Escherichia coli SeqA Structures Relocalize Abruptly upon Termination of Origin Sequestration during Multifork DNA Replication

The Escherichia coli SeqA protein forms complexes with new, hemimethylated DNA behind replication forks and is important for successful replication during rapid growth. Here, E. coli cells with two simultaneously replicating chromosomes (multifork DNA replication) and YFP tagged SeqA protein was studied. Fluorescence microscopy showed that in the beginning of the cell cycle cells contained a single focus at midcell. The focus was found to remain relatively immobile at midcell for a period of time equivalent to the duration of origin sequestration. Then, two abrupt relocalization events occurred within 2–6 minutes and resulted in SeqA foci localized at each of the cell’s quarter positions. Imaging of cells containing an additional fluorescent tag in the origin region showed that SeqA colocalizes with the origin region during sequestration. This indicates that the newly replicated DNA of first one chromosome, and then the other, is moved from midcell to the quarter positions. At the same time, origins are released from sequestration. Our results illustrate that newly replicated sister DNA is segregated pairwise to the new locations. This mode of segregation is in principle different from that of slowly growing bacteria where the newly replicated sister DNA is partitioned to separate cell halves and the decatenation of sisters a prerequisite for, and possibly a mechanistic part of, segregation.     

Organization of sister origins and replisomes during multifork DNA replication in Escherichia coli

The replication period of Escherichia coli cells grown in rich medium lasts longer than one generation. Initiation thus occurs in the 'mother-' or 'grandmother generation'. Sister origins in such cells were found to be colocalized for an entire generation or more, whereas sister origins in slow-growing cells were colocalized for about 0.1-0.2 generations. The role of origin inactivation (sequestration) by the SeqA protein in origin colocalization was studied by comparing sequestration-deficient mutants with wild-type cells. Cells with mutant, non-sequesterable origins showed wild-type colocalization of sister origins. In contrast, cells unable to sequester new origins due to loss of SeqA, showed aberrant localization of origins indicating a lack of organization of new origins. In these cells, aberrant replisome organization was also found. These results suggest that correct organization of sister origins and sister replisomes is dependent on the binding of SeqA protein to newly formed DNA at the replication forks, but independent of origin sequestration. In agreement, in vitro experiments indicate that SeqA is capable of pairing newly replicated DNA molecules.     

Regulation of Sister Chromosome Cohesion by the Replication Fork Tracking Protein SeqA

Analogously to chromosome cohesion in eukaryotes, newly replicated DNA in E. coli is held together by inter-sister linkages before partitioning into daughter nucleoids. In both cases, initial joining is apparently mediated by DNA catenation, in which replication-induced positive supercoils diffuse behind the fork, causing newly replicated duplexes to twist around each other. Type-II topoisomerase-catalyzed sister separation is delayed by the well-characterized cohesin complex in eukaryotes, but cohesion control in E. coli is not currently understood. We report that the abundant fork tracking protein SeqA is a strong positive regulator of cohesion, and is responsible for markedly prolonged cohesion observed at “snap” loci. Epistasis analysis suggests that SeqA stabilizes cohesion by antagonizing Topo IV-mediated sister resolution, and possibly also by a direct bridging mechanism. We show that variable cohesion observed along the E. coli chromosome is caused by differential SeqA binding, with oriC and snap loci binding disproportionally more SeqA. We propose that SeqA binding results in loose inter-duplex junctions that are resistant to Topo IV cleavage. Lastly, reducing cohesion by genetic manipulation of Topo IV or SeqA resulted in dramatically slowed sister locus separation and poor nucleoid partitioning, indicating that cohesion has a prominent role in chromosome segregation.     

Structural insights into the cooperative binding of SeqA to a tandem GATC repeat

SeqA is a negative regulator of DNA replication in Escherichia coli and related bacteria that functions by sequestering the origin of replication and facilitating its resetting after every initiation event. Inactivation of the seqA gene leads to unsynchronized rounds of replication, abnormal localization of nucleoids and increased negative superhelicity. Excess SeqA also disrupts replication synchrony and affects cell division. SeqA exerts its functions by binding clusters of transiently hemimethylated GATC sequences generated during replication. However, the molecular mechanisms that trigger formation and disassembly of such complex are unclear. We present here the crystal structure of a dimeric mutant of SeqA [SeqAΔ(41–59)-A25R] bound to tandem hemimethylated GATC sites. The structure delineates how SeqA forms a high-affinity complex with DNA and it suggests why SeqA only recognizes GATC sites at certain spacings. The SeqA–DNA complex also unveils additional protein–protein interaction surfaces that mediate the formation of higher ordered complexes upon binding to newly replicated DNA. Based on this data, we propose a model describing how SeqA interacts with newly replicated DNA within the origin of replication and at the replication forks.     

