Transcription-driven supercoiling of DNA: direct biochemical evidence from in vitro studies

A supercoil-dependent structural alteration within the regulatory region of the human transferrin receptor gene

The transferrin receptor gene is transcribed at low levels in quiescent cells and at much higher levels in growing or transformed cells. This regulation involves elements located within the first 114 base pairs upstream of the major transcriptional start site. This region is specifically recognized by several transacting factors and contains an element that is composed of alternating purines and pyrimidines. In vitro this element can adopt a non-B DNA conformation in a supercoil-dependent manner. Similar elements, with nearly identical spacing relative to a protein recognition sequence, can be observed in several other proliferation dependent gene promoters.

Propagation of pSC101 plasmids defective in binding of integration host factor

Integration host factor (IHF), a multifunctional protein of E. coli, normally is required for the replication of plasmid pSC101. T. T. Stenzel, P. Patel, and D. Bastia (Cell 49:709-717, 1987) have reported that IHF binds to a DNA locus near the pSC101 replication origin and enhances a static bend present in this region; mutation of the IHF binding site affects the plasmid's ability to replicate. We report here studies indicating that the requirement for IHF binding near the pSC101 replication origin is circumvented partially or completely by (i) mutation of the plasmid-encoded repA (replicase) gene or the chromosomally encoded topA gene, (ii) the presence on the plasmid of the pSC101 partition (par) locus, or (iii) replacement of the par locus by a strong transcriptional promoter. With the exception of the repA mutation, the factors that substitute for a functional origin region IHF binding site are known to alter plasmid topology by increasing negative DNA supercoiling, as does IHF itself. These results are consistent with the proposal that IHF binding near the pSC101 replication origin promotes plasmid replication by inducing a conformational change leading to formation of a repA-dependent DNA-protein complex. A variety of IHF-independent mechanisms can facilitate formation of the putative replication-initiation complex.

Direct evidence for the effect of transcription on local DNA supercoiling in vivo

The B-to-Z structural transition of varying lengths (74 to 14 base-pairs) of (CG) tracts has been used as a superhelicity probe to examine the local topological changes induced by transcription at defined genetic loci in vivo. The local-topology reporter sequences indicate that under steady-state transcription the region upstream from the promoter experiences an increase in negative supercoiling whereas the region downstream from the terminator displays a decrease in negative superhelicity. This result provides direct in vivo evidence for the notion that the translocation of an RNA polymerase elongation complex along the double-helical DNA generates positive supercoils in front of it and negative supercoils behind it. Also, this twin-supercoiled domain model was tested inside a transcribed region where a high degree of negative supercoiling generated by the passage of each individual RNA polymerase was detected. Hence, these data indicate that the induced supercoils are confined to the vicinity of each RNA polymerase complex in a multipolymerase system.

Transcribed chromatin

In eukaryotes, DNA that is transcribed is packaged first into nucleosomes and then into chromatin fibres. How does transcription proceed through chromatin? Studies of transcription through nucleosomes in vitro suggest that the intracellular environment may provide factors which alleviate the inhibitory effect that nucleosomes have on transcription, possibly via positive supercoiling induced by the migrating polymerase. Stable changes in nucleosome structure have been correlated with transcriptionally active chromatin, but the precise mechanism by which RNA polymerase transcribes through nucleosomal DNA remains unknown.

Transcription in vivo within the replication origin of the Escherichia coli chromosome: a mechanism for activating initiation of replication

Within the replication origin, oriC, of the Escherichia coli chromosome, novel in vivo transcripts were detected which proceeded rightward and whose production was activated by DnaA protein. In contrast, DnaA protein repressed the previously described ori-L leftward transcription. The former should introduce negative supercoiling, and the latter positive supercoiling, into the 13-mers. The effects of transcription on the initiation of replication were also investigated by making constructs with promoters placed near oriC. Transcription was found to enhance the origin activity only when it was oriented in such a way as to introduce negative supercoiling into the 13-mers. From these results, we propose that transcription within oriC regulates replication initiation by altering the topology of the 13-mer region.

Evidence for torsional stress in transcriptionally activated chromatin

The existence of torsional stress in eukaryotic chromatin has been controversial. To determine whether it could be detected, we probed the structure of an alternating AT tract. These sequences adopt cruciform geometry when the DNA helix is torsionally strained by negative supercoiling. The single-strand-specific nuclease P1 was used to determine the structure of an alternating AT sequence upstream of the Xenopus beta-globin gene when assembled into chromatin in microinjected Xenopus oocytes. The pattern of cleavage by P1 nuclease strongly suggests that the DNA in this chromatin template is under torsional stress. The cruciform was detected specifically in the most fully reconstituted templates at later stages of chromatin assembly, suggesting that negative supercoiling is associated with chromatin maturation. Furthermore, the number of torsionally strained templates increased dramatically at the time when transcription of assembled chromatin templates began. Transcription itself has been shown to induce supercoiling, but the requisite negative supercoiling for cruciform extrusion by (AT)n in oocytes was not generated in this way since the characteristic P1 cutting pattern was retained even when RNA polymerase elongation was blocked with alpha-amanitin. Thus, torsional stress is associated with transcriptional activation of chromatin templates in the absence of ongoing transcription.

