DNAaseI-hypersensitive minichromosomes of SV40 possess an elastic torsional strain in DNA

Deregulation of SATB2 in carcinogenesis with emphasis on miRNA-mediated control

The special AT-rich DNA binding protein (SATB2) is a nuclear matrix-associated protein and an important transcription factor for biological development, gene regulation and chromatin remodeling. Aberrant regulation of SATB2 has been found to highly correlate with various types of cancers including lung, colon, prostate, breast, gastric and liver. Recent studies have revealed that a subset of small non-coding RNAs, termed microRNAs (miRNAs), are important regulators of SATB2 function. As post-transcriptional regulators, miRNAs have been found to have fundament importance maintaining normal cellular development. Evidence suggests that multiple miRNAs, including miR-31, miR-34, miR-182, miR-211, miR-599, are capable of regulating SATB2 in cancers of the lung, liver, colon and breast. This review examines the molecular functions of SATB2 and miRNAs in the text of cancer development and potential strategies for cancer therapy with a focus on systemic miRNA delivery.

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.

Effects of histone acetylation on chromatin topology in vivo

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

Effects of histone acetylation on chromatin topology in vivo

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

Enhancer-activated plasmid transcription complexes contain constrained supercoiling

It has been proposed that transcriptionally active chromatin contains totally unconstrained supercoiling. The results of recent studies have raised the possibility that this topological state is the property of highly transcribed genes. Since the transcription rate of RNA polymerase II genes can be dramatically increased by the presence of an enhancer, we have determined if the transcription complex of an enhancer-activated plasmid contains totally unconstrained supercoils. Following transfection into COS7 cells, the topology of the transcription complex DNA was determined directly by agarose gel electrophoresis. We find that an enhancer-activated plasmid transcription complex is supercoiled, and these supercoils remain following topoisomerase I treatment. Thus the transcribing complexes contain constrained supercoils, and the level of supercoiling suggests a nucleosome-like organization. However, we cannot rule out the possibility that unconstrained supercoils exist in addition to these constrained supercoils in the transcription complex in the cell.

A matrix/scaffold attachment region binding protein: identification, purification, and mode of binding

Matrix/scaffold attachment regions (MARs/SARs) partition chromatin into functional loop domains. Here we have identified a chicken protein that selectively binds to MARs from the chicken lysozyme locus and to MARs from Drosophila, mouse, and human genes. This protein, named ARBP (for attachment region binding protein), was purified to homogeneity and shown to bind to MARs in a cooperative fashion. ARBP is an abundant nuclear protein and a component of the internal nuclear network. Deletion mutants indicate that multiple AT-rich sequences, if contained in a minimal approximately 350 bp MAR fragment, can lead to efficient binding of ARBP. Furthermore, dimerization mutants show that, to bind ARBP efficiently, MAR sequences can act synergistically over large distances, apparently with the intervening DNA looping out. The binding characteristics of ARBP to MARs reproduce those of unfractionated matrix preparations, suggesting that ARBP is an important nuclear element for the generation of functional chromatin loops.

P1 nuclease defines a subpopulation of active SV40 chromatin--a new nuclease hypersensitivity assay

Under exhaustive digestion conditions P1 nuclease was found to cleave a subpopulation of intracellular SV40 chromatin only once. The major P1 cleavage site in SV40 DNA was mapped at the origin of DNA replication, and the two minor sites at the SV40 enhancers. The P1-sensitive SV40 chromatin subpopulation was found to have higher superhelical density than the bulk of the intracellular SV40 chromatin. Furthermore, pulse labeled SV40 DNA which had higher superhelical density than that of the steady state viral DNA (S.S. Chen and M.T.Hsu, J. Virol 51:14-19, 1984) was also found to be preferentially cleaved by P1 nuclease. These results are consistent with a supercoil-dependent alteration of chromatin conformation near the regulatory region of the viral genome that can be recognized by P1 nuclease. Since P1 nuclease cleaves the subpopulation of SV40 chromatin only once without further degradation, this nuclease can be used as a general tool to define viral or cellular chromatin fraction with altered chromatin conformation and to map nuclease hypersensitive sites. Preliminary studies indicate that P1 makes limited double stranded cleavages in cellular chromatin to generate large DNA fragments.

