Supercoiling in prokaryotic and eukaryotic DNA: changes in response to topological perturbation of plasmids in E. coli and SV40 in vitro, in nuclei and in CV-1 cells

Tethered particle analysis of supercoiled circular DNA using peptide nucleic acid handles

This protocol describes how to monitor individual naturally supercoiled circular DNA plasmids bound via peptide nucleic acid (PNA) handles between a bead and a surface. The protocol was developed for single-molecule investigation of the dynamics of supercoiled DNA, and it allows the investigation of both the dynamics of the molecule itself and of its interactions with a regulatory protein. Two bis-PNA clamps designed to bind with extremely high affinity to predetermined homopurine sequence sites in supercoiled DNA are prepared: one conjugated with digoxigenin for attachment to an anti-digoxigenin-coated glass cover slide, and one conjugated with biotin for attachment to a submicron-sized streptavidin-coated polystyrene bead. Plasmids are constructed, purified and incubated with the PNA handles. The dynamics of the construct is analyzed by tracking the tethered bead using video microscopy: less supercoiling results in more movement, and more supercoiling results in less movement. In contrast to other single-molecule methodologies, the current methodology allows for studying DNA in its naturally supercoiled state with constant linking number and constant writhe. The protocol has potential for use in studying the influence of supercoils on the dynamics of DNA and its associated proteins, e.g., topoisomerase. The procedure takes ~4 weeks.

DNA supercoiling enhances cooperativity and efficiency of an epigenetic switch

Bacteriophage λ stably maintains its dormant prophage state but efficiently enters lytic development in response to DNA damage. The mediator of these processes is the λ repressor protein, CI, and its interactions with λ operator DNA. This λ switch is a model on the basis of which epigenetic switch regulation is understood. Using single molecule analysis, we directly examined the stability of the CI-operator structure in its natural, supercoiled state. We marked positions adjacent to the λ operators with peptide nucleic acids and monitored their movement by tethered particle tracking. Compared with relaxed DNA, the presence of supercoils greatly enhances juxtaposition probability. Also, the efficiency and cooperativity of the λ switch is significantly increased in the supercoiled system compared with a linear assay, increasing the Hill coefficient.

The structure of (CENP-A-H4)(2) reveals physical features that mark centromeres

Centromeres are specified epigenetically, and the histone H3 variant CENP-A is assembled into the chromatin of all active centromeres. Divergence from H3 raises the possibility that CENP-A generates unique chromatin features to mark physically centromere location. Here we report the crystal structure of a subnucleosomal heterotetramer, human (CENP-A-H4)(2), that reveals three distinguishing properties encoded by the residues that comprise the CENP-A targeting domain (CATD; ref. 2): (1) a CENP-A-CENP-A interface that is substantially rotated relative to the H3-H3 interface; (2) a protruding loop L1 of the opposite charge as that on H3; and (3) strong hydrophobic contacts that rigidify the CENP-A-H4 interface. Residues involved in the CENP-A-CENP-A rotation are required for efficient incorporation into centromeric chromatin, indicating specificity for an unconventional nucleosome shape. DNA topological analysis indicates that CENP-A-containing nucleosomes are octameric with conventional left-handed DNA wrapping, in contrast to other recent proposals. Our results indicate that CENP-A marks centromere location by restructuring the nucleosome from within its folded histone core.

Gel mobilities of linking-number topoisomers and their dependence on DNA helical repeat and elasticity

Agarose-gel electrophoresis has been used for more than thirty years to characterize the linking-number (Lk) distribution of closed-circular DNA molecules. Although the physical basis of this technique remains poorly understood, the gel-electrophoretic behavior of covalently closed DNAs has been used to determine the local unwinding of DNA by proteins and small-molecule ligands, characterize supercoiling-dependent conformational transitions in duplex DNA, and to measure helical-repeat changes due to shifts in temperature and ionic strength. Those results have been analyzed by assuming that the absolute mobility of a particular topoisomer is mainly a function of the integral number of superhelical turns, and thus a slowly varying function of plasmid molecular weight. In examining the mobilities of Lk topoisomers for a series of plasmids that differ incrementally in size over more than one helical turn, we found that the size-dependent agarose-gel mobility of individual topoisomers with identical values of Lk (but different values of the excess linking number, DeltaLk) vary dramatically over a duplex turn. Our results suggest that a simple semi-empirical relationship holds between the electrophoretic mobility of linking-number topoisomers and their average writhe in solution.