Evidence for torsional stress in transcriptionally activated chromatin

The existence of torsional stress in eukaryotic chromatin has been controversial. To determine whether it could be detected, we probed the structure of an alternating AT tract. These sequences adopt cruciform geometry when the DNA helix is torsionally strained by negative supercoiling. The single-strand-specific nuclease P1 was used to determine the structure of an alternating AT sequence upstream of the Xenopus beta-globin gene when assembled into chromatin in microinjected Xenopus oocytes. The pattern of cleavage by P1 nuclease strongly suggests that the DNA in this chromatin template is under torsional stress. The cruciform was detected specifically in the most fully reconstituted templates at later stages of chromatin assembly, suggesting that negative supercoiling is associated with chromatin maturation. Furthermore, the number of torsionally strained templates increased dramatically at the time when transcription of assembled chromatin templates began. Transcription itself has been shown to induce supercoiling, but the requisite negative supercoiling for cruciform extrusion by (AT)n in oocytes was not generated in this way since the characteristic P1 cutting pattern was retained even when RNA polymerase elongation was blocked with alpha-amanitin. Thus, torsional stress is associated with transcriptional activation of chromatin templates in the absence of ongoing transcription.

Concurrent transcription from the gid and mioC promoters activates replication of an Escherichia coli minichromosome

The origin of replication of the Escherichia coli chromosome (oriC) is located in an intercistronic region between the gidA and the mioC genes. The possibility that transcription from the promoters of these two genes is involved in minichromosome replication was examined. Inactivation of the gid promoter led to a reduction in transformation frequency with an oriC plasmid but inactivation of the mioC promoter did not. The decrease in transformation frequency was most pronounced when both promoters were inactive. Under conditions that selected for plasmid-harboring cells, mutation of the gid promoter caused efficient multimerization or integration of oriC plasmids into the chromosomal oriC region and loss of free plasmid molecules. These changes in plasmid structure were also observed, albeit less frequently, with some plasmids defective in mioC promoter activity. In an in vitro DNA replication system for oriC DNA, plasmids with a defective gid promoter had greatly reduced template activity and essentially no replication occurred when both promoters were inactive. These results suggest that coupled transcription starting from the gid as well as the mioC promoter activates initiation of plasmid replication, the major contribution being made by gid transcription. These two promoters are suggested to be under stringent control.

The influence of an alternate template conformation on elongating phage T7 RNA polymerase

We investigated the effect of left-handed Z-DNA on transcription by bacteriophage T7 RNA polymerase in vitro and, surprisingly, found that the enzyme can efficiently utilize a template containing a stretch of left-handed DNA close to the promoter. Analysis of transcription products revealed that only a small fraction of elongating polymerases abort transcription either at the promoter proximal or at the distal B-to-Z junction and, even less frequently, within the stretch of left-handed DNA. Our results indicate that, unlike E. coli RNA polymerase, T7 RNA polymerase can utilize a template with a CG stretch in an alternate conformation. In contrast, polymerases are completely blocked at the promoter proximal junction by a monoclonal antibody directed against Z-DNA. This blockage remains stable over a remarkable time, even when negative supercoiling is released by linearization of the template. Together with our recent finding of transcription-induced formation of Z-DNA (3), our data provide an example for a possible auto-regulatory mechanism that employs a change in DNA conformation.

The remote control of transcription, DNA looping and DNA compaction

mRNA synthesis can be controlled at some distance from the start of transcription in eukaryotes and prokaryotes. It is generally assumed that the distal elements of the transcriptional machinery directly interact with the proximal elements, forcing the DNA to bend in a loop. DNA loop formation and transcription can be affected by the distance between the sites, their helical positioning, their orientation, their concentration (responsible for a cis- or a trans-effect of the DNA sequences), and DNA compaction in chromatin. The corresponding in vitro and in vivo situations have been critically examined for a number of systems, mostly prokaryotic.

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.

