Regulatory cross-talk links Vibrio cholerae chromosome II replication and segregation

There is little knowledge of factors and mechanisms for coordinating bacterial chromosome replication and segregation. Previous studies have revealed that genes (and their products) that surround the origin of replication (oriCII) of Vibrio cholerae chromosome II (chrII) are critical for controlling the replication and segregation of this chromosome. rctB, which flanks one side of oriCII, encodes a protein that initiates chrII replication; rctA, which flanks the other side of oriCII, inhibits rctB activity. The chrII parAB2 operon, which is essential for chrII partitioning, is located immediately downstream of rctA. Here, we explored how rctA exerts negative control over chrII replication. Our observations suggest that RctB has at least two DNA binding domains--one for binding to oriCII and initiating replication and the other for binding to rctA and thereby inhibiting RctB's ability to initiate replication. Notably, the inhibitory effect of rctA could be alleviated by binding of ParB2 to a centromere-like parS site within rctA. Furthermore, by binding to rctA, ParB2 and RctB inversely regulate expression of the parAB2 genes. Together, our findings suggest that fluctuations in binding of the partitioning protein ParB2 and the chrII initiator RctB to rctA underlie a regulatory network controlling both oriCII firing and the production of the essential chrII partitioning proteins. Thus, by binding both RctB and ParB2, rctA serves as a nexus for regulatory cross-talk coordinating chrII replication and segregation.     

rctB mutations that increase copy number of Vibrio cholerae oriCII in Escherichia coli

RctB serves as the initiator protein for replication from oriCII, the origin of replication of Vibrio cholerae chromosome II. RctB is conserved between members of Vibrionaceae but shows no homology to known replication initiator proteins and has no recognizable sequence motifs. We used an oriCII based minichromosome to isolate copy-up mutants in Escherichia coli. Three point mutations rctB(R269H), rctB(L439H) and rctB(Y381N) and one IS10 insertion in the 3'-end of the rctB gene were obtained. We determined the maximal C-terminal deletion that still gave rise to a functional RctB protein to be 165 amino acids. All rctB mutations led to decreased RctB-RctB interaction indicating that the monomer is the active form of the initiator protein. All mutations also showed various defects in rctB autoregulation. Loss of the C-terminal part of RctB led to overinitiation by reducing binding of RctB to both rctA and inc regions that normally serve to limit initiation from oriCII. Overproduction of RctB(R269H) and RctB(L439H) led to a rapid increase in oriCII copy number. This suggests that the initiator function of the two mutant proteins is increased relative to the wild-type.     

Functional analysis of two putative chromosomal replication origins from Pseudomonas aeruginosa

Two autonomously replicating elements previously isolated from Pseudomonas aeruginosa were characterized in vitro for pre-priming complex formation using combinations of replication proteins from P. aeruginosa and Escherichia coli. The results of these studies showed that the P. aeruginosa DnaA and DnaB proteins could form a pre-priming complex on plasmid templates containing either of the two autonomously replicating elements of P. aeruginosa, pYJ50 (containing oriCI), and pYJ52 (containing oriCII), or the E. coli chromosomal origin (plasmid pYJ2). The E. coli DnaA, DnaB, and DnaC proteins were also able to form a pre-priming complex on pYJ2, pYJ50, and pYJ52. Neither pYJ50 nor pYJ52 could be established in E. coli, suggesting a block in steps subsequent to the formation of the pre-priming complex. Similarly, pYJ2 could not be established in P. aeruginosa. Since pYJ50 and pYJ52 could be established in P. aeruginosa and both putative origins form a pre-priming complex in vitro, attempts were made to delete each of these two putative origins. The results indicate that the oriCI sequence is essential for cell viability under typical laboratory growth conditions but that oriCII is not.     