The Escherichia coli SeqA protein

The Escherichia coli SeqA protein contributes to regulation of chromosome replication by preventing re-initiation at newly replicated origins. SeqA protein binds to new DNA which is hemimethylated at the adenine of GATC sequences. Most of the cellular SeqA is found complexed with the new DNA at the replication forks. In vitro the SeqA protein binds as a dimer to two GATC sites and is capable of forming a helical fiber of dimers through interactions of the N-terminal domain. SeqA can also bind, with less affinity, to fully methylated origins and affect timing of “primary” initiations. In addition to its roles in replication, the SeqA protein may also act in chromosome organization and gene regulation.     

Replication fork inhibition in seqA mutants of Escherichia coli triggers replication fork breakage

SeqA protein negatively regulates replication initiation in Escherichia coli and is also proposed to organize maturation and segregation of the newly replicated DNA. The seqA mutants suffer from chromosomal fragmentation; since this fragmentation is attributed to defective segregation or nucleoid compaction, two‐ended breaks are expected. Instead, we show that, in SeqA's absence, chromosomes mostly suffer one‐ended DNA breaks, indicating disintegration of replication forks. We further show that replication forks are unexpectedly slow in seqA mutants. Quantitative kinetics of origin and terminus replication from aligned chromosomes not only confirm origin overinitiation in seqA mutants, but also reveal terminus under‐replication, indicating inhibition of replication forks. Pre‐/post‐labelling studies of the chromosomal fragmentation in seqA mutants suggest events involving single forks, rather than pairs of forks from consecutive rounds rear‐ending into each other. We suggest that, in the absence of SeqA, the sister‐chromatid cohesion ‘safety spacer’ is destabilized and completely disappears if the replication fork is inhibited, leading to the segregation fork running into the inhibited replication fork and snapping the latter at single‐stranded DNA regions.     

A case for sliding SeqA tracts at anchored replication forks during Escherichia coli chromosome replication and segregation

SeqA is an Escherichia coli DNA-binding protein that acts at replication origins and controls DNA replication. However, binding is not exclusive to origins. Many fragments containing two or more hemi-methylated GATC sequences bind efficiently. Binding was optimal when two such sequences were closely apposed or up to 31 bases apart on the same face of the DNA helix. Binding studies suggest that neighboring bound proteins contact each other to form a complex with the intervening DNA looped out. There are many potential binding sites distributed around the E.coli chromosome. As replication produces a transient wave of hemi-methylation, tracts of SeqA binding are likely to associate with each fork as replication progresses. The number and positions of green fluorescent protein-SeqA foci seen in living cells suggest that they correspond to these tracts, and that the forks are tethered to planes of cell division. SeqA may help to tether the forks or to organize newly replicated DNA into a structure that aids DNA to segregate away from the replication machinery.     

DNA replication-dependent formation of joint DNA molecules in Physarum polycephalum

Two-dimensional neutral/neutral agarose gel electrophoresis is used extensively to localize replication origins. This method resolves DNA structures containing replication forks. It also detects X-shaped recombination intermediates in meiotic cells, in the form of a typical vertical spike. Intriguingly, such a spike of joint DNA molecules is often detectable in replicating DNA from mitotic cells. Here, we used naturally synchronous DNA samples from Physarum polycephalum to demonstrate that postreplicative, DNA replication-dependent X-shaped DNA molecules are formed between sister chromatids. These molecules have physical properties reminiscent of Holliday junctions. Our results demonstrate frequent interactions between sister chromatids during a normal cell cycle and suggest a novel phase during DNA replication consisting of transient, joint DNA molecules formed on newly replicated DNA.     

