Abstract
Many products of secondary metabolism are activated by quorum sensing (QS), yet even at cell densities sufficient for QS, their production may be repressed under suboptimal growth conditions via mechanisms that still require elucidation. For many beneficial plant-associated bacteria, secondary metabolites such as phenazines are important for their competitive survival and plant-protective activities. Previous work established that phenazine biosynthesis in Pseudomonas chlororaphis 30-84 is regulated by the PhzR/PhzI QS system, which in turn is regulated by transcriptional regulator Pip, two-component system RpeA/RpeB and stationary phase/stress sigma factor RpoS. Disruption of MiaA, a tRNA modification enzyme, altered primary metabolism and growth leading to widespread effects on secondary metabolism, including reduced phenazine production and oxidative stress tolerance. Thus, the miaA mutant provided the opportunity to examine the regulation of phenazine production in response to altered metabolism and growth or stress tolerance. Despite the importance of MiaA for translation efficiency, the most significant effect of miaA disruption on phenazine production was the reduction in the transcription of phzR, phzI and pip, whereas neither the transcription nor translation of RpeB, a transcriptional regulator of pip, was affected. Constitutive expression of rpeB or pip in the miaA mutant completely restored phenazine production, but it resulted in further growth impairment. Constitutive expression of RpoS alleviated sensitivity to oxidative stress resulting from RpoS translation inefficiency in the miaA mutant, but it did not restore phenazine production. Our results support the model that cells curtail phenazine biosynthesis under suboptimal growth conditions via RpeB/Pip-mediated regulation of QS.
Highlights
Phenazines are heterocyclic, nitrogen-containing compounds that are produced by a number of bacterial genera
Means followed by the same letter are not significantly different as determined by Fisher’s protected LSD test (P>0.05). Both the wild-type and the miaA mutant significantly increased phenazine production compared to the same strains carrying an empty vector. These results indicate that reduced phenazine production by the miaA mutant was due to the reduced expression of pip, which led to the reduction in phzI/phzR quorum sensing (QS)-mediated activities
Our study showed reductions in the cellular yields of 30-84MiaA compared to the wild-type in all medium types tested, with the largest differences in yield observed in phenazine-promoting PPMD medium, supporting the highest phenazine production and cellular yield by the wild-type
Summary
Phenazines are heterocyclic, nitrogen-containing compounds that are produced by a number of bacterial genera. They have been studied as antimicrobial compounds that are determinants of the biological control abilities of certain rhizosphere-associated Pseudomonas species, including Pseudomonas chlororaphis and Pseudomonas fluorescens, as well as virulence factors important in Pseudomonas aeruginosa infections. The antimicrobial activity and virulence traits associated with phenazine production are related to their ability to generate reactive oxygen species. In addition to pathogen inhibition, phenazine production by P. chlororaphis 30-84 is essential for rhizosphere persistence [7], biofilm formation [8] and extracellular DNA release [9]. Phenazine production alters the expression of many genes, including those involved in oxidative stress response, cell autolysis, production of other secondary metabolites, iron transport and efflux mechanisms [9, 10]
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