Project description:Within the bacterial phylum of the Alphaproteobacteria many species show complex life cycles. Proper regulation of these life cycles requires cell cycle regulation pathways, one of which is the so-called CtrA pathway. Key factors in the CtrA pathway are the histidine kinases PleC and DivJ (located at opposite poles in the cell) and the response regulator DivK. Within the Alphaproteobacteria, stalked budding bacteria are even more asymmetric than most other representatives. How they regulate their cell cycle has not been studied before. Here, we investigated the transcriptional profiles of Hyphomonas neptunium cells lacking either PleC, DivJ or DivK and compared their profiles to that of wildtype cells. We found that the changes upon deletion of DivJ, PleC and especially DivK were smaller than expected from related organisms.

Project description:Alphaproteobacteria stand out for their complex cell cycles, which are often regulated by the DivJ/PleC-DivK-DivL-CckA-ChpT-CtrA pathway. DivJ and PleC set up the polarity of the cell, thereby eventually leading to differential activation of the DNA-binding response regulator CtrA in the two nascent daughter cells. CtrA regulates replication and transcription of many genes, thereby ensuring that processes such as motility and cell division take place at the appropriate cell cycle stage. The cell cycle of the stalked budding alphaproteobacterium Hyphomonas neptunium culminates in an asymmetric cell division at the stalk-bud junction. Here, we investigate the role of the pathway from DivJ and PleC down to CtrA in this recently established model organism. Even though DivJ and PleC are localized to opposite poles, suggesting they are involved in polarity establishment inH. neptunium, DivJ, PleC and the other components of the upstream pathway (DivK and PleD) are not essential for cell cycle regulation. In contrast, the downstream part of the pathway starting from DivL is essential and involved in the regulation of important functions such as replication inhibition, cell division and motility, as shown by the identification of the (direct) regulon of CtrA. The overlap between the regulons of DivJ and PleC, DivK and CtrA is only partial, demonstrating that additional factors feeding into the pathway must be present in H. neptunium. Furthermore, unlike in other alphaproteobacteria, the regulation of CtrA throughout the cell cycle does not take place at the level of CtrA abundance in H. neptunium. All in all, the DivL-CckA-ChpT-CtrA pathway plays an essential role in the regulation of the complicated cell cycle ofH. neptunium, but several proteins feeding into CtrA remain undiscovered. The in-depth analysis of CtrA regulation in this stalked budding organism leads to hypotheses that might also hold in well-established model organisms such as Caulobacter crescentus.

Project description:Supporting data for Chen et al., "Cytokinesis signals truncation of the PodJ polarity factor by a cell cycle-regulated protease" The microarray component of this work seeks to identify genes whose expression is controlled by the Caulobacter crescentus DivJ-PleC-DivK system. Keywords: time course, mutant/wild-type comparisons

Project description:A conserved regulatory pathway directs developmental transitions and asymmetries in Agrobacterium tumefaciens. Core components of this coordination of division and development (CDD) pathway include two integrated phosphorelays. One of these phosphorelays includes at least four histidine sensor kinase homologues, DivJ, PleC, PdhS1, and PdhS2, and at least two response regulators, DivK and PleD. Previously we demonstrated that PdhS2 reciprocally regulates biofilm formation and swimming motility. In the current study we further dissect the architecture of the CDD pathway in A. tumefaciens with respect to PdhS2. We show that PdhS2-dependent effects on attachment and motility require the response regulator, DivK, but do not require PdhS2 autokinase or phosphotransfer activities. We also demonstrate that PdhS2 regulation of biofilm formation is dependent upon multiple diguanylate cyclases, including PleD, DgcA, and DgcB, implying that PdhS2 regulation of this process intersects with pathways regulating levels of the second messenger cyclic-di-GMP. Finally, we show that upon cell division a GFP fusion to PdhS2 dynamically localizes to the new pole of the bacterium suggesting that PdhS2 controls processes in the daughter cell compartment of predivisional cells. These observations suggest that PdhS2 negatively regulates DivK, and possibly PleD, activity to control developmental processes in the daughter cell compartment of predivisional cells, as well as in newly released motile daughter cells. Three biological replicates, independent RNA preparations, one dye swap.

Project description:A conserved regulatory pathway directs developmental transitions and asymmetries in Agrobacterium tumefaciens. Core components of this coordination of division and development (CDD) pathway include two integrated phosphorelays. One of these phosphorelays includes at least four histidine sensor kinase homologues, DivJ, PleC, PdhS1, and PdhS2, and at least two response regulators, DivK and PleD. Previously we demonstrated that PdhS2 reciprocally regulates biofilm formation and swimming motility. In the current study we further dissect the architecture of the CDD pathway in A. tumefaciens with respect to PdhS2. We show that PdhS2-dependent effects on attachment and motility require the response regulator, DivK, but do not require PdhS2 autokinase or phosphotransfer activities. We also demonstrate that PdhS2 regulation of biofilm formation is dependent upon multiple diguanylate cyclases, including PleD, DgcA, and DgcB, implying that PdhS2 regulation of this process intersects with pathways regulating levels of the second messenger cyclic-di-GMP. Finally, we show that upon cell division a GFP fusion to PdhS2 dynamically localizes to the new pole of the bacterium suggesting that PdhS2 controls processes in the daughter cell compartment of predivisional cells. These observations suggest that PdhS2 negatively regulates DivK, and possibly PleD, activity to control developmental processes in the daughter cell compartment of predivisional cells, as well as in newly released motile daughter cells.

