Inhibition of transcription in eukaryotic cells by X-irradiation: relation to the loss of topological constraint in closed DNA loops

Intercalation of small molecules into DNA in chromatin is primarily controlled by superhelical constraint

The restricted access of regulatory factors to their binding sites on DNA wrapped around the nucleosomes is generally interpreted in terms of molecular shielding exerted by nucleosomal structure and internucleosomal interactions. Binding of proteins to DNA often includes intercalation of hydrophobic amino acids into the DNA. To assess the role of constrained superhelicity in limiting these interactions, we studied the binding of small molecule intercalators to chromatin in close to native conditions by laser scanning cytometry. We demonstrate that the nucleosome-constrained superhelical configuration of DNA is the main barrier to intercalation. As a result, intercalating compounds are virtually excluded from the nucleosome-occupied regions of the chromatin. Binding of intercalators to extranucleosomal regions is limited to a smaller degree, in line with the existence of net supercoiling in the regions comprising linker and nucleosome free DNA. Its relaxation by inducing as few as a single nick per ~50 kb increases intercalation in the entire chromatin loop, demonstrating the possibility for long-distance effects of regulatory potential.

Influence of Different Irradiation Protocols on Vascularization and Bone Formation Parameters in Rat Femora

Aim of the present study was the establishment of an efficient and reproducible model for irradiation of rat femora as a model for impaired osteogenesis and angiogenesis. Four different irradiation protocols were compared: single irradiation of the left femur with 20 Gy and explantation after 4 or 8 weeks (group A, B) and three irradiation fractions at 3-4 days intervals with 10 Gy and explantation after 4 or 8 weeks (group C, D). The contralateral, unirradiated femur served as control. Evaluation included histology, microcomputertomography (μCT), and real-time polymerase chain reaction. Histology showed a pronounced increase of vacuoles in bone marrow after irradiation, especially after 4 weeks (group A and C), demonstrating bone marrow edema and fatty degeneration. Irradiation provoked a decrease of total cell numbers in cortical bone and of hypoxia-inducible factor 1 alpha (HIF1α)-positive cells in bone marrow. The expression of several markers (osteocalcin [OCN], runt-related transcription factor 2 [RUNX2], transforming growth factor beta 1 [TGFβ1], tumor necrosis factor alpha [TNFα], vascular endothelial growth factor A [VEGFA], and HIF1α) was decreased in group A after irradiation. This might suggest a decreased metabolism after irradiation. A significant decrease in small-sized vessels was seen in μCT evaluation in group A and D. Single irradiation with 20 Gy had the most severe and reproducible impact on osteogenesis and angiogenesis after 4 weeks while being well tolerated by all animals, thus making it an excellent model for evaluation of bone healing and vascularization in irradiated tissue.

DNA conformational transitions induced by supercoiling control transcription in chromatin

Regulation of transcription in eukaryotes is considered in the light of recent findings demonstrating the presence of negative and positive superhelical tension in chromatin. This tension induces conformational transitions in DNA duplex. Particularly, the transition into A-form renders DNA accessible and waylaying for initiation of transcription producing RNA molecules long known to belong to the A-conformation. Competition between conformational transitions in various DNA sequences for the energy of elastic spring opens a possibility for understanding of fine tuning of transcription at a distance.

Repair of DNA strand breaks in a minichromosome in vivo: kinetics, modeling, and effects of inhibitors

