Effect of topological constraint on transcription of ribosomal DNA in Xenopus oocytes. Comparison of plasmid and endogenous genes

Double-strand breaks in the myotonic dystrophy type 1 and the fragile X syndrome triplet repeat sequences induce different types of mutations in DNA flanking sequences in Escherichia coli

The putative role of double-strand breaks (DSBs) created in vitro by restriction enzyme cleavage in or near CGG*CCG or CTG*CAG repeat tracts on their genetic instabilities, both within the repeats and in their flanking sequences, was investigated in an Escherichia coli plasmid system. DSBs at TRS junctions with the vector generated a large number of mutagenic events in flanking sequences whereas DSBs within the repeats elicited no similar products. A substantial enhancement in the number of mutants was caused by transcription of the repeats and by the absence of recombination functions (recA-, recBC-). Surprisingly, DNA sequence analyses on mutant clones revealed the presence of only single deletions of 0.4-1.6 kb including the TRS and the flanking sequence from plasmids originally containing (CGG*CCG)43 but single, double and multiple deletions as well as insertions were found for plasmids originally containing (CTG*CAG)n (where n = 43 or 70). Non-B DNA structures (slipped structures with loops, cruciforms, triplexes and tetraplexes) as well as microhomologies are postulated to participate in the recombination and/or repair processes.

DNA supercoiling and transcription control: a model from the study of suppression of the leu-500 mutation in Salmonella typhimurium topA- strains

DNA supercoiling is known to modulate gene expression. The functional relationship between DNA supercoiling and transcription initiation has been established genetically and biochemically. The molecular mechanism whereby DNA supercoiling regulates gene expression remains unclear however. Quite commonly, the same gene responds to the same DNA supercoiling change differently when the gene is positioned at different locations. Such strong positional effects on gene expression suggest that rather than the overall DNA supercoiling change, the variation of DNA supercoiling at a local site might be important for transcription control. We have started to understand the local DNA supercoiling dynamic on the chromosome. As a primary source of local DNA supercoiling fluctuation, transcription-driven DNA supercoiling is important in determining the chromosome supercoiling dynamic and theoretically, therefore, for transcription control as well. Indeed, by studying the coordinated expression of genes in the ilvIH-leuO-leuABCD gene cluster, we found that transcription-driven DNA supercoiling governs the expression of a group of functionally related genes in a sequential manner. Based on the findings in this model system, we put forward the possible mechanisms whereby DNA supercoiling plays its role in transcription control.

Modeling transcriptional regulation using microinjection into Xenopus oocytes

Transcriptional regulation is a complex process that requires cooperation between specific DNA sequence elements, the DNA-binding proteins that bind to these sequences, the general transcriptional machinery, and chromatin. Oocyte microinjection offers a technique to study the integrated transcription process while still providing the opportunity to experimentally perturb this process. We describe here techniques for manipulating DNA templates and the protein complement of the oocyte to study multiple facets of transcriptional regulation. We present sample results showing that the GAL4-VP16 fusion activator is sensitive to distance in constructs containing only a minimal promoter, but can activate transcription at greater distances when proximal promoter elements are present.

DNA supercoiling factor localizes to puffs on polytene chromosomes in Drosophila melanogaster

DNA supercoiling factor (SCF) was first identified in silkworm as a protein that generates negative supercoils in DNA in conjunction with eukaryotic topoisomerase II. To analyze the in vivo role of the factor, we cloned a cDNA encoding Drosophila melanogaster SCF. Northern analysis revealed 1.6- and 1.8-kb mRNAs throughout development. The longer mRNA contains an open reading frame that shares homology with mouse reticulocalbin whereas the shorter one encodes a truncated version lacking the N-terminal signal peptide-like sequence. An antibody against SCF detected a 45-kDa protein in the cytoplasmic fraction and a 30-kDa protein in the nuclear fraction of embryonic extracts. Immunoprecipitation suggests that the 30-kDa protein interacts with topoisomerase II in the nucleus, and hence that it is a functional form of SCF. Immunostaining of blastoderm embryos showed that SCF is present in nuclei during interphase but is excluded from mitotic chromosomes. In larvae, the antibody stained the nuclei of several tissues including a posterior part of the salivary gland. This latter staining was associated with natural or ecdysteroid-induced puffs on polytene chromosomes. Upon heat treatment of larvae, the staining on the endogenous puffs disappeared, and strong staining appeared on heat shock puffs. These results implicate SCF in gene expression.

