Loss of RecA function affects the ability of Escherichia coli to maintain recombinant plasmids containing a Ter site.

In the Escherichia coli chromosome, DNA replication forks arrested by a Tus-Ter complex or by DNA damage are reinitiated through pathways that involve RecA and numerous other recombination functions. To examine the role of recombination in the processing of replication forks arrested by a Tus-Ter complex, the requirements for recombination-associated gene products were assessed in cells carrying Ter plasmids, i.e., plasmids that contain a Ter site oriented to block DNA replication. Of the E. coli recombination functions tested, only loss of recA conferred an observable phenotype on cells containing a Ter plasmid, which was inefficient transformation and reduced ability to maintain a Ter plasmid when Tus was expressed. Given the current understanding of replication reinitiation, the simplest explanation for the restriction of Ter plasmid maintenance was a reduced ability to restart plasmid replication in a recA tus(+) background. However, we were unable to detect a difference in the efficiency of replication arrest by Tus in recA-proficient and recA-deficient cells, which suggests that the inability to restart arrested replication forks is not the cause of the restriction on growth, but is due to an additional function provided by RecA. Other explanations for restriction of Ter plasmid maintenance were examined, including plasmid multimerization, plasmid rearrangements, and copy number differences. The most likely cause of the restriction on Ter plasmid maintenance was a reduced copy number in recA cells that was detected when the copy number was measured in relation to an external control. Possibly, loss of RecA function leads to improper processing of replication forks arrested at a Ter site, leading to the generation of degradation-prone substrates.     

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.     

Differential Tus-Ter binding and lock formation: implications for DNA replication termination in Escherichia coli

In E. coli, DNA replication termination occurs at Ter sites and is mediated by Tus. Two clusters of five Ter sites are located on each side of the terminus region and constrain replication forks in a polar manner. The polarity is due to the formation of the Tus-Ter-lock intermediate. Recently, it has been shown that DnaB helicase which unwinds DNA at the replication fork is preferentially stopped at the non-permissive face of a Tus-Ter complex without formation of the Tus-Ter-lock and that fork pausing efficiency is sequence dependent, raising two essential questions: Does the affinity of Tus for the different Ter sites correlate with fork pausing efficiency? Is formation of the Tus-Ter-lock the key factor in fork pausing? The combined use of surface plasmon resonance and GFP-Basta showed that Tus binds strongly to TerA-E and G, moderately to TerH-J and weakly to TerF. Out of these ten Ter sites only two, TerF and H, were not able to form significant Tus-Ter-locks. Finally, Tus's resistance to dissociation from Ter sites and the strength of the Tus-Ter-locks correlate with the differences in fork pausing efficiency observed for the different Ter sites by Duggin and Bell (2009).     

Site-directed mutagenesis and phylogenetic comparisons of the Escherichia coli Tus protein: DNA-protein interactions alone can not account for Tus activity

The Tus protein of Escherichia coli is capable of arresting DNA replication in an orientation-dependent manner when bound to specific sequences in the bacterial chromosome called Ter sites. Arrest of DNA replication has been postulated to occur either by a barrier mechanism, where Tus acts as a physical block to replication fork progression, or through protein-protein interactions between Tus and some component of the replication fork. A previous mutational analysis of Tus suggested that the amino acids in the L1 loop might play a role in replication arrest. Site-directed mutagenesis of amino acids in the L1 loop and other amino acid residues on the "non-permissive" face of Tus was performed to identify residues that affected Tus function. One mutant, E47Q, gave results that are inconsistent with the barrier model, showing a greater affinity for the Ter site (with a t 1/2 of 348 min versus 150 min for wild-type Tus) but a reduced ability to arrest DNA replication in vivo. In addition to the site-directed mutagenesis studies, the tus genes of Salmonella, Klebsiella, and Yersinia were sequenced and the proteins expressed in E. coli to assess their ability to arrest DNA replication. The results presented here support a role for protein-protein interactions in Tus function, and suggest that residues E47 and E49 participate in replication fork arrest.     

Use of electrospray ionization mass spectrometry to study binding interactions between a replication terminator protein and DNA

Tus protein binds tightly to specific DNA sequences (Ter) on the Escherichia coli chromosome halting replication. We report here conditions for detecting the 1 : 1 Tus-Ter complex by electrospray ionization mass spectrometry (ESI-MS). ESI mass spectra of a mixture of Tus and nonspecific DNA showed ions predominantly from uncomplexed Tus protein, indicating that the Tus-Ter complex observed in the gas phase was the result of a specific interaction rather than nonspecific associations in the ionization source. The Tus-Ter complex was very stable using a spray solvent of 10 mM ammonium acetate at pH 8.0, and initial attempts to distinguish binding affinities of Tus and mutant Tus proteins for Ter DNA were unsuccessful. Increasing the ammonium acetate concentration in the electrospray solvent (800 mM at pH 8.0) increased the dissociation constants sufficiently such that relative orders of binding affinity for Tus and various mutant Tus proteins for various DNA sequences could be determined. These were in agreement with the dissociation constants determined in solution studies. A dissociation constant of 700 x 10(-9) M for the binding of the mutant Tus protein A173T (where residue 173 is changed from alanine to threonine) to Ter DNA was estimated, compared with a value of 相似文献   