To obtain an overall picture of the repair of DNA single and double strand breaks in a defined region of chromatin in vivo, we studied their repair in a ∼170 kb circular minichromosome whose length and topology are analogous to those of the closed loops in genomic chromatin. The rate of repair of single strand breaks in cells irradiated with γ photons was quantitated by determining the sensitivity of the minichromosome DNA to nuclease S1, and that of double strand breaks by assaying the reformation of supercoiled DNA using pulsed field electrophoresis. Reformation of supercoiled DNA, which requires that all single strand breaks have been repaired, was not slowed detectably by the inhibitors of poly(ADP-ribose) polymerase-1 NU1025 or 1,5-IQD. Repair of double strand breaks was slowed by 20–30% when homologous recombination was supressed by KU55933, caffeine, or siRNA-mediated depletion of Rad51 but was completely arrested by the inhibitors of nonhomologous end-joining wortmannin or NU7441, responses interpreted as reflecting competition between these repair pathways similar to that seen in genomic DNA. The reformation of supercoiled DNA was unaffected when topoisomerases I or II, whose participation in repair of strand breaks has been controversial, were inhibited by the catalytic inhibitors ICRF-193 or F11782. Modeling of the kinetics of repair provided rate constants and showed that repair of single strand breaks in minichromosome DNA proceeded independently of repair of double strand breaks. The simplicity of quantitating strand breaks in this minichromosome provides a usefull system for testing the efficiency of new inhibitors of their repair, and since the sequence and structural features of its DNA and its transcription pattern have been studied extensively it offers a good model for examining other aspects of DNA breakage and repair.

DNA of a circular minichromosome linearized by restriction enzymes or other reagents is resistant to further cleavage: an influence of chromatin topology on the accessibility of DNA

The accessibility of DNA in chromatin is an essential factor in regulating its activities. We studied the accessibility of the DNA in a ∼170 kb circular minichromosome to DNA-cleaving reagents using pulsed-field gel electrophoresis and fibre-fluorescence in situ hybridization on combed DNA molecules. Only one of several potential sites in the minichromosome DNA was accessible to restriction enzymes in permeabilized cells, and in growing cells only a single site at an essentially random position was cut by poisoned topoisomerase II, neocarzinostatin and γ-radiation, which have multiple potential cleavage sites; further sites were then inaccessible in the linearized minichromosomes. Sequential exposure to combinations of these reagents also resulted in cleavage at only a single site. Minichromosome DNA containing single-strand breaks created by a nicking endonuclease to relax any unconstrained superhelicity was also cut at only a single position by a restriction enzyme. Further sites became accessible after ≥95% of histones H2A, H2B and H1, and most non-histone proteins were extracted. These observations suggest that a global rearrangement of the three-dimensional packing and interactions of nucleosomes occurs when a circular minichromosome is linearized and results in its DNA becoming inaccessible to probes.

Impaired repair of ionizing radiation-induced DNA damage in Cockayne syndrome cells

Cockayne syndrome (CS) cells are defective in transcription-coupled repair (TCR) and sensitive to oxidizing agents, including ionizing radiation. We examined the hypothesis that TCR plays a role in ionizing radiation-induced oxidative DNA damage repair or alternatively that CS plays a role in transcription elongation after irradiation. Irradiation with doses up to 100 Gy did not inhibit RNA polymerase II-dependent transcription in normal and CS-B fibroblasts. In contrast, RNA polymerase I-dependent transcription was severely inhibited at 5 Gy in normal cells, indicating different mechanisms of transcription response to X rays. The frequency of radiation-induced base damage was 2 × 10(-7) lesions/base/Gy, implying that 150 Gy is required to induce one lesion/30-kb transcription unit; no TCR of X-ray-induced base damage in the p53 gene was observed. Therefore, it is highly unlikely that defective TCR underlies the sensitivity of CS to ionizing radiation. Overall genome repair levels of radiation-induced DNA damage measured by repair replication were significantly reduced in CS-A and CS-B cells. Taken together, the results do not provide evidence for a key role of TCR in repair of radiation-induced oxidative damages in human cells; rather, impaired repair of oxidative lesions throughout the genome may contribute to the CS phenotype.