Participation of chromosome segregation protein ParAI of Vibrio cholerae in chromosome replication

Vibrio cholerae carries homologs of plasmid-borne parA and parB genes on both of its chromosomes. The par genes help to segregate many plasmids and chromosomes. Here we have studied the par genes of V. cholerae chromosome I. Earlier studies suggested that ParBI binds to the centromeric site parSI near the origin of replication (oriI), and parSI-ParBI complexes are placed at the cell poles by ParAI. Deletion of parAI and parSI caused the origin-proximal DNA to be less polar. Here we found that deletion of parBI also resulted in a less polar localization of oriI. However, unlike the deletion of parAI, the deletion of parBI increased the oriI number. Replication was normal when both parAI and parBI were deleted, suggesting that ParBI mediates its action through ParAI. Overexpression of ParAI in a parABI-deleted strain also increased the DNA content. The results are similar to those found for Bacillus subtilis, where ParA (Soj) stimulates replication and this activity is repressed by ParB (SpoOJ). As in B. subtilis, the stimulation of replication most likely involves the replication initiator DnaA. Our results indicate that control of chromosomal DNA replication is an additional function of chromosomal par genes conserved across the Gram-positive/Gram-negative divide.     

Multipartite regulation of rctB, the replication initiator gene of Vibrio cholerae chromosome II

Replication initiator proteins in bacteria not only allow DNA replication but also often regulate the rate of replication initiation as well. The regulation is mediated by limiting the synthesis or availability of initiator proteins. The applicability of this principle is demonstrated here for RctB, the replication initiator for the smaller of the two chromosomes of Vibrio cholerae. A strong promoter for the rctB gene named rctBp was identified and found to be autoregulated in Escherichia coli. Promoter activity was lower in V. cholerae than in E. coli, and a part of this reduction is likely to be due to autorepression. Sequences upstream of rctBp, implicated earlier in replication control, enhanced the repression. The action of the upstream sequences required that they be present in cis, implying long-range interactions in the control of the promoter activity. A second gene specific for chromosome II replication, rctA, reduced rctB translation, most likely by antisense RNA control. Finally, optimal rctBp activity was found to be dependent on Dam. Increasing RctB in trans increased the copy number of a miniplasmid carrying oriCII(VC), implying that RctB can be rate limiting for chromosome II replication. The multiple modes of control on RctB are expected to reduce fluctuations in the initiator concentration and thereby help maintain chromosome copy number homeostasis.     

Selective chromosome amplification in Vibrio cholerae

Most bacteria have one chromosome but some have more than one, as is common in eukaryotes. How multiple chromosomes are maintained in bacteria remains largely obscure. Here we have examined the behaviour of the two Vibrio cholerae chromosomes as a function of growth rate. At slow growth rates, both chromosomes were maintained at copy numbers of one to two per cell. Increasing the growth rate by nutritional shift-up amplified the origin-proximal DNA of the larger chromosome (chrI) to four copies per cell, but not that of the smaller chrII. The latter was amplified when its specific initiator was supplied in excess or a specific negative regulator was deleted. The growth rate-insensitive behaviour of chrII, whose origin is similar to origins of members of a major class of plasmids, was shared by some but not all of several representative plasmids tested in V. cholerae. Also, unlike plasmid replication, chrII replication is known to be initiated at a specific stage of the cell cycle. Raising chrII copy number decreased growth rate, suggesting that this chromosome might serve as a repository for necessary but potentially deleterious genes.     

Distinct centromere-like parS sites on the two chromosomes of Vibrio spp

Vibrio cholerae, the cause of cholera, has two circular chromosomes. The parAB genes on each V. cholerae chromosome act to control chromosome segregation in a replicon-specific fashion. The chromosome I (ChrI) parAB genes (parAB1) govern the localization of the origin region of ChrI, while the chromosome II (ChrII) parAB genes (parAB2) control the segregation of ChrII. In addition to ParA and ParB proteins, Par systems require ParB binding sites (parS). Here we identified the parS sites on both V. cholerae chromosomes. We found three clustered origin-proximal ParB1 binding parS1 sites on ChrI. Deletion of these three parS1 sites abrogated yellow fluorescent protein (YFP)-ParB1 focus formation in vivo and resulted in mislocalization of the ChrI origin region. However, as observed in a parA1 mutant, mislocalization of the ChrI origin region in the parS1 mutant did not compromise V. cholerae growth, suggesting that additional (non-Par-related) mechanisms may mediate the partitioning of ChrI. We also identified 10 ParB2 binding parS2 sites, which differed in sequence from parS1. Fluorescent derivatives of ParB1 and ParB2 formed foci only with the cognate parS sequence. parABS2 appears to form a functional partitioning system, as we found that parABS2 was sufficient to stabilize an ordinarily unstable plasmid in Escherichia coli. Most parS2 sites were located within 70 kb of the ChrII origin of replication, but one parS2 site was found in the terminus region of ChrI. In contrast, in other sequenced vibrio species, the distribution of parS1 and parS2 sites was entirely chromosome specific.     