Daughter origins can be held together by O protein in phage lambda replicative intermediates

When lambda replicative intermediates are incubated with initiator protein O, complex molecules are observed in which O interacts with both daughter origin segments and with growing points. In the simplest of these molecules it appears that daughter origins and growing points may all be bound together at a single point. When replicative intermediates are sequentially incubated with single-stranded binding protein and O protein, simpler structures are observed. In this case, both daughter origins are bound together by O protein. This result mimics that found when plasmid containing two tandem lambda origin sequences is reacted with O protein. In this case double origin binding produces a DNA loop. Double origin binding, as demonstrated in this investigation, creates the potential for topological domains which will have important effects on the ability of daughter origins to initiate replication.

Preferential repair of DNA damage on the transcribed strand of the human metallothionein genes requires RNA polymerase II

To examine the possible role of transcription in directing repair of DNA damage in active genes, we compared repair of UV- and aflatoxin B1-induced damage on each strand of the human metallothionein (hMT) genes. Repair on the transcribed strand of an active hMT gene occurs at least 3 times faster than that on its nontranscribed strand. Both strands of inactive genes and both strands of a regulatory region 5' to an active gene are not repaired at this faster rate. Inducing higher levels of transcription with dexamethasone selectively increased the rate of repair on only the transcribed strand of the induced gene, while treatment of cells with alpha-amanitin eliminated the strand-selective repair. These results demonstrate that repair on the transcribed strand of a gene is independent of repair on the nontranscribed strand and that the transcriptional complex plays a role in directing repair to the transcribed strand of active genes.

DNA looping alters local DNA conformation during transcription

The effect of protein-mediated DNA looping on local DNA conformation during active transcription was studied using the lac repressor-operator system. Our results suggest that lac repressor-mediated DNA looping within a plasmid DNA molecule containing two lac repressor binding sequences in vivo effectively separates plasmid DNA into two topological domains. Supercoils generated by transcription within each topological domain can be rapidly removed by DNA topoisomerase I.

Transcription-induced conformational change in a topologically closed DNA domain

We have tested in vitro the occurrence of a B-to-Z transition in a region of alternating purines and pyrimidines as a consequence of transcription-induced negative supercoiling. By using a monoclonal antibody as a specific Z-DNA stabilizing agent, we demonstrate that the formation of left-handed DNA can transiently occur when a topologically unconstrained template is transcribed. The B-to-Z transition, observed in a subpopulation of templates, appears to be induced by negative supercoiling generated in the wake of an elongating T7 RNA polymerase. Consistent with this, the presence of topoisomerases during the transcription period prevents the change in DNA conformation. These data agree with the 'twin-supercoiled-domain' model for transcription of Liu and Wang (1). Interestingly, our results suggest that the diffusion rate of transcription-induced superhelical twists must be relatively slow compared to their generation, and that under in vitro conditions localized transient supercoiling can reach unexpectedly high levels.

Supercoiling is essential for the formation and stability of the initiation complex at the divergent malEp and malKp promoters

malEp and malKp are divergent and partially overlapping promoters of the Escherichia coli maltose regulon, whose activity depends on the presence of two transcriptional activators. MalT and CRP (cAMP receptor protein). Their activation involves a common 210 base-pair regulatory region encompassing multiple binding sites for both activators. Using a supercoiled plasmid containing malEp and malKp as template, purified proteins and a single-round transcription assay, we developed an in vitro system in which both promoters behave as in vivo. In this system, malEp and malKp are active only in the presence of both MalT and CRP, and various mutations in the MalT or CRP binding sites affect the promoters in the same way as they do in vivo. We showed that supercoiling plays a crucial role not only for the formation of the initiation complex at malEp and malKp but also for its stability. In addition, dimethylsulphate protection experiments provide evidence that the nucleoprotein complexes formed by CRP and MalT bound to malEp and malKp on supercoiled and relaxed DNA are different. We speculate that one of the roles of supercoiling might be to assist the assembly of a preinitiation complex involving the regulatory region DNA and several molecules of MalT and CRP.

Eukaryotic topoisomerase I-DNA interaction is stabilized by helix curvature

The influence of DNA structure on topoisomerase I-DNA interaction has been investigated using a high affinity binding site and mutant derivatives thereof. Parallel determinations of complex formation and helix structure in the absence of superhelical stress suggest that the interaction is intensified by stable helix curvature. Previous work showed that a topoisomerase I binding site consists of two functionally distinct subdomains. A region located 5' to the topoisomerase I cleavage site is essential for binding. The region 3' to the cleavage site is covered by the enzyme, but not essential. We report here that the helix conformation of the latter region is an important modulator of complex formation. Thus, complex formation is markedly stimulated, when an intrinsically bent DNA segment is installed in this region. A unique pattern of phosphate ethylation interferences in the 3'-part of the binding site indicates that sensing of curvature involves backbone contacts. Since dynamic curvature in supercoiled DNA may substitute for stable curvature, our findings suggest that topoisomerase I is able to probe DNA topology by assessment of writhe, rather than twist.