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.

Positive and negative DNA sequence elements are required to establish the pattern of Pax3 expression

The transcription start site and DNA sequence elements required for the induction of Pax3 expression in differentiating P19 embryonal carcinoma cells have been localized. These elements consist of a promoter and additional elements located within 1.6 kbp 5′ to the transcription start site. Sequence elements within this 1.6 kbp region are also sufficient to mediate the induction and dorsal restriction of Pax3 in the neural tube and somites of transgenic mice throughout the hindbrain and trunk. Additional elements required for expression anterior to the hindbrain and in migrating myoblasts are located within 14 kbp 5′ to the transcription start site. This region also contains element(s) that repress Pax3 expression in the ventral body wall mesoderm of the tail bud.

DNA length is a critical parameter for eukaryotic transcription in vivo

The organization of eukaryotic chromosomes into topological domains has led to the assumption that DNA topology and perhaps supercoiling are involved in eukaryotic nuclear processes. Xenopus oocytes provide a model system for studying the role of DNA topology in transcription. Linear plasmid templates for RNA polymerases (Pols) I and II are not transcribed in Xenopus oocytes, while circular templates are transcriptionally active. Here we show that circularity is not required for transcription of Pol I or Pol II promoters if the linear template is sufficiently long (> 17 to 19 kb). The Xenopus rRNA (Pol I) promoter is active in central positions on a long linear template but is not transcribed when located near an end. Because supercoils generated by transcription could be retained by viscous drag against the long template, these results are consistent with a supercoiling requirement for this promoter. Surprisingly, the herpes simplex virus thymidine kinase (Pol II) promoter is active even 100 bp from the end of the long template, indicating that template length fulfills a critical parameter for transcription that is not consistent with a supercoiling requirement. These results show that DNA length has unrecognized importance for transcription in vivo.

Regulation of beta-globin gene expression: straightening out the locus

A casual examination of the globin literature would leave most readers with the impression that all aspects of beta-globin gene regulation are controlled by the upstream locus control region (LCR). There is no clear evidence, however, that the LCR affects transcription in the beta-globin locus other than by altering its topology to maintain it in a state permissive for expression of the globin genes. Developmental switching of the globin genes may be independent of the LCR, relying only on elements close to the genes and the arrangement of the genes with respect to each other.

Primitive streak mesoderm-like cell lines expressing Pax-3 and Hox gene autoinducing activities

Differentiating P19 embryonal carcinoma (EC) cells transiently express an endogenous activity capable of inducing Pax-3 expression in adjacent P19 stem cells (Pruitt, Development 116, 573–583, 1992). In the present study, expression of this activity in mesodermal cell lineages is demonstrated. First, expression of the mesodermal marker Brachyury correlates with expression of Pax-3-inducing activity. Second, the ability of leukemia inhibitory factor (LIF) to block mesoderm differentiation at two different points is demonstrated and correlated with the inhibition of Pax-3-inducing activity. Finally, two mesodermal cell lines that express Pax-3-inducing activity were derived from P19 EC cells. Each of these lines expresses high levels of the mesodermal marker Brachyury and high levels of Oct-3/4 (which is down-regulated at early times during mesoderm differentiation) suggesting that these lines are early mesodermal derivatives. Unlike EC or embryonic stem cell lines, each of the two mesodermal derivatives autoinduces Hox gene expression on aggregation even in the presence of LIF. Following aggregation, anterior-specific genes are expressed more rapidly than more posterior genes. These observations directly demonstrate the ability of murine mesodermal derivatives to autoinduce Hox gene expression in the absence of signals from other cell lineages. Similar to the Pax-3-inducing activity, signals from mesodermal cell lines were sufficient to induce HOX expression in adjacent P19 stem cells in cell mixing assays. These observations are consistent with the previous suggestion (Blum, M., Gaunt, S. J., Cho, K. W. Y., Steinbeisser, H., Blumberg, B., Bittner, D. and De Robertis, E. M. (1992) Cell 69, 1097–1106) that signals responsible for anterior-posterior organizer activity are localized to the anterior primitive streak mesoderm of the mouse embryo.

