Comamonas testosteroni TAU1 was not able to grow on phenol as a sole carbon and energy source, but it gained the ability to utilize phenol after a 2-3-week incubation in a medium containing phenol. Phenol hydroxylase (PH) and catechol2,3-dioxygenase (C230) were highly induced by phenol in the adapted strain designated as strain P1, suggesting that phenol was degraded via the meta-pathway. Gene clusters for phenol degradation were isolated from both strains TAU1 and P1. The structural genes encoding multicomponent PH and C230 (aphKLMNOPQB), and a regulatory gene of the NtrC family (aphR), were located in a divergent transcriptional organization. The cloned aphKLMNOPQl3 genes from either strain TAU1 or strain P1 produced active PH and C230 enzymes in strain TA441. No difference was found between the strains in the sequences of aphR and the intergenic promoter region of aphK and aphR. However, the transcriptional activities of the aphK and aphR promoters were higher in strain P1 than in strain TA441. The aphK-promoter activity was not observed in aphR mutant strains and these strains could not grow on phenol. The aphR mutant of strain P1 was able to grow on phenol after transformation with a recombinant aphR gene but strain TAM1 was not, suggesting that the expression of the aph genes is silenced by an unidentified repressor in strain TAU1 and that this repressor is modified in strain P1.
Comamonas testosteroni TA441 adapts to utilization of phenol upon incubation with phenol as the major carbon source. Strain TA441 has a cluster of genes (aphKLMNOPQB) encoding the catabolic enzymes phenol hydroxylase and catechol 2,3‐dioxygenase, and a divergently transcribed regulatory gene (aphR), but these genes are silent until adaptation occurs. We found another regulatory gene (aphS) downstream of aphR. AphS belongs to the GntR family of transcriptional regulators. All adapted strains were found to have mutations in the aphS gene or in the aphR–aphS intervening region. The adapted strains expressed phenol hydroxylase and catechol 2,3‐dioxygenase activity in the presence of phenol. The transcriptional activity of both the aphK and the aphR promoters was elevated in the adapted strains. A strain whose aphS gene was artificially disrupted was found to be able to grow using phenol, and the cells showed high levels of the above‐mentioned transcriptional and enzymatic activities, indicating that adaptation was caused only by the mutation in the aphS gene. Gel retardation analysis revealed that AphS bound to two specific sites in the promoter region between aphK and aphR. These results indicate that the active aphS gene product acts as a trans‐acting factor and represses transcription of the aph genes in strain TA441.
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