Subcellular localization of plasmids containing the oriC region of the Escherichia coli chromosome, with or without the sopABC partitioning system

Fluorescence in situ hybridization (FISH) analysis has revealed the subcellular localization of specific chromosomal segments and plasmid molecules during the cell division cycle in Escherichia coli: the replication origin (oriC) segments on the chromosome are localized at nucleoid borders, and actively partitioning mini-F plasmid molecules are localized at the 1/4 and 3/4 positions of the cell. In contrast, mini-F plasmid molecules lacking the sopABC segment are randomly localized in cytoplasmic areas at cell poles. In this study, we analysed the subcellular localization of an oriC plasmid that contains the minimum E. coli chromosomal replication origin and its flanking regions. These oriC plasmid molecules were mainly localized in cytosolic areas at cell poles. On the other hand, oriC plasmid DNA molecules carrying the sopABC segment of F plasmid were localized at cell quarter sites, as were actively partitioning mini-F plasmid DNA molecules. Therefore, we conclude that oriC itself and its flanking regions are not sufficient for positioning the replication origin domain of the E. coli chromosome within the cell.     

Localization of plastid DNA replication on a nucleoid structure

Plastids contain multiple copies of the plastid genome that are arranged into discrete aggregates, termed nucleoids. Nucleoid molecular organization and its possible role in ensuring genome continuity have not yet been carefully explored. We examined the relationship between plastid DNA synthesis and nucleoid cytology in the unicellular chrysophyte Ochromonas danica, which is useful for such work because the genomes in each plastid are arranged in a single ring-shaped nucleoid. Immunocytochemical detection of thymidine analog incorporation into replicating DNA revealed that plastid DNA synthesis occurs at several sites along the ring nucleoid simultaneously, and that all plastids of a single cell display similar replication patterns. Plastid DNA replication was observed in G1, S, and G2 phase cells. Pulse-chase-pulse labelling with two different thymidine analogs revealed that new sites are activated as cells progress through the cell cycle while some old sites continue. The double labelling patterns suggest that the individual genomes are arranged consecutively, either singly or in clusters, along the nucleoid perimeter and that the selection of which genome replicates when is a matter of chance. These observations eliminate a number of alternative hypotheses concerning plastid DNA organization, and suggest how cells might maintain a constancy of plastid DNA amount and why plastid genome variants segregate so rapidly during mitosis.     

FtsZ ring formation without subsequent cell division after replication runout in Escherichia coli

In this report, we have investigated cell division after inhibition of initiation of chromosome replication in Escherichia coli. In a culture grown to the stationary phase, cells containing more than one chromosome were able to divide some time after restart of growth, under conditions not allowing initiation of chromosome replication. This shows that there is no requirement for cell division to take place within a certain time after initiation of chromosome replication. Continued growth without initiation of replication resulted in filamented cells that generally did not have any constrictions. Interestingly, FtsZ rings were formed in a majority of these cells as they reached a certain cell length. These rings appeared and were maintained for some time at the cell quarter positions on both sides of the centrally localized nucleoid. These results confirm previous findings that cell division sites are formed independently of chromosome replication and indicate that FtsZ ring assembly is dependent on cell size rather than on the capacity of the cell to divide. Disruption of the mukB gene caused a significant increase in the region occupied by DNA after the replication runout, consistent with a role of MukB in chromosome condensation. The aberrant nucleoid structure was accompanied by a shift in FtsZ ring positioning, indicating an effect of the nucleoid on the positioning of the FtsZ ring. A narrow cell length interval was found, under and over which primarily central and non-central FtsZ rings, respectively, were observed. This finding correlates well with the previously observed oscillatory movement of MinC and MinD in short and long cells.     