Structural maintenance of chromosomes protein of Bacillus subtilis affects supercoiling in vivo

Structural maintenance of chromosomes (SMC) proteins are found in nearly all organisms. Members of this protein family are involved in chromosome condensation and sister chromatid cohesion. Bacillus subtilis SMC protein (BsSMC) plays a role in chromosome organization and partitioning. To better understand the function of BsSMC, we studied the effects of an smc null mutation on DNA supercoiling in vivo. We found that an smc null mutant was hypersensitive to the DNA gyrase inhibitors coumermycin A1 and norfloxacin. Furthermore, depleting cells of topoisomerase I substantially suppressed the partitioning defect of an smc null mutant. Plasmid DNA isolated from an smc null mutant was more negatively supercoiled than that from wild-type cells. In vivo cross-linking experiments indicated that BsSMC was bound to the plasmid. Our results indicate that BsSMC affects supercoiling in vivo, most likely by constraining positive supercoils, an activity which contributes to chromosome compaction and organization.

Control of Mammary Tumor Cell Growth in Vitro by Novel Cell Differentiation and Apoptosis Agents

The use of breast tumor differentiating agents to complement existing therapies has the potential to improve breast cancer treatment. Previously we showed quinidine caused MCF-7 cells to synchronously arrest in G1 phase of the cell cycle, transition into G0 and undergo progressive differentiation. After 72-96 h cells became visibly apoptotic. Using several analogs of quinidine we determined that MCF-7 cell cycle exit and differentiation are typical of quinoline antimalarial drugs bearing a tertiary amine side chain (chloroquine, quinine, quinidine). Differentiated cells accumulated lipid droplets and mammary fat globule membrane protein. Apoptosis was assayed by a nucleosome release ELISA. Quinidine and chloroquine triggered apoptosis, but not quinine, a quinidine stereoisomer that displayed weak DNA binding. The apoptotic response to quinidine and chloroquine was p53-dependent. A 4-15-fold induction of p21(WAF1) protein was observed in cells treated with quinidine or chloroquine prior to apoptosis, but p21(WAF1) was not increased in cells that differentiated in response to quinine. Chloroquine was most active in stimulating MCF-7 apoptosis, and quinine was most active in promoting MCF-7 cell differentiation. We conclude, distinct mechanisms are responsible for breast tumor cell differentiation and activation of apoptosis by quinoline antimalarials. Alkylamino-substituted quinoline ring compounds represented by quinidine, quinine, and chloroquine will be useful model compounds in the search for more active breast tumor differentiating agents.

Chromatin structural transitions in Drosophila embryo cell-free extract result in a high conformational flexibility of nucleosomal DNA

DNA within chromatin has considerably more restricted flexibility in comparison with naked DNA. This raises the main question of how the functioning multi-enzyme complexes overcome the nucleosomal level of DNA packaging. We studied the DNA conformational flexibility of reconstituted chromatin in a cell-free system derived from Drosophila embryo extracts. Using this system, we have found evidence for a energy-independent chromatin remodelling process that efficiently destabilizes the nucleosome structure resulting in a high conformational flexibility of nucleosomal DNA. The described chromatin remodelling process may lay on the basis of defined molecular principles governing the molecular heterogeneity of chromatin structures in vivo.

Effect of in vivo histone hyperacetylation on the state of chromatin fibers

We evaluated the contribution of in vivo histone acetylation to the folding of chromatin into its higher-order structures. We have compared high-order folding patterns of hyperacetylated vs. unmodified chromatin in living green monkey kidney cells (CV1 line) using intercalator chloroquine diphospate to induce alterations in the twist of internucleosomal linker DNA. We have shown that histone hyperacetylation induced by antibiotic Trichostatin A significantly alters intercalator-mediated chromatin folding pattern.

