Supercoiling of intracellular DNA can occur in eukaryotic cells

The topoisomerase I gene from Ustilago maydis: sequence, disruption and mutant phenotype

The Ustilago maydis genomic TOP1 gene encoding DNA topoisomerase I was cloned by amplifying a gene fragment using the polymerase chain reaction, and using this fragment to search a genomic DNA library by hybridization. The predicted peptide sequence exhibited 30-40% identity to other eukaryotic TOP1 genes, yet differed in several features. First, an unusually long acidic region was identified near the amino terminus (28/29 residues are acidic), which resembles other nucleolar peptide motifs. Second, an atypical carboxy-terminal 'tail', absent in other TOP1 genes, followed the active site tyrosine residue. A top1 gene disruption mutant was constructed by replacing the genomic TOP1 gene, with a top1::HygR null allele. This mutant lost the abundant topoisomerase I activity evident in wild-type U.maydis, and displayed a subtle coloration phenotype evident during cell senescence.

Intramolecular recombination in polyomavirus DNA is a nonconservative process directed from the viral intergenic region

Previously, we have studied intramolecular homologous recombination in polyomavirus replicons under conditions allowing only one amplifiable recombination product to be generated from a single precursor molecule. In order to detect putative reciprocal product(s), we have now constructed precursor polyomavirus replicons which contain two copies, instead of one copy, of the viral intergenic region, including the origin of replication as well as both promoters. Upon transfection of mouse cells, constructs containing directly repeated intergenic regions yielded distinct amplifiable products, in number depending upon the functional integrity of both intergenic regions. Our data indicate that of two possible reciprocal products, a given precursor molecule would yield either one or the other but never both at the same time. Most striking, however, is the observation that promoter function is required for recombination, while the origin of replication function may be needed only for amplification of the recombination product once it has been formed. The data reported here confirm and extend previous data suggesting that (i) transcription is instrumental in recombination between direct repeats and (ii) nonconservative recombination involving direct repeats relies upon two promoters of opposing polarities.

The C-terminal domain of Saccharomyces cerevisiae DNA topoisomerase II

A set of carboxy-terminal deletion mutants of Saccharomyces cerevisiae DNA topoisomerase II were constructed for studying the functions of the carboxyl domain in vitro and in vivo. The wild-type yeast enzyme is a homodimer with 1,429 amino acid residues in each of the two polypeptides; truncation of the C terminus to Ile-1220 has little effect on the function of the enzyme in vitro or in vivo, whereas truncations extending beyond Gln-1138 yield completely inactive proteins. Several mutant enzymes with C termini in between these two residues were found to be catalytically active but unable to complement a top2-4 temperature-sensitive mutation. Immunomicroscopy results suggest that the removal of a nuclear localization signal in the C-terminal domain is likely to contribute to the physiological dysfunction of these proteins; the ability of these mutant proteins to relax supercoiled DNA in vivo shows, however, that at least some of the mutant proteins are present in the nuclei in a catalytically active form. In contrast to the ability of the catalytically active mutant proteins to relax supercoiled intracellular DNA, all mutants that do not complement the temperature-dependent lethality and high frequency of chromosomal nondisjunction of top2-4 were found to lack decatenation activity in vivo. The plausible roles of the DNA topoisomerase II C-terminal domain, in addition to providing a signal for nuclear localization, are discussed in the light of these results.

Dynamics of the interactions of histones H2A,H2B and H3,H4 with torsionally stressed DNA

The interactions of histones H2A,H2B and H3,H4 with closed circular DNA maintained in either a positively or negatively coiled state have been studied. The interactions were assayed by measuring the rate at which negative stress was stored in the DNA by the histones and by the salt concentration sufficient to cause dissociation on sucrose gradients. Additional experiments were performed in which DNAs of substantially different molecular weights and opposite topological states were mixed with the histones in order to study histone mobility under varied conditions. This mobility was characterized by separating the complexes on sucrose gradients and by analyzing the DNA's topological state after topoisomerase I treatment. Histones H3,H4 were found to differ substantially from histones H2A,H2B with regard to the DNA topology with which they prefer to interact. The results are consistent with a model in which transcription-induced positive stress in advance of the RNA polymerase unfolds the nucleosome to facilitate the release of H2A,H2B. The data are also consistent with a model in which histones H3,H4 remain associated with the DNA during polymerase passage and serve as a nucleation site for the reassociation of H2A,H2B. The rapid production of transcription-induced negative stress in the wake of a polymerase would have substantial importance in facilitating the reassociation of histones H2A,H2B.

