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The Phn and Pst systems of Mycobacterium smegmatis : phosphate transport and gene regulation

Phosphate is an essential but often growth-limiting nutrient for bacteria. At low concentrations of phosphate in the growth medium, bacteria induce high-affinity uptake systems for phosphate, and this is usually the ABC-type phosphate specific transport system Pst. In the fully sequenced genomes of pathogenic species of mycobacteria, several copies of the genes encoding for the Pst system (pstSCAB) have been identified and some of these genes have been shown to be virulence factors. The reasons for the presence of multiple copies of pst genes in pathogenic mycobacteria are not understood, and phosphate transport by these bacteria, as well as the gene regulation involved, is poorly characterised. The fast-growing M. smegmatis contains only a single copy of the pst operon, but we recently identified a gene locus containing three genes, phnDCE, which encode for a putative ABC-type phosphate/phosphonate transport system, and a gene, phnF, which encodes for a putative transcriptional regulator of the HutC subfamily of GntR like regulators.
To identify a function for the PhnDCE transport system and to characterise high-affinity phosphate transport in M. smegmatis, we created allelic exchange mutants in phnD and pstS, as well as a phnD pstS double deletion mutant. All three mutants failed to grow in minimal medium containing 10 mM phosphate, while the wildtype was able to grow in the presence of micromolar phosphate concentrations. No differences were observed in complex growth medium. Steady-state levels of [��P]-phosphate uptake were approximately 25% lower in all mutant strains as compared to the wildtype. Kinetics of phosphate uptake in the wildtype strain when grown at low phosphate concentrations (50 [mu]M P[i]) were biphasic, suggesting the presence of two inducible transport systems with apparent K[m] values of 16 [mu]M P[i] and 64 [mu]M P[i], respectively. Analysis of the kinetics of phosphate transport in the mutant strains led us to the proposition that the Pst system has an apparent Km value of ca. 16 [mu]M P[i], and the Phn system has an apparent Km of ca. 60 [mu]M P[i]. A third inducible phosphate transport system, which was active in the double mutant strain, had an apparent K[m] of ca. 90 [mu]M P[i]. Uptake of phosphate in all strains was not inhibited by the presence of excess phosphonates or phosphite, suggesting that all three transport systems were specific for phosphate. The study of phosphate transport in the presence of various metabolic inhibitors revealed that uptake by the Phn and Pst systems is driven by ATP-hydrolysis, consistent with ABC-type transport, while the third, unidentified transport system may be driven by the proton motive force.
We showed that phnDCE formed an operon, and that the promoter area of the operon lies within 200 bp of the start of phnD. To investigate the regulation of the phn and pst genes, β-galacosidase activities of strains carrying transcriptional lacZ-fusions of the pstSCAB, phnDCE and phnF promoter areas, and levels of mRNA of the phn and pst genes were studied. All genes were induced when phosphate concentrations fell below a threshold value of 30 [mu]M, which coincided with a shift in the growth characteristics of M. smegmatis. Expression of the pst operon appeared to be controlled directly by the PhoPR two-component regulatory system, while the phn operon may be under direct or indirect control by PhoPR.
To identify a role for PhnF in the regulation of phn gene expression, we created a phnF deletion mutant. PhnF appeared to repress transcription of phnDCE and phnF under phosphate-replete conditions. We identified two putative binding sequences for PhnF in the intergenic region between phnD and phnF with the sequence TGGTATAGACCA, which is similar to the proposed recognition consensus for HutC-like transcriptional regulators. Using site-directed mutagenesis of these sequences, we demonstrated that they are required for the repression of phnDCE and phnF. To prove PhnF binding to these potential binding sites, we attempted to express the M. smegmatis PhnF protein in E. coli, but could not obtain soluble recombinant protein. Electrophoretic mobility shift assays of the phnDCE promoter fragment using cell-free crude extracts of M. smegmatis were not successful.
We propose that Pst and Phn both constitute high-affinity phosphate specific transport systems of M. smegmatis, and that a third inducible phosphate transport system is present in this bacterium. PhnF is required for repression of phnDCE and phnF transcription under phosphate-replete conditions, while induction of the pst operon, and possibly the phn operon, under phosphate-limited conditions involves the PhoPR system.

Identiferoai:union.ndltd.org:ADTP/217589
Date January 2006
CreatorsGebhard, Susanne, n/a
PublisherUniversity of Otago. Department of Microbiology & Immunology
Source SetsAustraliasian Digital Theses Program
LanguageEnglish
Detected LanguageEnglish
Rightshttp://policy01.otago.ac.nz/policies/FMPro?-db=policies.fm&-format=viewpolicy.html&-lay=viewpolicy&-sortfield=Title&Type=Academic&-recid=33025&-find), Copyright Susanne Gebhard

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