DNA gyrase, topoisomerase IV, and the 4-quinolones

For many years, DNA gyrase was thought to be responsible both for unlinking replicated daughter chromosomes and for controlling negative superhelical tension in bacterial DNA. However, in 1990 a homolog of gyrase, topoisomerase IV, that had a potent decatenating activity was discovered. It is now clear that topoisomerase IV, rather than gyrase, is responsible for decatenation of interlinked chromosomes. Moreover, topoisomerase IV is a target of the 4-quinolones, antibacterial agents that had previously been thought to target only gyrase. The key event in quinolone action is reversible trapping of gyrase-DNA and topoisomerase IV-DNA complexes. Complex formation with gyrase is followed by a rapid, reversible inhibition of DNA synthesis, cessation of growth, and induction of the SOS response. At higher drug concentrations, cell death occurs as double-strand DNA breaks are released from trapped gyrase and/or topoisomerase IV complexes. Repair of quinolone-induced DNA damage occurs largely via recombination pathways. In many gram-negative bacteria, resistance to moderate levels of quinolone arises from mutation of the gyrase A protein and resistance to high levels of quinolone arises from mutation of a second gyrase and/or topoisomerase IV site. For some gram-positive bacteria, the situation is reversed: primary resistance occurs through changes in topoisomerase IV while gyrase changes give additional resistance. Gyrase is also trapped on DNA by lethal gene products of certain large, low-copy-number plasmids. Thus, quinolone-topoisomerase biology is providing a model for understanding aspects of host-parasite interactions and providing ways to investigate manipulation of the bacterial chromosome by topoisomerases.

Heat shock-induced DNA relaxation in vitro by DNA gyrase of Escherichia coli in the presence of ATP

Genetic studies revealed that DNA gyrase seems to catalyze immediate and transient DNA relaxation after Escherichia coli cells are exposed to heat shock (Ogata, Y., Mizushima, T., Kataoka, K., Miki, T., and Sekimizu, K. (1994) Mol. Gen. Genet. 244, 451-455). We have now obtained biochemical evidence to support this hypothesis. DNA gyrase catalyzed an increase in the linking number of DNA and relaxation of negatively supercoiled DNA, under physiological concentrations of ATP. Analyses by gel filtration chromatography of each subunit revealed that DNA relaxation activity co-migrated with each subunit. The linking number of DNA increased as the temperature increased. Further, the reaction was inhibited by nalidixic acid or by oxolinic acid. Based on these results, we propose that DNA gyrase participates in a concerted reaction with DNA topoisomerases in the immediate relaxation of DNA in cells exposed to heat shock.

Differential control of transcription-induced and overall DNA supercoiling by eukaryotic topoisomerases in vitro

The global superhelical state of intracellular DNA is stringently controlled by topoisomerase action. Little is know, however, about topoisomerase-directed relaxation of localized DNA supercoiling generated by protein tracking processes such as transcription. Here we use transcription by a yeast Gal4 and phage T7 RNA polymerase fusion protein to induce localized supercoiling which, in turn, triggers site-specific DNA recombination by gamma delta resolvase. We demonstrate that only large amounts of eukaryotic topoisomerase I interfere, through supercoiling relaxation, with the topological coupling between transcription and recombination. The additional presence of a strong cleavage site for topoisomerase I has little influence on the relaxation of localized supercoiling. We also show that high levels of human topoisomerase II fail to compete with transcription-driven recombination. However, drastically reduced amounts of either enzyme completely suppress recombination of overall supercoiled DNA. Together, our results reveal a marked difference in topoisomerase requirement to relax transcription-induced and global DNA supercoiling. We discuss possible reasons for this difference and conclude that localized supercoiling frequently may escape relaxation by eukaryotic topoisomerases to mediate topological couplings between DNA transactions.