Excess SeqA prolongs sequestration of oriC and delays nucleoid segregation and cell division

Following initiation of chromosomal replication in Escherichia coli, newly initiated origins (oriCs) are prevented from further initiations by a mechanism termed sequestration. During the sequestration period (which lasts about one-third of a cell cycle), the origins remain hemimethylated. The SeqA protein binds hemimethylated oriC in vitro. In vivo, the absence of SeqA causes overinitiation and strongly reduces the duration of hemimethylation. The pattern of immunostained SeqA complexes in vivo suggests that SeqA has a role in organizing hemimethylated DNA at the replication forks. We have examined the effects of overexpressing SeqA under different cellular conditions. Our data demonstrate that excess SeqA significantly increases the time oriC is hemimethylated following initiation of replication. In some cells, sequestration continued for more than one generation and resulted in inhibition of primary initiation. SeqA overproduction also interfered with the segregation of sister nucleoids and caused a delay in cell division. These results suggest that SeqA's function in regulation of replication initiation is linked to chromosome segregation and possibly cell division.     

A Reduction in Ribonucleotide Reductase Activity Slows Down the Chromosome Replication Fork but Does Not Change Its Localization

Background

It has been proposed that the enzymes of nucleotide biosynthesis may be compartmentalized or concentrated in a structure affecting the organization of newly replicated DNA. Here we have investigated the effect of changes in ribonucleotide reductase (RNR) activity on chromosome replication and organization of replication forks in Escherichia coli.

Methodology/Principal Findings

Reduced concentrations of deoxyribonucleotides (dNTPs) obtained by reducing the activity of wild type RNR by treatment with hydroxyurea or by mutation, resulted in a lengthening of the replication period. The replication fork speed was found to be gradually reduced proportionately to moderate reductions in nucleotide availability. Cells with highly extended C periods showed a “delay” in cell division i.e. had a higher cell mass. Visualization of SeqA structures by immunofluorescence indicated no change in organization of the new DNA upon moderate limitation of RNR activity. Severe nucleotide limitation led to replication fork stalling and reversal. Well defined SeqA structures were not found in situations of extensive replication fork repair. In cells with stalled forks obtained by UV irradiation, considerable DNA compaction was observed, possibly indicating a reorganization of the DNA into a “repair structure” during the initial phase of the SOS response.

Conclusion/Significance

The results indicate that the replication fork is slowed down in a controlled manner during moderate nucleotide depletion and that a change in the activity of RNR does not lead to a change in the organization of newly replicated DNA. Control of cell division but not control of initiation was affected by the changes in replication elongation.     

Replication fork movement and methylation govern SeqA binding to the Escherichia coli chromosome

In Escherichia coli, the SeqA protein binds specifically to GATC sequences which are methylated on the A of the old strand but not on the new strand. Such hemimethylated DNA is produced by progression of the replication forks and lasts until Dam methyltransferase methylates the new strand. It is therefore believed that a region of hemimethylated DNA covered by SeqA follows the replication fork. We show that this is, indeed, the case by using global ChIP on Chip analysis of SeqA in cells synchronized regarding DNA replication. To assess hemimethylation, we developed the first genome-wide method for methylation analysis in bacteria. Since loss of the SeqA protein affects growth rate only during rapid growth when cells contain multiple replication forks, a comparison of rapid and slow growth was performed. In cells with six replication forks per chromosome, the two old forks were found to bind surprisingly little SeqA protein. Cell cycle analysis showed that loss of SeqA from the old forks did not occur at initiation of the new forks, but instead occurs at a time point coinciding with the end of SeqA-dependent origin sequestration. The finding suggests simultaneous origin de-sequestration and loss of SeqA from old replication forks.     

Are the SSB-Interacting Proteins RecO,RecG, PriA and the DnaB-Interacting Protein Rep Bound to Progressing Replication Forks in Escherichia coli?

In all organisms several enzymes that are needed upon replication impediment are targeted to replication forks by interaction with a replication protein. In most cases these proteins interact with the polymerase clamp or with single-stranded DNA binding proteins (SSB). In Escherichia coli an accessory replicative helicase was also shown to interact with the DnaB replicative helicase. Here we have used cytological observation of Venus fluorescent fusion proteins expressed from their endogenous loci in live E. coli cells to determine whether DNA repair and replication restart proteins that interact with a replication protein travel with replication forks. A custom-made microscope that detects active replisome molecules provided that they are present in at least three copies was used. Neither the recombination proteins RecO and RecG, nor the replication accessory helicase Rep are detected specifically in replicating cells in our assay, indicating that either they are not present at progressing replication forks or they are present in less than three copies. The Venus-PriA fusion protein formed foci even in the absence of replication forks, which prevented us from reaching a conclusion.     

