Project description:Potassium (K+) is an essential physiological element determining membrane potential, intracellular pH, osmotic/turgor pressure, and protein synthesis in cells. Nevertheless, K+ homeostasis remains poorly studied in bacteria. Here we describe the regulation of potassium uptake systems in the oligotrophic -proteobacterium Caulobacter crescentus known as a model for asymmetric cell division. We show that C. crescentus can grow in concentrations from the micromolar to the millimolar range by essentially using two K+ transporters to maintain potassium homeostasis, the low affinity Kup and the high affinity Kdp uptake systems. When K+ is not limiting, we found that the kup gene is essential while kdp inactivation does not impact the growth. In contrast, kdp becomes critical but not essential and kup dispensable for growth in K+-limited environments. However, in the absence of kdp, mutations in kup were selected to improve growth in K+-depleted conditions, likely by improving the affinity of Kup for K+. In addition, mutations in the KdpDE two-component system, which regulates kdpABC expression, suggest that the inner membrane sensor regulatory component KdpD works as a kinase in early stages of growth and as a phosphatase to regulate transition into stationary phase. Our data also show that KdpE is not only phosphorylated by KdpD but also by another non-cognate histidine kinase. On top of this, we determined the KdpE-dependent and independent K+ transcriptome and identified the direct targets of KdpE. Together, our work illustrates how an oligotrophic bacterium responds to fluctuation in K+ availability.

Project description:Potassium (K+) is an essential physiological element determining membrane potential, intracellular pH, osmotic/turgor pressure, and protein synthesis in cells. Nevertheless, K+ homeostasis remains poorly studied in bacteria. Here we describe the regulation of potassium uptake systems in the oligotrophic -proteobacterium Caulobacter crescentus known as a model for asymmetric cell division. We show that C. crescentus can grow in concentrations from the micromolar to the millimolar range by essentially using two K+ transporters to maintain potassium homeostasis, the low affinity Kup and the high affinity Kdp uptake systems. When K+ is not limiting, we found that the kup gene is essential while kdp inactivation does not impact the growth. In contrast, kdp becomes critical but not essential and kup dispensable for growth in K+-limited environments. However, in the absence of kdp, mutations in kup were selected to improve growth in K+-depleted conditions, likely by improving the affinity of Kup for K+. In addition, mutations in the KdpDE two-component system, which regulates kdpABC expression, suggest that the inner membrane sensor regulatory component KdpD works as a kinase in early stages of growth and as a phosphatase to regulate transition into stationary phase. Our data also show that KdpE is not only phosphorylated by KdpD but also by another non-cognate histidine kinase. On top of this, we determined the KdpE-dependent and independent K+ transcriptome and identified the direct targets of KdpE. Together, our work illustrates how an oligotrophic bacterium responds to fluctuation in K+ availability.

Project description:Intracellular zinc concentration needs to be maintained within strict limits due to its toxicity at high levels, and this is achieved by a finely regulated balance between uptake and efflux. Many bacteria use the Zinc Uptake Regulator Zur to orchestrate zinc homeostasis, but little is known regarding the transport of this metal across the bacterial outer membrane. In this work we determined the C. crescentus Zur regulon by global transcriptional and in silico analyses. Among the genes directly repressed by Zur are those encoding a putative high affinity ABC uptake system (znuCBA), three TonB-dependent receptors (znuD, znuE and znuF) and one new putative transporter of a family not yet characterized (zrpW). Zur is also directly involved in the activation of a RND and a P-type ATPase efflux systems, as revealed by β-galactosidase and site-directed mutagenesis assays. Several genes belonging to the Fur regulon were also downregulated in the zur mutant, suggesting a putative cross-talk between Zur and Fur regulatory networks. Interestingly, a phenotypic analysis of the znuD and znuE mutants has shown that these genes are essential for growth under zinc starvation, suggesting that C. crescentus uses these TonB-dependent outer membrane transporters as key zinc scavenging systems.