Alterations in the internucleosomal DNA helical twist in chromatin of human erythroleukemia cells in vivo influences the chromatin higher-order folding

In the present study chloroquine diphosphate, a DNA intercalating drug, was used to alter the internucleosomal DNA helical twist in chromatin of living mammalian cells. The intercalative binding of chloroquine effectively unwinds the DNA double helix and its binding is restricted to nucleosomal linker regions without noticeable disruption of nucleosomes. The results presented here imply that the alterations in the rotation angle between the adjacent nucleosomes in chromatin of eukaryotic cells in vivo significantly influences the way the chain of nucleosomes folds in higher-order chromatin structures, as evidenced by specific alterations in nuclease susceptibility of chromatin.

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.

Protein tracking-induced supercoiling of DNA: a tool to regulate DNA transactions in vivo?

An interplay between DNA-dependent biological processes appears to be crucial for cell viability. At the molecular level, this interplay relies heavily on the communication between DNA-bound proteins, which can be facilitated and controlled by the dynamic structure of double-stranded DNA. Hence, DNA structural alterations are recognized as potential tools to transfer biological information over some distance within a genome. Until recently, however, direct evidence for DNA structural information as a mediator between cellular processes was lacking. This changed when the concept of transient waves of DNA supercoiling, induced by proteins tracking along the right-handed DNA double helix, came into the limelight. Indeed, a number of observations now suggest that helix tracking-induced DNA structural information might be exploited to participate in the regulation of a variety of DNA transactions in vivo.

Evidence for a salt-induced conformational transition in UV-irradiated superhelical PM2 DNA

Upon treatment with UV irradiation, native (supercoiled) PM2 DNA undergoes an increase in electrophoretic mobility relative to the nicked circular form in the presence of 1 M NaCl or 5 mM CaCl2 or MgCl2. This effect is dependent upon supercoiling in that the relative electrophoretic mobility decreases with decreasing superhelical density of the molecule. These findings indicate that supercoil-dependent aspects of the secondary and tertiary structure of nonirradiated PM2 DNA can be altered by a combination of UV irradiation and any of the ionic environments above. We show that the alteration is not the result of a conversion of Z-DNA segments to a right-handed helix or to a renaturation of denatured regions in PM2 DNA. Circular dichroism studies do not support a simple model in which A-form DNA induced by superhelical stress is converted to B-form DNA by UV-induced photodamage and salt. We, therefore, present three alternative explanations for these observations two of which invoke conformational transitions in secondary structure and a third which requires a change in tertiary structure due to an increase in flexibility.

Topoisomerase mutations affect the relative abundance of many Escherichia coli proteins

The relative abundance of 88 proteins was measured in extracts from three strains of Escherichia coli K-12 that are isogenic except for the topA and gyrB genes. Mutations in these genes slightly raise or lower, respectively, steady-state DNA supercoiling levels but have little effect on growth rate. Altered protein abundances were observed in the mutant strains relative to wild type. Many proteins exhibited minimum abundance at wild-type supercoiling levels, and other proteins exhibited maximal abundance at relaxed levels. A smaller number showed maximal abundance at elevated levels of supercoiling. These data suggest that small, non-lethal changes in DNA supercoiling can have widespread effects on patterns of gene expression.

Flexibility of DNA within transcriptionally active nucleosomes: analysis by circular dichroism measurements

The conformational flexibility of DNA in transcriptionally active chromatin fractions has been estimated by circular dichroism spectroscopy analysis and was found to be restricted in the same fashion as in bulk chromatin. The observation is discussed in the context of different models of active chromatin organization.