Portrait of transcriptional responses to ultraviolet and ionizing radiation in human cells

To understand the human response to DNA damage, we used microarrays to measure transcriptional responses of 10 000 genes to ionizing radiation (IR) and ultraviolet radiation (UV). To identify bona fide responses, we used cell lines from 15 individuals and a rigorous statistical method, Significance Analysis of Microarrays (SAM). By exploring how sample number affects SAM, we rendered a portrait of the human damage response with a degree of accuracy unmatched by previous studies. By showing how SAM can be used to estimate the total number of responsive genes, we discovered that 24% of all genes respond to IR and 32% respond to UV, although most responses were less than 2-fold. Many genes were involved in known damage-response pathways for cell cycling and proliferation, apoptosis, DNA repair or the stress response. However, the majority of genes were involved in unexpected pathways, with functions in signal transduction, RNA binding and editing, protein synthesis and degradation, energy metabolism, metabolism of macromolecular precursors, cell structure and adhesion, vesicle transport, or lysosomal metabolism. Although these functions were not previously associated with the damage response in mammals, many were conserved in yeast. These insights reveal new directions for studying the human response to DNA damage.

DNA topology in heterochromatin (a hypothesis)

A hypothesis explaining the known heterochromatin features--a compact DNA packaging, transcriptional inactivity, propensity to aggregate (stickiness) and position effect variegation-is described. The hypothesis is based on the assumption that DNA molecules in heterochromatin are topologically open and contain single-strand breaks in the regions with identical or similar primary sequences.

Psoralen cross-linking as probe of torsional tension and topological domain size in vivo

DNA within a cell is organized with unrestrained torsional tension, and each molecule is divided into multiple individual topological domains. Psoralen photobinding can be used as an assay for supercoiling and topological domain size in living cells. Psoralen photobinds to DNA at a rate nearly linearly proportional to superhelical density. Comparison of the rate of photobinding to supercoiled and relaxed DNA in cells provides a measure of superhelical density. For this, in vivo superhelical tension is relaxed by the introduction of nicks by either ionizing radiation or photolysis of bromodeoxyuridine in the DNA. Since nicks are introduced in a random fashion, the distribution of nicks is described by a Poisson distribution. Thus, after nicking, the fraction of topological domains containing no nicks is described by the zero term of the Poisson distribution. From measurement of the number of nicks introduced in the DNA and the fraction of torsional tension remaining, an average topological domain size can be estimated. Using this logic, procedures were designed and described for measuring supercoiling and domain size at specific sites in eukaryotic genomes.

Inhibition of RNA polymerase II as a trigger for the p53 response

The mechanisms by which the p53 response is triggered following exposure to DNA-damaging agents have not yet been clearly elucidated. We and others have previously suggested that blockage of RNA polymerase II may be the trigger for induction of the p53 response following exposure to ultraviolet light. Here we report on the correlation between inhibition of mRNA synthesis and the induction of p53, p21WAF1 and apoptosis in diploid human fibroblasts treated with either UV light, cisplatin or the RNA synthesis inhibitors actinomycin D, DRB, H7 and alpha-amanitin. Exposure to ionizing radiation or the proteasome inhibitor LLnL, however, induced p53 and p21WAF1 without affecting mRNA synthesis. Importantly, induction of p53 by the RNA synthesis or proteasome inhibitors did not correlate with the induction of DNA strand breaks. Furthermore, cisplatin-induced accumulation of active p53 in repair-deficient XP-A cells occurred despite the lack of DNA strand break induction. Our results suggest that the induction of the p53 response by certain toxic agents is not triggered by DNA strand breaks but rather, may be linked to inhibition of mRNA synthesis either directly by the poisoning of RNA polymerase II or indirectly by the induction of elongation-blocking DNA lesions.

Template topology and transcription: chromatin templates relaxed by localized linearization are transcriptionally active in yeast

To address the role of transient torsional stress in transcription, we have utilized the regulated expression of HO endonuclease in yeast to create double-strand breaks in DNA templates in vivo at preselected sites. Linearization of circular minichromosomes, either 2 kb upstream or immediately downstream of a lacZ reporter gene controlled by the yeast metallothionein gene (CUP1) promoter, did not alter the copper induction profile of lacZ RNA transcripts compared to that of nonlinearized controls. Constructs site-specifically integrated into yeast chromosome II gave similar results. In vivo cross-linking with psoralen as a probe for negative DNA supercoiling demonstrated that template linearization efficiently dissipated DNA supercoiling induced by transcription. Therefore, the efficient transcription of linearized, relaxed templates found here demonstrates that transient torsional tension is not required for transcription of chromatin templates in yeast.

