Superhelical Density Research Articles

Flow of structural information between four DNA conformational levels.

Closed-circular supercoiled DNA molecules have been shown to form a cholesteric assembly within bacteria as well as in vitro under physiological DNA and salt concentrations. Circular dichroism and X-ray scattering studies indicate that the macroscopic structural properties of the chiral mesophase are directly and uniquely dictated by the supercoiling parameters of the constituent molecules. Specifically, we find that the pitch of the DNA cholesteric phase derived from supercoiled DNA is determined by the superhelical density, which, in turn, is modulated by secondary conformational changes. A direct interrelationship among four DNA structural levels, namely, DNA sequence, secondary structural transitions, the tertiary superhelical conformation, and the quaternary, supramolecular organization is accordingly pointed out. Since secondary conformational changes are both sequence and environment dependent, alterations of cellular conditions may effectively modulate the properties of the packed DNA organization, through their effects on secondary structural transitions and hence on the superhelical parameters. On the basis of these results we suggest that liquid crystallinity represents an effectively regulated packaging mode of plectonemic, nucleosome-free DNA molecules in living systems.

Promoter Selectivity of Escherichia coli RNA Polymerase Eσ70 and Eσ38 Holoenzymes: EFFECT OF DNA SUPERCOILING

The functional specificity was compared between two sigma factors, sigma 70 (the major sigma at exponentially growing phase) and sigma 38 (the essential sigma at stationary growth phase), of Escherichia coli RNA polymerase. The core enzyme binding affinity of sigma 38 was less than half the level of sigma 70 as measured by gel filtration column chromatography or by titrating the concentration of sigma required for the maximum transcription in the presence of a fixed amount of core enzyme. In addition, the holoenzyme concentration required for the maximum transcription of a fixed amount of templates was higher for E sigma 38 than E sigma 70. The transcription by E sigma 38 was, however, enhanced with the use of templates with low superhelical density, in good agreement with the decrease in DNA superhelicity in the stationary growth phase. We thus propose that the selective transcription of stationary-specific genes by E sigma 38 holoenzyme requires either a specific reaction condition(s) or a specific factor(s) such as template DNA with low superhelical density.

Influence of the linking number of template DNA on sigma 32-dependent transcription initiation in vitro of the Escherichia coli groE gene.

Plasmids carrying the groE promoter with a superhelical density of 0 to -0.091 were used for in vitro transcription with RNA polymerase holoenzyme containing sigma 32. The promoter activity of the groE gene in vitro on the plasmid DNA was decreased to 100-fold when the superhelical density of the template DNA decreased from -0.059 to 0. As the superhelical density of DNA inside the cells was estimated to be approximately -0.025, it seems likely that the increase in the linking number of template DNA caused by stress which induces heat shock response may not stimulate the groE promoter activity in vivo on the chromosomal DNA. At higher concentrations of salt, the dependence of the groE promoter activity on negative supercoiling was even more apparent. Since melting of the DNA duplex is inhibited by high salt concentrations, DNA supercoiling may facilitate melting of the groE promoter by an RNA polymerase holoenzyme containing sigma 32.

Sequence-dependent effects of spermine on the thermodynamics of the B-DNA to Z-DNA transition.