Independent control of replication initiation of the two Vibrio cholerae chromosomes by DnaA and RctB

Although the two Vibrio cholerae chromosomes initiate replication in a coordinated fashion, we show here that each chromosome appears to have a specific replication initiator. DnaA overproduction promoted overinitiation of chromosome I and not chromosome II. In contrast, overproduction of RctB, a protein that binds to the origin of replication of chromosome II, promoted overinitiation of chromosome II and not chromosome I.     

The two chromosomes of Vibrio cholerae are initiated at different time points in the cell cycle

The bacterium Vibrio cholerae, the cause of the diarrhoeal disease cholera, has its genome divided between two chromosomes, a feature uncommon for bacteria. The two chromosomes are of different sizes and different initiator molecules control their replication independently. Using novel methods for analysing flow cytometry data and marker frequency analysis, we show that the small chromosome II is replicated late in the C period of the cell cycle, where most of chromosome I has been replicated. Owing to the delay in initiation of chromosome II, the two chromosomes terminate replication at approximately the same time and the average number of replication origins per cell is higher for chromosome I than for chromosome II. Analysis of cell-cycle parameters shows that chromosome replication and segregation is exceptionally fast in V. cholerae. The divided genome and delayed replication of chromosome II may reduce the metabolic burden and complexity of chromosome replication by postponing DNA synthesis to the last part of the cell cycle and reducing the need for overlapping replication cycles during rapid proliferation.     

Comparison of genome structures of vibrios,bacteria possessing two chromosomes

Vibrios are gram-negative gamma-proteobacteria which are ubiquitous in marine and estuarine environments. Recently, we demonstrated that some, if not all, Vibrio species have two circular chromosomes. The whole genome sequence of Vibrio cholerae N16961 has been reported. In this study, we constructed a physical and genetic map of the genome of Kanagawa phenomenon-positive Vibrio parahaemolyticus strain KX-V237 and compared it with those of V. parahaemolyticus AQ4673 and V. cholerae N16961. The genome of KX-V237 comprised two circular chromosomes (3.3 and 1.9 Mb), similar to the structure of the AQ4673 genome. The relative positions of the genes on the genomes were well conserved in the two strains, but a large inversion on the large chromosomes, probably symmetric around the replication origin, was suggested. Although the sizes of the large chromosomes of KX-V237 and V. cholerae N16961 were similar, the sizes of the small chromosomes were very different. Unlike N16961, the superintegron of KX-V237 was located on the large chromosome. Comparison of the genetic maps of the chromosomes of KX-V237 and V. cholerae N16961 revealed that most of the open reading frames (ORFs) present on the large chromosome of the V. cholerae strain had homologues on the large chromosome of the V. parahaemolyticus strain and that most of the ORFs on the small chromosome of N16961 were present on the small chromosome of KX-V237. The difference in the orders of the ORFs on the chromosomes of N16961 and KX-V237 implies that numerous and frequent genetic exchanges have occurred intrachromosomally rather than interchromosomally.     

Distinct segregation dynamics of the two Vibrio cholerae chromosomes

The study of prokaryotic chromosome segregation has focused primarily on bacteria with single circular chromosomes. Little is known about segregation in bacteria with multipartite genomes. The human diarrhoeal pathogen Vibrio cholerae has two circular chromosomes of unequal sizes. Using static and time-lapse fluorescence microscopy, we visualized the localization and segregation of the origins of replication of the V. cholerae chromosomes. In all stages of the cell cycle, the two origins localized to distinct subcellular locations. In newborn cells, the origin of chromosome I (oriCIvc) was located near the cell pole while the origin of chromosome II (oriCIIvc) was at the cell centre. Segregation of oriCIvc occurred asymmetrically from a polar position, with one duplicated origin traversing the length of the cell towards the opposite pole and the other remaining relatively fixed. In contrast, oriCIIvc segregated later in the cell cycle than oriCIvc and the two duplicated oriCIIvc regions repositioned to the new cell centres. DAPI staining of the nucleoid demonstrated that both origin regions were localized to the edge of the visible nucleoid and that oriCIvc foci were often associated with specific nucleoid substructures. The differences in localization and timing of segregation of oriCIvc and oriCIIvc suggest that distinct mechanisms govern the segregation of the two V. cholerae chromosomes.     