Scaffold/matrix-attached regions: structural properties creating transcriptionally active loci

The expression characteristics of the human interferon-beta gene, as part of a long stretch of genomic DNA, led to the discovery of the putative domain bordering elements. The chromatin structure of these elements and their surroundings was determined during the process of gene activation and correlated with their postulated functions. It is shown that these "scaffold-attached regions" (S/MAR elements) have some characteristics in common with and others distinct from enhancers with which they cooperate in various ways. Our model of S/MAR function will focus on their properties of mediating topological changes within the respective domain.

Recognition and alignment of homologous DNA sequences between minichromosomes and single-stranded DNA promoted by RecA protein

The incorporation of DNA into nucleosomes and higher-order forms of chromatin in vivo creates difficulties with respect to its accessibility for cellular functions such as transcription, replication, repair and recombination. To understand the role of chromatin structure in the process of homologous recombination, we have studied the interaction of nucleoprotein filaments, comprised of RecA protein and ssDNA, with minichromosomes. Using this paradigm, we have addressed how chromatin structure affects the search for homologous DNA sequences, and attempted to distinguish between two mutually exclusive models of DNA-DNA pairing mechanisms. Paradoxically, we found that the search for homologous sequences, as monitored by unwinding of homologous or heterologous duplex DNA, was facilitated by nucleosomes, with no discernible effect on homologous pairing. More importantly, unwinding of minichromosomes required the interaction of nucleoprotein filaments and led to the accumulation of circular duplex DNA sensitive to nuclease P1. Competition experiments indicated that chromatin templates and naked DNA served as equally efficient targets for homologous pairing. These and other findings suggest that nucleosomes do not impede but rather facilitate the search for homologous sequences and establish, in accordance with one proposed model, that unwinding of duplex DNA precedes alignment of homologous sequences at the level of chromatin. The potential application of this model to investigate the role of chromosomal proteins in the alignment of homologous sequences in the context of cellular recombination is considered.

Presence of negative torsional tension in the promoter region of the transcriptionally poised dihydrofolate reductase gene in vivo

DNA topology has been suggested to play an important role in the process of transcription. Negative torsional tension has been shown to stimulate both pre-initiation complex formation and promoter clearance on plasmid DNA in vitro. We recently showed that genomic DNA in human cells contains localized torsional tension. In the present study we have further characterized and mapped torsional tension in the dihydrofolate reductase (DHFR) gene in Chinese hamster ovary (CHO) cells and investigated the effects of differential rates of transcription on the magnitude and location of this tension. Using psoralen photo-cross-linking in conjunction with X-irradiation, we found that relaxable psoralen hypersensitivity was specifically localized to the promoter region of the serum-regulated DHFR gene in serum-stimulated, but not in serum-starved, cells. Moreover, this hypersensitivity did not appear to be caused by transcription elongation, since it persisted in cells in which transcription of the DHFR gene had been reduced by the transcription inhibitor 5,6-dichloro-1-beta-D-ribofurano-sylbenzimidazole (DRB). We suggest that the generation of negative torsional tension in DNA may play an important role in gene regulation by poising genes for transcription.

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.

DNA strand breaks: the DNA template alterations that trigger p53-dependent DNA damage response pathways

