Benjamin R. Lundgren scite author profile

There is a wealth of information on the genetic regulation and biochemical properties of bacterial C 4 -dicarboxylate transport systems. In sharp contrast, there are far fewer studies describing the transport and assimilation of C 5 -dicarboxylates among bacteria. In an effort to better our understanding on this subject, we identified the structural and regulatory genes necessary for the utilization of ␣-ketoglutarate (␣-KG) in Pseudomonas aeruginosa PAO1. The PA5530 gene, encoding a putative dicarboxylate transporter, was found to be essential for the growth of P. aeruginosa PAO1 on both ␣-KG and glutarate (another C 5 -dicarboxylate). Metabolite analysis confirmed that the PA5530 gene was necessary for the uptake of extracellular ␣-KG. Like other substrate-inducible transporter genes, expression of the PA5530 gene was induced by extracellular C 5 -dicarboxylates. It was later found that the expression of the PA5530 gene was driven solely by a ؊24/؊12 promoter recognized by the alternative sigma factor RpoN. Surprisingly, the enhancer binding protein MifR, which is known to have an essential role in biofilm development, was required for the expression of the PA5530 gene. The MifR protein is homologous to other transcriptional regulators involved in dicarboxylate assimilation, suggesting that MifR might interact with RpoN to activate the expression of the PA5530 gene in response to extracellular C 5 -dicarboxylates, especially ␣-KG. The results of this study provide a framework for exploring the assimilation of ␣-KG in other pseudomonads.

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Gene PA2449 Is Essential for Glycine Metabolism and Pyocyanin Biosynthesis in Pseudomonas aeruginosa PAO1

Lundgren

Thornton

Dornan

et al. 2013

J Bacteriol

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bMany pseudomonads produce redox active compounds called phenazines that function in a variety of biological processes. Phenazines are well known for their toxicity against non-phenazine-producing organisms, which allows them to serve as crucial biocontrol agents and virulence factors during infection. As for other secondary metabolites, conditions of nutritional stress or limitation stimulate the production of phenazines, but little is known of the molecular details underlying this phenomenon. Using a combination of microarray and metabolite analyses, we demonstrate that the assimilation of glycine as a carbon source and the biosynthesis of pyocyanin in Pseudomonas aeruginosa PAO1 are both dependent on the PA2449 gene. The inactivation of the PA2449 gene was found to influence the transcription of a core set of genes encoding a glycine cleavage system, serine hydroxymethyltransferase, and serine dehydratase. PA2449 also affected the transcription of several genes that are integral in cell signaling and pyocyanin biosynthesis in P. aeruginosa PAO1. This study sheds light on the unexpected relationship between the utilization of an unfavorable carbon source and the production of pyocyanin. PA2449 is conserved among pseudomonads and might be universally involved in the assimilation of glycine among this metabolically diverse group of bacteria.

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