Project description:Intracellular zinc concentration needs to be maintained within strict limits due to its toxicity at high levels, and this is achieved by a finely regulated balance between uptake and efflux. Many bacteria use the Zinc Uptake Regulator Zur to orchestrate zinc homeostasis, but little is known regarding the transport of this metal across the bacterial outer membrane. In this work we determined the C. crescentus Zur regulon by global transcriptional and in silico analyses. Among the genes directly repressed by Zur are those encoding a putative high affinity ABC uptake system (znuCBA), three TonB-dependent receptors (znuD, znuE and znuF) and one new putative transporter of a family not yet characterized (zrpW). Zur is also directly involved in the activation of a RND and a P-type ATPase efflux systems, as revealed by β-galactosidase and site-directed mutagenesis assays. Several genes belonging to the Fur regulon were also downregulated in the zur mutant, suggesting a putative cross-talk between Zur and Fur regulatory networks. Interestingly, a phenotypic analysis of the znuD and znuE mutants has shown that these genes are essential for growth under zinc starvation, suggesting that C. crescentus uses these TonB-dependent outer membrane transporters as key zinc scavenging systems. The DNA microarray experiments were performed as described in (da Silva Neto et al., 2013). Briefly, cDNA was generated from 12.5 µg of total RNA and labeled with either Cy3 or Cy5 fluorescent dyes (FairPlay III Microarray Labeling System, Stratagene). Labeled cDNA samples were hybridized to a Caulobacter DNA oligo microarray (Agilent), and the arrays were scanned with an Agilent High Resolution Microarray Scanner. RNA from three independent biological cultures was used for DNA microarray analysis. We considered as differentially expressed genes those showing a minimum of 2-fold change relative to the control, considering at least three out of the four last probes for each gene (that are downstream of the translational start site) in at least two of three biological replicates. The values for the relative expression of each gene were obtained as the average of the four last probes.

Project description:Cesium (Cs+) is a potentially toxic mineral element that is released into the environment and taken up by plants. Although Cs+ is chemically similar to potassium (K+), and much is known about K+ transport mechanisms, it is not clear through which K+ transport mechanisms Cs+ is taken up by plant roots. In this study, the role of AtHAK5 in high affinity K+ and Cs+ uptake was characterized. It is demonstrated that AtHAK5 is localized to the plasma membrane under conditions of K+ deprivation, when it is expressed. 9 samples were used in this experiment.

Project description:Maintenance of ion homeostatic mechanisms is essential for living cells, including the budding yeast S. cerevisiae. Whereas the impact of changes in phosphate metabolism on metal ion homeostasis has been recently examined, the inverse effect is still largely unexplored. We show here that depletion of potassium from the medium or alteration of diverse regulatory pathways controlling potassium uptake, such as the Trk1 potassium transporter or the Pma1 H+-ATPase, trigger a response that mimics that of phosphate (Pi) deprivation, exemplified by accumulation of the high-affinity Pi transporter Pho84. This response is mediated by and requires the integrity of the PHO signaling pathway. Removal of potassium from the medium does not alter the amount of total or free intracellular Pi, but is accompanied by decreased in the ATP and ADP levels and a rapid depletion of cellular polyphosphates. Therefore, our data do not support the notion of Pi being the major signaling molecule triggering phosphate-starvation responses. We also observe that cells with compromised potassium uptake cannot grow under limiting Pi conditions. The link between potassium and phosphate homeostasis reported here could explain the invasive phenotype, characteristic of nutrient deprivation, observed in potassium-deficient yeast cells.

Project description:Cesium (Cs+) is a potentially toxic mineral element that is released into the environment and taken up by plants. Although Cs+ is chemically similar to potassium (K+), and much is known about K+ transport mechanisms, it is not clear through which K+ transport mechanisms Cs+ is taken up by plant roots. In this study, the role of AtHAK5 in high affinity K+ and Cs+ uptake was characterized. It is demonstrated that AtHAK5 is localized to the plasma membrane under conditions of K+ deprivation, when it is expressed.