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.

Inhibition of topoisomerase II does not inhibit transcription of RNA polymerase I and II genes

Injection of VM-26 (teniposide) into Xenopus oocytes inhibits the activity of topoisomerase II but does not inhibit transcription by RNA polymerases I and II. A specific assay for topoisomerase II, resolution of catenated DNA molecules into product rings, was used to quantitate VM-26 inhibition in vivo. When catenanes were injected without VM-26, about 60% of them were separated into product rings in the first 5 min after injection, and decatenation of the remainder was complete within 15 min. When VM-26 was coinjected, 60% of the catenanes were separated into product rings in the first 5 min after injection, but the remaining 40% were stable over the next 40 min. At 1 h after injection catenanes were no longer detected in the gel analysis, but the increasing numbers of linear product rings indicated that topoisomerase II continued to be inhibited by VM-26. These results suggest that a short lag of approximately 5 min is required for VM-26 to inhibit topoisomerase II and that after this initial period topoisomerase II is inhibited by more than 90%. There was no detectable decrease in transcription of injected rRNA and thymidine kinase (TK) genes or in the activity of the rRNA enhancer when these transcription templates were coinjected with VM-26. The time required for assembly of injected DNA into chromatin doubled in the presence of VM-26.

Inhibition of topoisomerase II does not inhibit transcription of RNA polymerase I and II genes

Injection of VM-26 (teniposide) into Xenopus oocytes inhibits the activity of topoisomerase II but does not inhibit transcription by RNA polymerases I and II. A specific assay for topoisomerase II, resolution of catenated DNA molecules into product rings, was used to quantitate VM-26 inhibition in vivo. When catenanes were injected without VM-26, about 60% of them were separated into product rings in the first 5 min after injection, and decatenation of the remainder was complete within 15 min. When VM-26 was coinjected, 60% of the catenanes were separated into product rings in the first 5 min after injection, but the remaining 40% were stable over the next 40 min. At 1 h after injection catenanes were no longer detected in the gel analysis, but the increasing numbers of linear product rings indicated that topoisomerase II continued to be inhibited by VM-26. These results suggest that a short lag of approximately 5 min is required for VM-26 to inhibit topoisomerase II and that after this initial period topoisomerase II is inhibited by more than 90%. There was no detectable decrease in transcription of injected rRNA and thymidine kinase (TK) genes or in the activity of the rRNA enhancer when these transcription templates were coinjected with VM-26. The time required for assembly of injected DNA into chromatin doubled in the presence of VM-26.

DNA superhelicity enhances the assembly of transcriptionally active chromatin in vitro

Using an in vitro chromatin assembly system, we analyzed the influence of DNA superhelicity on the development of transcriptionally active minichromosomes. Plasmid DNA molecules containing either a Xenopus borealis 5S RNA gene or an X. laevis methionine tRNA gene were utilized as templates for the assembly of chromatin. Both plasmids were processed into active minichromosomes if introduced as supercoiled molecules into the extract (S-150). The degree of superhelicity is a determining factor in the assembly of active chromatin. Molecules containing varying superhelical densities were processed into minichromosomes with different transcriptional activities. The absence of supercoils leads to the assembly of chromatin with substantially lower transcriptional activity. Assembled minichromosomes are stable enough to be isolated by sucrose gradient centrifugation while retaining their transcriptional phenotype. The formation of nucleosomes with a periodic spacing occurred with the same efficiency and to the same degree regardless of the initial DNA topology. Hence, a determining factor in the development of transcriptionally active chromatin may be the initial superhelicity of the DNA molecule to which activator (trans-acting factors) or repressor (histones) proteins bind. Once the chromatin assembly process has begun, the transcriptional activity of the resulting minichromosome may already have been determined.

