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.
SummaryIn 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.
SummaryDnaA initiates chromosomal replication in Escherichia coli at a well-regulated time in the cell cycle. To determine how the spatial distribution of DnaA is related to the location of chromosomal replication and other cell cycle events, the localization of DnaA in living cells was visualized by confocal fluorescence microscopy. The gfp gene was randomly inserted into a dnaA-bearing plasmid via in vitro transposition to create a library that included internally GFP-tagged DnaA proteins. The library was screened for the ability to rescue dnaA ts mutants, and a candidate gfp-dnaA was used to replace the dnaA gene of wild-type cells. The resulting cells produce close to physiological levels of GFP-DnaA from the endogenous promoter as their only source of DnaA and somewhat under-initiate replication with moderate asynchrony. Visualization of GFPtagged DnaA in living cells revealed that DnaA adopts a helical pattern that spirals along the long axis of the cell, a pattern also seen in wild-type cells by immunofluorescence with affinity purified antiDnaA antibody. Although the DnaA helices closely resemble the helices of the actin analogue MreB, co-visualization of GFP-tagged DnaA and RFPtagged MreB demonstrates that DnaA and MreB adopt discrete helical structures along the length of the longitudinal cell axis.
The Escherichia coli SeqA protein binds preferentially to hemimethylated DNA and is required for inactivation (sequestration) of newly formed origins. A mutant SeqA protein, SeqA4 (A25T), which is deficient in origin sequestration in vivo, was found here to have lost the ability to form multimers, but could bind as dimers with wild-type affinity to a pair of hemimethylated GATC sites. In vitro, binding of SeqA dimers to a plasmid first generates a topology change equivalent to a few positive supercoils, then the binding leads to a topology change in the "opposite" direction, resulting in a restraint of negative supercoils. Binding of SeqA4 mutant dimers produced the former effect, but not the latter, showing that a topology change equivalent to positive supercoiling is caused by the binding of single dimers, whereas restraint of negative supercoils requires multimerization via the N-terminus. In vivo, mutant SeqA4 protein was not capable of forming foci observed by immunofluorescence microscopy, showing that N-terminus-dependent multimerization is required for building SeqA foci. Overproduction of SeqA4 led to partially restored initiation synchrony, indicating that origin sequestration may not depend on efficient higher-order multimerization into foci, but do require a high local concentration of SeqA.
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