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.     

Regulatory cohesion of cell cycle and cell differentiation through interlinked phosphorylation and second messenger networks

In Caulobacter crescentus, phosphorylation of key regulators is coordinated with the second messenger cyclic di-GMP to drive cell-cycle progression and differentiation. The diguanylate cyclase PleD directs pole morphogenesis, while the c-di-GMP effector PopA initiates degradation of the replication inhibitor CtrA by the AAA+ protease ClpXP to license S phase entry. Here, we establish a direct link between PleD and PopA reliant on the phosphodiesterase PdeA and the diguanylate cyclase DgcB. PdeA antagonizes DgcB activity until the G1-S transition, when PdeA is degraded by the ClpXP protease. The unopposed DgcB activity, together with PleD activation, upshifts c-di-GMP to drive PopA-dependent CtrA degradation and S phase entry. PdeA degradation requires CpdR, a response regulator that delivers PdeA to the ClpXP protease in a phosphorylation-dependent manner. Thus, CpdR serves as a crucial link between phosphorylation pathways and c-di-GMP metabolism to mediate protein degradation events that irreversibly and coordinately drive bacterial cell-cycle progression and development.     

Activation and polar sequestration of PopA,a c‐di‐GMP effector protein involved in Caulobacter crescentus cell cycle control

When Caulobacter crescentus enters S‐phase the replication initiation inhibitor CtrA dynamically positions to the old cell pole to be degraded by the polar ClpXP protease. Polar delivery of CtrA requires PopA and the diguanylate cyclase PleD that positions to the same pole. Here we present evidence that PopA originated through gene duplication from its paralogue response regulator PleD and subsequent co‐option as c‐di‐GMP effector protein. While the C‐terminal catalytic domain (GGDEF) of PleD is activated by phosphorylation of the N‐terminal receiver domain, functional adaptation has reversed signal transduction in PopA with the GGDEF domain adopting input function and the receiver domain serving as regulatory output. We show that the N‐terminal receiver domain of PopA specifically interacts with RcdA, a component required for CtrA degradation. In contrast, the GGDEF domain serves to target PopA to the cell pole in response to c‐di‐GMP binding. In agreement with the divergent activation and targeting mechanisms, distinct markers sequester PleD and PopA to the old cell pole upon S‐phase entry. Together these data indicate that PopA adopted a novel role as topology specificity factor to help recruit components of the CtrA degradation pathway to the protease specific old cell pole of C. crescentus.     

A dynamically localized protease complex and a polar specificity factor control a cell cycle master regulator

Regulated proteolysis is essential for cell cycle progression in both prokaryotes and eukaryotes. We show here that the ClpXP protease, responsible for the degradation of multiple bacterial proteins, is dynamically localized to specific cellular positions in Caulobacter where it degrades colocalized proteins. The CtrA cell cycle master regulator, that must be cleared from the Caulobacter cell to allow the initiation of chromosome replication, interacts with the ClpXP protease at the cell pole where it is degraded. We have identified a novel, conserved protein, RcdA, that forms a complex with CtrA and ClpX in the cell. RcdA is required for CtrA polar localization and degradation by ClpXP. The localization pattern of RcdA is coincident with and dependent upon ClpX localization. Thus, a dynamically localized ClpXP proteolysis complex in concert with a cytoplasmic factor provides temporal and spatial specificity to protein degradation during a bacterial cell cycle.     

ClpXP and ClpAP proteolytic activity on divisome substrates is differentially regulated following the Caulobacter asymmetric cell division

Proteolytic control of Caulobacter cell cycle proteins is primarily executed by ClpXP, a dynamically localized protease implicated in turnover of several factors critical for faithful cell cycle progression. Here, we show that the transient midcell localization of ClpXP that precedes cytokinesis requires the FtsZ component of the divisome. Although ClpAP does not exhibit subcellular localization, FtsZ is a substrate of both ClpXP and ClpAP in vivo and in vitro. A peptide containing the C‐terminal portion of the FtsA divisome protein is a substrate of both ClpXP and ClpAP in vitro but is primarily degraded by ClpAP in vivo. Caulobacter carries out an asymmetric division in which FtsZ and FtsA are stable in stalked cells but degraded in the non‐replicative swarmer cell where ClpAP alone degrades FtsA and both ClpAP and ClpXP degrade FtsZ. While asymmetric division in Caulobacter normally yields larger stalked and smaller swarmer daughters, we observe a loss of asymmetric size distribution among daughter cells when clpA is depleted from a strain in which FtsZ is constitutively produced. Taken together, these results suggest that the activity of both ClpXP and ClpAP on divisome substrates is differentially regulated in daughter cells.     

