The initiator protein DnaA contributes to keeping new origins inactivated by promoting the presence of hemimethylated DNA

The Escherichia coli replication origin oriC and other regions with high numbers of GATC sites remain hemimethylated after replication much longer than regions with average numbers of GATC sites. The prolonged period of hemimethylation has been attributed to the presence of bound SeqA protein. Here, it was found that a GATC cluster inserted at the datA site, which binds large amounts of DnaA in vivo, did not become remethylated at all, unless the availability of the DnaA protein was severely reduced. Sequestration of oriC was also found to be affected by the availability of DnaA. The period of origin hemimethylation was reduced by approximately 30% upon a reduction in the availability of DnaA. The result shows that not only SeqA binding but also DnaA binding to newly replicated origins contributes to keeping them hemimethylated. It was also found that the number of SeqA foci increased in cells with a combination of DnaA-mediated protection and sequestration at the GATC::datA cluster.     

The Escherichia coli SeqA protein binds specifically and co-operatively to two sites in hemimethylated and fully methylated oriC

The Escherichia coli SeqA protein has been found to affect initiation of replication negatively, both in vivo and in vitro. The mechanism of inhibition is, however, not known. SeqA has been suggested to affect the formation and activity of the initiation complex at oriC, either by binding to DNA or by interacting with the DnaA protein. We have investigated the binding of SeqA to oriC by electron microscopy and found that SeqA binds specifically to two sites in oriC, one on each side of the DnaA binding site R1. Specific binding was found for fully and hemimethylated but not unmethylated oriC in good agreement with earlier mobility shift studies. The affinity of SeqA for hemi-methylated oriC was higher than for fully methylated oriC. The binding was in both cases strongly cooperative. We suggest that SeqA binds to two nucleation sites in oriC, and by the aid of protein-protein interaction spreads to adjacent regions in the same oriC as well as recruiting additional oriC molecules and/or complexes into larger aggregates.     

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.     

Escherichia coli prereplication complex assembly is regulated by dynamic interplay among Fis, IHF and DnaA

Initiator DnaA and DNA bending proteins, Fis and IHF, comprise prereplication complexes (pre-RC) that unwind the Escherichia coli chromosome's origin of replication, oriC. Loss of either Fis or IHF perturbs synchronous initiation from oriC copies in rapidly growing E. coli. Based on dimethylsulphate (DMS) footprinting of purified proteins, we observed a dynamic interplay among Fis, IHF and DnaA on supercoiled oriC templates. Low levels of Fis inhibited oriC unwinding by blocking both IHF and DnaA binding to low affinity sites. As the concentration of DnaA was increased, Fis repression was relieved and IHF rapidly redistributed DnaA to all unfilled binding sites on oriC. This behaviour in vitro is analogous to observed assembly of pre-RC in synchronized E. coli. We propose that as new DnaA is synthesized in E. coli, opposing activities of Fis and IHF ensure an abrupt transition from a repressed complex with unfilled weak affinity DnaA binding sites to a completely loaded unwound complex, increasing both the precision of DNA replication timing and initiation synchrony.     

Two oppositely oriented arrays of low-affinity recognition sites in oriC guide progressive binding of DnaA during Escherichia coli pre-RC assembly

The onset of chromosomal DNA replication requires highly precise and reproducible interactions between initiator proteins and replication origins to assemble a pre-replicative complex (pre-RC) that unwinds the DNA duplex. In bacteria, initiator protein DnaA, bound to specific high- and low-affinity recognition sites within the unique oriC locus, comprises the pre-RC, but how complex assembly is choreographed to ensure precise initiation timing during the cell cycle is not well understood. In this study, we present evidence that higher-order DnaA structures are formed at oriC when DnaA monomers are closely positioned on the same face of the DNA helix by interaction with two oppositely oriented essential arrays of closely spaced low-affinity DnaA binding sites. As DnaA levels increase, peripheral high-affinity anchor sites begin cooperative loading of the arrays, which is extended by sequential binding of additional DnaA monomers resulting in growth of the complexes towards the centre of oriC. We suggest that this polarized assembly of unique DnaA oligomers within oriC plays an important role in mediating pre-RC activity and may be a feature found in all bacterial replication origins.     

