DNA replication and transcription in a temperature-sensitive mutant of E. coli with a defective DNA gyrase B subunit

Thirty years of Escherichia coli DNA gyrase: from in vivo function to single-molecule mechanism

The level of negative DNA supercoiling of the Escherichia coli chromosome is tightly regulated in the cell and influences many DNA metabolic processes including DNA replication, transcription, repair and recombination. Gyrase is the only type II topoisomerase able to introduce negative supercoils into DNA, a unique ability that arises from the specialized C-terminal DNA wrapping domain of the GyrA subunit. Here, we review the biological roles of gyrase in vivo and its mechanism in vitro.

Topological challenges to DNA replication: conformations at the fork

The unwinding of the parental DNA duplex during replication causes a positive linking number difference, or superhelical strain, to build up around the elongating replication fork. The branching at the fork and this strain bring about different conformations from that of (-) supercoiled DNA that is not being replicated. The replicating DNA can form (+) precatenanes, in which the daughter DNAs are intertwined, and (+) supercoils. Topoisomerases have the essential role of relieving the superhelical strain by removing these structures. Stalled replication forks of molecules with a (+) superhelical strain have the additional option of regressing, forming a four-way junction at the replication fork. This four-way junction can be acted on by recombination enzymes to restart replication. Replication and chromosome folding are made easier by topological domain barriers, which sequester the substrates for topoisomerases into defined and concentrated regions. Domain barriers also allow replicated DNA to be (-) supercoiled. We discuss the importance of replicating DNA conformations and the roles of topoisomerases, focusing on recent work from our laboratory.

Analysis of topoisomerase function in bacterial replication fork movement: use of DNA microarrays

We used DNA microarrays of the Escherichia coli genome to trace the progression of chromosomal replication forks in synchronized cells. We found that both DNA gyrase and topoisomerase IV (topo IV) promote replication fork progression. When both enzymes were inhibited, the replication fork stopped rapidly. The elongation rate with topo IV alone was 1/3 of normal. Genetic data confirmed and extended these results. Inactivation of gyrase alone caused a slow stop of replication. Topo IV activity was sufficient to prevent accumulation of (+) supercoils in plasmid DNA in vivo, suggesting that topo IV can promote replication by removing (+) supercoils in front of the chromosomal fork.

Biochemistry of homologous recombination in Escherichia coli

Homologous recombination is a fundamental biological process. Biochemical understanding of this process is most advanced for Escherichia coli. At least 25 gene products are involved in promoting genetic exchange. At present, this includes the RecA, RecBCD (exonuclease V), RecE (exonuclease VIII), RecF, RecG, RecJ, RecN, RecOR, RecQ, RecT, RuvAB, RuvC, SbcCD, and SSB proteins, as well as DNA polymerase I, DNA gyrase, DNA topoisomerase I, DNA ligase, and DNA helicases. The activities displayed by these enzymes include homologous DNA pairing and strand exchange, helicase, branch migration, Holliday junction binding and cleavage, nuclease, ATPase, topoisomerase, DNA binding, ATP binding, polymerase, and ligase, and, collectively, they define biochemical events that are essential for efficient recombination. In addition to these needed proteins, a cis-acting recombination hot spot known as Chi (chi: 5'-GCTGGTGG-3') plays a crucial regulatory function. The biochemical steps that comprise homologous recombination can be formally divided into four parts: (i) processing of DNA molecules into suitable recombination substrates, (ii) homologous pairing of the DNA partners and the exchange of DNA strands, (iii) extension of the nascent DNA heteroduplex; and (iv) resolution of the resulting crossover structure. This review focuses on the biochemical mechanisms underlying these steps, with particular emphases on the activities of the proteins involved and on the integration of these activities into likely biochemical pathways for recombination.

The level of supercoiling affects the regulation of DNA replication in Escherichia coli

The chromosome of Escherichia coli is negatively supercoiled. This favours processes that unwind the two DNA strands, such as DNA replication. In this paper, we have investigated the effect of changed levels of overall chromosomal supercoiling on the initiation of DNA replication. Specifically, we have used flow cytometry to reveal effects on the synchrony of initiations of DNA replication in single cells. An increase in the level of supercoiling moderately reduced initiation synchrony. In contrast, decreased supercoiling led to pronounced asynchrony. We have excluded the possibility that this asynchrony is caused by changes in the level of the Dam methyltransferase or the DnaA protein. We suggest that the global level of supercoiling influences the topology of oriC and thereby the sequence of events leading to initiation of DNA replication in E. coli.