Project description:The alpha-proteobacterium Caulobacter crescentus thrives in oligotrophic environments and is able to optimally exploit minimal resources by entertaining an intricate network of gene expression control mechanisms. Numerous transcriptional activators and repressors have been reported to contribute to these processes, but only few studies have focused on regulation at the post-transcriptional level in C. crescentus. Small RNAs (sRNAs) are a prominent class of regulators of bacterial gene expression, and most sRNAs characterized today engage in direct base-pairing interactions to modulate translation and/or stability of target mRNAs. In many cases, the ubiquitous RNA chaperone, Hfq, contributes to the establishment of RNA-RNA interactions. Although the deletion of the hfq gene is associated with a severe loss of fitness in C. crescentus, the RNA ligands of the chaperone have remained largely unexplored. Here we report on the identification of coding and non-coding transcripts associated with Hfq in C. crescentus, and demonstrate Hfq-dependent post-transcriptional regulation in this organism. We show that the conserved, Hfq-bound sRNA RusT is transcriptionally controlled by the conserved NtrYX two-component system and induced in response to iron starvation. By combining RusT pulse expression with whole-genome transcriptome analysis we determine 16 candidate target transcripts, more than half of which encode outer membrane transporters. We hence suggest RusT to support remodeling of the C. crescentus cell surface when iron supplies are limiting.

Project description:BACKGROUND: With the aim of remaining viable, bacteria must deal with changes in environmental conditions, including increases in external osmolarity. While studies concerning bacterial response to this stress condition have focused on soil, marine and enteric species, this report is about Caulobacter crescentus, a species inhabiting freshwater oligotrophic habitats. RESULTS: A genomic analysis reported in this study shows that most of the classical genes known to be involved in intracellular solute accumulation under osmotic adaptation are missing in C. crescentus. Consistent with this observation, growth assays revealed a restricted capability of the bacterium to propagate under hyperosmotic stress, and addition of the compatible solute glycine betaine did not improve bacterial resistance. A combination of transcriptomic and proteomic analyses indicated quite similar changes triggered by the presence of either salt or sucrose, including down-regulation of many housekeeping processes and up-regulation of functions related to environmental adaptation. Furthermore, a GC-MS analysis revealed some metabolites at slightly increased levels in stressed cells, but none of them corresponding to well-established compatible solutes. CONCLUSION: Despite a clear response to hyperosmotic stress, it seems that the restricted capability of C. crescentus to tolerate this unfavorable condition is probably a consequence of the inability to accumulate intracellular solutes. This finding is consistent with the ecology of the bacterium, which inhabits aquatic environments with low nutrient concentration. Three experimental procedures, each of them performed in three replicates. A total of nine independent biological samples were used

Project description:In this study, we showed for the first time that c-di-AMP is produced by C. difficile and controls the uptake of potassium, making it essential for growth. We found that c-di-AMP is involved in biofilm formation, cell wall homeostasis, osmotolerance as well as detergent and bile salt resistance in C. difficile. We identified BusR as a new regulator that binds c-di-AMP and represses the expression of the compatible solute transporter BusAA-AB. Interestingly, a busR mutant is highly resistant to a hyperosmotic or bile salt stress compared to the parental strain while a busAA mutant is more susceptible. A short exposure of C. difficile cells to bile salts resulted in a decrease of the c-di-AMP concentrations reinforcing the hypothesis that changes in membrane characteristics due to variations of the cellular turgor or membrane damages constitute a signal for the adjustment of the intracellular c-di-AMP concentration. In a colonization mouse model, a strain producing elevated c-di-AMP concentrations failed to persist in the gut in contrast to the parental strain. Thus, c-di-AMP is a signaling molecule with pleiotropic effects that controls osmolyte uptake to confer osmotolerance and bile salt resistance in C. difficile and that is important for colonization of the host.