Urs Jenal

Structural and mechanistic determinants of c-di-GMP signalling

Bis-(3′-5′)-cyclic dimeric GMP (c-di-GMP) is a ubiquitous second messenger that regulates cell surface-associated traits in bacteria. Components of this regulatory network include GGDEF and EAL domain-containing proteins that determine the cellular concentrations of c-di-GMP by mediating its synthesis and degradation, respectively. Crystal structure analyses in combination with functional studies have revealed the catalytic mechanisms and regulatory principles involved. Downstream, c-di-GMP is recognized by PilZ domain-containing receptors that can undergo large-scale domain rearrangements on ligand binding. Here, we review recent data on the structure and functional properties of the protein families that are involved in c-di-GMP signalling and discuss the mechanistic implications.

Second Messenger-Mediated Adjustment of Bacterial Swimming Velocity

Bacteria swim by means of rotating flagella that are powered by ion influx through membrane-spanning motor complexes. Escherichia coli and related species harness a chemosensory and signal transduction machinery that governs the direction of flagellar rotation and allows them to navigate in chemical gradients. Here, we show that Escherichia coli can also fine-tune its swimming speed with the help of a molecular brake (YcgR) that, upon binding of the nucleotide second messenger cyclic di-GMP, interacts with the motor protein MotA to curb flagellar motor output. Swimming velocity is controlled by the synergistic action of at least five signaling proteins that adjust the cellular concentration of cyclic di-GMP. Activation of this network and the resulting deceleration coincide with nutrient depletion and might represent an adaptation to starvation. These experiments demonstrate that bacteria can modulate flagellar motor output and thus swimming velocity in response to environmental cues.

An essential protease involved in bacterial cell-cycle control.

Proteolytic inactivation of key regulatory proteins is essential in eukaryotic cell‐cycle control. We have identified a protease in the eubacterium Caulobacter crescentus that is indispensable for viability and cell‐cycle progression, indicating that proteolysis is also involved in controlling the bacterial cell cycle. Mutants of Caulobacter that lack the ATP‐dependent serine protease ClpXP are arrested in the cell cycle before the initiation of chromosome replication and are blocked in the cell division process. ClpXP is composed of two types of polypeptides, the ClpX ATPase and the ClpP peptidase. Site‐directed mutagenesis of the catalytically active serine residue of ClpP confirmed that the proteolytic activity of ClpXP is essential. Analysis of mutants lacking ClpX or ClpP revealed that both proteins are required in vivo for the cell‐cycle‐dependent degradation of the regulatory protein CtrA. CtrA is a member of the response regulator family of two‐component signal transduction systems and controls multiple cell‐cycle processes in Caulobacter. In particular, CtrA negatively controls DNA replication and our findings suggest that specific degradation of the CtrA protein by the ClpXP protease contributes to G1‐to‐S transition in this organism.

Allosteric control of cyclic di-GMP signaling

Cyclic di-guanosine monophosphate is a bacterial second messenger that has been implicated in biofilm formation, antibiotic resistance, and persistence of pathogenic bacteria in their animal host. Although the enzymes responsible for the regulation of cellular levels of c-di-GMP, diguanylate cyclases (DGC) and phosphodiesterases, have been identified recently, little information is available on the molecular mechanisms involved in controlling the activity of these key enzymes or on the specific interactions of c-di-GMP with effector proteins. By using a combination of genetic, biochemical, and modeling techniques we demonstrate that an allosteric binding site for c-di-GMP (I-site) is responsible for non-competitive product inhibition of DGCs. The I-site was mapped in both multi- and single domain DGC proteins and is fully contained within the GGDEF domain itself. In vivo selection experiments and kinetic analysis of the evolved I-site mutants led to the definition of an RXXD motif as the core c-di-GMP binding site. Based on these results and based on the observation that the I-site is conserved in a majority of known and potential DGC proteins, we propose that product inhibition of DGCs is of fundamental importance for c-di-GMP signaling and cellular homeostasis. The definition of the I-site binding pocket provides an entry point into unraveling the molecular mechanisms of ligand-protein interactions involved in c-di-GMP signaling and makes DGCs a valuable target for drug design to develop new strategies against biofilm-related diseases.