ATP-dependent partitioning of the DNA template into supercoiled domains by Escherichia coli UvrAB

The helicase action of the Escherichia coli UvrAB complex on a covalently closed circular DNA template was monitored using bacterial DNA topoisomerase I, which specifically removes negative supercoils. In the presence of E. coli DNA topoisomerase I and ATP, the UvrAB complex gradually introduced positive supercoils into the input relaxed plasmid DNA template. Positive supercoils were not produced when E. coli DNA topoisomerase I was replaced by eukaryotic DNA topoisomerase I or when both E. coli and eukaryotic DNA topoisomerases I were added simultaneously. These results suggest that like other DNA helix-tracking processes, the ATP-dependent action of the UvrAB complex on duplex DNA simultaneously generates both positive and negative supercoils, which are not constrained by protein binding but are torsionally strained. The supercoiling activity of UvrAB on UV-damaged DNA was also studied using UV-damaged plasmid DNA and a mutant UvrA protein that lacks the 40 C-terminal amino acids and is defective in preferential binding to UV-damaged DNA. UvrAB was found to preferentially supercoil the UV-damaged DNA template, whereas the mutant protein supercoiled UV-damaged and undamaged DNA with equal efficiency. Our results therefore suggest that the DNA helix-tracking activity of UvrAB may be involved in searching and/or prepriming the damaged DNA for UvrC incision. A possible role of supercoiled domains in the incision process is discussed.

The strong ADH1 promoter stimulates mitotic and meiotic recombination at the ADE6 gene of Schizosaccharomyces pombe

The effect of the strong promoter from the alcohol dehydrogenase gene on mitotic and meiotic intragenic recombination has been studied at the ade6 locus of the fission yeast Schizosaccharomyces pombe. A 700-bp fragment containing the functional adh1 promoter was used to replace the weak wild-type promoter of the ade6 gene. Analysis of mRNA showed that strains with this ade6::adh1 fusion construct had strongly elevated ade6-specific mRNA levels during vegetative growth as well as in meiosis. These increased levels of mRNA correlated with a 20- to 25-fold stimulation of intragenic recombination in meiosis and a 7-fold increased prototroph formation during vegetative growth. Analysis of flanking marker configurations of prototrophic recombinants indicated that simple conversions as well as conversions associated with crossing over were stimulated in meiosis. The strongest stimulation of recombination was observed when the adh1 promoter was homozygous. Studies with heterologous promoter configurations revealed that the highly transcribed allele was the preferred acceptor of genetic information. The effect of the recombinational hot spot mutation ade6-M26 was also investigated in this system. Its effect was only partly additive to the elevated recombination rate generated by the ade6::adh1 fusion construct.

The target DNA sequence for resolution of poxvirus replicative intermediates is an active late promoter

The linear double-stranded genomes of poxviruses such as Shope fibroma virus (SFV) replicate autonomously within the cytoplasm of infected cells, and it is believed that all of the replication functions are virally encoded. During DNA replication the incompletely base-paired terminal hairpin loops of the viral genome transiently exist in the form of inverted repeat replicative intermediates. These inverted repeat structures form the target for telomere resolution events that include sequence-specific cleavage and directed strand exchange to form the hairpin termini of progeny virus genomes. The terminal sequence domain which forms the telomere resolution target (TRT) shares considerable sequence similarity with viral late promoters. In this study we demonstrate that the TRT of SFV is capable of functioning as a strong viral promoter late in infection. A spectrum of TRT mutations affects telomere resolution and late transcription in a strictly concordant fashion, suggesting that the two activities may be inextricably linked. Further support for this concept comes from the demonstration that a late SFV promoter sequence designated cryptic TRT, which differs substantially from the native TRT in terms of sequence, can support telomere resolution when placed in the correct spatial context. The proposed model for telomere resolution invokes directed unwinding of the TRT double helix by a transcription initiation complex and processing of the resulting secondary structure by viral late-gene products.

A potential Z-DNA-forming sequence is located between two transcription units alternatively expressed during development of Drosophila hydei

Recent studies have demonstrated that Z-DNA exists in vivo in Escherichia coli as well as in Drosophila and mammalian cells. In the present paper, we show the existence in vivo of Z-DNA epitopes in the developmentally regulated subregion 4-75C of polytene chromosomes in Drosophila hydei. The Z-DNA epitopes were detected in subdivision C2 only during late third instar when the transcriptional activity of the locus was high. Accumulation of nonhistone chromosomal proteins in that locus was also detected during late third instar only at the time of the Z-DNA formation. Northern blot data and nucleotide sequence analysis indicated that the Z-DNA-forming sequence is located between two transcription units whose expression is regulated during the third instar. Our results suggest that in subdivision 4-75C2 a B- to Z-DNA flux occurs at a specific time during late third instar and that this flux may play a negative as well as a positive role in gene expression.

