Chromosomal sites of DNA-membrane attachment in Escherichia coli

Evidence is presented to show that both the chromosomal replication point and the chromosomal origin in Escherichia coli are associated with a structure possessing the sedimentation properties and enzyme sensitivities characteristic of membrane. The data suggest that both newly synthesized DNA strands and template DNA strands are bound at this replication point and that both strands are also bound at the origin.     

Escherichia coli DnaA protein--phospholipid interactions: in vitro and in vivo

DNA replication in Escherichia coli is controlled at the initiation stage, possibly by regulation of the essential activity of DnaA protein. The cellular membrane has long been hypothesized to be involved in chromosomal replication. Accumulating evidence, both in vitro and in vivo, that supports the importance of membrane phospholipids influencing the initiation activity of DnaA is reviewed.     

DnaA, the initiator of Escherichia coli chromosomal replication, is located at the cell membrane

Given the lack of a nucleus in prokaryotic cells, the significance of spatial organization in bacterial chromosome replication is only beginning to be fully appreciated. DnaA protein, the initiator of chromosomal replication in Escherichia coli, is purified as a soluble protein, and in vitro it efficiently initiates replication of minichromosomes in membrane-free DNA synthesis reactions. However, its conversion from a replicatively inactive to an active form in vitro occurs through its association with acidic phospholipids in a lipid bilayer. To determine whether the in situ residence of DnaA protein is cytoplasmic, membrane associated, or both, we examined the cellular location of DnaA using immunogold cryothin-section electron microscopy and immunofluorescence. Both of these methods revealed that DnaA is localized at the cell membrane, further suggesting that initiation of chromosomal replication in E. coli is a membrane-affiliated event.     

Compartmentalization of prokaryotic DNA replication

It becomes now apparent that prokaryotic DNA replication takes place at specific intracellular locations. Early studies indicated that chromosomal DNA replication, as well as plasmid and viral DNA replication, occurs in close association with the bacterial membrane. Moreover, over the last several years, it has been shown that some replication proteins and specific DNA sequences are localized to particular subcellular regions in bacteria, supporting the existence of replication compartments. Although the mechanisms underlying compartmentalization of prokaryotic DNA replication are largely unknown, the docking of replication factors to large organizing structures may be important for the assembly of active replication complexes. In this article, we review the current state of this subject in two bacterial species, Escherichia coli and Bacillus subtilis, focusing our attention in both chromosomal and extrachromosomal DNA replication. A comparison with eukaryotic systems is also presented.     

Participation of plasmid F in the replication of the chromosome of an Hfr strain of Escherichia coli K-12

In the region of plasmid F DNA with coordinates 52,2-55,8 kb, the chr ("chromosome replication") locus has been revealed. A failure in the functioning of this locus in the integrated plasmid, which leads to a temperature-sensitive disturbance in chromosome replication of the Hfr strain and to the changes in its sensitivity to some membranotropic agents. Integration of an F segment containing the chr+ allele into the chromosome of an F-like derivative of such Hfr strain (retaining a mutant part of the F DNA), results in formation of temperature-resistant clones. In these clones, chromosomal replication is controlled by the plasmid replicon at the elevated temperature. It has been concluded that the F plasmid can control chromosome replication of the dna+ HfrC strain of Escherichia coli K-12 and that the product of the chr gene is a membrane protein involved in chromosomal replication.     

Protein kinase A is required for chromosomal DNA replication.

Passage through mitosis resets cells for a new round of chromosomal DNA replication [1]. In late mitosis, the pre-replication complex - which includes the origin recognition complex (ORC), Cdc6 and the minichromosome maintenance (MCM) proteins - binds chromatin as a pre-requisite for DNA replication. S-phase-promoting cyclin-dependent kinases (Cdks) and the kinase Dbf4-Cdc7 then act to initiate replication. Before the onset of replication Cdc6 dissociates from chromatin. S-phase and M-phase Cdks block the formation of a new pre-replication complex, preventing DNA over-replication during the S, G2 and M phases of the cell cycle [1]. The nuclear membrane also contributes to limit genome replication to once per cell cycle [2]. Thus, at the end of M phase, nuclear membrane breakdown and the collapse of Cdk activity reset cells for a new round of chromosomal replication. We showed previously that protein kinase A (PKA) activity oscillates during the cell cycle in Xenopus egg extracts, peaking in late mitosis. The oscillations are induced by the M-phase-promoting Cdk [3] [4]. Here, we found that PKA oscillation was required for the following phase of DNA replication. PKA activity was needed from mitosis exit to the formation of the nuclear envelope. PKA was not required for the assembly of ORC2, Cdc6 and MCM3 onto chromatin. Inhibition of PKA activity, however, blocked the release of Cdc6 from chromatin and subsequent DNA replication. These data suggest that PKA activation in late M phase is required for the following S phase.     

