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.     

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.     

Identification of the tip-encoded receptor in bacterial sensing.

Relaxation of titratable supercoils in bacterial nucleoids was measured following treatment of topA mutants with coumermycin or oxolinic acid, inhibitors of DNA gyrase. Relaxation occurred after treatment of the mutants with either inhibitor. We detected no significant difference in relaxation between topA- and topA+ strains treated with coumermycin. This finding, together with previous observations, supports the idea that relaxation caused by coumermycin probably arises from the relaxing activity of gyrase itself. The source of DNA relaxation caused by oxolinic acid was not identified. Nucleoid supercoiling can be increased by adding oxolinic acid to a strain that carries three topoisomerase mutations: delta topA, gyrB225, and gyrA (Nalr) (S. H. Manes, G. J. Pruss, and K. Drlica, J. Bacteriol. 155:420-423, 1983). We found that this increase in supercoiling requires partial sensitivity to the drug and at the delta topA and gyrA mutations. Full resistance to oxolinic acid in the presence of the delta topA, gyrB225, and gyrA mutations was conferred by an additional mutation that maps at or near gyrB.     

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.     

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.     

Tus-mediated arrest of DNA replication in Escherichia coli is modulated by DNA supercoiling

In the absence of RecA, expression of the Tus protein of Escherichia coli is lethal when ectopic Ter sites are inserted into the chromosome in an orientation that blocks completion of chromosome replication. Using this observation as a basis for genetic selection, an extragenic suppressor of Tus-mediated arrest of DNA replication was isolated with diminished ability of Tus to halt DNA replication. Resistance to tus expression mapped to a mutation in the stop codon of the topA gene (topA869), generating an elongated topoisomerase I protein with a marked reduction in activity. Other alleles of topA with mutations in the carboxyl-terminal domain of topoisomerase I, topA10 and topA66, also rendered recA strains with blocking Ter sites insensitive to tus expression. Thus, increased negative supercoiling in the DNA of these mutants reduced the ability of Tus-Ter complexes to arrest DNA replication. The increase in superhelical density did not diminish replication arrest by disrupting Tus-Ter interactions, as Tus binding to Ter sites was essentially unaffected by the topA mutations. The topA869 mutation also relieved the requirement for recombination functions other than recA to restart replication, such as recC, ruvA and ruvC, indicating that the primary effect of the increased negative supercoiling was to interfere with Tus blockage of DNA replication. Introduction of gyrB mutations in combination with the topA869 mutation restored supercoiling density to normal values and also restored replication arrest at Ter sites, suggesting that supercoiling alone modulated Tus activity. We propose that increased negative supercoiling enhances DnaB unwinding activity, thereby reducing the duration of the Tus-DnaB interaction and leading to decreased Tus activity.     

Control of bacterial DNA supercoiling

Two DNA topoisomerases control the level of negative supercoiling in bacterial cells. DNA gyrase introduces supercoils, and DNA topoisomerase I prevents supercoiling from reaching unacceptably high levels. Perturbations of supercoiling are corrected by the substrate preferences of these topoisomerases with respect to DNA topology and by changes in expression of the genes encoding the enzymes. However, supercoiling changes when the growth environment is altered in ways that also affect cellular energetics. The ratio of [ATP] to [ADP], to which gyrase is sensitive, may be involved in the response of supercoiling to growth conditions. Inside cells, supercoiling is partitioned into two components, superhelical tension and restrained supercoils. Shifts in superhelical tension elicited by nicking or by salt shock do not rapidly change the level of restrained supercoiling. However, a steady-state change in supercoiling caused by mutation of topA does alter both tension and restrained supercoils. This communication between the two compartments may play a role in the control of supercoiling.     

DNA supercoiling in vivo

DNA topoisomerase mutants of Escherichia coli and Saccharomyces cerevisiae were used to study the topological state of intracellular DNA. In E. coli, it is shown that switching off the gene topA encoding DNA topoisomerase I leads to an increase in the degree of negative supercoiling of intracellular DNA and inhibition of the growth of the cells: a d(pCpG)16.d(pCpG)16 sequence on a plasmid is also shown to flip from a right-handed B-helical structure to a left-handed Z-helical structure in vivo when topA is switched off. In S. cerevisiae, the topological state of intracellular DNA is little affected by the cellular levels of the topoisomerases.     

Constitutive stable DNA replication in Escherichia coli cells lacking type 1A topoisomerase activity

Type 1A topoisomerases (topos) are ubiquitous enzymes involved in supercoiling regulation and in the maintenance of genome stability. Escherichia coli possesses two type 1A enzymes, topo I (topA) and topo III (topB). Cells lacking both enzymes form very long filaments and have severe chromosome segregation and growth defects. We previously found that RNase HI overproduction or a dnaT::aph mutation could significantly correct these phenotypes. This leads us to hypothesize that they were related to unregulated replication originating from R-loops, i.e. constitutive stable DNA replication (cSDR). cSDR, first observed in rnhA (RNase HI) mutants, is characterized by its persistence for several hours following protein synthesis inhibition and by its requirement for primosome components, including DnaT. Here, to visualize and measure cSDR, the incorporation of the nucleotide analog ethynyl deoxyuridine (EdU) during replication in E. coli cells pre-treated with protein synthesis inhibitors, was revealed by “click” labeling with Alexa Fluor^® 488 in fixed cells, and flow cytometry analysis. cSDR was detected in rnhA mutants, but not in wild-type strains, and the number of cells undergoing cSDR was significantly reduced by the introduction of the dnaT::aph mutation. cSDR was also found in topA, double topA topB but not in topB null cells. This result is consistent with the established function of topo I in the inhibition of R-loop formation. Moreover, our finding that topB rnhA mutants are perfectly viable demonstrates that topo III is not uniquely required during cSDR. Thus, either topo I or III can provide the type 1A topo activity that is specifically required during cSDR to allow chromosome segregation.     

New Escherichia coli gyrA and gyrB mutations which have a graded effect on DNA supercoiling

Summary We isolated new gyrA and gyrB mutations in Escherichia coli which have a graded effect on DNA supercoiling. The mutants, selected respectively for resistance to nalidixic acid and coumermycin, were sorted by means of a rapid in vivo assay of DNA gyrase activity (Aleixandre and Blanco 1987). Cells carrying a gyrB (Cou^r) mutation usually showed a decrease in DNA supercoiling, which would indicate a reduction in gyrase activity. In contrast, most of the gyrA (Nal^r) mutations had no significant effect on DNA supercoiling. Moreover, they conferred a high level of resistance to nalidixic acid and other quinolones, thus being similar to the gyrA(Nal^r) mutants currently used. We also detected rare gyrA mutants showing a reduction in DNA gyrase activity. These mutants were, in addition, resistant to only low concentrations of quinolones, which allowed us to use the phenotype of partial quinolone resistance as an indicator to score gyrA mutations affecting DNA supercoiling. When gyrB mutations were introduced into the gyrA mutants, these became more sensitive to quinolones and a decrease in supercoiling was observed. Moreover, the topA10 mutation sensitized gyrA(Nal^r) cells to quinolones. We conclude therefore that the GyrA-dependent quinolone resistance is diminished as a consequence of the reduction either in topoisomerase I or gyrase activities.