A system for the analysis of yeast ribosomal DNA mutations

To develop a system for the analysis of eucaryotic ribosomal DNA (rDNA) mutations, we cloned a complete, transcriptionally active rDNA unit from the yeast Saccharomyces cerevisiae on a centromere-containing yeast plasmid. To distinguish the plasmid-derived ribosomal transcripts from those encoded by the rDNA locus, we inserted a tag of 18 base pairs within the first expansion segment of domain I of the 26S rRNA gene. We demonstrate that this insertion behaves as a neutral mutation since tagged 26S rRNA is normally processed and assembled into functional ribosomal subunits. This system allows us to study the effect of subsequent mutations within the tagged rDNA unit on the biosynthesis and function of the rRNA. As a first application, we wanted to ascertain whether the assembly of a 60S subunit is dependent on the presence in cis of an intact 17S rRNA gene. We found that a deletion of two-thirds of the 17S rRNA gene has no effect on the accumulation of active 60S subunits derived from the same operon. On the other hand, deletions within the second domain of the 26S rRNA gene completely abolished the accumulation of mature 26S rRNA.

Effect of DNA supercoiling on in vitro transcription from the adenovirus early region 4

The effect of DNA supercoiling on in vitro transcription from the early region 4 (E4) promoter of adenovirus type 5 (Ad5) has been investigated by using a cell-free transcription system that maintains supercoiled DNA templates. The supercoiled DNAs yield several-fold higher levels of E4 transcripts and more faithfully reflect the regulation of in vivo transcription than the linear DNAs.

Changes in DNA topology can modulate in vitro transcription of certain RNA polymerase III genes

The role of DNA supercoiling in eukaryotic gene expression is not fully understood. The objective of this study was to examine the regulation of in vitro chromatin assembly by topological alterations in the DNA template using a cell-free extract from Xenopus laevis oocytes (S-150). The results suggest that input DNA topology may be a determining factor in controlling the transcriptional activity of the Xenopus tRNA and one particular 5S gene. When the input topology is supercoiled, high levels of transcription are observed, whereas input relaxed DNA is transcribed to a much lower extent. Transcription from an input relaxed template is stimulated by the addition of supercoiled nonspecific, vector DNA. Furthermore, in direct competition experiments, supercoiled DNA molecules were shown to be transcriptionally dominant over relaxed DNA molecules. Taken together, these data suggest that the efficiency with which a repressor or activator binding protein interacts with DNA may be significantly influenced by the topological status of its target. We demonstrate that modulation of reaction parameters which alter the normal topological processing events catalyzed by the S-150 can dramatically influence the level of gene expression.

A system for the analysis of yeast ribosomal DNA mutations

To develop a system for the analysis of eucaryotic ribosomal DNA (rDNA) mutations, we cloned a complete, transcriptionally active rDNA unit from the yeast Saccharomyces cerevisiae on a centromere-containing yeast plasmid. To distinguish the plasmid-derived ribosomal transcripts from those encoded by the rDNA locus, we inserted a tag of 18 base pairs within the first expansion segment of domain I of the 26S rRNA gene. We demonstrate that this insertion behaves as a neutral mutation since tagged 26S rRNA is normally processed and assembled into functional ribosomal subunits. This system allows us to study the effect of subsequent mutations within the tagged rDNA unit on the biosynthesis and function of the rRNA. As a first application, we wanted to ascertain whether the assembly of a 60S subunit is dependent on the presence in cis of an intact 17S rRNA gene. We found that a deletion of two-thirds of the 17S rRNA gene has no effect on the accumulation of active 60S subunits derived from the same operon. On the other hand, deletions within the second domain of the 26S rRNA gene completely abolished the accumulation of mature 26S rRNA.

Supercoiled loop organization of genomic DNA: a close relationship between loop domains, expression units, and replicon organization in rDNA from Xenopus laevis

Analysis of the organization of a specific chromosomal gene, the gene for rRNA in Xenopus laevis, has evidenced a close relationship between loop organization, replication organization, and expression units. The nontranscribed spacer appears to be involved in all three levels of organization. Furthermore the replication origin region appears to be involved in nuclear matrix anchorage and is closely related to the 40 S transcription promoter. This organization suggests how expression domains may be regulated and how this functional organization may be transmitted to daughter cells after DNA replication, thus allowing selected expression patterns not to be lost during development.

Gene transfer and expression studies in cultured avian neural crest cells differentiating into melanocytes

Neural crest cells obtained from explanted neural tubes take up, express, and retain exogenous DNA applied by the CaPO4 co-precipitation method during their differentiation into melanocytes. High efficiencies of gene transfer were obtained with both supercoiled DNA and intact phage particles; linear DNA or DNA from the phage yielded very low efficiencies. There is some evidence that transferred gene expression is differentiation dependent. The system should be useful for studies concerned with the analysis of cell developmental genes and their regulatory elements.