Spermine has been shown to bind to and stabilize a number of altered DNA conformations, including left-handed Z-DNA. Here, we have quantitatively studied the effects of spermine on the negative supercoil-induced transition from B- to Z-DNA. We have determined the intrinsic association constants for and the effective number of ligands that bind to both B- and Z-DNA. The intrinsic affinity of spermine for Z-DNA is approximately 10 times higher for d(CA/TG) (KZP = 1.2 x 10(8) M-1) than for d(CG) dinucleotides (KZP = 1.5 x 10(7) M-1), and both are greater than that for B-DNA (KBP = 1.4 x 10(5) M-1). This accounts for the stabilization of Z-DNA by spermine. The number of spermine accommodated by Z-DNA (nZ) is sequence-dependent [nZ = 0.6 spermine per 18 d(CA/TG) dinucleotides and 2.3 for 12 d(CG) dinucleotides]. The value of nZ of < 1 was interpreted as evidence for negative cooperativity in spermine binding to d(CA/TG) dinucleotides. Thus, although d(CA/TG) sequences saturate at lower spermine concentrations, the ligand has an overall greater effect on the stability of d(CG) dinucleotides as Z-DNA. B-DNA accommodates more spermines per base pair than either sequence as Z-DNA. At higher concentrations (> 10 microM), spermine destabilizes Z-DNA. Using these parameters in a model for competitive spermine binding to B-DNA and Z-DNA, we can make predictions for how potential Z-DNA sequences found in the human genome are affected by cellular levels of superhelical density and spermine.

Neutron and Gamma-Radiation Sensitivity of Plasmid DNA of Varying Superhelical Density

Several families of negatively supercoiled topoisomers of plasmid pIBI30 were prepared by a modification of the procedure of Singleton and Wells (Anal. Biochem. 122, 253-257, 1982). The average superhelical density (sigma) was determined by two-dimensional agarose gel electrophoresis and varied from -0.010 to -0.067, corresponding to a change in the number of supercoils from 3 to 19 and an effective volume change from 1.6 x 10(8) to 4 x 10(8) A3. Samples were exposed to either fission-neutron or 60Co gamma radiation and assayed for single-strand breaks by agarose gel electrophoresis. Form I DNA for all topoisomers decreased exponentially with increasing dose. The D37 values for both neutron and gamma radiation increased monotonically with increasing magnitude of sigma. Using a branched plectonemic (interwound) form for DNA over the range of sigma studied and standard (single-hit) target theory, a quantitative linear fit to (D37)-1 as a function of the effective DNA radius, S(A), was obtained. The model predicts that both the slope (a) and the intercept (b) of (D37)-1 as a function of S(A) are directly proportional to the length of DNA and the radiation fluence. Furthermore, the ratio b/a (= ro) at sigma = 0 depends only on the ionic strength of the medium and is independent of the radiation source parameters. Our results support the model and we calculate ro = 13.4 +/- 1.4 nm, a value consistent with other investigations. Our results are consistent with studies using 137Cs (Milligan et al., Radiat.(ABSTRACT TRUNCATED AT 250 WORDS)

Eukaryotic topoisomerase II cleavage is independent of duplex DNA conformation

Alternating purine-pyrimidine (RY) repeats have been identified in naturally occurring DNA and have many intriguing properties. Eukaryotic topoisomerase II displays significant cleavage activity at RY repeats (Spitzner et al. (1990) Nucleic Acids Res. 18, 1–11) due to the homology between RY repeat and the topoisomerase II consensus sequence. Cleavages are remarkably strong on duplex B form DNA. Certain RY elements are known to adopt altered DNA forms, such as Z-DNA, under the influence of superhelical stress. To investigate the dependence of topoisomerase II activity on DNA conformation, a plasmid containing a 40 bp of deoxyguanine-thymine repeat was constructed and the dependence of topoisomerase II cleavage patterns were compared. Although the degree of negative supercoiling strongly affected the overall efficiency of topoisomerase II cleavage, the sequence specificity was identical over a wide range of superhelical densities. These results suggest that topoisomerase II site specific action of duplex DNA is largely independent of DNA conformation. Moreover, since the GT target sequence is known to adopt a Z-DNA structure under conditions of superhelical density used in these experiments, the results reveal that topoisomerase II is a DNA binding protein capable of recognizing Z-DNA structure in eukaryotic cell.

Escherichia coli DNA topoisomerase III is a site-specific DNA binding protein that binds asymmetrically to its cleavage site.