Distribution of the Escherichia coli structural maintenance of chromosomes (SMC)-like protein MukB in the cell

Fluorescent polyclonal antibodies specific for MukB have been used to study its localization in Escherichia coli. In wild-type cells, the MukB protein appeared as a limited number of oblong shapes embracing the nucleoid. MukB remained associated with the nucleoid in the absence of DNA replication. The centre of gravity of the dispersed MukB signal initially localized near mid-cell, but moved to approximately quarter positions well before the termination of DNA replication and its subsequent reinitiation. Because MukB had been reported to bind to FtsZ and to its eukaryotic homologue tubulin in vitro, cells were co-labelled with MukB- and FtsZ-specific fluorophores. No co-localization of MukB with polymerized FtsZ (the FtsZ ring) was observed at any time during the cell cycle. A possible role for MukB in preventing premature FtsZ polymerization and in DNA folding that might assist DNA segregation is discussed.     

DNA replication initiation is required for mid-cell positioning of FtsZ rings in Caulobacter crescentus

Polymerization of the GTPase FtsZ to form a structure called the Z-ring is the earliest known step in bacterial cell division. Mid-cell Z-ring assembly coincides with the beginning of the replication cycle in the differentiating bacterium Caulobacter crescentus. Z-ring disassembly occurs at the end of the division cycle, resulting in the complete degradation of FtsZ from both stalked and swarmer progeny cells. New Z-rings can only form in the replicative stalked cell. Conditional mutants in DNA replication were used to determine what role DNA replication events play in the process of Z-ring assembly at different stages in the cell cycle. Z-ring assembly occurred even when early stages of DNA replication were blocked; however, the Z-rings were localized at a subpolar region of the cell. Z-rings only assembled at the proper mid-cell location if DNA replication had initiated. Z-ring assembly coincided with areas containing little or no DNA, and Z-rings could not form over an unreplicated chromosome. Overexpressed FtsZ in the absence of DNA replication did not stimulate productive mid-cell Z-ring assembly but, instead, caused the ends of cells to constrict over an extended area away from the nucleoid. These results indicate that the state of chromosome replication is a major determinant of Z-ring localization in Caulobacter.     

Nuclear and nucleoid localization are independently conserved functions in bacteriophage terminal proteins

Bacteriophage terminal proteins (TPs) prime DNA replication and become covalently linked to the DNA 5′‐ends. In addition, they are DNA‐binding proteins that direct early organization of phage DNA replication at the bacterial nucleoid and, unexpectedly, contain nuclear localization signals (NLSs), which localize them to the nucleus when expressed in mammalian cells. In spite of the lack of sequence homology among the phage TPs, these three properties share some common features, suggesting a possible evolutionary common origin of TPs. We show here that NLSs of three different phage TPs, Φ29, PRD1 and Cp‐1, are mapped within the protein region required for nucleoid targeting in bacteria, in agreement with a previously proposed common origin of DNA‐binding domains and NLSs. Furthermore, previously reported point mutants of Φ29 TP with no nuclear localization still can target the bacterial nucleoid, and Cp‐1 TP contains two independent NLSs, only one of them required for nucleoid localization. Altogether, our results show that nucleoid and nucleus localization sequence requirements partially overlap, but they can be uncoupled, suggesting that conservation of both features could have a common origin but, at the same time, they have been independently conserved during evolution.     

Division of chloroplast nucleoids and replication of chloroplast DNA during the cell cycle ofDunaliella salina grown under blue and red light

Summary Synchronous cultures of the algaDunaliella salina were grown in blue or red light. The relationships between replication of chloroplast DNA, cell size, cell age and the number of chloroplast nucleoids were studied. The replication of chloroplast DNA and the division of chloroplast nucleoids occurred in two separate periods of the chloroplast cycle. DNA replication was concomitant with that in the nucleocytoplasmic compartment but nucleoid division occurred several hours earlier than nuclear division. Red-light-grown cells were bigger and grew more rapidly than those grown in blue light. In newly formed daughter cells, the chloroplast nucleoids were small and spherical and they were localized around the pyrenoid. During the cell cycle they spread to other parts of the chloroplast. The number of DNA molecules per nucleoid doubled during DNA replication in the first third of the cell cycle but decreased several hours later when the nucleoids divided. Their number was fairly constant independent of the different light quality. Cells grown in red light replicated their chl-DNA and divided their nucleoids before those grown in blue light and their daughter cells possessed about 25 nucleoids as opposed to 15.Abbreviations DAPI 4,6-diamidino-2-phenylindole - chl-DNA chloroplast DNA - PAR photosynthetically active radiation     