Mutational analysis reveals Escherichia coli oriC interacts with both DnaA-ATP and DnaA-ADP during pre-RC assembly

Prior to initiating DNA synthesis, Escherichia coli oriC switches from ORC, comprising initiator DnaA bound at three high-affinity sites, to pre-RC, when additional DnaA molecules interact with low-affinity sites. Two types of low-affinity sites exist: R boxes that bind DnaA-ATP and DnaA-ADP with equal affinity, and I-sites with a three- to fourfold preference for DnaA-ATP. To assess the regulatory role of weak DnaA interactions during pre-RC assembly in vivo, we compared the behaviour of plasmid-borne wild-type oriC with mutants having an increased or decreased number of DnaA-ATP discriminatory I-sites. Increasing the number of discriminatory sites by replacing R5M with I2 inactivated extrachromosomal oriC function. Mutants with no discriminatory sites perturbed host growth and rapidly replaced wild-type chromosomal oriC, but normal function returned if one I-site was restored at either the I2, I3 or R5M position. These observations are consistent with assembly of E. coli pre-RC in vivo from mixtures of DnaA-ATP and DnaA-ADP, with I-site interactions coupling pre-RC assembly to DnaA-ATP levels.     

Interaction of SeqA and Dam methylase on the hemimethylated origin of Escherichia coli chromosomal DNA replication

Preferential binding of SeqA protein to hemimethylated oriC, the origin of Escherichia coli chromosomal replication, delays methylation by Dam methylase. Because the SeqA-oriC interaction appears to be essential in timing of chromosomal replication initiation, the biochemical functions of SeqA protein and Dam methylase at the 13-mer L, M, and R region containing 4 GATC sequences at the left end of oriC were examined. We found that SeqA protein preferentially bound hemimethylated 13-mers but not fully nor unmethylated 13-mers. Regardless of strand methylation, the binding of SeqA protein to the hemimethylated GATC sequence of 13-mer L was followed by additional binding to other hemimethylated GATC sequences of 13-mer M and R. On the other hand, Dam methylase did not discriminate binding of 13-mers in different methylation patterns and was not specific to GATC sequences. The binding specificity and higher affinity of SeqA protein over Dam methylase to the hemimethylated 13-mers along with the reported cellular abundance of this protein explains the dominant action of SeqA protein over Dam methylase to the newly replicated oriC for the sequestration of chromosomal replication. Furthermore, SeqA protein bound to hemimethylated 13-mers was not dissociated by Dam methylase, and most SeqA protein spontaneously dissociated 10 min after binding. Also, SeqA protein delayed the in vitro methylation of hemimethylated 13-mers by Dam methylase. These in vitro results suggest that the intrinsic binding instability of SeqA protein results in release of sequestrated hemimethylated oriC.     

Suppressors of DnaA(ATP) imposed overinitiation in Escherichia coli

Chromosome replication in Escherichia coli is limited by the supply of DnaA associated with ATP. Cells deficient in RIDA (Regulatory Inactivation of DnaA) due to a deletion of the hda gene accumulate suppressor mutations (hsm) to counteract the overinitiation caused by an elevated DnaA(ATP) level. Eight spontaneous hda suppressor mutations were identified by whole-genome sequencing, and three of these were analysed further. Two mutations (hsm-2 and hsm-4) mapped in the dnaA gene and led to a reduced ability to initiate replication from oriC. One mutation (hsm-1) mapped to the seqA promoter and increased the SeqA protein level in the cell. hsm-1 cells had prolonged origin sequestration, reduced DnaA protein level and reduced DnaA-Reactivating Sequence (DARS)-mediated rejuvenation of DnaA(ADP) to DnaA(ATP) , all of which could contribute to the suppression of RIDA deficiency. Despite of these defects hsm-1 cells were quite similar to wild type with respect to cell cycle parameters. We speculate that since SeqA binding sites might overlap with DnaA binding sites spread throughout the chromosome, excess SeqA could interfere with DnaA titration and thereby increase free DnaA level. Thus, in spite of reduction in total DnaA, the amount of DnaA molecules available for initiation may not be reduced.     