The tumor suppressor protein p53 serves as a critical regulator of a G1 cell cycle checkpoint and of apoptosis following exposure of cells to DNA-damaging agents. The mechanism by which DNA-damaging agents elevate p53 protein levels to trigger G1/S arrest or cell death remains to be elucidated. In fact, whether damage to the DNA template itself participates in transducing the signal leading to p53 induction has not yet been demonstrated. We exposed human cell lines containing wild-type p53 alleles to several different DNA-damaging agents and found that agents which rapidly induce DNA strand breaks, such as ionizing radiation, bleomycin, and DNA topoisomerase-targeted drugs, rapidly triggered p53 protein elevations. In addition, we determined that camptothecin-stimulated trapping of topoisomerase I-DNA complexes was not sufficient to elevate p53 protein levels; rather, replication-associated DNA strand breaks were required. Furthermore, treatment of cells with the antimetabolite N(phosphonoacetyl)-L-aspartate (PALA) did not cause rapid p53 protein increases but resulted in delayed increases in p53 protein levels temporally correlated with the appearance of DNA strand breaks. Finally, we concluded that DNA strand breaks were sufficient for initiating p53-dependent signal transduction after finding that introduction of nucleases into cells by electroporation stimulated rapid p53 protein elevations. While DNA strand breaks appeared to be capable of triggering p53 induction, DNA lesions other than strand breaks did not. Exposure of normal cells and excision repair-deficient xeroderma pigmentosum cells to low doses of UV light, under conditions in which thymine dimers appear but DNA replication-associated strand breaks were prevented, resulted in p53 induction attributable to DNA strand breaks associated with excision repair. Our data indicate that DNA strand breaks are sufficient and probably necessary for p53 induction in cells with wild-type p53 alleles exposed to DNA-damaging agents.

DNA strand breaks: the DNA template alterations that trigger p53-dependent DNA damage response pathways

The tumor suppressor protein p53 serves as a critical regulator of a G1 cell cycle checkpoint and of apoptosis following exposure of cells to DNA-damaging agents. The mechanism by which DNA-damaging agents elevate p53 protein levels to trigger G1/S arrest or cell death remains to be elucidated. In fact, whether damage to the DNA template itself participates in transducing the signal leading to p53 induction has not yet been demonstrated. We exposed human cell lines containing wild-type p53 alleles to several different DNA-damaging agents and found that agents which rapidly induce DNA strand breaks, such as ionizing radiation, bleomycin, and DNA topoisomerase-targeted drugs, rapidly triggered p53 protein elevations. In addition, we determined that camptothecin-stimulated trapping of topoisomerase I-DNA complexes was not sufficient to elevate p53 protein levels; rather, replication-associated DNA strand breaks were required. Furthermore, treatment of cells with the antimetabolite N(phosphonoacetyl)-L-aspartate (PALA) did not cause rapid p53 protein increases but resulted in delayed increases in p53 protein levels temporally correlated with the appearance of DNA strand breaks. Finally, we concluded that DNA strand breaks were sufficient for initiating p53-dependent signal transduction after finding that introduction of nucleases into cells by electroporation stimulated rapid p53 protein elevations. While DNA strand breaks appeared to be capable of triggering p53 induction, DNA lesions other than strand breaks did not. Exposure of normal cells and excision repair-deficient xeroderma pigmentosum cells to low doses of UV light, under conditions in which thymine dimers appear but DNA replication-associated strand breaks were prevented, resulted in p53 induction attributable to DNA strand breaks associated with excision repair. Our data indicate that DNA strand breaks are sufficient and probably necessary for p53 induction in cells with wild-type p53 alleles exposed to DNA-damaging agents.

Influence of amsacrine (m-AMSA) on bulk and gene-specific DNA damage and c-myc expression in MCF-7 breast tumor cells