Subcellular localization of Dna-initiation proteins of Bacillus subtilis: evidence that chromosome replication begins at either edge of the nucleoids

We examined the intracellular distribution of Bacillus subtilis Dna-initiation proteins by immunofluorescence microscopy to visualize the initiation complex of replication in vivo. DnaA was distributed throughout the cytoplasm, but both DnaB and DnaI were always detected as foci during the cell-division cycle. Interaction of DnaI with the DnaC helicase by the yeast two-hybrid assay suggests that DnaI acts as a helicase loader. The number of DnaB and DnaI foci within the cell exceeded that of oriC. Although the foci were not always co-localized with oriC, they seemed to be localized near the outer or inner edges of the nucleoids at initiation of replication. When the replication cycle was synchronized in cells using a temperature-sensitive dnaA mutant, duplication of the oriC region was observed predominantly near an edge of the nucleoid. Before initiation occurred, each one of the DnaB and DnaI foci was frequently observed near there. Furthermore, DnaX-GFP (DnaX is a component of DNA polymerase III) foci were detected near either of the edges of the nucleoids at the onset of replication. These results suggest that the replisome is recruited into oriC near either edge of the nucleoids to initiate chromosome replication in B. subtilis.     

Bacillus subtilis Cell Cycle as Studied by Fluorescence Microscopy: Constancy of Cell Length at Initiation of DNA Replication and Evidence for Active Nucleoid Partitioning

Fluorescence microscopic methods have been used to characterize the cell cycle of Bacillus subtilis at four different growth rates. The data obtained have been used to derive models for cell cycle progression. Like that of Escherichia coli, the period required by B. subtilis for chromosome replication at 37°C was found to be fairly constant (although a little longer, at about 55 min), as was the cell mass at initiation of DNA replication. The cell cycle of B. subtilis differed from that of E. coli in that changes in growth rate affected the average cell length but not the width and also in the relative variability of period between termination of DNA replication and septation. Overall movement of the nucleoid was found to occur smoothly, as in E. coli, but other aspects of nucleoid behavior were consistent with an underlying active partitioning machinery. The models for cell cycle progression in B. subtilis should facilitate the interpretation of data obtained from the recently introduced cytological methods for imaging the assembly and movement of proteins involved in cell cycle dynamics.     

Insertion of inverted Ter sites into the terminus region of the Escherichia coli chromosome delays completion of DNA replication and disrupts the cell cycle

To investigate the co-ordination between DNA replication and cell division, we have disrupted the DNA replication cycle of Escherichia coli by inserting inverted Ter sites into the terminus region to delay completion of the chromosome. The inverted Ter sites (designated Inv Ter :: spc ^r) were initially inserted into the chromosome of a Δ tus strain to allow unrestrained chromosomal replication. We then introduced a functional tus gene by transforming the Inv Ter :: spc ^r strain with a plasmid carrying the tus gene under control of an arabinose-inducible promoter. In the presence of 0.2% arabinose, the cells formed long filaments, suggesting that activation of the inverted Ter sites by Tus arrested DNA replication and delayed the onset of cell division. Induction of sfiA , a gene in the SOS regulon, was observed following arrest of DNA replication; however, when a sfiB114 allele was introduced into Inv Ter :: spc ^r strain, long filaments were still formed, suggesting that the sfi -independent pathway also caused filamentation. Either recA :: cam ^r or lexA3 alleles suppressed filamentation when introduced in the Inv Ter strain. Interestingly, in both the recA :: cam ^r and lexA3 mutants, virtually all cells had a nucleoid, suggesting that cell division was proceeding even though DNA replication was not complete. These results suggest that DNA replication and cell division are uncoupled when recA is inactivated or when genes repressed by LexA cannot be induced.     