The binding of DNA topoisomerase III (Topo III) to a single-stranded DNA substrate containing a strong cleavage site has been examined. The minimal substrate requirement for Topo III-catalyzed cleavage has been determined to consist of 7 bases; 6 bases 5' to the cleavage site and only 1 base 3' to the site. Nuclease P1 protection experiments indicate that the enzyme also binds to its substrate asymmetrically, protecting approximately 12 bases 5' to the cleavage site and only 2 bases 3' to the cleavage site. A catalytically inactive mutant of Topo III shows the same protection pattern as the active polypeptide, indicating that Topo III is a site-specific binding protein as well as a topoisomerase. Consistent with this view, an oligonucleotide containing a cleavage site is a more effective inhibitor and is bound more efficiently by Topo III than an oligonucleotide without a cleavage site.

Influence of DNA supercoiling on cisplatin toxicity in Escherichia coli K-12

DNA supercoiling is known to modulate the activity of numerous promoters in vitro and in vivo. Moreover, it has been reported to modulate the rate of formation of cisplatin/DNA crosslinks in vitro. In order to address the question of how the topology influences CDDP toxicity in E. coli, three mutants with altered gyrase activity which led to a decrease of about 25% in superhelical density were studied. Mutant strains gyrA 224 and gyrB 225 showed similar sensitivity to CDDP as the parental strain while the gyrB 226 mutant was resistant. This resistance was abolished in uvrA (excision-repair) and recA (recombination and SOS processes) mutant derivatives. Thus supercoiling might play a role as an indirect modulator of CDDP toxicity in bacteria by interfering with repair processes.

Preferential binding of histones H3 and H4 to highly positively coiled DNA.

The interaction of histones H3 and H4 with highly positively coiled DNA has been studied. To carry out this study, it was necessary to develop a protocol for the preparation of large quantities of highly positively coiled DNA. Such preparations were obtained by maximizing transcription-induced stress in cells containing PBR322 and then applying a short-term treatment with novobiocin, which inhibits gyrase. Fractionation on CsCl-EtBr gradients gave PBR322 plasmids with topological states ranging from +0.15 to -0.043 superhelical density. In competition experiments between negatively and positively coiled DNA, histones H3,H4 preferentially bound the positively coiled DNA when the superhelical density was greater than +0.10. This preference was shown on the basis of sedimentation rate on sucrose gradients, selective aggregation by H3,H4 binding, and cross-linking experiments in which the histone-DNA content was characterized on CsCl density gradients. An analysis of the DNA helical pitch in 1.1 M NaCl, a condition in which moderately positively coiled DNA preferentially binds H3,H4 indicated that the preferential binding may be due to a decrease in helical pitch that approximates 0.06 bp/turn. Consistent with this observation is the ability of histones H3,H4 to transiently hold this altered pitch in the presence of topoisomerase I. A possible explanation for this preference is based on the known observation that histones overwind the DNA helix when in a nucleosome. These data provide an explanation for the in vivo observation that histones H3,H4 are rarely displaced during the transcription process. These observations are discussed with regard to mechanisms for transcription through nucleosomes.

Stimulation of DNA synthesis by mouse DNA helicase B in a DNA replication system containing eukaryotic replication origins.

A number of DNA helicases have been isolated from mammalian cells, but their abilities to stimulate DNA replication accompanied with DNA unwinding have not been addressed so far. We constructed a model DNA replication system using the yeast autonomously replicating sequence (ARS) as the replication origin. In this system, SV40 T antigen as a DNA helicase assembles to the replication origin where the DNA duplex is unwound by torsional stress due to the negative supercoiling of template DNA, which leads to bidirectional DNA replication from the origin. We report here that DNA helicase B isolated from mouse FM3A cells can greatly stimulate DNA synthesis in this replication system in place of SV40 T antigen. DNA synthesis was dependent on the presence of single-stranded DNA binding protein (RP-A), DNA polymerase alpha/primase from mouse cells, and Escherichia coli DNA gyrase. DNA gyrase was required not only at elongation as a DNA swivelase but also at initiation to increase negative superhelical density of template DNA with the assistance of RP-A. A mammalian DNA fragment containing a replication initiation zone upstream of the c-myc gene as well as the yeast ARS fragment acted as a cis-element in this system using DNA helicase B. Both DNA helicase B and SV40 T antigen have the ability to extensively unwind the template DNA in the presence of RP-A and DNA gyrase, which may be crucial for stimulation of DNA synthesis in this system.