In the MCF-7 human breast tumor cell line, the aminoacridine, m-AMSA, induces protein-associated DNA strand breaks consistent with inhibition of topoisomerase II. However, neither single-strand nor double-strand breaks in DNA, determined using conventional assays, show a consistent relationship with m-AMSA-induced inhibition of growth. In contrast, when DNA strand breaks are determined by alkaline unwinding under the high salt conditions of the alkaline unwinding/Southern blotting (AU/SB) assay, developed by our laboratories, damage to DNA corresponds closely with growth inhibition. The AU/SB assay, which is capable of assessing breaks within large-scale domains (upwards of 1 megabase) surrounding genes of interest, was further utilized to explore the capacity of m-AMSA to induce damage within specific genomic regions that may regulate cell growth. Regions encompassing the transcriptionally active oncogenes, c-myc and c-fos, were found to be more susceptible to m-AMSA-induced strand breaks than the region encompassing the non-transcribed alpha-satellite DNA or the genome as a whole (bulk DNA). These findings demonstrate that m-AMSA may produce more pronounced damage within specific genomic regions than in bulk DNA, m-AMSA also preferentially altered expression of the c-myc oncogene; at an m-AMSA concentration where growth was inhibited by between 70 and 80%, steady-state c-myc mRNA levels declined to approximately 10-15% of control levels within 2-3 hr; furthermore, concentration-dependent reductions in c-myc expression appeared to coincide with growth inhibition. In addition, inhibition of [3H]thymidine incorporation after 2 hr directly paralleled inhibition of growth, suggesting an early effect at the level of DNA biosynthesis, possibly related to the down-regulation of c-myc expression. It is proposed that specific lesions, e.g., in regions surrounding the c-myc gene, as well as generalized lesions in DNA may lead to growth inhibition mediated by down-regulation of the expression of select growth regulatory genes, such as c-myc.

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.

Relationship of histone acetylation to DNA topology and transcription

An autonomously replicating plasmid constructed from bovine papiloma virus (BPV) and pBR322 was stably maintained as a nuclear episome in a mouse cell culture. Addition to a cell culture of sodium butyrate (5 mM) induced an increase in plasmid DNA supercoiling of 3-5 turns, an increase in acetylation of cellular histones, and a decrease in plasmid transcription by 2- to 4-fold. After withdrawal of butyrate, DNA supercoiling began to fluctuate in a wave-like manner with an amplitude of up to 3 turns and a period of 3-4 h. These waves gradually faded by 24 h. The transcription of the plasmid and acetylation of cellular histones also oscillated with the same period. The wave-like alterations were not correlated with the cell cycle, for there was no resumption of DNA replication after butyrate withdrawal for at least 24 h. In vitro chemical acetylation of histones with acetyl adenylate also led to an increase in the superhelical density of plasmid DNA. The parallel changes in transcription, histone acetylation, and DNA supercoiling in vivo may indicate a functional innerconnection. Also, the observed in vivo variation in the level of DNA supercoiling directly indicates the possibility of its natural regulation in eukaryotic cells.

High rotational mobility of DNA in animal cells and its modulation by histone acetylation

DNA rotational mobility in a bovine papilloma virus (BPV)-based minichromosome, autonomously replicating in mouse cells, was studied using topoisomer analysis in temperature shift experiments. It was found that in live cells the average number of topological turns increased by six in the course of temperature shift through a range of 37 degrees C. This comprised approximately 85% of the total potential mobility of naked plasmid DNA. DNA rotation in isolated nuclei was found to be 3.5-4.0 turns per 37 degrees C in 100 mM NaCl - much higher than in all experiments with animal cells reported thus far. In low salt mobility was considerably lowered. Attempts to extract minichromosomes from nuclei allowed isolation of no more than 10% of minichromosomal DNA, with could indicate a very high proportion of transcriptionally active minichromosomes in the intracellular population. Growing cells in the presence of sodium butyrate resulted not only in an increase in the level of plasmid superhelicity and a decrease of its transcription (as we report in the accompanying publication) but also reduced rotational mobility of plasmid DNA threefold (from 6 to 2 turns per 37 degrees C). The decrease in DNA rotational mobility after butyrate treatment was also partially manifested in isolated nuclei (especially at lower ionic strength). To check whether histone acetylation is directly responsible for DNA immobilization, we performed in vitro acetylation of histones using acetyl adenylate. This resulted in severe DNA immobilization in experiments using both up and down temperature shifts.