Mutation of host delta9 fatty acid desaturase inhibits brome mosaic virus RNA replication between template recognition and RNA synthesis

All positive-strand RNA viruses assemble their RNA replication complexes on intracellular membranes. Brome mosaic virus (BMV) replicates its RNA in endoplasmic reticulum (ER)-associated complexes in plant cells and the yeast Saccharomyces cerevisiae. BMV encodes RNA replication factors 1a, with domains implicated in RNA capping and helicase functions, and 2a, with a central polymerase-like domain. Factor 1a interacts independently with the ER membrane, viral RNA templates, and factor 2a to form RNA replication complexes on the perinuclear ER. We show that BMV RNA replication is severely inhibited by a mutation in OLE1, an essential yeast chromosomal gene encoding delta9 fatty acid desaturase, an integral ER membrane protein and the first enzyme in unsaturated fatty acid synthesis. OLE1 deletion and medium supplementation show that BMV RNA replication requires unsaturated fatty acids, not the Ole1 protein, and that viral RNA replication is much more sensitive than yeast growth to reduced unsaturated fatty acid levels. In ole1 mutant yeast, 1a still becomes membrane associated, recruits 2a to the membrane, and recognizes and stabilizes viral RNA templates normally. However, RNA replication is blocked prior to initiation of negative-strand RNA synthesis. The results show that viral RNA synthesis is highly sensitive to lipid composition and suggest that proper membrane fluidity or plasticity is essential for an early step in RNA replication. The strong unsaturated fatty acid dependence also demonstrates that modulating fatty acid balance can be an effective antiviral strategy.     

Membrane-catalyzed nucleotide exchange on DnaA. Effect of surface molecular crowding

DnaA is the initiator protein for chromosomal replication in bacteria; its activity plays a central role in the timing of the primary initiations within the Escherichia coli cell cycle. A controlled, reversible conversion between the active ATP-DnaA and the inactive ADP forms modulates this activity. In a DNA-dependent manner, bound ATP is hydrolyzed to ADP. Acidic phospholipids with unsaturated fatty acids are capable of reactivating ADP-DnaA by promoting the release of the tightly bound ADP. The nucleotide dissociation kinetics, measured in the present study with the fluorescent derivative 3'-O-(N-methylantraniloyl)-5'-adenosine triphosphate, was dependent on the density of DnaA on the membrane in a cooperative manner: it increased 5-fold with decreased protein density. At all surface densities the nucleotide was completely released, presumably due to protein exchange on the membrane. Distinct temperature dependences and the effect of the crowding agent Ficoll suggest that two functional states of DnaA exist at high and low membrane occupancy, ascribed to local macromolecular crowding on the membrane surface. These novel phenomena are thought to play a major role in the mechanism regulating the initiation of chromosomal replication in bacteria.     

Patterns of chromosomal fragmentation due to uracil-DNA incorporation reveal a novel mechanism of replication-dependent double-stranded breaks

There is growing evidence that spontaneous chromosomal fragmentation, one of the main contributors to genetic instability, is intimately linked to DNA replication. In particular, we proposed before that uracil incorporation in DNA triggers chromosomal fragmentation due to replication fork collapse at uracil-excision intermediates. We tested predictions of this model at the chromosomal level in the dut mutants of Escherichia coli , by determining the relationship between DNA replication and patterns of fragmentation in defined chromosomal segments. Here we show that the uracil-DNA-triggered chromosomal fragmentation: (i) has a gradient that parallels the replication gradient, (ii) shows polarity within defined segments pointing towards replication origins and (iii) reorganizes to match induced replication gradients, confirming its dynamic pattern. Unexpectedly, these fragmentation patterns not only support the replication fork collapse model, but also reveal another mechanism of the replication-dependent chromosomal fragmentation triggered by uracil excision.     

Selective association of the chromosome with membrane in a stable L-form of Bacillus subtilis.

A stalbe L-form (Sal-1) of Bacillus subtilis was found to have retained a markedly modified chromosome-membrane association when compared to intact cells. The membrane-deoxyribonucleic acid complex of the L-form was similar to that of its parental strain in quantity and stability. Genetic analysis of the L-form membrane-deoxyribonucleic acid complex revealed enrichment for markers close to the replication origin, but not for internal markers, indicating preferential attachment of the origin of chromosomal replication to the membrane. These results are in close agreement with those found for the parental bacterial form. In contrast, the replication termius region was not preferentially attached to the membrane of the L-form, even though it is enriched in the bacterial form. The association of the chromosome with the membrane at the replication terminus does not appear to be necessary for cell growth and separation, but because the L-form divides aberrantly, it may be one of the factors required for normal deoxyribonucleic acid segregation and septation.     