Inactivation of the replication-termination system affects the replication mode and causes unstable maintenance of plasmid R1

Two so-called Ter sites, which bind the Escherichia coli Tus protein, are located near the replication origin of plasmid R1. Inactivation of the tus gene caused a large decrease in the stability of maintenance of the R1 mini-derivative pOU47 despite the presence of a functional partition system on the plasmid. Deletion of the right Ter site caused a drop in stability similar to that observed after inactivation of the tus gene. Substitution of 2 bp required for Tus binding also caused unstable plasmid maintenance, whereas no effects on stability were observed when the left Ter site was deleted. Inactivation of the tus gene was coupled to an increased occurrence of multimeric plasmid forms as shown by gel electrophoresis of pOU47 DNA. Inactivation of the recA gene did not increase plasmid stability, suggesting that the multimerization was not mediated by RecA. Plasmid DNA was isolated from the tus strain carrying plasmid pOU47 and from a wild-type strain carrying pOU47 in which the right Ter site had been inactivated; in both cases, electron microscopy revealed the presence of multimers as well as rolling-circle structures with double-stranded tails. Thus, the right Ter site in plasmid R1 appears to stabilize the plasmid by preventing multimerization and shifts from theta to rolling-circle replication.     

Replication termination in Escherichia coli: structure and antihelicase activity of the Tus-Ter complex.

The arrest of DNA replication in Escherichia coli is triggered by the encounter of a replisome with a Tus protein-Ter DNA complex. A replication fork can pass through a Tus-Ter complex when traveling in one direction but not the other, and the chromosomal Ter sites are oriented so replication forks can enter, but not exit, the terminus region. The Tus-Ter complex acts by blocking the action of the replicative DnaB helicase, but details of the mechanism are uncertain. One proposed mechanism involves a specific interaction between Tus-Ter and the helicase that prevents further DNA unwinding, while another is that the Tus-Ter complex itself is sufficient to block the helicase in a polar manner, without the need for specific protein-protein interactions. This review integrates three decades of experimental information on the action of the Tus-Ter complex with information available from the Tus-TerA crystal structure. We conclude that while it is possible to explain polar fork arrest by a mechanism involving only the Tus-Ter interaction, there are also strong indications of a role for specific Tus-DnaB interactions. The evidence suggests, therefore, that the termination system is more subtle and complex than may have been assumed. We describe some further experiments and insights that may assist in unraveling the details of this fascinating process.     

Involvement of integration host factor (IHF) in maintenance of plasmid pSC101 in Escherichia coli: mutations in the topA gene allow pSC101 replication in the absence of IHF.

Integration host factor (IHF), encoded by the himA and himD genes, is a histonelike DNA-binding protein that participates in many cellular functions in Escherichia coli, including the maintenance of plasmid pSC101. We have isolated and characterized a chromosomal mutation that compensates for the absence of IHF and allows the maintenance of wild-type pSC101 in him mutants, but does not restore IHF production. The mutation is recessive and was found to affect the gene topA, which encodes topoisomerase I, a protein that relaxes negatively supercoiled DNA and acts in concert with DNA gyrase to regulate levels of DNA supercoiling. A previously characterized topA mutation, topA10, could also compensate for the absence of IHF to allow pSC101 replication. IHF-compensating mutations affecting topA resulted in a large reduction in topoisomerase I activity, and plasmid DNA isolated from such strains was more negatively supercoiled than DNA from wild-type strains. In addition, our experiments show that both pSC101 and pBR322 plasmid DNAs isolated from him mutants were of lower superhelical density than DNA isolated from Him+ strains. A concurrent gyrB gene mutation, which reduces supercoiling, reversed the ability of topA mutations to compensate for a lack of him gene function. Together, these findings indicate that the topological state of the pSC101 plasmid profoundly influences its ability to be maintained in populations of dividing cells and suggest a model to account for the functional interactions of the him, rep, topA, and gyr gene products in pSC101 maintenance.     

The genetic control of DNA supercoiling in Salmonella typhimurium

We have elucidated the genetic control of DNA supercoiling in Salmonella typhimurium. The level of superhelix density is controlled by two classes of genes. The only member of the first class is topA, the structural gene for topoisomerase I. The second class, tos, (topoisomerase one suppressor) consists of at least two genes, one of which is linked to gyrA, the structural gene for the topoisomerase subunit of DNA gyrase. Deletions of topA result in oversupercoiling of plasmid DNA. These mutations do not require the acquisition of second-site compensatory mutations to allow cell growth, in contrast to the situation in Escherichia coli. However, tos mutations, unlinked to topA, have been isolated which reduce plasmid superhelix density. We conclude that the level of DNA supercoiling in S. typhimurium is a dynamic balance between the effects of the gene products of topA (relaxation) and tos (supercoiling) which act independently of each other. Using a variety of combinations of these mutations we have constructed a series of isogenic strains, each of which has a different but precisely defined level of plasmid supercoiling; the series as a whole provides a wide range of supercoiling both above and below the wild-type level.     