Conformational information in DNA: its role in the interaction with DNA topoisomerase I and nucleosomes

Information in DNA is not limited to sequence information. Both local and global conformational parameters are pivotal to the interaction with a number of relevant proteins. The function of the major components of the transcription machinery (RNA polymerase II, DNA topoisomerase I, nucleosomes, the TATA-binding factor) is dependent on the topological status of the substrate DNA molecule. The topological requirements and the conformational consensus that dictate the rules for localization of nucleosomes and define the active sites for DNA topoisomerase I have been established; the reaction of DNA topoisomerase I is regulated by a topological feedback mechanism. The integrating function of the free energy of supercoiling in the transcription process and the regulatory role of DNA topoisomerase I are discussed.

The C-terminal domain of Saccharomyces cerevisiae DNA topoisomerase II

A set of carboxy-terminal deletion mutants of Saccharomyces cerevisiae DNA topoisomerase II were constructed for studying the functions of the carboxyl domain in vitro and in vivo. The wild-type yeast enzyme is a homodimer with 1,429 amino acid residues in each of the two polypeptides; truncation of the C terminus to Ile-1220 has little effect on the function of the enzyme in vitro or in vivo, whereas truncations extending beyond Gln-1138 yield completely inactive proteins. Several mutant enzymes with C termini in between these two residues were found to be catalytically active but unable to complement a top2-4 temperature-sensitive mutation. Immunomicroscopy results suggest that the removal of a nuclear localization signal in the C-terminal domain is likely to contribute to the physiological dysfunction of these proteins; the ability of these mutant proteins to relax supercoiled DNA in vivo shows, however, that at least some of the mutant proteins are present in the nuclei in a catalytically active form. In contrast to the ability of the catalytically active mutant proteins to relax supercoiled intracellular DNA, all mutants that do not complement the temperature-dependent lethality and high frequency of chromosomal nondisjunction of top2-4 were found to lack decatenation activity in vivo. The plausible roles of the DNA topoisomerase II C-terminal domain, in addition to providing a signal for nuclear localization, are discussed in the light of these results.

Transcription, topoisomerases and recombination

Transcription, DNA topoisomerases and genetic recombination are interrelated for several structural reasons. Transcription can affect DNA topology, resulting in effects on recombination. It can also affect the chromatin structure in which the DNA resides. Topoisomerases can affect DNA and/or chromatin structure influencing the recombination potential at a given site. Here we briefly review the extent to which homologous direct repeat recombination and site-specific recombination in eukaryotes are affected by transcription and topoisomerases. In some cases, transcription or the absence of topoisomerases have little or no effect on recombination. In others, they are important components in the recombinational process. The common denominator of any effects of transcription and topoisomerases on recombination is their shared role in altering DNA topology.

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.

Yeast Saccharomyces cerevisiae as a model system to study the cytotoxic activity of the antitumor drug camptothecin

Eukaryotic DNA topoisomerase I catalyzes the relaxation of positively and negatively supercoiled DNA and plays a critical role in processes involving DNA, such as DNA replication, transcription and recombination. The enzyme is encoded by the TOP1 gene and is highly conserved in its amino acid sequence and sensitivity to the anti-neoplatic agent camptothecin. This plant alkaloid specifically targets DNA topoisomerase I by reversibly stabilizing the covalent enzyme-DNA intermediate. Presumably, it is the interaction of these drug-stabilized adducts with other cellular components, such as replication forks, that actually produces the DNA lesions leading to cell death. A conservation of the mechanism(s) of camptothecin-induced cell killing is also implicit in studies of the yeast Saccharomyces cerevisiae, where the camptothecin sensitivity of delta TOP1 yeast cells can be restored by plasmids expressing either yeast or human TOP1 sequences. This genetically tractable system is currently being exploited to describe the specific molecular interactions required for the cytotoxic action of camptothecin. The results of mutational analyses of yeast and human DNA topoisomerase I are presented, as well as a genetic screen designed to identify genes, other than TOP1, that are required for the cytotoxic activity of camptothecin.