Coordinated replication and sequestration of oriC and dnaA are required for maintaining controlled once-per-cell-cycle initiation in Escherichia coli

Escherichia coli cells were constructed in which the dnaA gene was moved to a location opposite oriC on the circular chromosome. In these cells the dnaA gene was replicated with significant delay relative to the origin. Consequently, the period where the newly replicated and hemimethylated oriC was sequestered no longer coincided with the period where the dnaA gene promoter was sequestered. DnaA protein synthesis was therefore expected to continue during origin sequestration. Despite a normal length of the sequestration period in such cells, they had increased origin content and also displayed asynchrony of initiation. This indicated that reinitiation occasionally occurred at some origins within the same cell cycle. The extra initiations took place in spite of a reduction in total DnaA protein concentration to about half of the wild-type level. We propose that this more efficient utilization of DnaA protein results from an increased availability at the end of the origin sequestration period. Therefore, coordinated sequestration of oriC and dnaA is required for maintaining controlled once-per-cell-cycle initiation.     

The E. coli cell surface specifically prevents the initiation of DNA replication at oriC on hemimethylated DNA templates

A particular outer membrane fraction previously defined as possessing specific affinity for the hemimethylated form of the origin of replication of the E. coli chromosome (oriC) is shown to inhibit the initiation of DNA synthesis at this site on hemimethylated DNA templates in vitro. The replication of fully methylated or unmethylated DNA templates is not affected. Also, no inhibition is observed if initiation takes place at random sites on the hemimethylated template. The key inactivation step appears to be membrane inhibition of DnaA initiator protein binding to oriC. Remethylation of the membrane-bound hemimethylated DNA results in reactivation. Our results demonstrate direct involvement of the membrane in the control of DNA replication. We propose that association/dissociation of the origin from the cell membrane is one of the control elements governing interinitiation times in E. coli.     

Escherichia coli SeqA protein affects DNA topology and inhibits open complex formation at oriC.

Chromosome replication in Escherichia coli is initiated by the DnaA protein. Binding of DnaA to the origin, oriC, followed by formation of an open complex are the first steps in the initiation process. Based on in vivo studies the SeqA protein has been suggested to function negatively in the initiation of replication, possibly by inhibiting open complex formation. In vitro studies have shown that SeqA inhibits oriC-dependent replication. Here we show by KMnO(4) probing that SeqA inhibits open complex formation. The inhibition was not caused by prevention of DnaA binding to the oriC plasmids, indicating that SeqA prevented strand separation in oriC either directly, by interacting with the AT-rich region, or indirectly, by changing the topology of the oriC plasmids. SeqA was found to restrain the negative supercoils of the oriC plasmid. In comparison with the effect of HU on plasmid topology, SeqA seemed to act more cooperatively. It is likely that the inhibition of open complex formation is caused by the effect of SeqA on the topology of the plasmids. SeqA also restrained the negative supercoils of unmethylated oriC plasmids, which do not bind SeqA specifically, suggesting that the effect on topology is not dependent on binding of SeqA to a specific sequence in oriC.     

SeqA protein aggregation is necessary for SeqA function.