Effects of histone acetylation on chromatin topology in vivo

Recently a model for eukaryotic transcriptional activation has been proposed in which histone hyperacetylation causes release of nucleosomal supercoils, and this unconstrained tension in turn stimulates transcription (V. G. Norton, B. S. Imai, P. Yau, and E. M. Bradbury, Cell 57:449-457, 1989; V. G. Norton, K. W. Marvin, P. Yau, and E. M. Bradbury, J. Biol. Chem. 265:19848-19852, 1990). These studies analyzed the effect of histone hyperacetylation on the change in topological linking number which occurs during nucleosome assembly in vitro. We have tested this model by determining the effect of histone hyperacetylation on the linking number change which occurs during assembly in vivo. We find that butyrate treatment of cells infected with simian virus 40 results in hyperacetylation of the histones of the extracted viral minichromosome as expected. However, the change in constrained supercoils of the minichromosome DNA is minimal, a result which is inconsistent with the proposed model. These results indicate that the proposed mechanism of transcriptional activation is unlikely to take place in the cell.

Effects of histone acetylation on chromatin topology in vivo

Recently a model for eukaryotic transcriptional activation has been proposed in which histone hyperacetylation causes release of nucleosomal supercoils, and this unconstrained tension in turn stimulates transcription (V. G. Norton, B. S. Imai, P. Yau, and E. M. Bradbury, Cell 57:449-457, 1989; V. G. Norton, K. W. Marvin, P. Yau, and E. M. Bradbury, J. Biol. Chem. 265:19848-19852, 1990). These studies analyzed the effect of histone hyperacetylation on the change in topological linking number which occurs during nucleosome assembly in vitro. We have tested this model by determining the effect of histone hyperacetylation on the linking number change which occurs during assembly in vivo. We find that butyrate treatment of cells infected with simian virus 40 results in hyperacetylation of the histones of the extracted viral minichromosome as expected. However, the change in constrained supercoils of the minichromosome DNA is minimal, a result which is inconsistent with the proposed model. These results indicate that the proposed mechanism of transcriptional activation is unlikely to take place in the cell.

Ellipticine increases the superhelical density of intracellular SV40 DNA by intercalation

We investigated the in vivo effect of ellipticine, a mammalian topoisomeraseII(topoII) inhibitor, on SV40 DNA topology. In contrast to epipodophyllotoxins, ellipticine did not cause significant double stranded cleavage of intracellular SV40 DNA. Furthermore, ellipticine reduced cleavage induced by epipodophyllotoxins, VP16 and VM26. Unexpectedly, ellipticine dramatically increased the superhelical density of a fraction of intracellular SV40 DNA. Several lines of evidence suggest that the formation of this highly supercoiled DNA species (Ih form DNA) is not due to the inhibition of topoII per se, but is the result of intercalation by ellipticine in a subfraction of the intracellular SV40 chromatin followed by the fixation of DNA linking number by a topoisomerase activity. Based on the linking number change and the known unwinding angle of ellipticine, the intercalation density was calculated as one ellipticine molecule per 10-20 bp in the Ih DNA. This result suggests the existence of different populations of intracellular SV40 chromatin with respect to the accessibility to ellipticine intercalation.

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.

On the deletion of inverted repeated DNA in Escherichia coli: effects of length, thermal stability, and cruciform formation in vivo

We have studied the deletion of inverted repeats cloned into the EcoRI site within the CAT gene of plasmid pBR325. A cloned inverted repeat constitutes a palindrome that includes both EcoRI sites flanking the insert. In addition, the two EcoRI sites represent direct repeats flanking a region of palindromic symmetry. A current model for deletion between direct repeats involves the formation of DNA secondary structure which may stabilize the misalignment between the direct repeats during DNA replication. Our results are consistent with this model. We have analyzed deletion frequencies for several series of inverted repeats, ranging from 42 to 106 bp, that were designed to form cruciforms at low temperatures and at low superhelical densities. We demonstrate that length, thermal stability of base pairing in the hairpin stem, and ease of cruciform formation affect the frequency of deletion. In general, longer palindromes are less stable than shorter ones. The deletion frequency may be dependent on the thermal stability of base pairing involving approximately 16-20 bp from the base of the hairpin stem. The formation of cruciforms in vivo leads to a significant increase in the deletion frequency. A kinetic model is presented to describe the relationship between the physical-chemical properties of DNA structure and the deletion of inverted repeats in living cells.