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.

Two-dimensional gel electrophoretic method for mapping DNA replicons

We describe in detail a method which allows determination of the directions of replication fork movement through segments of DNA for which cloned probes are available. The method uses two-dimensional neutral-alkaline agarose gel electrophoresis followed by hybridization with short probe sequences. The nascent strands of replicating molecules form an arc separated from parental and nonreplicating strands. The closer a probe is to its replication origin or to the origin-proximal end of its restriction fragment, the shorter the nascent strands that are detected by the probe. The use of multiple probes allows determination of directions of replication fork movement, as well as locations of origins and termini. In this study, we used simian virus 40 as a model to demonstrate the feasibility of the method, and we discuss its applicability to other systems.

Two-dimensional gel electrophoretic method for mapping DNA replicons

We describe in detail a method which allows determination of the directions of replication fork movement through segments of DNA for which cloned probes are available. The method uses two-dimensional neutral-alkaline agarose gel electrophoresis followed by hybridization with short probe sequences. The nascent strands of replicating molecules form an arc separated from parental and nonreplicating strands. The closer a probe is to its replication origin or to the origin-proximal end of its restriction fragment, the shorter the nascent strands that are detected by the probe. The use of multiple probes allows determination of directions of replication fork movement, as well as locations of origins and termini. In this study, we used simian virus 40 as a model to demonstrate the feasibility of the method, and we discuss its applicability to other systems.

In vitro transcription of eukaryotic genes is affected differently by the degree of DNA supercoiling

In a posterior silk gland extract, covalently closed circular (ccc) DNA is in a superhelical state that supports more transcription of fibroin gene than does linear DNA. A HeLa cell extract showed neither the supercoiling activity nor the preference for the transcription of ccc DNA over linear DNA. These activities could be added to the HeLa cell extract. Phosphocellulose fractionation of the posterior silk gland extract yielded a flow-through fraction and a 0.6 M KCl eluate fraction that were required for the supercoiling and for the efficient transcription of the ccc template in the acceptor HeLa cell extract. The 0.6 M KCl fraction had a DNA topoisomerase II activity, and the flow-through fraction contained a supercoiling factor that, with the aid of topoisomerase II, introduced negative supercoils into ccc DNA. When both fractions were added to the posterior silk gland extract, more supercoiling occurred than with the extract alone. Several genes were optimally transcribed under various extents of supercoiling. The fibroin gene and adenovirus 2 major late promoter were fully transcribed as partially supercoiled templates. The sericin gene required more supercoiling for full transcription, whereas no preference for supercoiling was seen with the transcription of hsp70. These results suggest that DNA topology plays a role in the regulation of gene expression.

The chemical carcinogen, chloroacetaldehyde, modifies a specific site within the regulatory sequence of human cytomegalovirus major immediate early gene in vivo

The reaction of chemical carcinogens with DNA is well documented, but whether this interaction occurs at specific sites in chromatin is unknown. We have examined in vivo the reaction of a known carcinogen, chloroacetaldehyde, with the active and inactive major immediate early gene of human cytomegalovirus. We found that during active transcription of the gene, this chemical carcinogen reacts with a unique DNA site in the 5' flanking sequence of the major immediate early gene. However, no reaction was detected in infected nonpermissive cells in which the gene was inactive. The chloroacetaldehyde-reactive site is located at -836 +/- 10 bp from the mRNA cap site in the part of the regulatory region that can both negatively and positively affect promoter activity [Nelson et al., Mol Cell Biol 7:4125-4129, 1987]. These results suggest, at least in the case of chloroacetaldehyde, the possibility that the molecular mechanism of chemical carcinogenesis involves a chemical reaction at specific sites in chromatin within the sequences responsible for regulation of gene expression. Such carcinogen-DNA interaction occurs as a consequence of a non-B DNA structure that contains unpaired DNA bases existing at specific sites in chromatin.

