Escherichia coli DNA topoisomerase I mutants: Increased supercoiling is corrected by mutations near gyrase genes

Bacterial chromosomes and plasmid (pBR322) DNA from topoisomerase I-defective Escherichia coli strains have been characterized with respect to superhelical density. The topoisomerase I defect results in increased negative superhelical density of both the bacterial chromosome and pBR322. Thus topoisomerase I is involved in determining the level of supercoiling in bacteria. Three of the topoisomerase I-defective strains we studied carry secondary mutations that decrease superhelical density; these additional mutations are closely linked to the gyrB locus in two of the strains and to the gyrA locus in the third strain.     

Escherichia coli response to hydrogen peroxide: a role for DNA supercoiling, topoisomerase I and Fis

Bacterial cells respond to the deleterious effects of reactive oxygen species by inducing the expression of antioxidant defence genes. Here we show that treatment with hydrogen peroxide leads to a transient decrease in DNA negative supercoiling. We also report that hydrogen peroxide activates topA P1 promoter expression. The peroxide-dependent topA P1 activation is independent of oxyR, but is mediated by Fis. This nucleoid-associated protein binds to the promoter region of topA. We also show that a fis deficient mutant strain is extremely sensitive to hydrogen peroxide. Our results suggest that topA activation by Fis is an important component of the Escherichia coli response to oxidative stress.     

Effect of phosphorothioate substitutions on DNA cleavage by Escherichia coli DNA topoisomerase I

To evaluate the structural influence of the DNA phosphate backbone on the activity of Escherichia coli DNA topoisomerase I, modified forms of oligonucleotide dA(7) were synthesized with a chiral phosphorothioate replacing the non-bridging oxygens at each position along the backbone. A deoxy-iodo-uracil replaced the 5'-base to crosslink the oligonucleotides by ultraviolet (UV) and assess binding affinity. At the scissile phosphate there was little effect on the cleavage rate. At the +1 phosphate, the rectus phosphorus (Rp)-thio-substitution reduced the rate of cleavage by a factor of 10. At the +3 and -2 positions from the scissile bond, the Rp-isomer was cleaved at a faster rate than the sinister phosphorus (Sp)-isomer. The results demonstrate the importance of backbone contacts between DNA substrate and E. coli topoisomerase I.     

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.     

Conditional growth of Escherichia coli caused by expression of vaccinia virus DNA topoisomerase I.

Active vaccinia virus topoisomerase I is expressed in Escherichia coli containing plasmid p1940 (S. Shuman, M. Golder, and B. Moss, J. Biol. Chem. 263:16401-16407, 1988). Growth curves showed a decline of 2 to 3 logs in the number of viable cells at 42 degrees C after shift from 30 degrees C because of increased vaccinia virus topoisomerase I level. Mutations in the gyrA and gyrB genes allowed cells to grow equally well at 42 and 30 degrees C. The presence of gyrase inhibitor also improved growth at 42 degrees C.     

A rapid procedure to purify Escherichia coli DNA topoisomerase I

On the basis of the asymmetrical charge distribution of Escherichia coli DNA topoisomerase I, we developed a new procedure to purify E. coli DNA topoisomerase I in the milligram range. The new procedure includes using both cation- and anion-exchange columns, i.e., SP-Sepharose FF and Q-Sepharose FF columns. The E. coli DNA topoisomerase I purified here is free of DNase contamination. The kinetic constants of the DNA relaxation reaction of E. coli DNA topoisomerase I were also determined.     

Duplex DNA knots produced by Escherichia coli topoisomerase I. Structure and requirements for formation

We investigated systematically the knotting of nicked circular duplex DNA by Escherichia coli topoisomerase I. Agarose gel electrophoresis of knots forms a ladder of DNA bands. Each rung is made up of a variety of knots with the same number of nodes, or segment crossings; knots in adjacent rungs differ by one node. We extended the technique of electron microscopy of recA protein-coated DNA to the visualization of the complex knots tied by topoisomerase I. The striking result is that the enzyme produces every knot theoretically possible. The requirement for excess enzyme to form complex knots suggests a role for topoisomerase I in contorting the DNA in addition to promoting strand passage. We conclude that nodes formed are equally likely to be positive or negative and that topoisomerase I can pass DNA strands through a transient enzyme-generated break without regard to orientation of the passing strand. The results are interpreted in terms of a formulation for the topological requirements for knotting.     