Reduced lipopolysaccharide phosphorylation in Escherichia coli lowers the elevated ori/ter ratio in seqA mutants

The seqA defect in Escherichia coli increases the ori/ter ratio and causes chromosomal fragmentation, making seqA mutants dependent on recombinational repair (the seqA recA colethality). To understand the nature of this chromosomal fragmentation, we characterized Δ seqA mutants and isolated suppressors of the Δ seqA recA lethality. We demonstrate that our Δ seqA alleles have normal function of the downstream pgm gene and normal ratios of the major phospholipids in the membranes, but increased surface lipopolysaccharide (LPS) phosphorylation. The predominant class of Δ seqA recA suppressors disrupts the rfaQGP genes, reducing phosphorylation of the inner core region of LPS. The rfaQGP suppressors also reduce the elevated ori/ter ratio of the Δ seqA mutants but, unexpectedly, the suppressed mutants still exhibit the high levels of chromosomal fragmentation and SOS induction, characteristic of the Δ seqA mutants. We also found that colethality of rfaP with defects in the production of acidic phospholipids is suppressed by alternative initiation of chromosomal replication, suggesting that LPS phosphorylation stimulates replication initiation. The rfaQGP suppression of the seqA recA lethality provides genetic support for the surprising physical evidence that the oriC DNA forms complexes with the outer membrane.     

Intracellular location of NRl-plasmid DNA inEscherichia coli minicells

Intracellular location of plasmid NR1 (M = 58 Mg/mol, stringent control of replication, 1–2 copies perEscherichia coli chromosomal equivalent) was studied and compared with that of plasmid R6KΔ1 (M = 21 Mg/mol, relaxed control of replication, 10–15 copies perE. coli chromosomal equivalent), both inE. coli minicells. Considerable difference in relative distribution of molecules of these two plasmid DNA’s between the cytoplasm and the membrane fraction was found when components of the corresponding minicell lyzates were fractionated by sedimentation in a double-linear gradient of caesium chlorid and sucrose. Also the difference in relative numbers of NR1 DNA and R6KΔ1 DNA molecules stably associated with the membrane of minicells, determined by electron-microscopic examination of the fractions containing plasmid DNA-membrane complexes, was evaluated as statistically significant. The association of NR1 DNA molecules withE. coli minicell membrane was found to be a much more frequent event than such association of R6KΔ1 molecules. The absolute amount of plasmid DNA associated with membrane in a single minicell corresponds to one molecule for both NR1 and R6KAΔ1.     

Host DNA replication forks are not preferred targets for bacteriophage Mu transposition.

Bacteriophage Mu DNA integration in Escherichia coli strains infected after alignment of chromosomal replication was analyzed by a sandwich hybridization assay. The results indicated that Mu integrated into chromosomal segments at various distances from oriC with similar kinetics. In an extension of these studies, various Hfr strains were infected after alignment of chromosomal replication, and Mu transposition was shut down early after infection. The positions of integrated Mu copies were inferred from the transfer kinetics of Mu to an F- strain. Our analysis indicated that the location of Mu DNA in the host chromosome was not dependent on the positions of host replication forks at the time of infection. However, the procedure for aligning chromosomal replication affected DNA transfer by various Hfr strains differently, and this effect could account for prior results suggesting preferential integration of Mu at host replication forks.     

DNA — protein interactions during replication of Genetic elements of bacteria

Specific interactions of DNA with proteins are required for both the replication of deoxyribonucleic acid proper and its regulation. Genetic elements of bacteria, their extrachromosomal elements in particular, represent a suitable model system for studies of these processes at the molecular level. In addition to replication enzymes (DNA polymerases), a series of other protein factors (e.g. topoisomerases, DNA unwinding enzymes, and DNA binding proteins) are involved in the replication of the chromosomal, phage and plasmid DNA. Specific interactions of proteins with DNA are particularly important in the regulation of initiation of DNA synthesis. Association of DNAs with the cell membrane also plays an important role in their replication in bacteria.     