DNA gyrase: structure and function

DNA gyrase is an essential bacterial enzyme that catalyzes the ATP-dependent negative super-coiling of double-stranded closed-circular DNA. Gyrase belongs to a class of enzymes known as topoisomerases that are involved in the control of topological transitions of DNA. The mechanism by which gyrase is able to influence the topological state of DNA molecules is of inherent interest from an enzymological standpoint. In addition, much attention has been focused on DNA gyrase as the intracellular target of a number of antibacterial agents as a paradigm for other DNA topoisomerases. In this review we summarize the current knowledge concerning DNA gyrase by addressing a wide range of aspects of the study of this enzyme.

Paranemic structures of DNA and their role in DNA unwinding

A DNA structure is defined as paranemic if the participating strands can be separated without mutual rotation of the opposite strands. The experimental methods employed to detect paranemic, unwound, DNA regions is described, including probing by single-strand specific nucleases (SNN), conformation-specific chemical probes, topoisomer analysis, NMR, and other physical methods. The available evidence for the following paranemic structures is surveyed: single-stranded DNA, slippage structures, cruciforms, alternating B-Z regions, triplexes (H-DNA), paranemic duplexes and RNA, protein-stabilized paranemic DNA. The problem of DNA unwinding during gene copying processes is analyzed; the possibility that extended paranemic DNA regions are transiently formed during replication, transcription, and recombination is considered, and the evidence supporting the participation of paranemic DNA forms in genes committed to or undergoing copying processes is summarized.

The strong ADH1 promoter stimulates mitotic and meiotic recombination at the ADE6 gene of Schizosaccharomyces pombe

The effect of the strong promoter from the alcohol dehydrogenase gene on mitotic and meiotic intragenic recombination has been studied at the ade6 locus of the fission yeast Schizosaccharomyces pombe. A 700-bp fragment containing the functional adh1 promoter was used to replace the weak wild-type promoter of the ade6 gene. Analysis of mRNA showed that strains with this ade6::adh1 fusion construct had strongly elevated ade6-specific mRNA levels during vegetative growth as well as in meiosis. These increased levels of mRNA correlated with a 20- to 25-fold stimulation of intragenic recombination in meiosis and a 7-fold increased prototroph formation during vegetative growth. Analysis of flanking marker configurations of prototrophic recombinants indicated that simple conversions as well as conversions associated with crossing over were stimulated in meiosis. The strongest stimulation of recombination was observed when the adh1 promoter was homozygous. Studies with heterologous promoter configurations revealed that the highly transcribed allele was the preferred acceptor of genetic information. The effect of the recombinational hot spot mutation ade6-M26 was also investigated in this system. Its effect was only partly additive to the elevated recombination rate generated by the ade6::adh1 fusion construct.

Mitotic chromatin condensation in vitro using somatic cell extracts and nuclei with variable levels of endogenous topoisomerase II

We report the development of a new method for producing mitotic extracts from tissue culture cells. These extracts reproducibly promote the condensation of chromatin in vitro when incubated with purified interphase nuclei. This condensation reaction is not species specific, since nuclei from chicken, human, and hamster cell lines all undergo chromatin condensation upon incubation with the extract. We have used this extract to investigate the role of DNA topoisomerase II (topo II) in the chromosome condensation process. Chromatin condensation does not require the presence of soluble topo II in the mitotic extract. However, the extent of formation of discrete chromosome-like structures correlates with the level of endogenous topo II present in the interphase nuclei. Our results further suggest that chromatin condensation in this extract may involve two processes: chromatin compaction and resolution into discrete chromosomes.

Identification of a heat shock promoter in the topA gene of Escherichia coli

The transcriptional activity of the topA gene which codes for topoisomerase I was examined. An in vitro assay determined that the P1 promoter was dependent on the sigma 32 subunit of RNA polymerase. The transcriptional activity of the four topA promoters was examined by nuclease S1 mapping of the transcripts during a heat shock. This sigma 32-dependent promoter was shown to function as a heat shock promoter, although topoisomerase I is not a heat shock protein. A possible method of compensation of transcription activity by the other promoters to maintain the level of topoisomerase I during heat shock is proposed.