Ribosomal DNA sequences attached to the nuclear matrix

The organization of rat liver ribosomal DNA (rDNA) as matrix-attached DNA loops was examined using a protocol which fractionates chromatin from discrete regions of DNA loops. Southern blot analysis of matrix-attached and solubilized chromatin DNA fragments demonstrated that rDNA is associated with the matrix via its 5' and 3' nontranscribed spacer sequences (NTS). Although the 45 S rRNA coding sequences were approximately threefold enriched in matrix preparations, the recovery of this DNA (unlike the NTS) was dependent on the extent of nuclease digest and proportional to the length of the matrix-attached DNA fragments. The data suggest that rDNA is organized as matrix-attached DNA loops and only the NTS are directly involved in matrix binding. Further, we demonstrated that while the kinetics and extent of nuclease digestion were similar in all regions of the DNA loops, the nuclease digestion pattern of bulk nuclear and matrix DNA showed a typical nucleosome organization, but the rDNA fragments retained with the nuclear matrix did not.

Yeast regulatory sequences preferentially adopt a non-B conformation in supercoiled DNA

Mung bean nuclease was used to probe for DNA unwinding in torsionally-stressed chimeric plasmids containing two micron plasmid sequences and the yeast LEU2 gene in a pBR322 vector. The yeast sequences are cleaved at only two sites, both of which map to regulatory regions: (1) the autonomously replicating sequence (ARS), an origin of DNA replication, of the two micron plasmid and (2) the transcription terminator region of the LEU2 gene. Nucleotide level analysis of the nuclease cleavage pattern shows that an A + T-rich structure, distinct from other non-B DNA conformations, is recognized. A computer analysis reveals that A + T content alone is not sufficient to explain the preferential occurrence of the A + T-rich structure in the ARS over other sequences of equal A + T content. The A + T-rich structure detected in the ARS maps to sequences required for DNA replication. Our findings demonstrate the DNA conformational flexibility of certain yeast regulatory regions and provide support for the hypothesis that the A + T-rich sequence in the ARS plays a role in DNA unwinding during the initiation of DNA replication.

Role of DNA topoisomerase I in the transcription of supercoiled rRNA gene

The fraction DE-B obtained by fractionating an extract from rat mammary adenocarcinoma cells on a DEAE-Sephadex column was used for transcribing linear and supercoiled rRNA gene (rDNA). This fraction, which is known to contain RNA polymerase I and essential transcription factors, also contains DNA topoisomerase I activity. Inhibition of this topoisomerase activity by the selective inhibitor camptothecin markedly diminished transcription of supercoiled rDNA, and at a concentration of 150 microM, camptothecin almost completely inhibited DNA topoisomerase I activity and supercoiled rDNA transcription. Addition of exogenous calf thymus DNA topoisomerase I to the sample containing the drug restored the ability of the extract to transcribe supercoiled rDNA. Camptothecin, even at a concentration of 500 microM, had no significant effect on the transcription of linear rDNA. These studies show that relaxation of supercoiled rDNA by DNA topoisomerase I is essential for its transcription. The preferential inhibition of rRNA synthesis in vivo following treatment with camptothecin is probably due to selective camptothecin inhibition of DNA topoisomerase I activity.

Expression of transfected DNA depends on DNA topology

Supercoiled DNAs, especially those containing enhancers, yield markedly higher levels of expression than linearized DNA when transfected into CV-1 cells or L cells. Different templates, linear or supercoiled, enhancer-containing or not, saturate for expression at 2 micrograms DNA per dish, suggesting that one role for enhancers and supercoiling is to increase the efficiency with which the same limiting component is used. Plasmids containing only enhancers or only promoters do not compete for expression with an enhancer-driven gene. However, plasmids that contain both enhancers and promoters do complete, suggesting that a second role for enhancers is to increase the binding of a limiting transcription factor. Linear and supercoiled enhancer-promoter plasmids compete equivalently. This suggests that supercoiling affects the ability of transcription factors to activate a given promoter, once bound.

Expression of ribosomal insertion in Drosophila: sensitivity to intercalating drugs

Ribosomal insertions in Drosophila are transcribed at very low levels. The abundance of the most prominent 0.8 kb type 1 insertion transcript increased up to 60-fold when cultured cells were exposed to the DNA intercalating drug chloroquine. After injection of insertion-containing rDNA in circular form into Xenopus laevis oocytes an apparently identical 0.8 kb insertion transcript was synthesized, and its accumulation was stimulated several fold by coinjection of chloroquine or ethidium bromide. We suggest that ribosomal insertions are assembled in a chromatin conformation that lacks unconstrained torsional stress, accounting for the inactivity of these DNA regions; introduction of stress by intercalation results in activation of transcription from the insertion sequences.

