was cloned in Streptomyces lividans. Nucleotide sequence analysis revealed that the gene for 3-ketosteroid-delta 1-dehydrogenase (ksdD) is clustered with at least two more genes possibly involved in steroid metabolism. Upstream of ksdD, we found a gene, ksdR, encoding a hypothetical regulatory protein that shows homologies to KdgR, the negative regulator of pectin biodegradation in Erwinia, and GyIR, the activator for glycerol metabolism in Steptomyces. A helix-turn-helix DNA-binding domain can be predicted at similar positions near the N-terminal of KsdR, KdgR and GyIR. ksdl adjoining downstream to ksdD codes for a protein that has strong similarities to 3-ketosteroid-delta 5-isomerases. The highly conserved Tyr and Asp residues are present in the active-centre motif of the enzyme. The translated ksdD gene product was found to be similar to the 3-ketosteroid-delta 1-dehydrogenase of Pseudomonas testosteroni and to the fumarate reductase of Shewanella putrefaciens. A region highly conserved between the two steroid dehydrogenases can be aligned to the active-centre motif of the fumarate reductase. S. lividans strains carrying the ksdD gene overexpressed 3-ketosteroid-delta 1-dehydrogenase. The expression of 3-ketosteroid-delta 5-isomerase, however, was barely detectable in recombinant S. lividans strains carrying the ksdl gene, or in the parental Arthrobacter strain.

Bacterial cholesterol oxidases are able to act as flavoprotein-linked ketosteroid monooxygenases that catalyse the hydroxylation of cholesterol to 4-cholesten-6-ol-3-one.

A new metabolite of cholesterol was found in reaction mixtures containing cholesterol or 4-cholesten-3-one as a substrate and extra- or intracellular protein extracts from recombinant Streptomyces lividans and Escherichia coli strains carrying cloned DNA fragments of Streptomyces sp. SA-COO, the producer of Streptomyces cholesterol oxidase. The new metabolite was identified as 4-cholesten-6-ol-3-one based on comparisons of its high-performance liquid chromatography, gas chromatography/mass spectrometry, infrared and proton-nuclear magnetic resonance spectra with those of an authentic standard. Genetic analyses showed that the enzyme responsible for the production of 4-cholesten-6-ol-3-one is cholesterol oxidase encoded by the choA gene. Commercially purified cholesterol oxidase (EC 1.1.3.6.) of a Streptomyces sp., as well as of Brevibacterium sterolicum and a Pseudomonas sp., and a highly purified recombinant Streptomyces cholesterol oxidase were also able to catalyse the 6-hydroxylation reaction. Hydrogen peroxide accumulating in the reaction mixtures as a consequence of the 3 beta-hydroxysteroid oxidase activity of the enzyme was shown to have no role in the formation of the 6-hydroxylated derivative. We propose a possible scheme of a branched reaction pathway for the concurrent formation of 4-cholesten-3-one and 4-cholesten-6-ol-3-one by cholesterol oxidase, and the observed differences in the rate of formation of the 6-hydroxy-ketosteroid by the enzymes of different bacterial sources are also discussed.