Torsionally tuned cruciform and Z-DNA probes for measuring unrestrained supercoiling at specific sites in DNA of living cells

We describe the development and application of "torsionally tuned" Z-DNA and cruciform probes for analyzing the level of unrestrained supercoiling at specific sites in the DNA of living cells. This approach is applicable for the analysis of dynamic differences in supercoiled DNA in different parts of plasmid, bacterial, or eukaryotic chromosomes. Using a psoralen-based assay, we have shown that the Z-DNA forming sequence (CG)6TA(CG)6, cloned into plasmid pUC8, exists as Z-DNA in 30 to 40% of plasmid molecules in wild-type Escherichia coli. This level suggested an in vivo superhelical density of sigma = -0.034 at the site of insertion in the plasmid. A higher level of Z-DNA found in cells deficient in topoisomerase I (topA10) suggested an in vivo superhelical density of sigma = -0.048. We have constructed a set of torsionally tuned inverted repeated DNA molecules which require different superhelical densities for cruciform formation. Using these inverted repeats and a crosslink assay for cruciforms, we present quantitative evidence for the existence of cruciforms in living E. coli cells. Cruciform formation was dependent on DNA supercoiling in vivo and on the location of the inverted repeat within a plasmid. In topA10 cells cruciforms were detected in less than 0.5% of plasmids when cloned into two different transcriptional units: the lacZ and CAT genes. However, when cloned outside a transcriptional unit, cruciforms were found at levels up to 50% in topA10 cells. More cruciforms were found upstream than downstream from divergent promoters in pBR322. From analysis of the fraction of different inverted repeats existing as cruciforms in vivo and the levels of supercoiling required for cruciform formation in vitro, we estimate in vivo superhelical densities of sigma = -0.034 and -0.041 for the EcoRI site of pUC8-based plasmids in wild-type and topA10 cells, respectively.

Bacterial DNA supercoiling and [ATP]/[ADP]. Changes associated with a transition to anaerobic growth

Shifting Escherichia coli from aerobic to anaerobic growth caused changes in the ratio of [ATP]/[ADP] and in negative supercoiling of chromosomal and plasmid DNA. Shortly after lowering oxygen tension, both [ATP]/[ADP] and supercoiling transiently decreased. Under conditions of exponential anaerobic growth, both were higher than under aerobic conditions. These correlations may reflect an effect of [ATP]/[ADP] on DNA gyrase, since in vitro [ATP]/[ADP] influences the level of plasmid supercoiling attained when gyrase is either introducing or removing supercoils. When the supercoiling activity of gyrase was perturbed by a mutation in gyrB, a shift to anaerobic conditions resulted in plasmid supercoil relaxation similar to that seen with wild-type. However, the low level of supercoiling in the mutant persisted during a time when supercoiling in wild-type recovered and then exceeded aerobic levels. Thus, changes in oxygen tension can alter DNA supercoiling through an effect on gyrase, and correlations exist between changes in supercoiling and changes in the intracellular ratio of [ATP]/[ADP].

Determination of the DNA conformation of the simian virus 40 (SV40) enhancer in SV40 minichromosomes

The simian virus 40 (SV40) enhancer contains three 8-bp purine-pyrimidine alternating sequences which are known to adopt the left-handed Z-DNA conformation in vitro. In this paper, we have undertaken the determination of the DNA conformation adopted by these Z-motifs in the SV40 minichromosome. We have analyzed the presence of Z-DNA through the change in linkage which should accompany formation of this left-handed conformation. Our results indicate that, regardless of the precise moment of the viral lytic cycle at which minichromosomes are harvested and the condition of the transfected DNA, either relaxed or negatively supercoiled, none of the three Z motifs of the SV40 enhancer exist to a significant extent as Z-DNA in SV40 minichromosomes. The SV40 enhancer adopts predominantly a right-handed B-DNA conformation in vivo.