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 replication in Escherichia coli gyrB(Ts) mutants analysed by flow cytometry

We have investigated the initiation of DNA replication in Escherichia coli gyrB (Ts) mutants and find that initiations in single cells, even those that occur at non-permissive temperature, are synchronous. Furthermore, our results indicate that the gradual arrest of DNA replication at non-permissive temperature reflects a general decrease in transcription activity and not an initiation-specific function of the DNA gyrase. At an intermediate temperature, the only effect observed was a lack of segregation (decatenation) of replicated chromosomes in a sizeable fraction of the cell population.

Effect of DNA superhelicity on transcription termination

Restriction fragments containing either leut (a rho-independent transcription termination site) and/or leut' (a rho-dependent transcription termination site) were cloned into plasmid pOL4. Treatment of plasmid-containing Escherichia coli strains with coumermycin resulted in loss of in vivo plasmid superhelicity 10 min after antibiotic addition. Galactokinase levels specified by these plasmid-containing strains were the same regardless of whether functional DNA gyrase was present. These results suggest that transcription termination is unaffected by the superhelical state of DNA.

Genetic analysis of mutations that compensate for loss of Escherichia coli DNA topoisomerase I

A transposon Tn10 insertion in topA, the structural gene of Escherichia coli DNA topoisomerase I, behaves as an excluded marker in genetic crosses with many strains of E. coli. However, derivative strains that accept this mutant topA allele are readily selected. We show that many of these topA mutant strains contain additional mutations that compensate for the loss of DNA topoisomerase I. Genetic methods for mapping and manipulating such compensatory mutations are described. These methods include a plate-mating test for the ability of strains to accept a topA::Tn10 allele and a powerful indirect selection for transferring compensatory mutations from male strains into non-compensatory female strains. One collection of spontaneous compensatory mutants is analyzed in detail and is shown to include compensatory mutations at three distinct loci: gyrA and gyrB, the genes that encode the subunits of DNA gyrase, and a previously unidentified locus near tolC. Mutations at this third locus, referred to as toc (topoisomerase one compensatory) mutations, do not behave as point mutations in transductional crosses and do not result in lowered DNA gyrase activity. These results show that wild-type strains of E. coli require DNA topoisomerase I, and at least one class of compensatory mutations can relieve this requirement by a mechanism other than reduction of DNA gyrase activity.

Native supercoiling of DNA: the effects of DNA gyrase and omega protein in E. coli

This study deals with the effects of a temperature-sensitive (ts) mutation at the gene encoding the DNA gyrase B subunit (gyrBts) and a deletion of the top gene encoding the omega protein upon the superhelical density of the pAO3 plasmid in E. coli cells. The alteration of the DNA gyrase B subunit is shown to lead to a partial relaxation of DNA. On the other hand, the lack of omega protein due to the top gene deletion leads to an abnormally high degree of DNA supercoiling. In a double gyrBts delta top mutant the DNA supercoiling is greater than native at the permissive temperature, while under nonpermissive conditions a partial relaxation is observed. However, the pattern of DNA relaxation in the latter case is quite different from that in a single gyrBts mutant. The conclusion is that the native supercoiling of DNA in the cell is maintained through the counter-activities of DNA gyrase and the omega protein.

DNA supercoiling in gyrase mutants

Nucleoids isolated from Escherichia coli strains carrying temperature-sensitive gyrA or gyrB mutations were examined by sedimentation in ethidium bromide-containing sucrose density gradients. A shift to restrictive temperature resulted in nucleoid DNA relaxation in all of the mutant strains. Three of these mutants exhibited reversible nucleoid relaxation: when cultures incubated at restrictive temperature were cooled to 0 degree C over a 4- to 5-min period, supercoiling returned to levels observed with cells grown at permissive temperature. Incubation of these three mutants at restrictive temperature also caused nucleoid sedimentation rates to increase by about 50%.

Positively supercoiled plasmid DNA is produced by treatment of Escherichia coli with DNA gyrase inhibitors

A procedure has been developed whereby the relative amounts of the topoisomers of E. coli plasmid can be determined for cells grown under a variety of conditions. Several applications of the procedure are presented. Addition of either novobiocin or oxolinic acid, two inhibitors of DNA gyrase, gives rise to positively supercoiled plasmid. A likely model for the introduction of positive supercoils, involving DNA gyrase itself, is discussed. Oxolinic acid is also shown to induce linearization of plasmid in vivo. Starvation of cells for ATP is shown to cause relaxation of plasmid. The shift of a gyrB temperature-sensitive strain to the restrictive temperature is also shown to cause plasmid relaxation. Finally, it is noted that polyamine starvation of E. coli has no detectable effect on the distribution of topoisomers.