Second messenger-mediated spatiotemporal control of protein degradation regulates bacterial cell cycle progression

Second messengers control a wide range of important cellular functions in eukaryotes and prokaryotes. Here we show that cyclic di-GMP, a global bacterial second messenger, promotes cell cycle progression in Caulobacter crescentus by mediating the specific degradation of the replication initiation inhibitor CtrA. During the G1-to-S-phase transition, both CtrA and its cognate protease ClpXP dynamically localize to the old cell pole, where CtrA is rapidly degraded. Sequestration of CtrA to the cell pole depends on PopA, a newly identified cyclic di-GMP effector protein. PopA itself localizes to the cell pole and directs CtrA to this subcellular site via the direct interaction with a mediator protein, RcdA. We present evidence that c-di-GMP regulates CtrA degradation during the cell cycle by controlling the dynamic sequestration of the PopA recruitment factor to the cell pole. Furthermore, we show that cell cycle timing of CtrA degradation relies on converging pathways responsible for substrate and protease localization to the old cell pole. This is the first report that links cyclic di-GMP to protein dynamics and cell cycle control in bacteria.

Role of the GGDEF regulator PleD in polar development of Caulobacter crescentus

Several members of the two‐component signal transduction family have been implicated in the control of  polar development in Caulobacter crescentus: PleC and DivJ, two polarly localized histidine sensor kinases; and the response regulators DivK and PleD. The PleD protein was shown previously to be required during the swarmer‐to‐stalked cell transition for flagellar ejection and efficient stalk biogenesis. Here, we present data indicating that PleD also controls the onset of motility and a cell density switch immediately preceding cell division. Constitutively active alleles of pleD or wspR, an orthologue from Pseudomonas fluorescens, almost completely suppressed C. crescentus motility and inhibited the increase in swarmer cell density during cell differentiation. The observation that these alleles also had a dominant‐negative effect on motility in a pleC divJ and a pleC divK mutant background indicated that PleD is located downstream of the other components in the signal transduction cascade, which controls the activity of the flagellar motor. In addition, the presence of a constitutive pleD or wspR allele resulted in a doubling of the average stalk length. Together, this is consistent with a model in which the active form of PleD, PleD∼P, negatively controls aspects of differentiation in the late predivisional cell, whereas it acts positively on polar development during the swarmer‐to‐stalked cell transition. In agreement with such a model, we found that DivJ, which localizes to the stalked pole during cell differentiation, positively controlled the in vivo phosphorylation status of PleD, and the swarmer pole‐specific PleC kinase modulated this status in a negative manner. Furthermore, domain switch experiments demonstrated that the WspR GGDEF output domain from P. fluorescens is active in C. crescentus, favouring a more general function for this novel signalling domain over a specific role such as DNA or protein interaction. Possible roles for PleD and its C‐terminal output domain in modulating the polar cell surface of C. crescentus are discussed.

Regulation by proteolysis in bacterial cells

Regulation by proteolysis plays a major role in bacterial stress responses, the cell cycle and development. Key regulators of these processes are subject to conditional proteolysis that depends on complex cellular information processing. This information includes temporal and spatial cues, and recent research has revealed a striking potential for multiple signal integration.

DgrA is a member of a new family of cyclic diguanosine monophosphate receptors and controls flagellar motor function in Caulobacter crescentus.