The binding of SeqA protein to hemimethylated GATC sequences is important in the negative modulation of chromosomal initiation at oriC, and in the formation of SeqA foci necessary for Escherichia coli chromosome segregation. Using gel-filtration chromotography and glycerol gradient sedimentation, we demonstrate that SeqA exists as a homotetramer. SeqA tetramers are able to aggregate or multimerize in a reversible, concentration-dependent manner. Using a bacterial two-hybrid system, we demonstrate that the N-terminal region of SeqA, especifically the 9th amino acid residue, glutamic acid, is required for functional SeqA-SeqA interaction. Although the SeqA(E9K) mutant protein, containing lysine rather than glutamic acid at the 9th amino acid residue, exists as a tetramer, the mutant protein binds to hemimethylated DNA with altered binding patterns as compared with wild-type SeqA. Aggregates of SeqA(E9K) are defective in hemimethylated DNA binding. Here we demonstrate that proper interaction between SeqA tetramers is required for both hemimethylated DNA binding and formation of active aggregates. SeqA tetramers and aggregates might be involved in the formation of SeqA foci required for the segregation of chromosomal DNA as well as the regulation of chromosomal initiation.     

Replication cycle dependent association of SeqA to the outer membrane fraction of E. coli

The hemimethylated oriC binding activity of the E. coli heavy density membrane fraction (outer membrane) was investigated by DNase I footprinting experiments using membranes obtained from different replication stages of PC-2 (dnaCts) cells. The maximal binding activity was found at the beginning of replication cycle and then decreased gradually. The same pattern of variation was observed with SeqA protein detected in the membranes by immunoblotting. Both binding activity and the presence of SeqA were conserved in the outer membrane even after floating centrifugation of the heavy density membrane fraction in a sucrose gradient, indicating that SeqA in fact can associate with the membrane and that this association varies according to replication cycle. Site specific binding to hemimethylated oriC, of the heavy density membrane obtained from seqA mutant, could be restored by addition of a low amount of His-tagged SeqA protein.     

A protein that binds to the P1 origin core and the oriC 13mer region in a methylation-specific fashion is the product of the host seqA gene.

The P1 plasmid replication origin P1oriR is controlled by methylation of four GATC adenine methylation sites within heptamer repeats. A comparable (13mer) region is present in the host origin, oriC. The two origins show comparable responses to methylation; negative control by recognition of hemimethylated DNA (sequestration) and a positive requirement for methylation for efficient function. We have isolated a host protein that recognizes the P1 origin region only when it is isolated from a strain proficient for adenine methylation. The substantially purified 22 kDa protein also binds to the 13mer region of oriC in a methylation-specific fashion. It proved to be the product of the seqA gene that acts in the negative control of oriC by sequestration. We conclude that the role of the SeqA protein in sequestration is to recognize the methylation state of P1oriR and oriC by direct DNA binding. Using synthetic substrates we show that SeqA binds exclusively to the hemimethylated forms of these origins forms that are the immediate products of replication in a methylation-proficient strain. We also show that the protein can recognize sequences with multiple GATC sites, irrespective of the surrounding sequence. The basis for origin specificity is primarily the persistence of hemimethylated forms that are over-represented in the natural. DNA preparations relative to controls.     

The replicative origin of the E. coli chromosome binds to cell membranes only when hemimethylated

DNA from the E. coli replicative origin binds with high affinity to outer membrane preparations. Specific binding regions are contained within a 463 bp stretch of origin DNA between positions -46 and +417 on the oriC map. This region of DNA contains an unusually high number of GATC sites, the recognition sequence for the E. coli DNA adenine methylase. We show here that oriC DNA binds to membrane only when it is hemimethylated. The E. coli chromosomal origin is hemimethylated for 8-10 min after initiation of replication, and origin DNA binds to membranes only during this time period. Based on these results, we propose a speculative model for chromosome segregation in E. coli.     

IHF and HU stimulate assembly of pre-replication complexes at Escherichia coli oriC by two different mechanisms

Pre-replication complexes (pre-RC) assemble on replication origins and unwind DNA in the presence of chromatin proteins. As components of Escherichia coli pre-RC, two histone-like proteins HU and IHF (integration host factor), stimulate initiator DnaA-catalysed unwinding of the chromosomal replication origin, oriC. Using in vivo footprint analysis just before DNA synthesis initiates, we detect IHF binding coincident with a shift of DnaA to weaker central oriC sites. Integration host factor redistributed pre-bound DnaA to identical sites in vitro. HU did not redistribute DnaA, but suppressed binding specifically at I3. These results suggest that different pathways mediated by bacterial chromatin proteins exist to regulate pre-RC assembly and unwind oriC.     

