A direct electrode-driven P450 cycle for biocatalysis

The large potential of redox enzymes to carry out formation of high value organic compounds motivates the search for innovative strategies to regenerate the cofactors needed by their biocatalytic cycles. Here, we describe a bioreactor where the reducing power to the cycle is supplied directly to purified cytochrome CYP101 (P450cam; EC 1.14.15.1) through its natural redox partner (putidaredoxin) using an antimony-doped tin oxide working electrode. Required oxygen was produced at a Pt counter electrode by water electrolysis. A continuous catalytic cycle was sustained for more than 5 h and 2,600 enzyme turnovers. The maximum product formation rate was 36 nmol of 5-exo-hydroxycamphor/nmol of CYP101 per min.

The University of Minnesota Biocatalysis/Biodegradation Database: emphasizing enzymes

The University of Minnesota Biocatalysis/Biodegradation Database (UM-BBD, http://umbbd.ahc.umn.edu/) provides curated information on microbial catabolic enzymes and their organization into metabolic pathways. Currently, it contains information on over 400 enzymes. In the last year the enzyme page was enhanced to contain more internal and external links; it also displays the different metabolic pathways in which each enzyme participates. In collaboration with the Nomenclature Commission of the International Union of Biochemistry and Molecular Biology, 35 UM-BBD enzymes were assigned complete EC codes during 2000. Bacterial oxygenases are heavily represented in the UM-BBD; they are known to have broad substrate specificity. A compilation of known reactions of naphthalene and toluene dioxygenases were recently added to the UM-BBD; 73 and 108 were listed respectively. In 2000 the UM-BBD is mirrored by two prestigious groups: the European Bioinformatics Institute and KEGG (the Kyoto Encyclopedia of Genes and Genomes). Collaborations with other groups are being developed. The increased emphasis on UM-BBD enzymes is important for predicting novel metabolic pathways that might exist in nature or could be engineered. It also is important for current efforts in microbial genome annotation.

Cloning of an organic solvent-resistance gene in Escherichia coli: the unexpected role of alkylhydroperoxide reductase.

Although bacterial strain able to grow in the presence of organic solvents have been isolated, little is known about the mechanism of their resistance. In the present study, 1,2,3,4-tetrahydronaphthalene (tetralin), a solvent with potential applications in industrial biocatalysis, was used to select a resistant mutant of Escherichia coli. The resultant mutant strain was tested for resistance to a wide range of solvents of varying hydrophobicities and was found to be resistant not only to tetralin itself but also to cyclohexane, propylbenzene, and 1,2-dihydronaphthalene. A recombinant library from mutant DNA was used to clone the resistance gene. The sequence of the cloned locus was determined and found to match the sequence of the previously described alkylhydroperoxide reductase operon ahpCF. The mutation was localized to a substitution of valine for glycine at position 142 in the coding region of ahpC, which is the gene encoding the catalytic subunit of the enzyme. The ahpC mutant was found to have an activity that was three times that of the wild type in reducing tetralin hydroperoxide to 1,2,3,4-tetrahydro-1-naphthol. We conclude that the toxicity of such solvents as tetralin is caused by the formation of toxic hydroperoxides in the cell. The ahpC mutation increases the activity of the enzyme toward hydrophobic hydroperoxides, thereby conferring resistance. The ahpC mutant was sensitive to the more hydrophilic solvents xylene and toluene, suggesting that there are additional mechanisms of solvent toxicity. Mutants resistant to a mixture of xylene and tetralin were isolated from the ahpC mutant but not from the wild-type strain.