New insights in the ϕ29 terminal protein DNA‐binding and host nucleoid localization functions

Protein‐primed DNA replication constitutes a strategy to initiate viral DNA synthesis in a variety of prokaryotic and eukaryotic organisms. Although the main function of viral terminal proteins (TPs) is to provide a free hydroxyl group to start initiation of DNA replication, there are compelling evidences that TPs can also play other biological roles. In the case of Bacillus subtilis bacteriophage ?29, the N‐terminal domain of the TP organizes viral DNA replication at the bacterial nucleoid being essential for an efficient phage DNA replication, and it contains a nuclear localization signal (NLS) that is functional in eukaryotes. Here we provide information about the structural properties of the ?29 TP N‐terminal domain, which possesses sequence‐independent DNA‐binding capacity, and dissect the amino acid residues important for its biological function. By mutating all the basic residues of the TP N‐terminal domain we identify the amino acids responsible for its interaction with the B. subtilis genome, establishing a correlation between the capacity of DNA‐binding and nucleoid localization of the protein. Significantly, these residues are important to recruit the DNA polymerase at the bacterial nucleoid and, subsequently, for an efficient phage DNA replication.     

Macromolecular crowding and the mandatory condensation of DNA in bacteria

Cellular DNA in bacteria is localized into nucleoids enclosed by cytoplasm. The forces which cause condensation of the DNA into nucleoids are poorly understood. We suggest that direct and indirect macromolecular crowding forces from the surrounding cytoplasm are critical factors for nucleoid condensation, and that within a bacterial cell these crowding forces are always present at such high levels that the DNA is maintained in a condensed state. The DNA affected includes not only the preexisting genomic DNA but also DNA that is newly introduced by viral infection, replication or other means.     

Dynamic organization of DNA replication in mammalian cell nuclei: spatially and temporally defined replication of chromosome-specific alpha-satellite DNA sequences

Five distinct patterns of DNA replication have been identified during S-phase in asynchronous and synchronous cultures of mammalian cells by conventional fluorescence microscopy, confocal laser scanning microscopy, and immunoelectron microscopy. During early S-phase, replicating DNA (as identified by 5-bromodeoxyuridine incorporation) appears to be distributed at sites throughout the nucleoplasm, excluding the nucleolus. In CHO cells, this pattern of replication peaks at 30 min into S-phase and is consistent with the localization of euchromatin. As S-phase continues, replication of euchromatin decreases and the peripheral regions of heterochromatin begin to replicate. This pattern of replication peaks at 2 h into S-phase. At 5 h, perinucleolar chromatin as well as peripheral areas of heterochromatin peak in replication. 7 h into S-phase interconnecting patches of electron-dense chromatin replicate. At the end of S-phase (9 h), replication occurs at a few large regions of electron-dense chromatin. Similar or identical patterns have been identified in a variety of mammalian cell types. The replication of specific chromosomal regions within the context of the BrdU-labeling patterns has been examined on an hourly basis in synchronized HeLa cells. Double labeling of DNA replication sites and chromosome-specific alpha-satellite DNA sequences indicates that the alpha-satellite DNA replicates during mid S-phase (characterized by the third pattern of replication) in a variety of human cell types. Our data demonstrates that specific DNA sequences replicate at spatially and temporally defined points during the cell cycle and supports a spatially dynamic model of DNA replication.     

Replication fork passage drives asymmetric dynamics of a critical nucleoid‐associated protein in Caulobacter

In bacteria, chromosome dynamics and gene expression are modulated by nucleoid‐associated proteins (NAPs), but little is known about how NAP activity is coupled to cell cycle progression. Using genomic techniques, quantitative cell imaging, and mathematical modeling, our study in Caulobacter crescentus identifies a novel NAP (GapR) whose activity over the cell cycle is shaped by DNA replication. GapR activity is critical for cellular function, as loss of GapR causes severe, pleiotropic defects in growth, cell division, DNA replication, and chromosome segregation. GapR also affects global gene expression with a chromosomal bias from origin to terminus, which is associated with a similar general bias in GapR binding activity along the chromosome. Strikingly, this asymmetric localization cannot be explained by the distribution of GapR binding sites on the chromosome. Instead, we present a mechanistic model in which the spatiotemporal dynamics of GapR are primarily driven by the progression of the replication forks. This model represents a simple mechanism of cell cycle regulation, in which DNA‐binding activity is intimately linked to the action of DNA replication.     