CtrA controls cell division and outer membrane composition of the pathogen Brucella abortus

Brucella abortus is a pathogen infecting cattle, able to survive, traffic, and proliferate inside host cells. It belongs to the Alphaproteobacteria, a phylogenetic group comprising bacteria with free living, symbiotic, and pathogenic lifestyles. An essential regulator of cell cycle progression named CtrA was described in the model bacterium Caulobacter crescentus. This regulator is conserved in many alphaproteobacteria, but the evolution of its regulon remains elusive. Here we identified promoters that are CtrA targets using ChIP‐seq and we found that CtrA binds to promoters of genes involved in cell cycle progression, in addition to numerous genes encoding outer membrane components involved in export of membrane proteins and synthesis of lipopolysaccharide. Analysis of a conditional B. abortus ctrA loss of function mutant confirmed that CtrA controls cell division. Impairment of cell division generates elongated and branched morphologies, that are also detectable inside HeLa cells. Surprisingly, abnormal bacteria are able to traffic to the endoplasmic reticulum, the usual replication niche of B. abortus in host cells. We also found that CtrA depletion affected outer membrane composition, in particular the abundance and spatial distribution of Omp25. Control of the B. abortus envelope composition by CtrA indicates the plasticity of the CtrA regulon along evolution.     

Lon recognition of the replication initiator DnaA requires a bipartite degron

DnaA initiates chromosome replication in bacteria. In Caulobacter crescentus, the Lon protease degrades DnaA to coordinate replication with nutrient availability and to halt the cell cycle during acute stress. Here, we characterize the mechanism of DnaA recognition by Lon. We find that the folded state of DnaA appears crucial for its degradation, in contrast to the well‐known role of Lon in degrading misfolded proteins. We fail to identify a single degradation motif (degron) sufficient for DnaA degradation, rather we show that both the ATPase domain and a species‐specific N‐terminal motif are important for productive Lon degradation of full‐length DnaA. Mutations in either of these determinants disrupt DnaA degradation in vitro and in vivo. However, analysis of truncation products reveals that appending other extensions to the ATPase domain is sufficient to trigger degradation, suggesting plasticity in Lon recognition. Our final working model is that Lon engages DnaA through at least two elements, one of which anchors DnaA to Lon and the other acting as an initiation site for degradation.     

Sinorhizobium meliloti CpdR1 is critical for co-ordinating cell cycle progression and the symbiotic chronic infection

ATP-driven proteolysis plays a major role in regulating the bacterial cell cycle, development and stress responses. In the nitro -fixing symbiosis with host plants, Sinorhizobium meliloti undergoes a profound cellular differentiation, including endoreduplication of the ome. The regulatory mechanisms governing the alterations of the S. meliloti cell cycle in planta are largely unknown. Here, we report the characterization of two cpdR homologues, cpdR1 and cpdR2 , of S. meliloti that encode single-domain response regulators. In Caulobacter crescentus , CpdR controls the polar localization of the ClpXP protease, thereby mediating the regulated proteolysis of key protein(s), such as CtrA, involved in cell cycle progression. The S. meliloti cpdR1 -null mutant can invade the host cytoplasm, however, the intracellular bacteria are unable to differentiate into bacteroids. We show that S. meliloti CpdR1 has a polar localization pattern and a role in ClpX positioning similar to C. crescentus CpdR, suggesting a conserved function of CpdR proteins among α-proteobacteria. However, in S. meliloti , free-living cells of the cpdR1 -null mutant show a striking morphology of irregular coccoids and aberrant DNA replication. Thus, we demonstrate that CpdR1 mediates the co-ordination of cell cycle events, which are critical for both the free-living cell division and the differentiation required for the chronic intracellular infection.     