A protein factor from Xenopus oocytes with simian virus 40 large tumor antigen-like DNA supercoiling activity

The ATP-dependent movement of simian virus 40 large tumor antigen on DNA can cause positive supercoiling of template DNA in the presence of bacterial DNA topoisomerase I, which specifically relaxes negative supercoils. With such a supercoiling assay, an activity capable of ATP-dependent, positive supercoiling of DNA in the presence of bacterial DNA topoisomerase I was found in 7S particles prepared from Xenopus laevis oocytes but not in purified transcription factor IIIA. The positive supercoils accumulated during the reaction are strained, as evidenced by their sensitivity to eukaryotic DNA topoisomerase I. Purification of this activity led to the identification of a DNA-dependent ATPase. Molar excess of transcription factor IIIA or spermidine was found to strongly stimulate the supercoiling reaction of the purified ATPase. These results suggest that this DNA-dependent ATPase can interact with and translocate along closed-circular duplex DNA, producing local alterations in the supercoiled state of the DNA template in a manner analogous to that of simian virus 40 large tumor antigen.

Local sequence requirements for DNA cleavage by mammalian topoisomerase II in the presence of doxorubicin

Doxorubicin, a DNA-intercalator, is one of several anti-cancer drugs that have been found to stabilizes topoisomerase II cleavage complexes at drug-specific DNA sites. The distribution and DNA sequence environments of doxorubicin-stabilized sites were determined in the SV40 genome. The sites were found to be most concentrated in the major nuclear matrix-associated region and nearly absent in the vicinity of the replication origin including the enhancer sequences in the 21-bp and 72-bp tandem repeats. Among 97 doxorubicin-stabilized sites that were localized at the DNA sequence level, none coincided with any of the 90 topoisomerase II cleavage sites detected in the same regions in the absence of drug. Cleavage at the 90 enzyme-only sites was inhibited by doxorubicin and never stimulated even at low drug concentrations. All of the doxorubicin-stabilized sites had an A at the 3' terminus of at least one member of each pair of strand breaks that would constitute a topoisomerase II double-strand scission. Conversely, none of the enzyme-only sites had an A simultaneously at the corresponding positions on opposite strands. The 3'-A requirement for doxorubicin-stabilized cleavage is therefore incompatible with enzyme-only cleavage and explains the mutual exclusivity of the two classes of sites.

Induction of RNA-stabilized DNA conformers by transcription of an immunoglobulin switch region

A deletion DNA rearrangement is associated with immunoglobulin class switching from IgM to IgG, IgA or IgE This recombination occurs in immunoglobulin switch regions, which are complex, highly repetitive regions of DNA. As switch regions become transcriptionally active just before switch recombination, analysis of the behaviour of these sequences during transcription could elucidate the mechanism of switch recombination. Here, we report that transcription of a supercoiled plasmid containing the murine IgA switch region (S alpha) leads to a loss of superhelical turns. The resulting series of less supercoiled plasmids is stabilized by RNA-DNA hybrids formed by the nascent RNA transcripts, which remain base-paired with their DNA templates.

Selection for mutations in the PR promoter of bacteriophage lambda

Insertion of DNA containing PR, the early rightward promoter of bacteriophage lambda, is lethal to M13-derived vectors when the promoter directs transcription (using the '+' strand as template) toward the M13 origin of replication (ori). Lethality can be relieved by mutation of PR, repression of the promoter by the lambda cl repressor, or by insertion of a strong transcription terminator between PR and ori. We have used selection for plaque formation in the absence of repressor to isolate 14 different mutations at 8 sites in PR. This method of isolating promoter mutants in vivo is applicable generally to strong promoters whose activity is regulated either positively or negatively.

Template supercoiling by a chimera of yeast GAL4 protein and phage T7 RNA polymerase

Fusion of the DNA-binding domain of yeast GAL4 protein to the amino terminus of bacteriophage T7 RNA polymerase yields a chimera that retains the characteristics of its components. The presence of the GAL4 peptide allows the chimeric enzyme to anchor itself on the DNA template, and this anchoring in turn drives the formation of a supercoiled DNA loop, in linear or circular templates, when RNA synthesis at the polymerase site forces a translocation of the DNA relative to the site. Nonspecific interaction between the chimeric enzyme and DNA appears to be sufficient to effect supercoiling during transcription. Transcription by the chimeric polymerase is strictly dependent on the presence of a T7 promoter; thus it provides a tool in vitro and in vivo for specifically supercoiling DNA segments containing T7 promoter sequences.

Supercoil-induced unusual DNA structures as transcriptional block

The transcriptional activity of pBR322 form V DNA template, a topologically unlinked, highly supercoiled molecule having unusual structures around or within coding regions was studied. Significant transcription was observed in vitro from this template despite high levels of supercoiling. An attenuated transcript, initiated accurately from the P4 promoter of rep gene, was observed which indicated pausing of E. coli RNA polymerase within the gene. This pausing could be removed by relieving the torsional stress implying that a supercoil induced structural alteration within the gene was acting as a transcriptional block. A stabilized unusual structure, most likely a cruciform, was found to be responsible for the elongation block. Absence of initiation from the tetR gene was correlated with the unusual structure present within its promoter region in form V DNA. These in vitro studies show that structural alterations within natural DNA could act as transcriptional blocks both at the level of initiation and elongation.

