The interplay between the polar growth determinant DivIVA, the segregation protein ParA and their novel interaction partner PapM controls theMycobacterium smegmatiscell cycle by modulation of DivIVA subcellular distribution

Abstract

AbstractBacterial chromosome segregation is facilitated by the ParABS system. The ParB protein binds centromere-likeparSsequences and forms nucleoprotein complexes. These nucleoprotein complexes are segregated by the dynamic ATPase ParA. In mycobacteria, ParA also interacts with the polar growth determinant DivIVA (Wag31). This interaction was earlier shown to facilitate the segregation of ParB complexes but also to affect cell extension. Here, we identify an additional partner of ParA inMycobacterium smegmatis, named PapM. UsingE. colibased analysis, we show that PapM likewise interacts with DivIVA and that the tripartite interaction of ParA-PapM-DivIVA is phosphorylation-dependent: ParA binding to DivIVA is diminished, while PapM binding is promoted upon phosphorylation of DivIVA. The presence of PapM enhances the dissociation of ParA from the DivIVA complex upon its phosphorylation. Studies ofM. smegmatismutant strains reveal that altered PapM levels influence chromosome segregation and cell length. The elimination of PapM affects ParA dynamics. Further, ParA and, to a lesser extent, PapM modulates the subcellular distribution of DivIVA. Altogether our studies show that the tripartite interplay between ParA-DivIVA and PapM controls the switch between cell division and cell elongation and in this way affects the mycobacterial cell cycle.ImportanceThe genus of Mycobacteria includes important clinical pathogens (M. tuberculosis). Bacteria of this genus share the unusual features of their cell cycle such as asymmetric polar cell elongation and long generation time. Markedly, control of the mycobacterial cell cycle still remains not fully understood. The main cell growth determinant in Mycobacteria is an essential protein DivIVA, which is also involved in cell division. DivIVA activity is controlled by phosphorylation but the mechanism and significance of this process is unknown. Here, we show how the previously established protein interaction partner of DivIVA in Mycobacteria, the segregation protein ParA, affects the DivIVA subcellular distribution. We also demonstrate the role of a newly identifiedM. smegmatisDivIVA and ParA interaction partner, a protein named PapM, and we establish how their interactions are modulated by phosphorylation. Demonstrating that the tripartite interplay affects the mycobacterial cell cycle contributes to general understanding of mycobacterial growth regulation.