Replication fork and SeqA focus distributions in Escherichia coli suggest a replication hyperstructure dependent on nucleotide metabolism

Replication from the origin of Escherichia coli has traditionally been visualized as two replisomes moving away from each other, each containing a leading and a lagging strand polymerase. Fluorescence microscopy studies of tagged polymerases or forks have, however, indicated that the polymerases may be confined to a single location (or a few locations in cells with overlapping replication cycles). Here, we have analysed the exact replication patterns of cells growing with four different growth and replication rates, and compared these with the distributions of SeqA foci. The SeqA foci represent replication forks because the SeqA protein binds to the newly formed hemimethylated DNA immediately following the forks. The results show that pairs of forks originating from the same origin stay coupled for most of the cell cycle and thus support the replication factory model. They also suggest that the factories consisting of four polymerases are, at the time immediately after initiation, organized into higher order structures consisting of eight or 12 polymerases. The organization into replication factories was lost when replication forks experienced a limitation in the supply of nucleotides or when the thymidylate synthetase gene was mutated. These results support the idea that the nucleotide synthesis apparatus co-localizes with the replisomes forming a 'hyperstructure' and further suggest that the integrity of the replication factories and hyperstructures is dependent on nucleotide metabolism.     

Binding of SeqA protein to hemi-methylated GATC sequences enhances their interaction and aggregation properties

The SeqA protein regulates chromosome initiation and is involved in segregation in Escherichia coli. One SeqA protein binds to two hemi-methylated GATC sequences to form a stable SeqA-DNA complex. We found that binding induced DNA bending, which was pronounced when the two sequences were on the same face of the DNA. Two SeqA molecules bound cooperatively to each pair of hemi-methylated sites when the spacing between the sites was < or = 30 bp. This cooperative binding was able to stabilize the binding of a wild type to a single hemi-methylated site, or mutant form of SeqA protein to hemi-methylated sites, although such binding did not occur without cooperative interaction. Two cooperatively bound SeqA molecules interacted with another SeqA bound up to 185 bp away from the two bound SeqA proteins, and this was followed by aggregation of free SeqA proteins onto the bound proteins. These results suggest that the stepwise interaction of SeqA proteins with hemi-methylated GATC sites enhances their interaction and leads to the formation of SeqA aggregates. Cooperative interaction followed by aggregation may be the driving force for formation of the SeqA foci that appear to be located behind replication forks.     

Intracellular Locations of Replication Proteins and the Origin of Replication during Chromosome Duplication in the Slowly Growing Human Pathogen Helicobacter pylori

We followed the position of the replication complex in the pathogenic bacterium Helicobacter pylori using antibodies raised against the single-stranded DNA binding protein (HpSSB) and the replicative helicase (HpDnaB). The position of the replication origin, oriC, was also localized in growing cells by fluorescence in situ hybridization (FISH) with fluorescence-labeled DNA sequences adjacent to the origin. The replisome assembled at oriC near one of the cell poles, and the two forks moved together toward the cell center as replication progressed in the growing cell. Termination and resolution of the forks occurred near midcell, on one side of the septal membrane. The duplicated copies of oriC did not separate until late in elongation, when the daughter chromosomes segregated into bilobed nucleoids, suggesting sister chromatid cohesion at or near the oriC region. Components of the replication machinery, viz., HpDnaB and HpDnaG (DNA primase), were found associated with the cell membrane. A model for the assembly and location of the H. pylori replication machinery during chromosomal duplication is presented.     

A matter of choice: the establishment of sister chromatid cohesion

Sister chromatid cohesion is the basis for the recognition of chromosomal DNA replication products for their bipolar segregation in mitosis. Fundamental to sister chromatid cohesion is the ring‐shaped cohesin complex, which is loaded onto chromosomes long before the initiation of DNA replication and is thought to hold replicated sister chromatids together by topological embrace. What happens to cohesin when the replication fork approaches, and how cohesin recognizes newly synthesized sister chromatids, is poorly understood. The characterization of a number of cohesion establishment factors has begun to provide hints as to the reactions involved. Cohesin is a member of the evolutionarily conserved family of Smc subunit‐based protein complexes that contribute to many aspects of chromosome biology by mediating long‐range DNA interactions. I propose that the establishment of cohesion equates to the selective stabilization of those cohesin‐mediated DNA interactions that link sister chromatids in the wake of replication forks.     