Bacteria are able to switch between two mutually exclusive lifestyles, motile single cells and sedentary multicellular communities that colonize surfaces. These behavioral changes contribute to an increased fitness in structured environments and are controlled by the ubiquitous bacterial second messenger cyclic diguanosine monophosphate (c-di-GMP). In response to changing environments, fluctuating levels of c-di-GMP inversely regulate cell motility and cell surface adhesins. Although the synthesis and breakdown of c-di-GMP has been studied in detail, little is known about the downstream effector mechanisms. Using affinity chromatography, we have isolated several c-di-GMP-binding proteins from Caulobacter crescentus. One of these proteins, DgrA, is a PilZ homolog involved in mediating c-di-GMP-dependent control of C. crescentus cell motility. Biochemical and structural analysis of DgrA and homologs from C. crescentus, Salmonella typhimurium, and Pseudomonas aeruginosa demonstrated that this protein family represents a class of specific diguanylate receptors and suggested a general mechanism for c-di-GMP binding and signal transduction. Increased concentrations of c-di-GMP or DgrA blocked motility in C. crescentus by interfering with motor function rather than flagellar assembly. We present preliminary evidence implicating the flagellar motor protein FliL in DgrA-dependent cell motility control.

Activation of the diguanylate cyclase PleD by phosphorylation-mediated dimerization

Diguanylate cyclases (DGCs) are key enzymes of second messenger signaling in bacteria. Their activity is responsible for the condensation of two GTP molecules into the signaling compound cyclic di-GMP. Despite their importance and abundance in bacteria, catalytic and regulatory mechanisms of this class of enzymes are poorly understood. In particular, it is not clear if oligomerization is required for catalysis and if it represents a level for activity control. To address this question we perform in vitro and in vivo analysis of the Caulobacter crescentus diguanylate cyclase PleD. PleD is a member of the response regulator family with two N-terminal receiver domains and a C-terminal diguanylate cyclase output domain. PleD is activated by phosphorylation but the structural changes inflicted upon activation of PleD are unknown. We show that PleD can be specifically activated by beryllium fluoride in vitro, resulting in dimerization and c-di-GMP synthesis. Cross-linking and fractionation experiments demonstrated that the DGC activity of PleD is contained entirely within the dimer fraction, confirming that the dimer represents the enzymatically active state of PleD. In contrast to the catalytic activity, allosteric feedback regulation of PleD is not affected by the activation status of the protein, indicating that activation by dimerization and product inhibition represent independent layers of DGC control. Finally, we present evidence that dimerization also serves to sequester activated PleD to the differentiating Caulobacter cell pole, implicating protein oligomerization in spatial control and providing a molecular explanation for the coupling of PleD activation and subcellular localization.

Second messenger signalling governs Escherichia coli biofilm induction upon ribosomal stress.

Biofilms are communities of surface‐attached, matrix‐embedded microbial cells that can resist antimicrobial chemotherapy and contribute to persistent infections. Using an Escherichia coli biofilm model we found that exposure of bacteria to subinhibitory concentrations of ribosome‐targeting antibiotics leads to strong biofilm induction. We present evidence that this effect is elicited by the ribosome in response to translational stress. Biofilm induction involves upregulation of the polysaccharide adhesin poly‐β‐1,6‐N‐acetyl‐glucosamine (poly‐GlcNAc) and two components of the poly‐GlcNAc biosynthesis machinery, PgaA and PgaD. Poly‐GlcNAc control depends on the bacterial signalling molecules guanosine‐bis 3′, 5′(diphosphate) (ppGpp) and bis‐(3′‐5′)‐cyclic di‐GMP (c‐di‐GMP). Treatment with translation inhibitors causes a ppGpp hydrolase (SpoT)‐mediated reduction of ppGpp levels, resulting in specific derepression of PgaA. Maximal induction of PgaD and poly‐GlcNAc synthesis requires the production of c‐di‐GMP by the dedicated diguanylate cyclase YdeH. Our results identify a novel regulatory mechanism that relies on ppGpp signalling to relay information about ribosomal performance to the Pga machinery, thereby inducing adhesin production and biofilm formation. Based on the important synergistic roles of ppGpp and c‐di‐GMP in this process, we suggest that interference with bacterial second messenger signalling might represent an effective means for biofilm control during chronic infections.