SummaryPolyphosphate kinase 1 (PPK1) helps bacteria to survive under stress. The ppk1 gene of Mycobacterium tuberculosis was overexpressed in Escherichia coli and characterized. Residues R230 and F176, predicted to be present in the head domain of PPK1, were identified as residues critical for polyphosphate (polyP)-synthesizing ability and dimerization of PPK1. A ppk1 knockout mutant of Mycobacterium smegmatis was compromised in its ability to survive under long-term hypoxia. The transcription of the rel gene and the synthesis of the stringent response regulator ppGpp were impaired in the mutant and restored after complementation with ppk1 of M. tuberculosis, providing evidence that PPK1 is required for the stringent response. We present evidence that PPK1 is likely required for mprAB-sigE-rel signalling. s E regulates the transcription of rel, and we hypothesize that under conditions of stress polyP acts as a preferred donor for MprB-mediated phosphorylation of MprA facilitating transcription of the sigE gene thereby leading finally to the enhancement of the transcription of rel in M. smegmatis and M. tuberculosis. Downregulation of ppk1 led to impaired survival of M. tuberculosis in macrophages. PolyP plays a central role in the stress response of mycobacteria.
Phenotypic heterogeneity in an isogenic, microbial population enables a subset of the population to persist under stress. In mycobacteria, stresses like nutrient and oxygen deprivation activate the stress response pathway involving the two-component system MprAB and the sigma factor, SigE. SigE in turn activates the expression of the stringent response regulator, rel. The enzyme polyphosphate kinase 1 (PPK1) regulates this pathway by synthesizing polyphosphate required for the activation of MprB. The precise manner in which only a subpopulation of bacterial cells develops persistence, remains unknown. Rel is required for mycobacterial persistence. Here we show that the distribution of rel expression levels in a growing population of mycobacteria is bimodal with two distinct peaks corresponding to low (L) and high (H) expression states, and further establish that a positive feedback loop involving the mprAB operon along with stochastic gene expression are responsible for the phenotypic heterogeneity. Combining single cell analysis by flow cytometry with theoretical modeling, we observe that during growth, noise-driven transitions take a subpopulation of cells from the L to the H state within a “window of opportunity” in time preceding the stationary phase. It is these cells which adapt to nutrient depletion in the stationary phase via the stringent response. We find evidence of hysteresis in the expression of rel in response to changing concentrations of PPK1. Hysteresis promotes robustness in the maintenance of the induced state. Our results provide, for the first time, evidence that bistability and stochastic gene expression could be important for the development of “heterogeneity with an advantage” in mycobacteria and suggest strategies for tackling tuberculosis like targeting transitions from the low to the high rel expression state.
A cluster of genes encoded by ORFs Rv0014c-Rv0018c in Mycobacterium tuberculosis encodes candidate cell division proteins RodA and PBPA, a pair of serine/threonine kinases (STPKs), PknA and PknB, and a phosphatase, PstP. The organization of genes encompassing this region is conserved in a large number of mycobacterial species. This study demonstrates that recombinant PBPA of M. tuberculosis binds benzylpenicillin. Knockout of its counterpart in M. smegmatis resulted in hindered growth and defective cell septation. The phenotype of the knockout (PBPA-KO) could be restored to that of the wild-type upon expression of PBPA of M. tuberculosis. PBPA localized to the division site along with newly synthesized peptidoglycan, between segregated nucleoids. In vivo coexpression of PBPA and PknB, in vitro kinase assays and site-specific mutagenesis substantiated the view that PknB phosphorylates PBPA on T362 and T437. A T437A mutant could not complement PBPA-KO. These studies demonstrate for the first time that PBPA, which belongs to a subclass of class B high-molecular-mass PBPs, plays an important role in cell division and cell shape maintenance. Signal transduction mediated by PknB and PstP likely regulates the positioning of this PBP at the septum, thereby regulating septal peptidoglycan biosynthesis.
SummaryIn bacteria, biogenesis of cell wall at the division site requires penicillin-binding protein 3 (PBP3) (or FtsI). Using pull-down, bacterial two-hybrid, and peptide-based interaction assays, we provide evidence that FtsW of Mycobacterium tuberculosis
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