The pyrimidine/purine-biased region of the epidermal growth factor receptor gene is sensitive to S1 nuclease and may form an intramolecular triplex

The pyrimidine/purine-biased region located upstream of the EGF (epidermal growth factor) receptor gene transcription initiation sites was sensitive to S1 nuclease when under superhelical tension. The structural basis of this specific reactivity to S1 nuclease was probed by the use of diethyl pyrocarbonate. The patterns of modification suggested that the H-form proposed by Mirkin, Lyamichev, Drushlyak, Dobrynin, Filippov & Frank-Kamenetskii [Nature (London) (1987) 330, 495-497], which includes an intramolecular triplex and a single-stranded region, was the most plausible model for the sequence tested. The results of dimethyl sulphate modification also supported this model.

Archaebacterial reverse gyrase cleavage-site specificity is similar to that of eubacterial DNA topoisomerases I

ATP-dependent type I topoisomerases from extremely thermophilic archaebacteria--reverse gyrases--drive positive supercoiling of DNA. We showed that reverse gyrase from Desulfurococcus amylolyticus breaks the DNA at specific sites and covalently binds to the 5' end. In 30 out of 31 sites located in pBR322 DNA fragments, cleavage occurs at the sequence 5'---CNNN/---(N is any base). The same rule was previously shown to hold for single-stranded DNA breakage by eubacterial topoisomerases I. The relative cleavage frequencies at different sites depend on Mg2+ and temperature. We discuss the possible physiological and mechanistic role of the above specificity of the bacterial topoisomerases I.

Histone hyperacetylation can induce unfolding of the nucleosome core particle

A direct correlation exists between the level of histone H4 hyperacetylation induced by sodium butyrate and the extent to which nucleosomes lose their compact shape and become elongated (62.0% of the particles have a length/width ratio over 1.6; overall mean in the length/width ratio = 1.83 +/- 0.48) when bound to electron microscope specimen grids at low ionic strength (1mM EDTA, 10mM Tris, pH 8.0). A marked proportion of elongated core particles is also observed in the naturally occurring hyperacetylated chicken testis chromatin undergoing spermatogenesis when analyzed at low ionic strength (36.8% of the particles have a length/width ratio over 1.6). Core particles of elongated shape (length/width ratio over 1.6) generated under low ionic strength conditions are absent in the hypoacetylated chicken erythrocyte chromatin and represent only 2.3% of the untreated Hela S3 cell core particles containing a low proportion of hyperacetylated histones. The marked differences between control and hyperacetylated core particles are absent if the particles are bound to the carbon support film in the presence of 0.2 M NaCl, 6mM MgCl2 and 10mM Tris pH 8.0, conditions known to stabilize nucleosomes. A survey of the published work on histone hyperacetylation together with the present results indicate that histone hyperacetylation does not produce any marked disruption of the core particle 'per se', but that it decreases intranucleosomal stabilizing forces as judged by the lowered stability of the hyperacetylated core particle under conditions of shearing stress such as cationic competition by the carbon support film of the EM grid for DNA binding.

Effect of in vitro transcription on cruciform stability

We have investigated the effect of in vitro transcription on cruciform stability. Replicative form DNA of phiX174 strain ins6240, containing a 48 bp synthetic palindrome in the J-F intercistronic region, was supercoiled in vitro to mean negative superhelical densities (sigma) ranging from 0 to 0.15. The presence of cruciforms was probed by limited digestion with the single-strand specific nuclease Bal31. The 48 bp palindrome was extruded at a mean sigma = -0.05, but only after heating the DNA. An in vitro transcription reaction with E. coli RNA polymerase and [alpha-32P]UTP gave identical transcripts with heated or unheated template DNA. The synthetic cruciform was stable upon binding of the RNA polymerase to the template, but it was destabilized upon movement of the transcription complex along the template. Transcription of unheated templates did not result in cruciform formation. We propose that cruciform structures in supercoiled template DNAs present no hindrance to RNA polymerase, and thus have no detectable effect on transcription elongation in vitro.

DNA topoisomerase dysfunction: a new goal for antitumor chemotherapy

Topoisomerase enzymes--found in prokaryotes to human cells--control conformational changes in DNA and aid the orderly progression of DNA replication, gene transcription and the separation of daughter chromosomes at cell division. Several classes of anti-cancer drugs are now recognised as topoisomerase poisons because of their ability to trap topoisomerase molecules on DNA as 'cleavable complexes'. Understanding how drugs generate such complexes and why they are toxic to actively growing cancer cells is a major challenge for the development of modern approaches to chemotherapy.