DNA topoisomerase I controls the kinetics of promoter activation and DNA topology in Saccharomyces cerevisiae

Inactivation of the nonessential TOP1 gene, which codes for Saccharomyces cerevisiae DNA topoisomerase I, affects the rate of transcription starting at the ADH2 promoter. For both the chromosomal gene and the plasmid-borne promoter, mRNA accumulation is kinetically favored in the mutant relative to a wild-type isogenic strain. The addition of ethanol causes in wild-type yeast strains a substantial increase in linking number both on the ADH2-containing plasmid and on the resident 2 microns DNA. Evidence has been obtained that such an in vivo increase in linking number depends on (i) the activity of DNA topoisomerase I and of no other enzyme and (ii) ethanol addition, not on the release from glucose repression. A direct cause-effect relationship between the change in supercoiling and alteration of transcription cannot be defined. However, the hypothesis that a metabolism-induced modification of DNA topology in a eukaryotic cell plays a role in regulating gene expression is discussed.

Identification of barriers to rotation of DNA segments in yeast from the topology of DNA rings excised by an inducible site-specific recombinase

Controlled excision of DNA segments to yield intracellular DNA rings of well-defined sequences was utilized to study the determinants of transcriptional supercoiling of closed circular DNA in the yeast Saccharomyces cerevisiae. In delta top1 top2ts strains of S. cerevisiae expressing Escherichia coli DNA topoisomerase I, accumulation of positive supercoils in intracellular DNA normally occurs upon thermal inactivation of DNA topoisomerase II because of the simultaneous generation of positively and negatively supercoiled domains by transcription and the preferential relaxation of the latter by the bacterial enzyme. Positive supercoil accumulation in DNA rings is shown to depend on the presence of specific sequence elements; one likely cause of this dependence is that the persistence of oppositely supercoiled domains in an intracellular DNA ring requires the presence of barriers to rotation of the DNA segments connecting the domains. Analysis of the S. cerevisiae 2-microns plasmid partition system by this approach suggests that the plasmid-encoded REP1 and REP2 proteins are involved in forming such a barrier in DNA containing the REP3 sequence.

DNA topoisomerase I controls the kinetics of promoter activation and DNA topology in Saccharomyces cerevisiae

Inactivation of the nonessential TOP1 gene, which codes for Saccharomyces cerevisiae DNA topoisomerase I, affects the rate of transcription starting at the ADH2 promoter. For both the chromosomal gene and the plasmid-borne promoter, mRNA accumulation is kinetically favored in the mutant relative to a wild-type isogenic strain. The addition of ethanol causes in wild-type yeast strains a substantial increase in linking number both on the ADH2-containing plasmid and on the resident 2 microns DNA. Evidence has been obtained that such an in vivo increase in linking number depends on (i) the activity of DNA topoisomerase I and of no other enzyme and (ii) ethanol addition, not on the release from glucose repression. A direct cause-effect relationship between the change in supercoiling and alteration of transcription cannot be defined. However, the hypothesis that a metabolism-induced modification of DNA topology in a eukaryotic cell plays a role in regulating gene expression is discussed.

Modulation of antitumor alkylating agents by novobiocin, topotecan, and lonidamine

Topoisomerase I and topoisomerase II allow a metabolically active cell to mobilize its supercoiled chromosomal DNA and undergo replication, transcription, recombination, and repair. Several topoisomerase inhibitors have recently been shown to be active in preclinical systems. Topotecan (SK&F 104,864), a water-soluble camptothecin analog, is an inhibitor of topoisomerase I. Novobiocin is an inhibitor of topoisomerase II. Lonidamine depletes cellular adenosine 5'-triphosphate (ATP) and may impede energy-dependent DNA repair, MCF-7 human breast-cancer cells were treated in vitro with topotecan, novobiocin, and lonidamine alone, in paired combinations, and in combination with CDDP and melphalan. The three enzyme inhibitors alone and in combination did not increase tumor cell sensitivity to CDDP. However, the combinations of topotecan/novobiocin and lonidamine/novobiocin did enhance the cytotoxicity of melphalan. Mice bearing the FSaII fibrosarcoma were treated in vivo with topotecan, novobiocin, and lonidamine alone, in paired combinations, and in combination with CDDP, melphalan, BCNU, and cyclophosphamide. The combination of topotecan/novobiocin had the greatest impact on tumor cell sensitivity to each cytotoxic agent tested in both tumor cell-survival and tumor growth-delay assays. This sensitization was greatest at the highest concentrations of the cytotoxic agent tested. Combinations of topoisomerase I and topoisomerase II inhibitors may be useful as modulators of antitumor alkylating agents.