Overview of controls in the Escherichia coli cell cycle

The harmonious growth and cell-to-cell uniformity of steady-state bacterial populations indicate the existence of a well-regulated cell cycle, responding to a set of internal signals. In Escherichia coli, the key events of this cycle are the initiation of DNA replication, nucleoid segregation and the initiation of cell division. The replication initiator is the DnaA protein. In nucleoid segregation, the MukB protein, required for proper partitioning, may be a member of the myosin-kinesin superfamily of mechanoenzymes. In cell division, the FtsZ protein has a tubulin motif, is a GTPase and polymerizes in a ring around midcell during septation; the FtsA protein has an actin-like structure. The nature of the internal signals triggering these events is not known but candidates include cell mass, the superhelical density of the chromosome and the concentration of two regulatory nucleotides, cyclic AMP and ppGpp. The involvement of cytoskeletal-like proteins in key cycle events encourages the notion of a fundamental biological unity in cell cycle regulation in all organisms.

Genetic and physical interactions between yeast RGR1 and SIN4 in chromatin organization and transcriptional regulation.

The SIN4 and RGR1 genes of Saccharomyces cerevisiae were identified by mutations in quite different genetic screens. We have shown that the SIN4 gene product is required for proper transcriptional regulation of many genes and that a sin4 mutation can affect either activation or repression of specific genes. We have suggested that this dual nature of SIN4 in transcriptional regulation is due to its involvement in chromatin organization. We now report that the role of RGR1 in gene regulation is similar to that of SIN4. SIN4 and RGR1 both function as negative transcriptional regulators of HO and IME1, and mutations in either gene lead to decreased expression of other genes including CTS1. Strains with sin4 or rgr1 mutations both have phenotypes similar to those caused by histone mutations, including suppression of delta insertion into promoters (Spt- phenotype), activation of promoters lacking UAS elements, and decreased superhelical density of plasmid DNA molecules. Overexpression of RGR1 suppresses the temperature sensitivity due to a sin4 mutation. Finally, we use yeast strains expressing GST fusion proteins to demonstrate that the Sin4p and Rgr1p proteins are physically associated in vivo. These results indicate that Sin4p and Rgr1p act together in vivo to organize chromatin structure and thus regulate transcription.

Condensation of plasmids enhanced by Z-DNA conformation of d(CG)n inserts.

DNA molecules collapse into compact structures in the presence of multivalent cations. To probe the possible importance of supercoiling and conformational effects, pUC18 plasmids (2686 bp) were modified by inserting 12-bp and 20-bp alternating d(CG)n sequences, which are capable of converting to a left-handed Z-conformation under appropriate conditions, into the polycloning region. Condensation was induced by rapid addition of hexaammine cobalt(III) [Co(NH3)6(3+)] and monitored by laser light scattering and electron microscopy. Light scattering shows that plasmids with longer d(CG)n inserts condense more extensively at natural superhelical densities. Electron microscopy indicates that the morphological distribution of condensed d(CG)n-containing plasmids changes as a function of Co(NH3)6(3+) concentration. At lower Co(NH3)6(3+) concentration, the proportion of rods is higher, and at higher Co-(NH3)6(3+) concentration, most of the condensates have the form of toroids. In addition, the inner radii of the toroids are much smaller relative to condensed pUC18 under the same conditions. Enzymatic analysis and chemical probing show that the d(CG)n inserts in naturally supercoiled plasmids have extensively converted from B-form to Z-form in the presence of Co(NH3)6(3+) at the upper range of concentrations under which condensation occurs. To determine whether the enhanced condensation of d(CG)n-containing plasmids results from the change of superhelical density due to the B-Z transition, we treated wild-type pUC18 molecules with topoisomerase I and varying amounts of ethidium bromide to generate a range of supercoil densities. Light scattering indicates that supercoiling did not affect the condensation process.(ABSTRACT TRUNCATED AT 250 WORDS)