Re-replication from non-sequesterable origins generates three-nucleoid cells which divide asymmetrically

In rapidly growing Escherichia coli cells replication cycles overlap and initiation occurs at multiple replication origins (oriCs). All origins within a cell are initiated essentially in synchrony and only once per cell cycle. Immediate re-initiation of new origins is avoided by sequestration, a mechanism dependent on the SeqA protein and Dam methylation of GATC sites in oriC. Here, GATC sites in oriC were changed to GTTC. This reduced the sequestration to essentially the level found in SeqA-less cells. The mutant origins underwent re-initiation, showing that the GATC sites in oriC are required for sequestration. Each re-initiation eventually gave rise to a cell containing an extra nucleoid. The three-nucleoid cells displayed one asymmetrically placed FtsZ-ring and divided into a two-nucleoid cell and a one-nucleoid cell. The three nucleoid-cells thus divided into three daughters by two consecutive divisions. The results show that extra rounds of replication cause extra daughter cells to be formed prematurely. The fairly normal mutant growth rate and size distribution show, however, that premature rounds of replication, chromosome segregation, and cell division are flexibly accommodated by the existing cell cycle controls.     

Insertion and replication of the Pseudomonas aeruginosa mutator phage D3112

D3112 is a temperate bacteriophage of P. aeruginosa with heterogeneous sequences at one extremity of the virion DNA molecule. Infection of strain PAOl with phage D3112 results in a 40- to 65-fold increase in the frequency of ami mutants resistant to fluoroacetamide. Nine ami::D3112 prophages have been mapped to distinct sites within the ami locus by Southern blotting experiments with a cloned ami+ probe. All prophages have the same restriction map as the D3112 genome extracted from phage particles. The position of D3112 insertions correlates with the phenotype and reversion behavior of the ami mutants. Induction of D3112cts prophages results in amplification of internal prophage segments as discrete restriction fragments before the terminal viral fragments are visible as sharp hybridizing species. This indicates that D3112 replication is accompanied by recombination of prophage termini to numerous sites in the bacterial genome. Chromosomal junction fragments of an ami::D3112cts prophage are maintained through most of the replication cycle but are cleaved shortly before cell lysis, apparently by the viral encapsidation system.     

Characterization of the genome of the murine papovavirus K.

The DNA genome of the murine papovavirus K virus (KV) was characterized and compared with the genome of polyoma virus. A physical map of the KV genome was constructed by analysis of the size of DNA fragments generated by sequential cleavage with combinations of restriction endonucleases. By using one of the three EcoRI sites in the KV genome as the 0 map position, the KV physical map was then oriented to the polyoma virus genome. Of 42 restriction sites mapped within the KV genome, 7 were localized within 0.01 map unit of their respective sites in the polyoma virus genome; an eighth site mapped within 0.02 map unit. KV replication was examined and found to be bidirectional, initiating at approximately 0.70 map unit. This corresponds well to the origin of replication within the polyoma virus genome and further supports the orientation of the KV physical map.     

Signals at the bacteriophage phi 29 DNA replication origins required for protein p6 binding and activity.

Protein p6 of Bacillus subtilis phage phi 29 binds specifically to the ends of the viral DNA that contain the replication origins, giving rise to a nucleoprotein structure. DNA regions recognized by protein p6 have been mapped by deletion analysis and DNase I footprinting. Main protein p6-recognition signals have been located between nucleotides 62 and 125 at the right phi 29 DNA end and between nucleotides 46 and 68 at the left end. In addition, recognition signals are also present at other sites within 200-300 bp at each phi 29 DNA end. Protein p6 does not seem to recognize a specific sequence in the DNA, but rather a structural feature, which could be bendability. The formation of the protein p6-DNA nucleoprotein complex is likely to be the structural basis for the protein p6 activity in the initiation of replication.