Positive DNA supercoiling generates a chromatin conformation characteristic of highly active genes

During transcription, positive DNA supercoils generated ahead of RNA polymerase could theoretically uncoil the negative DNA supercoils associated with nucleosomes and thereby decondense the chromatin fiber in preparation for RNA polymerase passage. Here we examine the effect of positive DNA supercoiling on the structure of yeast 2-microns minichromosomes. We utilized a conditional topoisomerase mutant expressing Escherichia coli topoisomerase I to convert the DNA supercoiling state from negative to positive in vivo. Minichromosomes containing positively supercoiled DNA exhibited a striking increase in DNase I sensitivity. They also displayed additional micrococcal nuclease cleavage sites but yielded nearly typical nucleosomal ladders after extensive digestion. Upon in vitro relaxation with eukaryotic topoisomerase I, the minichromosomes remained DNase I sensitive but were converted to negative DNA supercoiling with a slightly increased linking number compared to typical minichromosomes, thus indicating the presence of bound histones. Therefore, positive DNA supercoiling provides a mechanism for generating, but is not required for maintaining, a conformation in chromatin characteristic of highly transcribed genes.

A. E. Braunstein Plenary Lecture. Nuclear skeleton, DNA domains and control of replication and transcription

Chromosomal DNA is organized in loops or domains of about 100 kb. Their ends seem to be attached to special protein skeletal structures. The DNA-attachment sites can be subdivided into permanent and transient types. The permanent or constitutive attachment sites, which are retained in all types of cells (including those inactive in replication and transcription), either coincide with or are located close to replication origins. This observation provides a simple way for isolation of DNA fragments containing replication origins. Such fragments from the chicken alpha-globin gene domain and other regions of the chicken genome contain DNA sequences which interact with nuclear proteins present in dividing cells, but absent from non-dividing cells. Several new consensus sequences interacting with nuclear proteins were detected. The 5' end region of the alpha-globin gene domain containing a replication origin was found to possess enhancer activity lacking tissue specificity. Hence, the domain organization of DNA is related to the organization of replication process. Other sets of data indicate that the integrity of DNA domains is important for maintaining transcription within the domain. According to these data, even a single nick at an distance of about 100 kbp seems to be sufficient for blocking transcription within the whole domain at the stage of RNA elongation. Thus, topological integrity of DNA may be an important factor involved in formation of active chromatin.

Relationship of eukaryotic DNA replication to committed gene expression: general theory for gene control

The historic arguments for the participation of eukaryotic DNA replication in the control of gene expression are reconsidered along with more recent evidence. An earlier view in which gene commitment was achieved with stable chromatin structures which required DNA replication to reset expression potential (D. D. Brown, Cell 37:359-365, 1984) is further considered. The participation of nonspecific stable repressor of gene activity (histones and other chromatin proteins), as previously proposed, is reexamined. The possible function of positive trans-acting factors is now further developed by considering evidence from DNA virus models. It is proposed that these positive factors act to control the initiation of replicon-specific DNA synthesis in the S phase (early or late replication timing). Stable chromatin assembles during replication into potentially active (early S) or inactive (late S) states with prevailing trans-acting factors (early) or repressing factors (late) and may asymmetrically commit daughter templates. This suggests logical schemes for programming differentiation based on replicons and trans-acting initiators. This proposal requires that DNA replication precede major changes in gene commitment. Prior evidence against a role for DNA replication during terminal differentiation is reexamined along with other results from terminal differentiation of lower eukaryotes. This leads to a proposal that DNA replication may yet underlie terminal gene commitment, but that for it to do so there must exist two distinct modes of replication control. In one mode (mitotic replication) replicon initiation is tightly linked to the cell cycle, whereas the other mode (terminal replication) initiation is not cell cycle restricted, is replicon specific, and can lead to a terminally differentiated state. Aberrant control of mitotic and terminal modes of DNA replication may underlie the transformed state. Implications of a replicon basis for chromatin structure-function and the evolution of metazoan organisms are considered.