The localization of topoisomerase II cleavage sites on DNA in the presence of antitumor drugs

Type II topoisomerase are enzymes that break and religate DNA phosphodiester bonds while crossing over DNA strands and altering DNA topology. They also are structural proteins that play a role in the spatial organization of chromatin and are involved in several crucial biological functions, such as DNA replication and transcription, chromosome segregation and recombination. Many drugs interfere with type II topoisomerases and can be assigned to two groups. Coumarin derivatives and synthetic quinolones act at the level of ATP binding or hydrolysis and are used for controlling bacterial infections. Drugs belonging to the second group produce DNA lesions by trapping a "cleavable complex" consisting of the normal transient topoisomerase II-DNA reaction intermediate in which the enzyme and the DNA are joined by two covalent bonds. There are four main categories of antitumour drugs that form cleavable complexes in eukaryotes: acridines, anthracyclines, ellipticines and epipodophyllotoxins. These drugs are cytotoxic and many--but not all--are endowed with antitumoral properties. The mechanisms of this pharmacological activity are not understood. Topoisomerase II-induced DNA breaks generated from cleavable complexes display different levels of cytotoxicity depending on their localization on DNA. The primary structure of DNA is not the only parameter that determines this localization. The spatial organization of the enzyme-DNA complex and both the topology and the structure of the underlying chromatin fiber constitute additional critical factors. It, therefore, may be unrealistic to expect that the actual pharmacological potency of antitumor drugs that act on type II topoisomerases can be accurately predicted solely on the basis of simple in vitro test tube experiments carried out using pure enzymes and naked DNA.

Transcription-dependent recombination induced by triple-helix formation

The homologous recombination between direct repeat sequences separated by either 200 or 1000 bp was induced by active transcription of the downstream gene when poly(dG)-poly(dC) sequences exist between the two direct repeats. This dG tract-mediated and transcription-induced recombination was RecA independent, and the frequency of recombination was dependent on both the length and the orientation of the poly(dG)-poly(dC) sequences relative to the gene. An intramolecular dG.dG.dC triplex formation was detected in Escherichia coli cells in a length-dependent manner when the transcription of the downstream gene was activated. We suggest that the negative superhelical strain generated by active transcription of the downstream gene induces poly(dG)-poly(dC) sequences to adopt a triple-helix structure in vivo and that this structure brings two remote sequences together to stimulate homologous recombination.

Transcribed heteroplasmic repeated sequences in the porcine mitochondrial DNA D-loop region

The mitochondrial D-loop region of the pig, Sus scrofa, was found to be several hundred base pairs larger than the corresponding region in cow, a related artiodactyl species, primarily because of an insertion containing the tandemly repeated sequence CGTGCGTACA. Porcine mitochondrial DNA from the tissue of a single animal exhibits a large population of length polymorphs, each member of which may have as few as 14 or as many as 29 of these repeat units. This intracellular variability may be due to the repeated and self-complementary properties of this sequence, which would favor mispairing and lead to replication slippage. The repeat domain is unusual in that symmetry properties suggest it may assume alternative conformations including cruciforms and left-handed (Z) DNA. It also appears to be the longest known, naturally occurring, alternating purine-pyrimidine sequence. In order to understand the functional significance of this heteroplasmic domain that potentially disrupts a key regulatory region in the mitochondrial genome, RNA and DNA mapping studies were conducted which located this region between the H-strand replication origin and the putative L-strand transcriptional start site. H-strand RNA analysis demonstrated that this heteroplasmic region is transcribed and, therefore, that priming for H-strand DNA replication in mitochondria is independent of the primer RNA length or secondary structure.