Environmental stimuli and transcriptional activity generate transient changes in DNA torsional tension

Transient changes in DNA torsional tension are generated by environmental stimuli and transcriptional activity. In eukaryotic cells, these changes can only be accommodated by a chromatin structure that is flexible. This property of chromatin may be essential to the regulation of eukaryotic gene activity.

Gyrase inhibitors can increase gyrA expression and DNA supercoiling

Treatment of bacterial cells with inhibitors of gyrase at high concentration leads to relaxation of DNA supercoils, presumably through interference with the supercoiling activity of gyrase. Under certain conditions, however, the inhibitors can also increase supercoiling. In the case of coumermycin A1, this increase occurs at low drug concentrations. Oxolinic acid increases supercoiling in a partially resistant mutant. We found that increases in chromosomal DNA supercoiling, which were blocked by treatment with chloramphenicol, were accompanied by an increased expression rate of gyrA. This result is consistent with gyrase being responsible for the increase in supercoiling. In wild-type cells, increases in gyrA expression were transient, suggesting that when supercoiling reaches sufficiently high levels, gyrase expression declines. Oxolinic acid studies carried out with a delta topA strain showed that drug treatment also increased plasmid supercoiling. The levels of supercoiling and topoisomer heterogeneity were much higher when the plasmid contained one of several promoters fused to galK. Since oxolinic acid causes an increase in gyrA expression, it appears that gyrase levels may be important in transcription-mediated changes in supercoiling even when topoisomerase I is absent.

The nucleoskeleton and the topology of transcription

Transcription is conventionally believed to occur by passage of a mobile polymerase along a fixed template. Evidence for this model is derived almost entirely from material prepared using hypotonic salt concentrations. Studies on subnuclear structures isolated using hypertonic conditions, and more recently using conditions closer to the physiological, suggest an alternative. Transcription occurs as the template moves past a polymerase attached to a nucleoskeleton; this skeleton is the active site of transcription. Evidence for the two models is summarised. Much of it is consistent with the polymerase being attached and not freely diffusible. Some consequences of such a model are discussed.

Thermal unwinding of simian virus 40 transcription complex DNA

Two long-standing questions in the control of eukaryotic gene expression have been how the structure of transcribing chromatin compares with that of nontranscribing chromatin and how chromatin structure differs among various eukaryotic organisms. We have addressed aspects of these two questions by characterizing the rotational flexibility of the DNA of the simian virus 40 (SV40) transcription complex. When transcription complex samples are incubated with topoisomerase at 0 degrees C or 37 degrees C, the DNA of the 37 degrees C sample is unwound by 1.8 turns relative to that of the 0 degrees C sample. This amount of unwinding is similar to that observed for bulk, untranscribed SV40 minichromosome DNA, indicating that the chromatin structure of a transcribed gene resembles that of a nontranscribed gene in the degree of constraint that it imposes on its DNA. However, this amount of unwinding differs substantially from the value observed for yeast plasmid chromatin DNA, suggesting that yeast chromatin differs significantly from mammalian chromatin in this fundamental property.

In vivo assessment of the Z-DNA-forming potential of d(CA.GT)n and d(CG.GC)n sequences cloned into SV40 minichromosomes

Alternating repeated d(CA.GT)n and d(CG.GC)n sequences constitute a significant proportion of the simple repeating elements found in eukaryotic genomic DNA. These sequences are known to form left-handed Z-DNA in vitro. In this paper, we have addressed the question of the in vivo determination of the Z-DNA-forming potential of such sequences in eukaryotic chromatin. For this purpose, we have investigated the ability of a d(CA.GT)30 sequence and a d(CG.GC)5 sequence to form left-handed Z-DNA when cloned into simian virus 40 (SV40) minichromosomes at two different positions: the TaqI site, which occurs in the intron of the T-antigen gene, and the HpaII site, which is located in the late promoter region within the SV40 control region. Formation of Z-DNA at the inserted repeated sequences was analyzed through the change in DNA linkage associated with the B to Z transition. Our results indicate that regardless of: (1) the site of insertion (either TaqI or HpaII), (2) the precise moment of the viral lytic cycle (from 12 h to 48 h postinfection) and (3) the condition of incorporation of the SV40 recombinants to the host cells (either as minichromosomes or as naked DNA, relaxed or negatively supercoiled), neither the d(CA.GT)30 nor the d(CG.GC)5 sequence are stable in the left-handed Z-DNA conformation in the SV40 minichromosome. The biological relevance of these results is discussed.