Project description:Analysis of global transcriptional changes in H. neptunium cells lacking the cell cycle regulatory genes pleC, divJ or divK

Project description:Progression through the Caulobacter cell cycle is driven by the master regulator CtrA, an essential two-component signaling protein that regulates the expression of nearly 100 genes. CtrA is abundant throughout the cell cycle except immediately prior to DNA replication. However, the expression of CtrA-activated genes is generally restricted to S-phase. We identify the conserved protein SciP (small CtrA inhibitory protein) and show that it accumulates during G1 where it inhibits CtrA from activating target genes. The depletion of SciP from G1 cells leads to the inappropriate induction of CtrA-activated genes and, consequently, a disruption of the cell cycle. Conversely, the ectopic synthesis of SciP is sufficient to inhibit CtrA-dependent transcription, also disrupting the cell cycle. SciP binds directly to CtrA without affecting stability or phosphorylation; instead SciP likely prevents CtrA from recruiting RNA polymerase. CtrA is thus tightly regulated by a protein-protein interaction which is critical to cell cycle progression.

Project description:Progression through the Caulobacter cell cycle is driven by the master regulator CtrA, an essential two-component signaling protein that regulates the expression of nearly 100 genes. CtrA is abundant throughout the cell cycle except immediately prior to DNA replication. However, the expression of CtrA-activated genes is generally restricted to S-phase. We identify the conserved protein SciP (small CtrA inhibitory protein) and show that it accumulates during G1 where it inhibits CtrA from activating target genes. The depletion of SciP from G1 cells leads to the inappropriate induction of CtrA-activated genes and, consequently, a disruption of the cell cycle. Conversely, the ectopic synthesis of SciP is sufficient to inhibit CtrA-dependent transcription, also disrupting the cell cycle. SciP binds directly to CtrA without affecting stability or phosphorylation; instead SciP likely prevents CtrA from recruiting RNA polymerase. CtrA is thus tightly regulated by a protein-protein interaction which is critical to cell cycle progression. For the sciP depletion studies, the sciP depletion strain was grown to mid-exponential phase in rich media supplemented with xylose, synchronized, and swarmer cells released into either glucose or xylose. Following one cell cycle, swarmers were again isolated from the two conditions and compared directly on arrays. This was done in duplicate. For the sciP overexpression studies, a wild type strain harboring the plasmid pJS14-Pxyl-sciP was grown to mid-exponential phase and xylose added for 2 hours. A strain harboring an empty vector was treated identically. The two populations were compared directly on arrays. This was done in duplicate.

Project description:The bacterial cell cycle has been extensively studied under standard growth conditions. How it is modulated in response to environmental changes remains poorly understood. Here, we demonstrate that the freshwater bacterium Caulobacter crescentus blocks cell division and grows to filamentous cells in response to stress conditions affecting the cell membrane. Our data suggest that stress switches the membrane-bound cell cycle kinase CckA to its phosphatase mode, leading to the rapid dephosphorylation, inactivation and proteolysis of the master cell cycle regulator CtrA. The clearance of CtrA results in downregulation of division and morphogenesis genes and consequently a cell division block. Upon shift to non-stress conditions, cells quickly restart cell division and return to normal cell size. Our data indicate that the temporary inhibition of cell division through the regulated inactivation of CtrA constitutes a growth advantage under stress. Taken together, our work reveals a new mechanism that allows bacteria to alter their mode of proliferation in response to environmental cues by controlling the activity of a master cell cycle transcription factor. Furthermore, our results highlight the role of a bifunctional kinase in this process that integrates the cell cycle with environmental information.

Project description:Cell fate determination in the asymmetric bacterium Caulobacter crescentus (Caulobacter) is triggered by the localization of the developmental regulator SpmX to the old (stalked) cell pole during the G1-S transition. While SpmX is required to localize and activate the cell fate-determining kinase DivJ at the stalked pole in Caulobacter, it is also required for organelle (stalk) positioning in the cousin Asticaccaulis. We unearth the conserved s54-dependent transcriptional activator regulator TacA as global regulator in Caulobacter whose activation by phosphorylation is indirectly down-regulated by SpmX. Using a combination of forward genetics and cytological screening we uncover a previously uncharacterized and polarized component (SpmY) of the TacA phosphorylation control system, and we show that the SpmY function and localization is conserved. Thus, we demonstrate that SpmX organizes a site-specific, ancestral and multi-functional regulatory hub whose function includes the coordinated control of two co-oscillating global transcriptional regulators, CtrA and TacA.