Chromatin structure of the developmentally regulated early histone genes of the sea urchin Strongylocentrotus purpuratus

Chromatin organization of the early histone gene repeat was studied at the early embryonic stages of the sea urchin S. purpuratus. Micrococcal nuclease digestion showed a highly irregular packaging of the whole repeat at the period of transcriptional activity, which was progressively replaced by more regular nucleosomal arrays upon developmentally programmed inactivation. No evidence for unique positioning of the nucleosomes was found. Regions upstream of each of the genes were hypersensitive to DNAase I digestion in the active state. These regions contained one (H2A and H2B), or two (H3 and H4) well-defined DNAase I cutting sites, or two poorly-defined sites (H1). They mapped within DNA sequences shown previously to be required for proper expression of the genes. Hypersensitivity continued in the hatching blastula, which have a conventional nucleosomal structure and a much reduced transcriptional activity. Hypersensitivity of these regions during morula and early blastula was not dependent on the torsional strain in chromatin, as it was not influenced by extensive gamma ray-induced nicking of the DNA in nuclei. By late blastula no hypersensitive regions were present.

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.

Structure of transcriptionally active chromatin: radiological evidence for requirement of torsionally constrained DNA

Synthesis of alpha- and beta-globin RNA in DMSO-induced Friend's erythroleukemia cells and synthesis of immunoglobulin gamma- and kappa-chain RNA, total RNA, 5S RNA, and tRNA in mouse myeloma cells (MPC-11) was inhibited by gamma-irradiation. For all RNA species, synthesis decreased nearly exponentially as a function of radiation dose, whereas RNA size distributions, turnover rates, and specific activities of radioactively labeled RNA were affected only insignificantly. D37 values for the loss of synthesis of various RNA species correspond to target sizes ranging from 21,000 to 53,000 kd, or 30-80 kbp of DNA. These target sizes are several-fold larger than the structural genes in question; however, they correspond well with the size of DNA loops, or "domains" constrained by the nuclear matrix. The data suggest that the eukaryotic transcription unit is the torsionally constrained chromatin loop, transcription of which may be inactivated, or significantly reduced by a DNA single-strand break.

Supercoiling of intracellular DNA can occur in eukaryotic cells

The supercoiling of 2 micron DNA in yeast by a process or processes that generate positively and negatively supercoiled domains was shown by the use of yeast DNA topoisomerase mutants expressing Escherichia coli DNA topoisomerase I, an enzyme that relaxes negative supercoils specifically. Intracellular 2 micron DNA becomes positively supercoiled in yeast top1 top2 ts strains expressing the E. coli enzyme when neither one of the yeast DNA topoisomerases I and II is functional. Examination of the linking number distributions of plasmids bearing the inducible promoters of GAL1 and GAL10 genes indicates that the generation of supercoiled domains of opposite signs is related to transcription.

Compositional patterns in vertebrate genomes: conservation and change in evolution

The evolution of vertebrate genomes can be investigated by analyzing their regional compositional patterns, namely the compositional distributions of large DNA fragments (in the 30-100-kb size range), of coding sequences, and of their different codon positions. This approach has shown the existence of two evolutionary modes. In the conservative mode, compositional patterns are maintained over long times (many million years), in spite of the accumulation of enormous numbers of base substitutions. In the transitional, or shifting, mode, compositional patterns change into new ones over much shorter times. The conservation of compositional patterns, which has been investigated in mammalian genomes, appears to be due in part to some measure of compositional conservation in the base substitution process, and in part to negative selection acting at regional (isochore) levels in the genome and eliminating deviations from a narrow range of values, presumably corresponding to optimal functional properties. On the other hand, shifts of compositional patterns, such as those that occurred between cold-blooded and warm-blooded vertebrates, appear to be due essentially to both negative and positive selection again operating at the isochore level, largely under the influence of changes in environmental conditions, and possibly taking advantage of mutational biases in the replication/repair enzymes and/or in the enzyme make-up of nucleotide precursor pools. Other events (like translocations and changes in chromosomal structure) also play a role in the transitional mode of genome evolution. The present findings (1) indicate that isochores, which correspond to the DNA segments of individual or contiguous chromatin domains, represent selection units in the vertebrate genome; and (2) shed new light on the selectionist-neutralist controversy.