Translesion-synthesis DNA polymerases participate in replication of the telomeres in Streptomyces

Linear chromosomes and linear plasmids of Streptomyces are capped by terminal proteins that are covalently bound to the 5'-ends of DNA. Replication is initiated from an internal origin, which leaves single-stranded gaps at the 3'-ends. These gaps are patched by terminal protein-primed DNA synthesis. Streptomyces contain five DNA polymerases: one DNA polymerase I (Pol I), two DNA polymerases III (Pol III) and two DNA polymerases IV (Pol IV). Of these, one Pol III, DnaE1, is essential for replication, and Pol I is not required for end patching. In this study, we found the two Pol IVs (DinB1 and DinB2) to be involved in end patching. dinB1 and dinB2 could not be co-deleted from wild-type strains containing a linear chromosome, but could be co-deleted from mutant strains containing a circular chromosome. The resulting ΔdinB1 ΔdinB2 mutants supported replication of circular but not linear plasmids, and exhibited increased ultraviolet sensitivity and ultraviolet-induced mutagenesis. In contrast, the second Pol III, DnaE2, was not required for replication, end patching, or ultraviolet resistance and mutagenesis. All five polymerase genes are relatively syntenous in the Streptomyces chromosomes, including a 4-bp overlap between dnaE2 and dinB2. Phylogenetic analysis showed that the dinB1-dinB2 duplication occurred in a common actinobacterial ancestor.     

Papillomavirus contains cis-acting sequences that can suppress but not regulate origins of DNA replication.

Bovine papillomavirus (BPV) DNA has been reported to restrict its own replication and that of the lytic simian virus 40 (SV40) origin to one initiation event per molecule per S phase, which suggests BPV DNA replication as a model for cellular chromosome replication. Suppression of the SV40 origin required two cis-acting BPV sequences (NCOR-1 and -2) and one trans-acting BPV protein. The results presented in this paper confirm the presence of two NCOR sequences in the BPV genome that can suppress polyomavirus (PyV) as well as SV40 origin-dependent DNA replication as much as 40-fold. However, in contrast to results of previous studies on SV40, most of the suppression of the PyV origin was due to NCOR-1, a 512-bp sequence that functioned independently of distance or orientation with respect to the PyV origin and that was not required for BPV DNA replication. Moreover, NCOR-1 alone or together with NCOR-2 did not restrict the ability of the PyV ori to reinitiate replication within a single S phase and did not require any BPV protein to exert suppression. Furthermore, NCOR-1 did not suppress BPV origin-dependent DNA replication except in the presence of PyV large tumor antigen (T-ag). Since NCOR-1 suppression of PyV origin activity also varied with T-ag concentration, suppression of origins by NCOR sequences appeared to require papovavirus T-ag. Therefore, it is unlikely that NCOR sequences are involved in regulating BPV DNA replication. When these results are taken together with those from other laboratories, BPV appears to be a slowly replicating version of papovaviruses rather than a model for origins of DNA replication in eukaryotic cell chromosomes.     

The DNA damage response pathway contributes to the stability of chromosome III derivatives lacking efficient replicators