Chromosomal loop anchorage of the kappa immunoglobulin gene occurs next to the enhancer in a region containing topoisomerase II sites

Introduction of torsional stress into active chromatin domains requires that linear DNA molecules be anchored in vivo to impede free rotation. While searching for these anchorage elements, we have localized a nuclear matrix association region (MAR) within the mouse immunoglobulin kappa gene that contains two topoisomerase II sites and is adjacent to the tissue-specific enhancer. The same matrix contact occurs when the kappa locus is in germ-line (inactive) or rear-ranged (transcribed) configurations. This constitutive anchorage site partitions the gene into V-J and C region chromatin domains. We demonstrate that at least 10,000 similar and evolutionarily conserved MAR binding sites exist in the nucleus. We propose that these sites, in association with topoisomerase II and possibly in conjunction with enhancers, play fundamental roles in the functional organization of chromatin loop domains.

Conservation of major nuclease S1-sensitive sites in the non-conserved spacer region of ribosomal DNA in Drosophila species

We have analysed nuclease S1-sensitive sites in cloned ribosomal DNA repeats from Drosophila melanogaster, D. hydei and D. virilis. All species contain major S1-sensitive sites in the spacer near the region of transcription termination, albeit with somewhat different positions and sensitivities. The same sites are also sensitive to the single-strand specificity of Bal31 nuclease at neutral pH. Additional major sites exist at each end of the intervening sequence within the 28 S gene of non-transcribed intervening-sequence-positive ribosomal DNA units of D. hydei. Only minor sites, however, were detected in the Pol I promoter regions. This is in contrast to Pol II transcribed genes, where S1 hypersensitivity becomes apparent at the 5' ends during gene expression. We have sequenced and mapped the S1 sites in the D. hydei spacer. They consist mainly of alternating A and T nucleotides that could form small cruciform structures. Cross-hybridization at low stringencies between the relevant S1-sensitive spacer regions of the three species indicates that the sites lie within very divergent sequences. We discuss the potential functional significance of S1 sites in rDNA spacers and intervening sequences, and the manner in which they might be maintained during rDNA sequence divergence.

DNase I footprinting shows three protected regions in the promoter of the rRNA genes of Xenopus laevis

Extracts prepared from Xenopus laevis oocytes contain a protein(s) which specifically protects three discrete regions of the RNA polymerase I promoter from digestion by DNase I. Protected region I, from nucleotide +15 to nucleotide -10, spans the site of transcription initiation. Protected region II extends from nucleotide -70 to nucleotide -100 relative to initiation, falling within a 42-base-pair sequence which is homologous to the 60/81-base-pair repeated elements which occur outside of the promoter in the spacer. Protected region III is upstream of region II, from nucleotide -120 to nucleotide -140. All three regions correlate with sequences known from deletion studies to be important for promoter function. Deletion mutants which retain either region I or regions II and III together footprint normally. Deletion of region III, however, reduces but does not eliminate footprinting on region II, suggesting either that one protein binds to both regions or that the proteins which bind to these sites interact with each other.

Effect of intercalating agents on RNA polymerase I promoter selection in Xenopus laevis

We have analyzed the effect of DNA intercalating agents on the transcription signals from two different Xenopus laevis RNA polymerase I promoters. The transcription signal from the promoter for the 7.5-kilobase rRNA precursor (the gene promoter) is unaffected over a large range of intercalating agent concentrations regardless of whether the template is injected plasmid DNA in oocytes, the amplified endogenous nucleoli of oocytes, or the endogenous chromosomes of cultured Xenopus kidney cells. The transcription signal from a closely related promoter located in the spacer DNA between genes (the spacer promoter) ranges between undetectable to equivalent to the gene promoter signal on different templates. The transcription signal from the spacer promoter is also differentially affected by intercalating agents relative to the gene promoter. Depending on the template, these agents can either increase or decrease the transcription signal from the spacer promoter. Fusions between the gene and spacer promoters demonstrate that intercalating agents affect transcription initiation. One explanation for these results is that the degree of supercoiling of the template DNA can differentially inhibit transcription from the spacer promoters. The different effects of intercalating agents on transcription from the spacer promoters of various templates could then be explained as differences in the degree of supercoiling present on these templates initially.