DNA supercoiling in Escherichia coli is under tight and subtle homeostatic control, involving gene-expression and metabolic regulation of both topoisomerase I and DNA gyrase.

DNA of prokaryotes is in a nonequilibrium structural state, characterized as 'active' DNA supercoiling. Alterations in this state affect many life processes and a homeostatic control of DNA supercoiling has been suggested [Menzel, R. & Gellert, M. (1983) Cell 34, 105-113]. We here report on a new method for quantifying homeostatic control of the high-energy state of in vivo DNA. The method involves making small perturbation in the expression of topoisomerase I, and measuring the effect on DNA supercoiling of a reporter plasmid and on the expression of DNA gyrase. In a separate set of experiments the expression of DNA gyrase was manipulated and the control on DNA supercoiling and topoisomerase I expression was measured [part of these latter experiments has been published in Jensen, P.R., van der Weijden, C.C., Jensen, L.B., Westerhoff, H.V. & Snoep, J.L. (1999) Eur. J. Biochem. 266, 865-877]. Of the two regulatory mechanisms via which homeostasis is conferred, regulation of enzyme activity or regulation of enzyme expression, we quantified the first to be responsible for 72% and the latter for 28%. The gene expression regulation could be dissected to DNA gyrase (21%) and to topoisomerase I (7%). On a scale from 0 (no homeostatic control) to 1 (full homeostatic control) we quantified the homeostatic control of DNA supercoiling at 0.87. A 10% manipulation of either topoisomerase I or DNA gyrase activity results in a 1.3% change of DNA supercoiling only. We conclude that the homeostatic regulation of the nonequilibrium DNA structure in wild-type Escherichia coli is almost complete and subtle (i.e. involving at least three regulatory mechanisms).     

Characterization of vaccinia virus DNA topoisomerase I expressed in Escherichia coli

The putative structural gene encoding the vaccinia virus type I DNA topoisomerase (EC 5.99.1.2) was expressed in Escherichia coli under the control of a bacteriophage T7 promoter. Provision of T7 RNA polymerase resulted in the accumulation to high level of a Mr = 33,000 type I topoisomerase with the properties of the vaccinia enzyme. A simple purification scheme yielded approximately 8 mg of recombinant vaccinia topoisomerase from 400 ml of bacteria. DNA unwinding by the enzyme was stimulated by magnesium, manganese, calcium, cobalt, and spermidine, but inhibited by copper and zinc. Like eukaryotic cellular type I topoisomerases, but unlike the prokaryotic counterpart, the recombinant topoisomerase relaxed positively and negatively supercoiled DNA. The viral topoisomerase I was, however, resistant to the effects of camptothecin, a drug that specifically inhibits cellular type I topoisomerases.     

Modulation of the relaxing activity of Escherichia coli topoisomerase I by single-stranded DNA binding proteins

Removal of negative superhelical turns in ColE1 plasmid DNA by Escherichia coli topoisomerase I was markedly enhanced by the presence of single-stranded DNA binding protein from E. coli. A lack of species specificity makes unlikely the possibility of physical association between topoisomerase I and single-stranded DNA binding proteins. Stabilization of single-stranded regions in supercoiled DNA by single-stranded DNA binding protein would appear to be the basis of the enhancement of topoisomerase activity.     

The expression of the DNA ligase gene of Escherichia coli is stimulated by relaxation of chromosomal supercoiling

Many genes of Escherichia coli have been shown to be sensitive to DNA superhelicity. The superhelicity of the chromosome is itself also supercoiling-dependent. We have developed a general strategy for investigating how a particular gene responds to changes in DNA topology. This approach is used to study the E. coli ligase gene. The thermosensitivity of the E. coli ligts251 mutation can be phenotypically suppressed by mutations which map close to, or in, the gyrB gene and which affect the degree of DNA supercoiling. The level of suppression correlates with the degree of DNA relaxation observed, suggesting that the gene encoding the E. coli DNA ligase is activated by relaxation of the chromosomal DNA.