In eukaryotic chromosomes, DNA replication initiates at multiple origins. Large inter-origin gaps arise when several adjacent origins fail to fire. Little is known about how cells cope with this situation. We created a derivative of Saccharomyces cerevisiae chromosome III lacking all efficient origins, the 5ORIΔ-ΔR fragment, as a model for chromosomes with large inter-origin gaps. We used this construct in a modified synthetic genetic array screen to identify genes whose products facilitate replication of long inter-origin gaps. Genes identified are enriched in components of the DNA damage and replication stress signaling pathways. Mrc1p is activated by replication stress and mediates transduction of the replication stress signal to downstream proteins; however, the response-defective mrc1(AQ) allele did not affect 5ORIΔ-ΔR fragment maintenance, indicating that this pathway does not contribute to its stability. Deletions of genes encoding the DNA-damage-specific mediator, Rad9p, and several components shared between the two signaling pathways preferentially destabilized the 5ORIΔ-ΔR fragment, implicating the DNA damage response pathway in its maintenance. We found unexpected differences between contributions of components of the DNA damage response pathway to maintenance of ORIΔ chromosome derivatives and their contributions to DNA repair. Of the effector kinases encoded by RAD53 and CHK1, Chk1p appears to be more important in wild-type cells for reducing chromosomal instability caused by origin depletion, while Rad53p becomes important in the absence of Chk1p. In contrast, RAD53 plays a more important role than CHK1 in cell survival and replication fork stability following treatment with DNA damaging agents and hydroxyurea. Maintenance of ORIΔ chromosomes does not depend on homologous recombination. These observations suggest that a DNA-damage-independent mechanism enhances ORIΔ chromosome stability. Thus, components of the DNA damage response pathway contribute to genome stability, not simply by detecting and responding to DNA template damage, but also by facilitating replication of large inter-origin gaps.     

Overexpression of the dnaA gene in Escherichia coli B/r: chromosome and minichromosome replication in the presence of rifampin.

The replication of chromosomes and minichromosomes in Escherichia coli B/r was examined under conditions in which the dnaA gene product was overproduced. Increased levels of the DnaA protein were achieved by thermoinduction of the dnaA gene, under the control of the lambda pL promoter, or by cellular maintenance of multicopy plasmids carrying the dnaA gene under the control of its own promoters. Previous work has shown that overproduction of DnaA protein stimulates replication of the chromosomal origin, oriC, but that the newly initiated forks do not progress along the length of the chromosome (T. Atlung, K. V. Rasmussen, E. Clausen, and F. G. Hansen, p. 282-297, in M. Schaechter, F. C. Neidhardt, J. L. Ingraham, and N. O. Kjeldgaard, ed., The Molecular Biology of Bacterial Growth, 1985). In the present study, it was found that overproduction of DnaA protein caused both a two- to threefold increase in the amount of residual chromosome replication and an extended synthesis of minichromosome DNA in the presence of rifampin. The amount of residual chromosome replication was consistent with the appearance of functional replication forks on the majority of the chromosomes. Since the rate of DNA accumulation and the cellular DNA/mass ratios were not increased significantly by overexpression of the dnaA gene, we concluded that the addition of rifampin either enabled stalled replication forks to proceed beyond oriC or enabled new forks to initiate on both chromosomes and minichromosomes, or both.     

Reversal of DNA methylation with 5-azacytidine alters chromosome replication patterns in human lymphocyte and fibroblast cultures

Prior studies demonstrated that developmental or induced methylation of DNA can inactivate associated gene loci. Such DNA methylation can be reversed and specific genes reactivated by treatment with 5-azacytidine (5- azaC ). The present cytogenetic studies using replication banding methods show that 5- azaC treatment also results in an increase or decrease in replication staining at one or more band locations in human lymphocyte and fibroblast chromosomes. New replication band locations are not formed. These changes in replication staining, which reflect changes in timing of replication, are different between these two tissues. However, in both tissues, the delayed onset of replication in the heterocyclic, inactive X is shortened by 5- azaC . A correlation is thus suggested between the induced temporal change to earlier DNA replication, and induced hypomethylation and gene activation. The temporal effect on chromosome replication in 5- azaC -treated cells depends on the portion of the S-period studied. Toward the beginning of S, early-replication patterns are increased in both lymphocytes and fibroblasts. Toward the end of S, late-replication patterns are increased only in lymphocytes, suggesting a differential effect of 5- azaC in: (1) early-vs. late-S, and (2) lymphocytes vs. fibroblasts. Generally, 5- azaC has its greatest effect on the inactive chromosome regions that are typically late-replicating prior to 5- azaC treatment. These observed changes in replication band staining suggest that DNA methylation may modify regional groups of genes in concert.