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.

Characterization of a topoisomerase-like activity at specific hypersensitive sites in the Drosophila histone gene cluster

It is well known that treatment of DNA-topoisomerase complexes with SDS induces cleavage of the DNA by trapping a reactive intermediate in which the topoisomerase is covalently linked to the terminal phosphates of the cut DNA. I have used this technique to examine potential topoisomerase binding sites in the histone gene chromatin of Drosophila Kc cells. Treatment of Kc nuclei with SDS induces Mg++-dependent DNA cleavage near the borders of two nuclease-hypersensitive sites located 5' and 3' of histone H4. It is likely that the SDS-induced cleavage at these hypersensitive sites is due to a topoisomerase because protein becomes tightly bound to the ends of the cleaved DNA fragments. Preliminary experiments suggest that a type II topoisomerase may be responsible for the cleavage.

Transcription elements and factors of RNA polymerase B promoters of higher eukaryotes

The promoter for eukaryotic genes transcribed by RNA polymerase B can be divided into the TATA box (located at -30) and startsite (+1), the upstream element (situated between -40 and about -110), and the enhancer (no fixed position relative to the startsite). Trans-acting factors, which bind to these elements, have been identified and at least partially purified. The role of the TATA box is to bind factors which focus the transcription machinery to initiate at the startsite. The upstream element and the enhancer somehow modulate this interaction, possibly through direct protein-protein interactions. Another class of transcription factors, typified by viral proteins such as the adenovirus EIA products, do not appear to require binding to a particular DNA sequence to regulate transcription. The latest findings in these various subjects are discussed.

The flexibility and topology of simian virus 40 DNA in minichromosomes

The linking number of DNA in minichromosomes increases by 2 turns during SV40 assembly. Changes in temperature also influence the average linking number of the total intracellular forms of SV40 DNA. When the isolated minichromosomes assembled in vivo are incubated with topoisomerase I at 33 degrees C in vitro, the linking number of SV40 DNA decreases. This decrease is about: -1.1 turns for minichromosomes with an average nucleosome spacing of 198 base pairs (bp), wt776; and -0.6 turns for minichromosomes containing a shorter average nucleosome repeat (177 bp), tsC219. The difference between the average linking number of naked SV40 DNA relaxed with topoI at 33 degrees C and minichromosomes relaxed with the enzyme at the same temperature indicates that SV40 chromatin contains on the average 26 nucleosomes. However, the results of studies obtained both on DNA flexibility in chromatin and in naked DNA, and on the shape of the topoisomer distribution curves, indicate that all of the minichromosomes, regardless of their overall structure, do not contain the same number of nucleosomes; this heterogeneity may be as large as 8 nucleosomes. We find no apparent correlation between the amount of minichromosomes containing unconstrained torsional stress and the abundance of the molecules with a structure characteristic of transcriptionally active chromatin.

Topological characterization of the simian virus 40 transcription complex

We have used sedimentation analysis as well as agarose gel electrophoresis to characterize the topological state of the DNA of the Simian Virus 40 (SV40) transcription complex. We found that the complex DNA contained constrained topological tension, presumably resulting from nucleosome-like structures, but no detectable unconstrained (i.e., relaxable) topological tension. These results contradict previous conclusions that the SV40 transcription complex contains only unconstrained topological tension. Our findings are also the opposite of what has been proposed to be the case for the 5S gene analyzed in Xenopus oocytes. Thus the proposal that expression from the 5S gene is associated with substantial topological tension is not valid for expression from the SV40 late gene.

Altered DNA conformations in the gene regulatory region of torsionally-stressed SV40 DNA

We used mung bean nuclease to probe the SV40 genome for DNA unwinding and unpairing. Cleavage occurred at a limited number of specific sites in supercoiled, but not relaxed DNA. The number and location of cleavage sites depended upon Mg2+ concentration. Without Mg2+, cutting occurred mainly in one early denaturation region located 3' to the t antigen gene and within the T antigen gene intron. With Mg2+, cleavage occurred at a number of alternative sites in the genome. Certain Mg2+ concentrations favored cleavage in the gene regulatory region. These cleavages were mapped at single nucleotide resolution and occurred in both transcriptional enhancers and upstream from the start of major late gene transcription. The cleavages occurred between 5 bp inverted repeat sequences, consistent with the recognition of unusually small cruciform structures.