Supercoiling-regulated liquid-crystalline packaging of topologically-constrained, nucleosome-free DNA molecules.

Electron microscopy and circular dichroism studies of cholesteric aggregates derived from topologically-constrained DNA molecules indicate that the overall morphology and structural properties of these aggregates are fundamentally different from those characterizing condensed structures of nonconstrained DNA species. Specifically, the cholesteric pitch and twist of all hitherto characterized lyotropic mesophases of biopolymers--including those obtained from linear DNA--depend predominantly upon environmental parameters such as the dielectric constant of the solvent. In contrast, the properties of aggregates derived from closed circular supercoiled DNA are found to be solely and directly dictated by the superhelical density and handedness. On the basis of these results, as well as on the demonstrated ubiquity of liquid-crystalline DNA organizations in vivo, we suggest that supercoiling-regulated liquid crystallinity represents an effective packaging mode of nucleosome-free, topologically-constrained DNA molecules in living systems.

Synapsis by Tn3 resolvase: speed and dependence on DNA supercoiling.

Synapsis by Tn3 resolvase: speed and dependence on DNA supercoiling.

Effects of salt and temperature on plasmid topology in the halophilic archaeon Haloferax volcanii.

We report here the effect of environmental parameters, salinity, temperature, and an intercalating drug on plasmid topology in the halophilic archaeon Haloferax volcanii. We first studied the topological state of the plasmid pHV11 in media of different salt compositions and concentrations. The superhelical density of plasmid PHV11 varies in a way that depends on the kind of salt and on the concentrations of individual salts. With respect to growth temperature, the plasmid linking number increased at higher temperature in a linear way, contrary to what has been reported for Escherichia coli, in which the plasmid linking number decreased at higher temperature. These results suggest that some of the mechanisms that control DNA supercoiling in halophilic Archaea may be different from those described for E. coli. However, homeostatic control of DNA supercoiling seems to occur in haloarchaea, as in Bacteria, since we found that relaxation of DNA by chloroquine triggers an increase in negative supercoiling.

Topoisomerase IV can support oriC DNA replication in vitro.

Escherichia coli has two type II topoisomerases, DNA gyrase and topoisomerase IV (Topo IV). Topo IV is required for the decatenation of the linked daughter chromosomes at the terminal stages of DNA replication, whereas gyrase, because of its ability to convert to negative supercoils the positive supercoils generated by replication fork progression in a circular chromosome, is required to support nascent chain elongation. Using an oriC DNA replication system in vitro, we show that Topo IV, which can relax positive supercoils, can also support replication fork progression. This activity is only observed at substoichiometric ratios of Topo IV to template, at higher ratios, the template becomes relaxed and initiation of DNA replication cannot occur. Topo IV was capable of supporting bidirectional DNA replication from oriC, although, unlike the case with gyrase, some templates apparently replicated unidirectionally. This suggests that either gyrase itself or a certain minimum superhelical density is required for proper initiation of DNA replication from oriC.

On higher buckling transitions in supercoiled DNA.