Identification of functional domains of the Escherichia coli SeqA protein

The Escherichia coli SeqA protein, a negative regulator of chromosomal DNA replication, prevents the overinitiation of replication within one cell cycle by binding to hemimethylated G-mA-T-C sequences in the replication origin, oriC. In addition to the hemimethylated DNA-binding activity, the SeqA protein has a self-association activity, which is also considered to be essential for its regulatory function in replication initiation. To study the functional domains responsible for the DNA-binding and self-association activities, we performed a deletion analysis of the SeqA protein and found that the N-terminal (amino acid residues 1-59) and the C-terminal (amino acid residues 71-181) regions form structurally distinct domains. The N-terminal domain, which is not involved in DNA binding, has the self-association activity. In contrast, the C-terminal domain, which lacks the self-association activity, specifically binds to the hemimethylated G-mA-T-C sequence. Therefore, two essential SeqA activities, self-association and DNA-binding, are independently performed by the structurally distinct N-terminal and C-terminal domains, respectively.     

Crystal structure of a SeqA-N filament: implications for DNA replication and chromosome organization

Escherichia coli SeqA binds clusters of transiently hemimethylated GATC sequences and sequesters the origin of replication, oriC, from methylation and premature reinitiation. Besides oriC, SeqA binds and organizes newly synthesized DNA at replication forks. Binding to multiple GATC sites is crucial for the formation of stable SeqA-DNA complexes. Here we report the crystal structure of the oligomerization domain of SeqA (SeqA-N). The structural unit of SeqA-N is a dimer, which oligomerizes to form a filament. Mutations that disrupt filament formation lead to asynchronous DNA replication, but the resulting SeqA dimer can still bind two GATC sites separated from 5 to 34 base pairs. Truncation of the linker between the oligomerization and DNA-binding domains restricts SeqA to bind two GATC sites separated by one or two full turns. We propose a model of a SeqA filament interacting with multiple GATC sites that accounts for both origin sequestration and chromosome organization.     

DnaA boxes are important elements in setting the initiation mass of Escherichia coli

The binding of DnaA protein to its DNA binding sites-DnaA boxes-in the chromosomal oriC region is essential for initiation of chromosome replication. In this report, we show that additional DnaA boxes affect chromosome initiation control, i.e., increase the initiation mass. The cellular DnaA box concentration was increased by introducing pBR322-derived plasmids carrying DnaA boxes from the oriC region into Escherichia coli and by growing the strains at different generation times to obtain different plasmid copy numbers. In fast-growing cells, where the DnaA box plasmid copy number per oriC locus was low, the presence of extra DnaA boxes caused only a moderate increase in the initiation mass. In slowly growing cells, where the DnaA box plasmid copy number per oriC locus was higher, we observed more pronounced increases in the initiation mass. Our data clearly show that the presence of extra DnaA boxes increases the initiation mass, supporting the idea that the initiation mass is determined by the normal complement of DnaA protein binding sites in E. coli cells.     

Insights into negative modulation of E. coli replication initiation from the structure of SeqA-hemimethylated DNA complex

The SeqA protein binds clusters of fully methylated or hemimethylated GATC sequences at oriC and negatively modulates the initiation of DNA replication. We find that SeqA can be proteolytically cleaved into an N-terminal multimerization and a C-terminal DNA-binding domain and have determined the crystal structure of the C-terminal domain in complex with a hemimethylated GATC site. SeqA makes direct hydrogen bonds and van der Waals contacts with the hemimethylated A-T base pair in addition to interactions with the surrounding bases and DNA backbone. The tetrameric protein-DNA complex found in the crystal suggests that SeqA binds multiple GATC sites on separate DNA duplexes, altering the overall DNA topology and sequestering oriC from replication initiation.