Lack of SeqA focus formation,specific DNA binding and proper protein multimerization in the Escherichia coli sequestration mutant seqA2

In Escherichia coli wild-type cells newly formed origins cannot be reinitiated. The prevention of reinitiation is termed sequestration and is dependent on the hemimethylated state of newly replicated DNA. Several mutants discovered in a screen for the inability to sequester hemimethylated origins have been mapped to the seqA gene. Here, one of these mutants, seqA2, harbouring a single amino acid change in the C-terminal end of the SeqA protein, was found to also be unable to form foci in vivo. The SeqA foci seen in the wild-type cells are believed to arise from multimerization of SeqA on hemimethylated DNA at the replication fork, presumably representing organization of newly formed DNA by SeqA. The result suggests that the process of origin sequestration is closely tied to the process of focus maintenance at the replication fork. In vitro, purified SeqA2 protein was found incapable of forming highly ordered multimers that bind hemimethylated oriC. The mutant protein was also incapable of restraining negative supercoils. Both in vivo and in vitro results support the idea that origin sequestration is an integral part of organization of newly formed DNA performed by SeqA.     

Iterative Optimization of DNA Duplexes for Crystallization of SeqA-DNA Complexes

Escherichia coli SeqA is a negative regulator of DNA replication that prevents premature reinitiation events by sequestering hemimethylated GATC clusters within the origin of replication¹. Beyond the origin, SeqA is found at the replication forks, where it organizes newly replicated DNA into higher ordered structures². SeqA associates only weakly with single GATC sequences, but it forms high affinity complexes with DNA duplexes containing multiple GATC sites. The minimal functional and structural unit of SeqA is a dimer, thereby explaining the requirement of at least two GATC sequences to form a high-affinity complex with hemimethylated DNA³. Additionally, the SeqA architecture, with the oligomerization and DNA-binding domains separated by a flexible linker, allows binding to GATC repeats separated by up to three helical turns. Therefore, understanding the function of SeqA at a molecular level requires the structural analysis of SeqA bound to multiple GATC sequences. In protein-DNA crystallization, DNA can have none to an exceptional effect on the packing interactions depending on the relative sizes and architecture of the protein and the DNA. If the protein is larger than the DNA or footprints most of the DNA, the crystal packing is primarily mediated by protein-protein interactions. Conversely, when the protein is the same size or smaller than the DNA or it only covers a fraction of the DNA, DNA-DNA and DNA-protein interactions dominate crystal packing. Therefore, crystallization of protein-DNA complexes requires the systematic screening of DNA length⁴ and DNA ends (blunt or overhang)^5-7. In this report, we describe how to design, optimize, purify and crystallize hemimethylated DNA duplexes containing tandem GATC repeats in complex with a dimeric variant of SeqA (SeqAΔ(41-59)-A25R) to obtain crystals suitable for structure determination.     

Subcellular localization of the Bacillus subtilis structural maintenance of chromosomes (SMC) protein

The Bacillus subtilis structural maintenance of chromosomes (SMC) protein is a member of a large family of proteins involved in chromosome organization. We found that SMC is a moderately abundant protein ( approximately 1000 dimers per cell). In vivo cross-linking and immunoprecipitation assays revealed that SMC binds to many regions on the chromosome. Visualization of SMC in live cells using a fusion to the green fluorescent protein (GFP) and in fixed cells using immunofluorescence microscopy indicated that a portion of SMC localizes as discrete foci in positions similar to that of the DNA replication machinery (replisome). When visualized simultaneously, SMC and the replisome were often in similar regions of the cell but did not always co-localize. Persistence of SMC foci did not depend on ongoing replication, but did depend on ScpA and ScpB, two proteins thought to interact with SMC. Our results indicate that SMC is bound to many sites on the chromosome and a concentration of SMC is localized near replication forks, perhaps there to bind and organize newly replicated DNA.     

The Escherichia coli SeqA protein binds specifically to two sites in fully and hemimethylated oriC and has the capacity to inhibit DNA replication and affect chromosome topology

The SeqA protein was identified as a factor that prevents reinitiation of newly replicated, hemimethylated origins. SeqA also seems to inhibit initiation of fully methylated origins, thus contributing to the regulation of chromosomal replication. The SeqA protein was found to bind to two sites in the left part of the origin, near the AT-rich region where strand separation takes place during initiation of replication. The same binding sites seemed to be preferred irrespective of whether the origin was in the newly replicated (hemimethylated) state or not. In addition to binding specifically to groups of GATC sites, the SeqA protein was capable of interacting non-specifically with negatively supercoiled DNA, restraining the supercoils in a fashion similar to that seen with histone-like protein HU. The restraint of supercoils by SeqA was, in contrast to that of HU, cooperative.