DNA conformational variations in the in vitro torsionally strained Ig kappa light chain gene localize on consensus sequences

We have analyzed the localization and the dependence upon superhelical density of the DNA sites which modify their conformation under torsional strain in a mouse Ig L kappa gene. The conformational variations occur on DNA sites which have been defined as protein interaction sites and consensus sequence motifs: the 5'-upstream regulatory decanucleotides, the TATA sequence, the consensus heptanucleotides of the J recombinational sequences.

The B- to Z-DNA equilibrium in vivo is perturbed by biological processes

Right-handed B and left-handed Z conformations coexist in equilibrium in portions of plasmids in Escherichia coli. The equilibria are influenced by the length of the sequences that undergo the structural transitions and are perturbed by biological processes. The composite results of three types of determinations indicate a supercoil density of -0.025 in vivo. The coexistence of alternative DNA conformations in living cells implies the potential of these structures or their transitions for important functions in genetic regulatory processes.

Rifampin and rpoB mutations can alter DNA supercoiling in Escherichia coli

Two cases are described which indicate that RNA polymerase could alter DNA supercoiling. One occurred in a topA mutant in which abnormally high levels of plasmid supercoiling were lowered by rifampin, an inhibitor of the beta subunit of RNA polymerase. The second case involves suppression of a temperature-sensitive gyrB mutation by a rifampin-resistant allele of rpoB, the gene encoding the beta subunit of RNA polymerase. Measurements of chromosomal DNA supercoiling show that the rpoB mutation reduced DNA relaxation.

DNA gyrase on the bacterial chromosome. Oxolinic acid-induced DNA cleavage in the dnaA-gyrB region

Oxolinic acid forms complexes with gyrase and DNA in such a way that subsequent denaturation of gyrase reveals DNA cleavage. Cleavage sites were mapped in a 10,000 base-pair region of the Escherichia coli chromosome containing the dnaA, dnaN, recF, and gyrB genes. Twenty-four cleavage sites were identified. The sites were cleaved at different frequencies, with the most frequent cleavage occurring within gyrB. Not all sites were equally sensitive to oxolinic acid concentration, some sites exhibited an altered cleavage frequency when the gyrB225 delta topA mutant strain DM800 was compared with wild-type cells, and coumermycin selectively changed the cleavage frequency at a few sites in the mutant strain DM800. These perturbations appear to alter the frequency of cleavage at a site but not the location of the site. The availability of many sites of differing strengths may be an important factor in the ability of gyrase to fine-tune the level of supercoiling or provide local swivels in bacterial DNA.

The influence of tertiary structural restraints on conformational transitions in superhelical DNA

This paper examines theoretically the effects that restraints on the tertiary structure of a superhelical DNA domain exert on the energetics of linking and the onset of conformational transitions. The most important tertiary constraint arises from the nucleosomal winding of genomic DNA in vivo. Conformational transitions are shown to occur at equilibrium at less extreme superhelicities in DNA whose tertiary structure is restrained than in unrestrained molecules where the residual linking difference alpha res (that part of the superhelical deformation which is not absorbed by transitions) may be freely partitioned between twisting and bending. In the extreme case of a rigidly held tertiary structure, this analysis predicts that the B-Z transition will occur at roughly half the superhelix density needed to drive the same transition in solution, other factors remaining fixed. This suggests that superhelical transitions may occur at more moderate superhelical deformations in vivo than in solution. The influence on transition behavior of the tertiary structural restraints imposed by gel conditions also are discussed.