Co‐evolution of multipartite interactions between an extended tmRNA tag and a robust Lon protease in Mycoplasma

Messenger RNAs that lack in‐frame stop codons promote ribosome stalling and accumulation of aberrant and potentially harmful polypeptides. The SmpB‐tmRNA quality control system has evolved to solve problems associated with non‐stop mRNAs, by rescuing stalled ribosomes and directing the addition of a peptide tag to the C‐termini of the associated proteins, marking them for proteolysis. In Escherichia coli, the ClpXP system is the major contributor to disposal of tmRNA‐tagged proteins. We have shown that the AAA+ Lon protease can also degrade tmRNA‐tagged proteins, but with much lower efficiency. Here, we present a unique case of enhanced recognition and degradation of an extended Mycoplasma pneumoniae (MP) tmRNA tag by the MP‐Lon protease. We demonstrate that MP‐Lon can efficiently and selectively degrade MP‐tmRNA‐tagged proteins. Most significantly, our studies reveal that the larger (27 amino acids long) MP‐tmRNA tag contains multiple discrete signalling motifs for efficient recognition and rapid degradation by Lon. We propose that higher‐affinity multipartite interactions between MP‐Lon and the extended MP‐tmRNA tag have co‐evolved from pre‐existing weaker interactions, as exhibited by Lon in E. coli, to better fulfil the function of MP‐Lon as the sole soluble cytoplasmic protease responsible for the degradation of tmRNA‐tagged proteins.     

The DivJ,CbrA and PleC system controls DivK phosphorylation and symbiosis in Sinorhizobium meliloti

Sinorhizobium meliloti is a soil bacterium that invades the root nodules it induces on Medicago sativa, whereupon it undergoes an alteration of its cell cycle and differentiates into nitrogen‐fixing, elongated and polyploid bacteroid with higher membrane permeability. In Caulobacter crescentus, a related alphaproteobacterium, the principal cell cycle regulator, CtrA, is inhibited by the phosphorylated response regulator DivK. The phosphorylation of DivK depends on the histidine kinase DivJ, while PleC is the principal phosphatase for DivK. Despite the importance of the DivJ in C. crescentus, the mechanistic role of this kinase has never been elucidated in other Alphaproteobacteria. We show here that the histidine kinases DivJ together with CbrA and PleC participate in a complex phosphorylation system of the essential response regulator DivK in S. meliloti. In particular, DivJ and CbrA are involved in DivK phosphorylation and in turn CtrA inactivation, thereby controlling correct cell cycle progression and the integrity of the cell envelope. In contrast, the essential PleC presumably acts as a phosphatase of DivK. Interestingly, we found that a DivJ mutant is able to elicit nodules and enter plant cells, but fails to establish an effective symbiosis suggesting that proper envelope and/or low CtrA levels are required for symbiosis.     

TmRNA is required for correct timing of DNA replication in Caulobacter crescentus

SsrA, or tmRNA, is a small RNA that interacts with selected translating ribosomes to target the nascent polypeptides for degradation. Here we report that SsrA activity is required for normal timing of the G(1)-to-S transition in Caulobacter crescentus. A deletion of the ssrA gene, or of the gene encoding SmpB, a protein required for SsrA activity, results in a specific delay in the cell cycle during the G(1)-to-S transition. The ssrA deletion phenotype is not due to accumulation of stalled ribosomes, because the deletion is not complemented by a mutated version of SsrA that releases ribosomes but does not target proteins for degradation. Degradation of the CtrA response regulator normally coincides with initiation of DNA replication, but in strains lacking SsrA activity there is a 40-min delay between the degradation of CtrA and replication initiation. This uncoupling of initiation of replication from CtrA degradation indicates that there is an SsrA-dependent pathway required for correct timing of DNA replication.     

Adaptor bypass mutations of Bacillus subtilis spx suggest a mechanism for YjbH‐enhanced proteolysis of the regulator Spx by ClpXP

The global regulator, Spx, is under proteolytic control exerted by the adaptor YjbH and ATP‐dependent protease ClpXP in Bacillus subtilis. While YjbH is observed to bind the Spx C‐terminus, YjbH shows little affinity for ClpXP, indicating adaptor activity that does not operate by tethering. Chimeric proteins derived from B. subtilis AbrB and the Spx C‐terminus showed that a 28‐residue C‐terminal section of Spx (AbrB28), but not the last 12 or 16 residues (AbrB12, AbrB16), was required for YjbH interaction and for ClpXP proteolysis, although the rate of AbrB28 proteolysis was not affected by YjbH addition. The result suggested that the YjbH‐targeted 28 residue segment of the Spx C‐terminus bears a ClpXP‐recognition element(s) that is hidden in the intact Spx protein. Residue substitutions in the conserved helix α6 of the C‐terminal region generated Spx substrates that were degraded by ClpXP at accelerated rates compared to wild‐type Spx, and showed reduced dependency on the YjbH activity. The residue substitutions also weakened the interaction between Spx and YjbH. The results suggest a model in which YjbH, through interaction with residues of helix α6, exposes the C‐terminus of Spx for recognition and proteolysis by ClpXP.     