Structure of replicating simian virus 40 minichromosomes. The replication fork, core histone segregation and terminal structures

The structure of replicating simian virus 40 (SV40) minichromosomes was studied by DNA crosslinking with trimethyl-psoralen. The procedure was used both in vitro with extracted SV40 minichromosomes as well as in vivo with SV40-infected cells. Both procedures gave essentially the same results. Mature SV40 minichromosomes are estimated to contain about 27 nucleosomes (error +/- 2), except for those molecules with a nucleosome-free gap, which are interpreted to contain 25 nucleosomes (error +/- 2). In replicative intermediates, nucleosomes are present in the unreplicated parental stem with the replication fork possibly penetrating into the nucleosomal DNA before the histone octamer is removed. Nucleosomes reassociate on the newly replicated DNA branches at distances from the branch point of 225 ( +/- 145) nucleotides on the leading strand and of 285( +/- 120) nucleotides on the lagging strand. In the presence of cycloheximide, daughter duplexes contained unequal numbers of nucleosomes, supporting dispersive and random segregation of parental nucleosomes. These were arranged in clusters with normal nucleosome spacing. We detected a novel type of interlocked dimer comprising two fully replicated molecules connected by a single-stranded DNA bridge. We cannot decide whether these dimers represent hemicatenanes or whether the two circles are joined by a Holliday-type structure. The joining site maps within the replication terminus. We propose that these dimers represent molecules engaged in strand segregation.

Supercoil induced S1 hypersensitive sites in the rat and human ribosomal RNA genes

Rat and human ribosomal RNA gene fragments in supercoiled plasmids were examined for S1 nuclease hypersensitivity. In the transcribed portion of genes the number and distribution of S1 sites were found to be species specific. No S1 sites were detected in the promoter regions. In the nontranscribed spacer (NTS), downstream of the 3' end of 28S RNA gene, S1 sites appear to be conserved in rat and human rDNAs. A rat NTS fragment (2987 nucleotides long), containing three S1 sites was sequenced and the S1 sites in this region were localized in polypyrimidine . polypurine simple repeat sequences. Other types of simple sequences, two type 2 Alu repeats and an ID sequence were also found in the sequenced region. The possible role of simple sequences and S1 sites in transcription and in recombination events of rDNA is discussed.

Transcriptionally active SV40 minichromosomes are restriction enzyme sensitive and contain a nucleosome-free origin region

A nucleosome-free region or gap containing the origin of replication and the transcriptional promoter elements is observed on 20 to 25% of the SV40 minichromosomes isolated at physiological ionic strength late in infection. We used the preferential sensitivity of the gapped minichromosomes to restriction enzymes to obtain sucrose gradient fractions containing 50 to 80% of gapped molecules. The same fractions are also enriched in RNA polymerase B (II) molecules engaged in transcription. Using electron microscopy, we demonstrate here that the transcriptional complexes are preferentially sensitive to restriction enzyme digestion, which indicate that they represent a subpopulation of the gapped minichromosomes.

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.

Effect of X-ray induced DNA damage on DNAase I hypersensitivity of SV40 chromatin: relation to elastic torsional strain in DNA

The effect of X-irradiation on DNAase I hypersensitivity of SV40 minichromosomes within nuclei or free in solution was investigated. The susceptibility of the specific DNA sites in the control region of minichromosomes to DNAase I decreased in a dose dependent manner after irradiation of isolated nuclei. On the other hand, the irradiation of minichromosomes extracted from nuclei in 0.1 M NaCl-containing buffer almost did not affect the level of their hypersensitivity to DNAase I. This suggests that DNAase I hypersensitivity may be determined by two different mechanisms. One of them may be connected with elastic torsional strain within a fraction of minichromosomes and another seems to be determined by nucleosome free region. The first mechanism may be primarily responsible for the hypersensitivity of minichromosomes within nuclei. After irradiation of the intact cells, DNAase I hypersensitivity tested in nuclei substantially increased. This was connected with activation of endogeneous nucleases by X-irradiation which led to accumulation of single- and double-strand breaks superimposed to DNAase I induced breaks in the control region of SV40 DNA.