Yeast DNA replication in vitro: initiation and elongation events mimic in vivo processes

An enzyme system prepared from Saccharomyces cerevisiae carries out the replication of exogenous yeast plasmid DNA. Replication in vitro mimics that in vivo in that DNA synthesis in extracts of strain cdc8, a temperature-sensitive DNA replication mutant, is thermolabile relative to the wild-type, and in that aphidicolin inhibits replication in vitro. Furthermore, only plasmids containing a functional yeast replicator, ARS, initiate replication at a specific site in vitro. Analysis of replicative intermediates shows that plasmid YRp7, which contains the chromosomal replicator ARS1, initiates bidirectional replication in a 100 bp region within the sequence required for autonomous replication in vivo. Plasmids containing ARS2, another chromosomal replicator, and the ARS region of the endogenous yeast plasmid 2 microns circle give similar results, suggesting that ARS sequences are specific origins of chromosomal replication. Used in conjunction with deletion mapping, the in vitro system allows definition of the minimal sequences required for the initiation of replication.     

RPA is an initiation factor for human chromosomal DNA replication

The initiation of chromosomal DNA replication in human cell nuclei is not well understood because of its complexity. To allow investigation of this process on a molecular level, we have recently established a cell-free system that initiates chromosomal DNA replication in an origin-specific manner under cell cycle control in isolated human cell nuclei. We have now used fractionation and reconstitution experiments to functionally identify cellular factors present in a human cell extract that trigger initiation of chromosomal DNA replication in this system. Initial fractionation of a cytosolic extract indicates the presence of at least two independent and non-redundant initiation factors. We have purified one of these factors to homogeneity and identified it as the single-stranded DNA binding protein RPA. The prokaryotic single-stranded DNA binding protein SSB cannot substitute for RPA in the initiation of human chromosomal DNA replication. Antibodies specific for human RPA inhibit the initiation step of human chromosomal DNA replication in vitro. RPA is recruited to DNA replication foci and becomes phosphorylated concomitant with the initiation step in vitro. These data establish a direct functional role for RPA as an essential factor for the initiation of human chromosomal DNA replication.     

Effects of temperature-sensitive variants of the Bacillus subtilis dnaB gene on the replication of a low-copy-number plasmid.

The dnaB gene of Bacillus subtilis is involved in the initiation of DNA replication and also in the binding of the chromosomal origin to the bacterial membrane. We studied the effect of temperature-sensitive dnaB mutants (dnaB1 and dnaB19) on the replication and on the DNA-membrane binding of the plasmid pKW1, which was derived from the low-copy-number plasmid pBS2. In the dnaB19 mutant, pKW1 was not able to replicate at the restrictive temperature. In the dnaB1 mutant, however, the dimeric form of pKW1 DNA was preferentially produced as the restrictive temperature, but the replication of the monomeric form was totally blocked. We also examined the effects of the dnaB(Ts) gene on the DNA-membrane binding of both the double-stranded and single-stranded DNA from pKW1. The single-stranded DNA from pKW1 was prepared from the DNA of the phage M13 mp19, which contained the origin of replication of pKW1. In the dnaB1 mutant, pKW1 DNA in both the double-stranded and single-stranded form was released from the membrane at the restrictive temperature. On the other hand, in the dnaB19 mutant, only double-stranded DNA, and not single-stranded DNA, was released from the membrane at the restrictive temperature. These results suggest that the product of the dnaB gene has at least two domains which influence the replication of DNA and the binding of DNA to the cell membrane in separate ways.     

Regulation of replication at the R/G chromosomal band boundary and pericentromeric heterochromatin of mammalian cells

Mammalian chromosomes consist of multiple replicons; however, in contrast to yeast, the details of this replication process (origin firing, fork progression and termination) relative to specific chromosomal domains remain unclear. Using direct visualization of DNA fibers, here we show that the rate of replication fork movement typically decreases in the early-mid S phase when the replication fork proceeds through the R/G chromosomal band boundary and pericentromeric heterochromatin. To support this, fluorescence in situ hybridization (FISH)-based replication profiles at the human 1q31.1 (R-band)-32.1 (G-band) regions revealed that replication timing switched around at the putative R/G chromosomal band boundary predicted by marked changes in GC content at the sequence level. Thus, the slowdown of replication fork movement is thought to be the general property of the band boundaries separating the functionally different chromosomal domains. By simultaneous visualization of replication fork movement and pericentromeric heterochromatin sequences on DNA fibers, we observed that this region is duplicated by many replication forks, some of which proceed unidirectionally, that originate from clustered replication origins. We showed that histone hyperacetylation is tightly associated with changes in the replication timing of pericentromeric heterochromatin induced by 5-aza-2'-deoxycytidine treatment. These results suggest that, similar to the yeast system, histone modification is involved in controlling the timing of origin firing in mammals.