Three downstream sites repress transcription of a Ty2 retrotransposon in Saccharomyces cerevisiae

Transcription of Ty1 and Ty2 retrotransposons of the yeast Saccharomyces cerevisiae is modulated by multiple downstream regulatory sites. Both transposon families include a positively acting site within the transcribed region which resembles a higher eukaryotic enhancer. We have demonstrated the existence of a repression site distal to the enhancer of the Ty2-917 element. Here we describe experiments investigating the internal structure of this site. We show that this 200-bp region includes three distinct repression sites which we term DRSI (downstream repression site I), DRSII, and DRSIII. Individually each site causes almost twofold repression, and together the sites repress eightfold. Unexpectedly, when the entire region encompassing the DRS sites is moved outside the transcription unit, it acts as a qualitatively positively acting element. In this context the DRS sites still repress transcription, since eliminating them increases transcription further. That the region can activate transcription implies that it includes activation sites in addition to the three repression sites. The change from qualitatively negatively acting to positively acting must reflect a change in the relative effects of the multiple positive and negative sites; when moved outside the transcription unit, the activators predominate. Importantly, DRSII and DRSIII repress transcription autonomously when inserted upstream of a heterologous promoter activated by the transcriptional activator GCN4, showing that they are indeed transcriptional repression sites.

The specific interactions of HMG 1 and 2 with negatively supercoiled DNA are modulated by their acidic C-terminal domains and involve cysteine residues in their HMG 1/2 boxes

Sedimentation and gel retardation studies show a stronger interaction of HMG 1 and 2 with negatively supercoiled DNA than with linear, nicked-circular, or positively supercoiled ds-DNA. An apparent unwinding angle of 58 degrees was obtained for HMG 1 and 2 when assayed by protection of negatively supercoiled DNA from topoisomerase I relaxation or when assayed by the supercoiling of nicked-circular DNA with T4 DNA ligase. The protection of negatively supercoiled DNA was linear up to molar ratios of about 250:1. There was little change in binding reactions or in the protection of supercoiled DNA at ratios above 250:1, indicating that both activities saturate and that HMG 1 and 2 have binding site sizes of about 20 bp. P1, the major tryptic fragment of HMG 1 or 2 which retains the two DNA binding HMG 1/2 boxes, displays a 2-fold increase in binding to all types of ds-DNA compared to intact HMG 1 or 2. However P1 protects negatively supercoiled DNA from topoisomerase I relaxation about 5-fold less than intact HMG 1 or 2. Complete protection with P1 occurs at a molar ratio 1040:1, indicating a DNA binding site size of about 4 bp and an apparent unwinding angle of 10 degrees. P1 binding to closed-circular ss-DNA also involves a binding site of about 4 bp. Adding the acidic C-terminal fragment to P1 reversed its binding and allowed topoisomerase I to relax supercoiled DNA. These findings highlight the importance of the acidic C-terminal domains of HMG 1 and 2 in limiting electrostatic interactions of the HMG 1/2 boxes with ds- or ss-DNA. N-Ethylmaleimide inhibited the binding of intact HMG 1 or 2 to negatively supercoiled DNA, but did not inhibit the electrostatic binding of HMG 1 or 2 to ss-DNA, or of P1 to any form of DNA (ds or ss). These results suggest that cysteine residues are involved in the specific interaction of HMG 1 or 2 with negatively supercoiled DNA and that the acidic C-terminal domains modulate an intramolecular conformational change involving sulfhydryls within the HMG 1/2 boxes.

Transcription-driven site-specific DNA recombination in vitro

Transcription of a topologically relaxed, circular DNA triggers recombination between two directly repeated res sites by gamma delta resolvase in vitro. This activation of recombination depends on the res site-to-site distance and the orientation of sites with respect to the direction of RNA polymerase tracking. In addition to functioning as a site-specific recombinase, gamma delta resolvase acts as a site-specific topoisomerase and increases the topological linking number of templates during transcription. The data suggest that the link between transcription and recombination could be negative DNA supercoiling that transiently builds up on a relatively short DNA segment in the wake of an advancing RNA polymerase. Surprisingly, transcription-driven recombination is not inhibited by the presence of large amounts of eukaryotic topoisomerase type I, indicating that site-specific recombination can override relaxation by diffusible topoisomerases. This in vitro system might therefore serve as a model for some transcription-directed recombination events observed in vivo.