Effect of intercalating agents on RNA polymerase I promoter selection in Xenopus laevis

We have analyzed the effect of DNA intercalating agents on the transcription signals from two different Xenopus laevis RNA polymerase I promoters. The transcription signal from the promoter for the 7.5-kilobase rRNA precursor (the gene promoter) is unaffected over a large range of intercalating agent concentrations regardless of whether the template is injected plasmid DNA in oocytes, the amplified endogenous nucleoli of oocytes, or the endogenous chromosomes of cultured Xenopus kidney cells. The transcription signal from a closely related promoter located in the spacer DNA between genes (the spacer promoter) ranges between undetectable to equivalent to the gene promoter signal on different templates. The transcription signal from the spacer promoter is also differentially affected by intercalating agents relative to the gene promoter. Depending on the template, these agents can either increase or decrease the transcription signal from the spacer promoter. Fusions between the gene and spacer promoters demonstrate that intercalating agents affect transcription initiation. One explanation for these results is that the degree of supercoiling of the template DNA can differentially inhibit transcription from the spacer promoters. The different effects of intercalating agents on transcription from the spacer promoters of various templates could then be explained as differences in the degree of supercoiling present on these templates initially.

DNase I footprinting shows three protected regions in the promoter of the rRNA genes of Xenopus laevis

Extracts prepared from Xenopus laevis oocytes contain a protein(s) which specifically protects three discrete regions of the RNA polymerase I promoter from digestion by DNase I. Protected region I, from nucleotide +15 to nucleotide -10, spans the site of transcription initiation. Protected region II extends from nucleotide -70 to nucleotide -100 relative to initiation, falling within a 42-base-pair sequence which is homologous to the 60/81-base-pair repeated elements which occur outside of the promoter in the spacer. Protected region III is upstream of region II, from nucleotide -120 to nucleotide -140. All three regions correlate with sequences known from deletion studies to be important for promoter function. Deletion mutants which retain either region I or regions II and III together footprint normally. Deletion of region III, however, reduces but does not eliminate footprinting on region II, suggesting either that one protein binds to both regions or that the proteins which bind to these sites interact with each other.

A transcription enhancer acts in vitro over distances of hundreds of base-pairs on both circular and linear templates but not on chromatin-reconstituted DNA

We have analyzed the effect of nucleosome formation and of the simian virus (SV40) enhancer on the efficiency of in vitro transcription. In a whole cell extract made from HeLa cells, nucleosome assembly on DNA results in the formation of chromatin-like complexes. However, transcription was detectable only when the DNA templates were partially or totally depleted of nucleosomes. On nucleosome-free templates, when the SV40 enhancer was present upstream from the complete SV40 early or rabbit beta-globin promoters, there was a five- to tenfold stimulation of specific transcription. When present upstream from its homologous promoter, the SV40 enhancer activated SV40 early transcription independently of its orientation with respect to the coding sequence. Point mutations known to impair the SV40 enhancer function in vivo had a similar effect in vitro. The extent of the enhancing effect was the same with linear or circular templates. When the SV40 enhancer was inserted upstream from the rabbit beta-globin gene, the activation of transcription was reduced with increasing distance between the enhancer and beta-globin upstream promoter elements, but was still significant over a distance of more than 400 base-pairs.

Enhancer-like properties of the 60/81 bp elements in the ribosomal gene spacer of Xenopus laevis

The spacer region of the Xenopus laevis ribosomal gene contains blocks of repetitive sequence elements that are 60 or 81 bp long. These 60/81 bp elements function as enhancer elements for the RNA polymerase I promoter at the 5' end of the gene. An RNA polymerase I promoter adjacent to a block of 60/81 bp elements is always dominant over a promoter on a second plasmid when both are coinjected into oocyte nuclei. If two promoters are placed on the same plasmid containing enhancers, both promoters come under their influence and are codominant. The influence of the enhancers can be transmitted through several kilobases of plasmid sequence, through a potentially active promoter, and is independent of the orientation of the enhancers. The enhancers appear to compete with promoters for the same transcription factor(s); however, the enhancers can only compete when they are on a circular plasmid.