A combination of detailed energy minimization and molecular dynamics studies of closed circular DNA offers here new information that may be relevant to the dynamics of short DNA chains and/or low superhelical densities. We find a complex dependence of supercoiled DNA energies and geometries on the linking number difference delta Lk as physiological superhelical densities (magnitude of sigma approximately 0.06) are approached. The energy minimization results confirm and extend predictions of classical elasticity theory for the equilibria of elastic rods. The molecular dynamics results suggest how these findings may affect the dynamics of supercoiled DNA. The minimization reveals sudden higher order configurational transitions in addition to the well-known catastrophic buckling from the circle to the figure-8. The competition among the bending, twisting, and self-contact forces leads to different families of supercoiled forms. Some of those families begin with configurations of near-zero twist. This offers the intriguing possibility that nicked DNA may relax to low-twist forms other than the circle, as generally assumed. Furthermore, for certain values of delta Lk, more than one interwound DNA minimum exists. The writhing number as a function of delta Lk is discontinuous in some ranges; it exhibits pronounced jumps as delta Lk is increased from zero, and it appears to level off to a characteristic slope only at higher values of delta Lk. These findings suggest that supercoiled DNA may undergo systematic rapid interconversions between different minima that are both close in energy and geometry. Our molecular dynamics simulations reveal such transitional behavior. We observe the macroscopic bending and twisting fluctuations of interwound forms about the global helix axis as well as the end-over-end tumbling of the DNA as a rigid body. The overall mobility can be related to magnitude of sigma and to the bending, twisting, and van der Waals energy fluctuations. The general character of molecular motions is thus determined by the types of energy minima found at a given delta Lk. Different time scales may be attributed to each type of motion: The overall chain folding occurs on a time scale almost an order of magnitude faster than the end-over-end tumbling. The local bending and twisting of individual chain residues occur at an even faster rate, which in turn correspond to several cycles of local variations for each large-scale bending and straightening motion of the DNA.

Selective binding of Escherichia coli RNA polymerase to topoisomers of minicircles carrying the TAC16 and TAC17 promoters.

We have studied the effect of DNA supercoiling on open complex formation by Escherichia coli RNA polymerase at the TAC16 and TAC17 promoters. A two-dimensional gel retardation assay was used to measure the relative rate of association between RNA polymerase and the TAC promoters on individual topoisomers. Plasmid DNAs usually have several promoters that complicate the analysis of RNA polymerase binding to only one of them. We avoided this problem by using minicircles of DNA carrying only a single promoter. These were generated in vivo by the site-specific recombination system of bacteriophage lambda. Both the TAC16 and TAC17 promoters exhibited a biphasic response to negative supercoiling. Between superhelical densities of 0 and -0.04, increases in the negative linking difference favored binding. Beyond -0.04, either no effect on binding (TAC16) or a slight inhibition of binding (TAC17) was observed for increases in the negative linking difference. The unwinding at the rate-limiting step was calculated for both TAC promoters at moderate superhelical densities. This unwinding was found to be a fraction (about 20-30%) of the total unwinding measured by topoisomerase I relaxation (about one turn). In addition, the 1-base pair difference in spacer length between the TAC16 and TAC17 promoters resulted in different extents of activation and inhibition by negative supercoiling.

Comparison of plasmid DNA topology among mesophilic and thermophilic eubacteria and archaebacteria

Several plasmid DNAs have been isolated from mesophilic and thermophilic archaebacteria. Their superhelical densities were estimated at their host strain's optimal growth temperature, and in some representative strains, the presence of reverse gyrase activity (positive DNA supercoiling) was investigated. We show here that these plasmids can be grouped in two clusters with respect to their topological state. The group I plasmids have a highly negatively supercoiled DNA and belong to the mesophilic archaebacteria and all types of eubacteria. The group II plasmids have DNA which is close to the relaxed state and belong exclusively to the thermophilic archaebacteria. All archaebacteria containing a relaxed plasmid, with the exception of the moderately thermophilic methanogen Methanobacterium thermoautotrophicum Marburg, also exhibit reverse gyrase activity. These findings show that extrachromosomal DNAs with very different topological states coexist in the archaebacterial domain.