Three downstream sites repress transcription of a Ty2 retrotransposon in Saccharomyces cerevisiae

Transcription of Ty1 and Ty2 retrotransposons of the yeast Saccharomyces cerevisiae is modulated by multiple downstream regulatory sites. Both transposon families include a positively acting site within the transcribed region which resembles a higher eukaryotic enhancer. We have demonstrated the existence of a repression site distal to the enhancer of the Ty2-917 element. Here we describe experiments investigating the internal structure of this site. We show that this 200-bp region includes three distinct repression sites which we term DRSI (downstream repression site I), DRSII, and DRSIII. Individually each site causes almost twofold repression, and together the sites repress eightfold. Unexpectedly, when the entire region encompassing the DRS sites is moved outside the transcription unit, it acts as a qualitatively positively acting element. In this context the DRS sites still repress transcription, since eliminating them increases transcription further. That the region can activate transcription implies that it includes activation sites in addition to the three repression sites. The change from qualitatively negatively acting to positively acting must reflect a change in the relative effects of the multiple positive and negative sites; when moved outside the transcription unit, the activators predominate. Importantly, DRSII and DRSIII repress transcription autonomously when inserted upstream of a heterologous promoter activated by the transcriptional activator GCN4, showing that they are indeed transcriptional repression sites.

Local domains of supercoiling activate a eukaryotic promoter in vivo

Experiments correlating template topology with transcriptional activity suggest that DNA topology plays a role in eukaryotic gene expression. Linear templates transfected into cultured cells produce far fewer transcripts than do circular transcription templates, and no transcripts can be detected from linear templates injected into Xenopus oocytes. Further, when transcriptionally active circular templates in Xenopus oocytes are linearized by injection of a restriction enzyme, transcription dramatically decreases. Here we show that transcription by phage T7 RNA polymerase from a divergent promoter can partially replace the requirement for circular Xenopus ribosomal RNA transcription templates in Xenopus oocytes. Supercoiled domains can apparently be generated on short pieces of DNA having no known sequences that result in association with the nuclear architecture, suggesting that localized, transient domains of supercoiling fulfil the minimum topological needs for Xenopus rRNA transcription in vivo.

The polyomavirus enhancer activates chromatin accessibility on integration into the HPRT gene

Recent studies suggest that enhancers may increase the accessibility of chromatin to transcription factors. To test the effects of a viral enhancer on chromatin accessibility, we have inserted minigenes with or without the polyomavirus enhancer into the third exon of the hypoxanthine phosphoribosyltransferase (HPRT) gene by homologous recombination and have prepared high-resolution maps of gene accessibility by using a novel polymerase chain reaction assay for DNase I sensitivity. In its native state, we find that the HPRT gene has low sensitivity to DNase I in fibrosarcoma cells. Insertion of the polyomavirus enhancer and neo reporter gene into exon 3 confers altered HPRT DNase I sensitivity for several kilobases on either side of the enhancer. The changes in DNase I sensitivity peak near the enhancer and decline with distance from the enhancer. The increase in HPRT DNase I sensitivity persisted when the tk promoter was deleted from the inserted construct but disappeared when the enhancer was deleted. These experiments identify the polyomavirus enhancer as a cis-acting initiator of chromatin accessibility.

Positive supercoiling of DNA greatly diminishes mRNA synthesis in yeast

In Saccharomyces cerevisiae cells harboring a GAL1 promoter-linked beta-galactosidase gene, the simultaneous expression of Escherichia coli DNA topoisomerase I and inactivation of yeast DNA topoisomerases I and II reduces the cellular level of beta-galactosidase to an undetectable level. Analysis of intracellular mRNA level and the density of RNA polymerase along DNA indicates that this reduction is due to the suppression of transcription and that both plasmid-borne and chromosomally located genes are affected. These results are interpreted in terms of inhibition of transcription in vivo due to positive supercoiling of the DNA template: preferential removal of transcription-generated negative supercoils by E. coli DNA topoisomerase I in the absence of both yeast DNA topoisomerases I and II results in the accumulation of positive supercoils in intracellular DNA. In normal prokaryotic or eukaryotic cells, accumulation of positive supercoils is presumably avoided through the balanced actions of DNA topoisomerases.