Transcription of adenovirus and HeLa cell genes in the presence of drugs that inhibit topoisomerase I and II function

The requirements for topoisomerases in transcription of adenovirus and HeLa cell genes were analyzed using drugs that specifically inhibit either topoisomerases I or II. Cleavage of viral DNA by topoisomerases in the presence of either camptothecin or VM26 was used to determine drug concentrations that led to maximal inhibition of ligation in the cleavage and ligation step of topoisomerase I or II respectively. Inhibition of topoisomerase II with VM26 did not cause a direct reduction in transcription of adenoviral genes or HeLa cell heat shock genes. VM26 did, however, interfere with other cellular processes. It reduced nucleoside uptake into HeLa cells from the medium, and it altered the normal nuclear to cytoplasmic ratio of specific RNAs. Treatment of cells with camptothecin to inhibit topoisomerase I reduced but did not abolish transcription of viral and HeLa cell genes. Transcription mediated by both RNA polymerases I and II was reduced. Topoisomerase II did not appear to substitute for topoisomerase I in transcription since treatment of cells with VM26 and camptothecin did not reduce transcript accumulation relative to cells treated with camptothecin alone.

Nucleotide excision repair in Escherichia coli

One of the best-studied DNA repair pathways is nucleotide excision repair, a process consisting of DNA damage recognition, incision, excision, repair resynthesis, and DNA ligation. Escherichia coli has served as a model organism for the study of this process. Recently, many of the proteins that mediate E. coli nucleotide excision have been purified to homogeneity; this had led to a molecular description of this repair pathway. One of the key repair enzymes of this pathway is the UvrABC nuclease complex. The individual subunits of this enzyme cooperate in a complex series of partial reactions to bind to and incise the DNA near a damaged nucleotide. The UvrABC complex displays a remarkable substrate diversity. Defining the structural features of DNA lesions that provide the specificity for damage recognition by the UvrABC complex is of great importance, since it represents a unique form of protein-DNA interaction. Using a number of in vitro assays, researchers have been able to elucidate the action mechanism of the UvrABC nuclease complex. Current research is devoted to understanding how these complex events are mediated within the living cell.

Involvement of topoisomerases in replication, transcription, and packaging of the linear adenovirus genome

The role of topoisomerases in the replication of human adenovirus type 5 was investigated with topoisomerase inhibitors. Both topoisomerase I and topoisomerase II inhibitors blocked adenovirus replication when added at the time of infection. Both types of inhibitors induced strand cleavages at specific sites in the adenovirus early templates. The cleavage sites were mapped near the 5' and 3' ends of the genes transcribed early during infection. At late times after infection, camptothecin, a topoisomerase I inhibitor, inhibited adenovirus DNA replication and induced the formation of single- and double-stranded fragments with breakpoints located at defined regions of the viral genome. The topoisomerase II inhibitors, VP-16 (etoposide) and ellipticine, did not block adenovirus DNA replication and did not induce an appreciable amount of double-strand cleavages in the newly synthesized DNA. On the other hand, VP-16 promoted double-strand cleavages at specific sites of nonreplicating adenovirus DNA. The packaging of adenovirus DNA into virus particles, which contain supercoiled adenovirus DNA (M.-L. Wong and M.-T. Hsu, Nucleic Acids Res. 17:3535-3550, 1989), was inhibited by the topoisomerase II inhibitors. Transcription of adenovirus major late genes was inhibited by both topoisomerase I and topoisomerase II inhibitors. In addition, camptothecin caused a premature termination of major late transcription. Electron microscopic analysis showed that adenovirus templates late after infection were arranged in topologically constrained loop domains. Together, these data provide evidence for the requirement of topoisomerase activities in the replication, transcription, and packaging of the linear adenovirus genome.

Rapid induction of c-fos transcription reveals quantitative linkage of RNA polymerase II and DNA topoisomerase I enzyme activities

The functional association between DNA topoisomerase I and gene activity has been analyzed using the tightly regulated c-fos proto-oncogene, which undergoes rapid transitions between active and inactive states of transcription. We show that the topoisomerase I inhibitor camptothecin can be used to measure topoisomerase I activity throughout the transcription cycle of the c-fos gene. Upon induction of c-fos transcription in the presence of camptothecin, topoisomerase I cleavages spread through the gene in the 5' to 3' direction and concomitantly transcriptional elongation is retarded. Parallel kinetic measurements of RNA polymerase II activity and topoisomerase I activity demonstrate a quantitative and temporal link between the two enzymes. Our results argue that topoisomerase I quantitatively relieves the torsional consequences of transcriptional elongation in intact cells.

On the biological role of histone acetylation

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