Replication termination: mechanism of polar arrest revealed

The Tus-Ter protein-DNA complex of Escherichia coli blocks progression of DNA replication from only one direction at the replication terminus. As the replication fork helicase unwinds one side of Ter, a conserved cytosine flips out of the duplex and binds to Tus, thereby creating a locked complex that blocks the advancing helicase.     

The Escherichia coli UvrD helicase is essential for Tus removal during recombination-dependent replication restart from Ter sites

Blocking replication forks in the Escherichia coli chromosome by ectopic Ter sites renders the RecBCD pathway of homologous recombination and SOS induction essential for viability. In this work, we show that the E. coli helicase II (UvrD) is also essential for the growth of cells where replication forks are arrested at ectopic Ter sites. We propose that UvrD is required for Tus removal from Ter sites. The viability of a SOS non-inducible Ter-blocked strain is fully restored by the expression of the two SOS-induced proteins UvrD and RecA at high level, indicating that these are the only two SOS-induced proteins required for replication across Ter/Tus complexes. Several observations suggest that UvrD acts in concert with homologous recombination and we propose that UvrD is associated with recombination-initiated replication forks and that it removes Tus when a PriA-dependent, restarted replication fork goes across the Ter/Tus complex. Finally, expression of the UvrD homologue from Bacilus subtilis PcrA restores the growth of uvrD-deficient Ter-blocked cells, indicating that the capacity to dislodge Tus is conserved in this distant bacterial species.     

DNA supercoiling in Escherichia coli: topA mutations can be suppressed by DNA amplifications involving the tolC locus

The level of DNA supercoiling is crucial for many cellular processes, including gene expression, and is determined, primarily, by the opposing actions of two enzymes: topoisomerase I and DNA gyrase. Escherichia coli strains lacking topoisomerase I (topA mutants) normally fail to grow in the absence of compensatory mutations which are presumed to relax DNA. We have found that, in media of low osmolarity, topA mutants are viable in the absence of any compensatory mutation, consistent with the view that decreased extracellular osmolarity causes a relaxation of cellular DNA. At higher osmolarity most compensatory mutations, as expected, are in the gyrA and gyrB genes. The only other locus at which compensatory mutations arise, designated toc, is shown to involve the amplification of a region of chromosomal DNA which includes the tolC gene. However, amplification of tolC alone is insufficient to explain the phenotypes of toc mutants. tolC insertion mutations alter the distribution of plasmid topoisomers in vivo. This effect is probably indirect, possibly a result of altered membrane structure and an alteration in the cell's osmotic barrier. As tolC is a highly pleiotropic locus, affecting the expression of many genes, it is possible that some of the TolC phenotypes are a direct result of this topological change. The possible relationship between toc and tolC mutations, and the means by which tolC mutations might affect DNA supercoiling, are discussed.     

Viability of Escherichia coli topA mutants lacking DNA topoisomerase I

The viability of the topA mutants lacking DNA topoisomerase I was thought to depend on the presence of compensatory mutations in Escherichia coli but not Salmonella typhimurium or Shigella flexneri. This apparent discrepancy in topA requirements in different bacteria prompted us to reexamine the topA requirements in E. coli. We find that E. coli strains bearing topA mutations, introduced into the strains by DNA-mediated gene replacement, are viable at 37 or 42 degrees C without any compensatory mutations. These topA(-) cells exhibit cold sensitivity in their growth, however, and this cold sensitivity phenotype appears to be caused by excessive negative supercoiling of intracellular DNA. In agreement with previous results (Zhu, Q., Pongpech, P., and DiGate, R. J. (2001) Proc. Natl. Acad. Sci. U. S. A. 98, 9766-9771), E. coli cells lacking both type IA DNA topoisomerases I and III are found to be nonviable, indicating that the two type IA enzymes share a critical cellular function.     

RNase HI overproduction is required for efficient full-length RNA synthesis in the absence of topoisomerase I in Escherichia coli

It has long been known that Escherichia coli cells deprived of topoisomerase I (topA null mutants) do not grow. Because mutations reducing DNA gyrase activity and, as a consequence, negative supercoiling, occur to compensate for the loss of topA function, it has been assumed that excessive negative supercoiling is somehow involved in the growth inhibition of topA null mutants. However, how excess negative supercoiling inhibits growth is still unknown. We have previously shown that the overproduction of RNase HI, an enzyme that degrades the RNA portion of an R-loop, can partially compensate for the growth defects because of the absence of topoisomerase I. In this article, we have studied the effects of gyrase reactivation on the physiology of actively growing topA null cells. We found that growth immediately and almost completely ceases upon gyrase reactivation, unless RNase HI is overproduced. Northern blot analysis shows that the cells have a significantly reduced ability to accumulate full-length mRNAs when RNase HI is not overproduced. Interestingly, similar phenotypes, although less severe, are also seen when bacterial cells lacking RNase HI activity are grown and treated in the same way. All together, our results suggest that excess negative supercoiling promotes the formation of R-loops, which, in turn, inhibit RNA synthesis.