Evolutionary biologists have postulated that several fitness advantages may be conferred by the maintenance of duplicate genes, including environmental adaptation resulting from differential regulation. We examined the expression and physiological contributions of two redundant operons in the adaptable bacterium Pseudomonas aeruginosa PA14. These operons, phzA1-G1 (phz1) and phzA2-G2 (phz2), encode nearly identical sets of proteins that catalyze the synthesis of phenazine-1-carboxylic acid, the precursor for several phenazine derivatives. Phenazines perform diverse roles in P. aeruginosa physiology and act as virulence factors during opportunistic infections of plant and animal hosts. Although reports have indicated that phz1 is regulated by the Pseudomonas quinolone signal, factors controlling phz2 expression have not been identified, and the relative contributions of these redundant operons to phenazine biosynthesis have not been evaluated. We found that in liquid cultures, phz1 was expressed at higher levels than phz2, although phz2 showed a greater contribution to phenazine production. In colony biofilms, phz2 was expressed at high levels, whereas phz1 expression was not detectable, and phz2 was responsible for virtually all phenazine production. Analysis of mutants defective in quinolone signal synthesis revealed a critical role for 4-hydroxy-2-heptylquinoline in phz2 induction. Finally, deletion of phz2, but not of phz1, decreased lung colonization in a murine model of infection. These results suggest that differential regulation of the redundant phz operons allows P. aeruginosa to adapt to diverse environments. G ene duplications give rise to genetic redundancy, an unstable condition that would not be expected to persist over time (1). This property is exhibited by diverse genomes (2-4), however, and evolutionary theorists have proposed several mechanisms whereby duplicate genes might provide selective advantages (5); for example, redundancy may be favored when spatial or temporal differences in expression enable tissue-specific variation or survival under varying environmental conditions (6, 7). Products of duplicated genes are involved in crucial cellular processes, including signal transduction, development, and metabolism (8).The genome of the bacterium Pseudomonas aeruginosa, an opportunistic pathogen that thrives in both soil and host environments, contains two redundant seven-gene operons termed phzA1-G1 (phz1) and phzA2-G2 (phz2). These operons are nearly identical (∼98% similarity at the DNA level), and each encodes the biosynthetic enzymes for phenazine-1-carboxylic acid (PCA) (9). Downstream modifications derivatize this precursor, generating other phenazines (SI Appendix, Fig. S1A). Pseudomonad phenazines are toxic to many other organisms and cell types due to their inherent redox activity (10, 11). Studies conducted in various plant and animal models of infection have implicated phenazines in colonization and pathogenicity (12, 13). In addition, recent studies have elucidated beneficial roles...
In enterics, the transcription factor SoxR triggers a global stress response by sensing a broad spectrum of redox-cycling compounds. In the non-enteric bacteria Pseudomonas aeruginosa and Streptomyces coelicolor, SoxR is activated by endogenous redox-active small molecules and only regulates a small set of genes. We investigated if the more general response in enterics is reflected in the ability of SoxR to sense a wider range of redox-cycling compounds. Indeed, while Escherichia coli SoxR is tuned to structurally diverse compounds that span a redox range of −450 to +80 mV, P. aeruginosa and S. coelicolor SoxR are less sensitive to viologens, which have redox potentials below −350 mV. Using a mutagenic approach, we pinpointed three amino acids that contribute to the reduced sensitivity of P. aeruginosa and S. coelicolor SoxR. Notably these residues are not conserved in homologs of the Enterobacteriaceae. We further identified a motif within the sensor domain that tunes the activity of SoxR from enterics – inhibiting constitutive activity while allowing sensitivity to drugs with low redox potentials. Our findings highlight how small alterations in structure can lead to the evolution of proteins with distinct specificities for redox-active small molecules.
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