The polyomavirus enhancer activates chromatin accessibility on integration into the HPRT gene

Recent studies suggest that enhancers may increase the accessibility of chromatin to transcription factors. To test the effects of a viral enhancer on chromatin accessibility, we have inserted minigenes with or without the polyomavirus enhancer into the third exon of the hypoxanthine phosphoribosyltransferase (HPRT) gene by homologous recombination and have prepared high-resolution maps of gene accessibility by using a novel polymerase chain reaction assay for DNase I sensitivity. In its native state, we find that the HPRT gene has low sensitivity to DNase I in fibrosarcoma cells. Insertion of the polyomavirus enhancer and neo reporter gene into exon 3 confers altered HPRT DNase I sensitivity for several kilobases on either side of the enhancer. The changes in DNase I sensitivity peak near the enhancer and decline with distance from the enhancer. The increase in HPRT DNase I sensitivity persisted when the tk promoter was deleted from the inserted construct but disappeared when the enhancer was deleted. These experiments identify the polyomavirus enhancer as a cis-acting initiator of chromatin accessibility.

Dynamics of DNA supercoiling by transcription in Escherichia coli

The relative rotation between RNA polymerase and DNA during transcription elongation can lead to supercoiling of the DNA template. However, the variables that influence the efficiency of supercoiling by RNA polymerase in vivo are poorly understood, despite the importance of supercoiling for DNA metabolism. We describe a model system to measure the rate of supercoiling by transcription and to estimate the rates of topoisomerase turnover in Escherichia coli. Transcription in a strain lacking topoisomerase I can lead to optimal supercoiling, wherein nearly one positive and one negative superturn are produced for each 10.4 base pairs transcribed. This rapid efficient supercoiling is observed during transcription of membrane-associated gene products, encoded by tet (the gene for tetracycline resistance) and phoA (the gene for E. coli alkaline phosphatase), when the genes are oppositely oriented. Replacement of tet by cat, the gene from Tn9 encoding resistance to chloramphenicol, whose gene product is soluble in the cytosol, reduces the efficiency of supercoiling by RNA polymerase. In a wild-type topoisomerase background, both gyrase and topoisomerase I are kinetically competent to relieve superturns produced by transcription. These results suggest that the level of DNA supercoiling in vivo is probably determined by topoisomerase activity, not by transcription.

A nucleosome core is transferred out of the path of a transcribing polymerase

We have determined the fate of a nucleosome core on transcription. A nucleosome core was assembled on a short DNA fragment and ligated into a plasmid containing a promoter and terminators for SP6 RNA polymerase. The nucleosome core was stable in the absence of transcription. The distribution of nucleosome cores after transcription was examined. The histone octamer was displaced from its original site and reformed a nucleosome core at a new site within the same plasmid molecule, with some preference for the untranscribed region behind the promoter. These observations eliminate several models that have been proposed for transcription through a nucleosome core. Our results suggest that a nucleosome core in the path of a transcribing polymerase is displaced by transfer to the closest acceptor DNA.

