Structures of GapR reveal a central channel which could accommodate B-DNA.

GapR is a nucleoid-associated protein required for the cell cycle of Caulobacter cresentus. We have determined new crystal structures of GapR to high resolution. As in a recently published structure, a GapR monomer folds into one long N-terminal α helix and two shorter α helices, and assembles into a tetrameric ring with a closed, positively charged, central channel.

Identification and characterization of OmpT-like proteases in uropathogenic Escherichia coli clinical isolates.

Bacterial colonization of the urogenital tract is limited by innate defenses, including the production of antimicrobial peptides (AMPs). Uropathogenic Escherichia coli (UPEC) resist AMP-killing to cause a range of urinary tract infections (UTIs) including asymptomatic bacteriuria, cystitis, pyelonephritis, and sepsis. UPEC strains have high genomic diversity and encode numerous virulence factors that differentiate them from non-UTI-causing strains, including ompT.

Crosstalk Regulation Between Bacterial Chromosome Replication and Chromosome Partitioning.

Despite much effort, the bacterial cell cycle has proved difficult to study and understand. Bacteria do not conform to the standard eukaryotic model of sequential cell-cycle phases. Instead, for example, bacteria overlap their phases of chromosome replication and chromosome partitioning.

A novel nucleoid-associated protein coordinates chromosome replication and chromosome partition.

We searched for regulators of chromosome replication in the cell cycle model Caulobacter crescentus and found a novel DNA-binding protein (GapR) that selectively aids the initiation of chromosome replication and the initial steps of chromosome partitioning. The protein binds the chromosome origin of replication (Cori) and has higher-affinity binding to mutated Cori-DNA that increases Cori-plasmid replication in vivo. gapR gene expression is essential for normal rapid growth and sufficient GapR levels are required for the correct timing of chromosome replication.

The Caulobacter crescentus Homolog of DnaA (HdaA) Also Regulates the Proteolysis of the Replication Initiator Protein DnaA.

Unlabelled: It is not known how diverse bacteria regulate chromosome replication. Based on Escherichia coli studies, DnaA initiates replication and the homolog of DnaA (Hda) inactivates DnaA using the RIDA (regulatory inactivation of DnaA) mechanism that thereby prevents extra chromosome replication cycles. RIDA may be widespread, because the distantly related Caulobacter crescentus homolog HdaA also prevents extra chromosome replication (J.

Redefining bacterial origins of replication as centralized information processors.

In this review we stress the differences between eukaryotes and bacteria with respect to their different cell cycles, replication mechanisms and genome organizations. One of the most basic and underappreciated differences is that a bacterial chromosome uses only one ori while eukaryotic chromosome uses multiple oris. Consequently, eukaryotic oris work redundantly in a cell cycle divided into separate phases: First inactive replication proteins assemble on eukaryotic oris, and then they await conditions (in the separate "S-phase") that activate only the ori-bound and pre-assembled replication proteins.

The Caulobacter crescentus chromosome replication origin evolved two classes of weak DnaA binding sites.

The Caulobacter crescentus replication initiator DnaA and essential response regulator CtrA compete to control chromosome replication. The C. crescentus replication origin (Cori) contains five strong CtrA binding sites but only two apparent DnaA boxes, termed G-boxes (with a conserved second position G, TGATCCACA).

Mycobacterium tuberculosis origin of replication and the promoter for immunodominant secreted antigen 85B are the targets of MtrA, the essential response regulator.

Efficient proliferation of Mycobacterium tuberculosis (Mtb) inside macrophage requires that the essential response regulator MtrA be optimally phosphorylated. However, the genomic targets of MtrA have not been identified. We show by chromatin immunoprecipitation and DNase I footprinting that the chromosomal origin of replication, oriC, and the promoter for the major secreted immunodominant antigen Ag85B, encoded by fbpB, are MtrA targets.

CtrA, a global response regulator, uses a distinct second category of weak DNA binding sites for cell cycle transcription control in Caulobacter crescentus.

CtrA controls cell cycle programs of chromosome replication and genetic transcription. Phosphorylated CtrA approximately P exhibits high affinity (dissociation constant [K(d)], <10 nM) for consensus TTAA-N7-TTAA binding sites with "typical" (N = 7) spacing. We show here that ctrA promoters P1 and P2 use low-affinity (K(d), >500 nM) CtrA binding sites with "atypical" (N not equal 7) spacing.

Comparative analysis of Caulobacter chromosome replication origins.

Caulobacter crescentus (CB15) initiates chromosome replication only in stalked cells and not in swarmers. To better understand this dimorphic control of chromosome replication, we isolated replication origins (oris) from freshwater Caulobacter (FWC) and marine Caulobacter (MCS) species. Previous studies implicated integration host factor (IHF) and CcrM DNA methylation sites in replication control.

CtrA response regulator binding to the Caulobacter chromosome replication origin is required during nutrient and antibiotic stress as well as during cell cycle progression.

The Caulobacter crescentus chromosome replication origin (Cori) has five binding sites for CtrA, an OmpR/PhoB family 'response regulator'. CtrA is degraded in replicating 'stalked' cells but is abundant in the non-replicating 'swarmer' cells, where it was proposed to repress replication by binding to Cori. We systematically mutated all Cori CtrA binding sites, and examined their consequences in the contexts of autonomous Cori-plasmid replication and in the natural chromosome locus.

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.

A dual binding site for integration host factor and the response regulator CtrA inside the Caulobacter crescentus replication origin.

The response regulator CtrA controls chromosome replication by binding to five sites, a, b, c, d, and e, inside the Caulobacter crescentus replication origin (Cori). In this study, we demonstrate that integration host factor (IHF) binds Cori over the central CtrA binding site c. Surprisingly, IHF and CtrA share DNA recognition sequences.

Glutamate at the phosphorylation site of response regulator CtrA provides essential activities without increasing DNA binding.

The essential response regulator CtrA controls the Caulobacter crescentus cell cycle and phosphorylated CtrA approximately P preferentially binds target DNA in vitro. The CtrA aspartate to glutamate (D51E) mutation mimics phosphorylated CtrA approximately P in vivo and rescues non-viable C.crescentus cells.

Conserved response regulator CtrA and IHF binding sites in the alpha-proteobacteria Caulobacter crescentus and Rickettsia prowazekii chromosomal replication origins.

CzcR is the Rickettsia prowazekii homolog of the Caulobacter crescentus global response regulator CtrA. CzcR expression partially compensates for developmental defects in ctrA mutant C. crescentus cells, and CzcR binds to all five CtrA binding sites in the C.

Control of chromosome replication in caulobacter crescentus.

Caulobacter crescentus permits detailed analysis of chromosome replication control during a developmental cell cycle. Its chromosome replication origin (Cori) may be prototypical of the large and diverse class of alpha-proteobacteria. Cori has features that both affiliate and distinguish it from the Escherichia coli chromosome replication origin.