Regulated degradation of chromosome replication proteins DnaA and CtrA in Caulobacter crescentus

DnaA protein binds bacterial replication origins and it initiates chromosome replication. The Caulobacter crescentus DnaA also initiates chromosome replication and the C. crescentus response regulator CtrA represses chromosome replication. CtrA proteolysis by ClpXP helps restrict chromosome replication to the dividing cell type. We report that C. crescentus DnaA protein is also selectively targeted for proteolysis but DnaA proteolysis uses a different mechanism. DnaA protein is unstable during both growth and stationary phases. During growth phase, DnaA proteolysis ensures that primarily newly made DnaA protein is present at the start of each replication period. Upon entry into stationary phase, DnaA protein is completely removed while CtrA protein is retained. Cell cycle arrest by sudden carbon or nitrogen starvation is sufficient to increase DnaA proteolysis, and relieving starvation rapidly stabilizes DnaA protein. This starvation-induced proteolysis completely removes DnaA protein even while DnaA synthesis continues. Apparently, C. crescentus relies on proteolysis to adjust DnaA in response to such rapid nutritional changes. Depleting the C. crescentus ClpP protease significantly stabilizes DnaA. However, a dominant-negative clpX allele that blocks CtrA degradation, even when combined with a clpA null allele, did not decrease DnaA degradation. We suggest that either a novel chaperone presents DnaA to ClpP or that ClpX is used with exceptional efficiency so that when ClpX activity is limiting for CtrA degradation it is not limiting for DnaA degradation. This unexpected and finely tuned proteolysis system may be an important adaptation for a developmental bacterium that is often challenged by nutrient-poor environments.     

APC/CCdh1-dependent proteolysis of USP1 regulates the response to UV-mediated DNA damage

Targeted protein destruction of critical cellular regulators during the G1 phase of the cell cycle is achieved by anaphase-promoting complex/cyclosome^Cdh1 (APC/C^Cdh1), a multisubunit E3 ubiquitin ligase. Cells lacking Cdh1 have been shown to accumulate deoxyribonucleic acid (DNA) damage, suggesting that it may play a previously unrecognized role in maintaining genomic stability. The ubiquitin-specific protease 1 (USP1) is a known critical regulator of DNA repair and genomic stability. In this paper, we report that USP1 was degraded in G1 via APC/C^Cdh1. USP1 levels were kept low in G1 to provide a permissive condition for inducing proliferating cell nuclear antigen (PCNA) monoubiquitination in response to ultraviolet (UV) damage before DNA replication. Importantly, expression of a USP1 mutant that cannot be degraded via APC/C^Cdh1 inhibited PCNA monoubiquitination during G1, likely compromising the recruitment of trans-lesion synthesis polymerase to UV repair sites. Thus, we propose a role for APC/C^Cdh1 in modulating the status of PCNA monoubiquitination and UV DNA repair before S phase entry.     

Differential degradation of variant medium-chain acyl-CoA dehydrogenase by the protein quality control proteases Lon and ClpXP

The coordinated activities of chaperones and proteases that supervise protein folding and degradation are important factors for deciding the fate of proteins whose folding is impaired by missense variations. We have studied the role of Lon and ClpXP proteases in handling of wild-type and a folding-impaired disease-associated variant (R28C) of the mitochondrial enzyme medium-chain acyl-CoA dehydrogenase (MCAD). Using an Escherichia coli model system, we co-overexpressed the MCAD variants and the respective proteases at two conditions: at 31 degrees C where R28C MCAD protein folds partially and at 37 degrees C where it misfolds and aggregates. Co-overexpression of Lon protease considerably accelerated the degradation rate of a pool of R28C variant MCAD synthesised during a 30min pulse and counteracted accumulation of aggregates at 37 degrees C, whereas increasing the amounts of ClpXP protease had no clear effect. Co-overexpression of either Lon or ClpXP protease markedly decreased the steady state levels of both wild-type and R28C mutant MCAD at 37 degrees C but not at 31 degrees C. Our results suggest that Lon is more efficient than ClpXP in elimination of non-native MCAD protein conformations, and accordingly, that Lon can recognise a broader spectrum of MCAD protein conformations.