Evolutionary consequences of nonrandom damage and repair of chromatin domains

Some evolutionary consequences of different rates and trends in DNA damage and repair are explained. Different types of DNA damaging agents cause nonrandom lesions along the DNA. The type of DNA sequence motifs to be preferentially attacked depends upon the chemical or physical nature of the assaulting agent and the DNA base composition. Higher-order chromatin structure, the nonrandom nucleosome positioning along the DNA, the absence of nucleosomes from the promoter regions of active genes, curved DNA, the presence of sequence-specific binding proteins, and the torsional strain on the DNA induced by an increased transcriptional activity all are expected to affect rates of damage of individual genes. Furthermore, potential Z-DNA, H-DNA, slippage, and cruciform structures in the regulatory region of some genes or in other genomic loci induced by torsional strain on the DNA are more prone to modification by genotoxic agents. A specific actively transcribed gene may be preferentially damaged over nontranscribed genes only in specific cell types that maintain this gene in active chromatin fractions because of (1) its decondensed chromatin structure, (2) torsional strain in its DNA, (3) absence of nucleosomes from its regulatory region, and (4) altered nucleosome structure in its coding sequence due to the presence of modified histones and HMG proteins. The situation in this regard of germ cell lineages is, of course, the only one to intervene in evolution. Most lesions in DNA such as those caused by UV or DNA alkylating agents tend to diminish the GC content of genomes. Thus, DNA sequences not bound by selective constraints, such as pseudogenes, will show an increase in their AT content during evolution as evidenced by experimental observations. On the other hand, transcriptionally active parts may be repaired at rates higher than inactive parts of the genome, and proliferating cells may display higher repair activities than quiescent cells. This might arise from a tight coupling of the repair process with both transcription and replication, all these processes taking place on the nuclear matrix. Repair activities differ greatly among species, and there is a good correlation between life span and repair among mammals. It is predicted that genes that are transcriptionally active in germ-cell lineages have a lower mutation rate than bulk DNA, a circumstance that is expected to be reflected in evolution. Exception to this rule might be genes containing potential Z-DNA, H-DNA, or cruciform structures in their coding or regulatory regions that appear to be refractory to repair.(ABSTRACT TRUNCATED AT 400 WORDS)

Localized torsional tension in the DNA of human cells

Torsional tension in DNA may be both a prerequisite for the efficient initiation of transcription and a consequence of the transcription process itself with the generation of positive torsional tension in front of the RNA polymerase and negative torsional tension behind it. To examine torsional tension in specific regions of genomic DNA in vivo, we developed an assay using photoactivated psoralen as a probe for unconstrained DNA superhelicity and x-rays as a means to relax DNA. Psoralen intercalates more readily into DNA underwound by negative torsional tension than into relaxed. DNA, and it can form interstrand DNA cross-links upon UVA irradiation. By comparing the amount of psoralen-induced DNA cross-links in cells irradiated with x-rays either before or after the psoralen treatment, we examined the topological state of the DNA in specific regions of the genome in cultured human 6A3 cells. We found that although no net torsional tension was detected in the bulk of the genome, localized tension was prominent in the DNA of two active genes. Negative torsional tension was found in the 5' end of the amplified dihydrofolate reductase gene and in a region near the 5' end of the 45S rRNA transcription unit, whereas a low level of positive torsional tension was found in a region near the 3' end of the dihydrofolate reductase gene. These results document an intragenomic heterogeneity of DNA torsional tension and lend support to the twin supercoiled domain model for transcription in the genome of intact human cells.

Topoisomerases and yeast rRNA transcription: negative supercoiling stimulates initiation and topoisomerase activity is required for elongation

Previous work has shown that rRNA synthesis is strongly inhibited in yeast top1-top2 double mutants. Here, we show that inactivation of yeast topoisomerases can have paradoxical effects on transcription by RNA polymerase I. For example, transcription of ribosomal minigenes on extrachromosomal plasmids is greatly stimulated in top1-top2 cells while accumulation of full-length endogenous rRNA is strongly inhibited. We present evidence for a mechanism that can partly account for these opposing effects on transcription. On the one hand, transcription initiation can be stimulated owing to an accumulation of negative superhelicity because polymerase I prefers to initiate on negatively supercoiled templates. Conversely, synthesis of full-length rRNA is inhibited owing to the fact that chain elongation requires a DNA relaxing activity.

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.

Biological significance of unwinding capability of nuclear matrix-associating DNAs

Matrix attachment regions (MARs) are thought to separate chromatin into topologically constrained loop domains. A MAR located 5' of the human beta-interferon gene becomes stably base-unpaired under superhelical strain, as do the MARs flanking the immunoglobulin heavy chain gene enhancer; in both cases a nucleation site exists for DNA unwinding. Concatemerized oligonucleotides containing the unwinding nucleation site exhibited a strong affinity for the nuclear scaffold and augmented SV40 promoter activity in stable transformants. Mutated concatemerized oligonucleotides resisted unwinding, showed weak affinity for the nuclear scaffold, and did not enhance promoter activity. These results suggest that the DNA feature capable of relieving superhelical strain is important for MAR functions.

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.