Assembly of transfected DNA into chromatin: structural changes in the origin-promoter-enhancer region upon replication

Chimeric SV40 DNA containing only the early region, or plasmid DNA harboring the origin-promoter-enhancer region of SV40, when introduced into CV-1 or Cos-1 monkey cells by DEAE-dextran mediated transfer are rapidly assembled in a typical chromatin structure revealed by the generation of a regular 190 bp repeat ladder after micrococcal nuclease digestion. DNA replication is not required for this assembly process. Chromatin-specific DNase I hypersensitive sites are observed in the enhancer region of these minichromosomes. The pattern of the sites differs between non-replicating and post-replicated chromatin. The latter is identical to that observed in the lytic cycle. The presence of large T antigen is not sufficient for the shift in the structure of the chromatin. These experiments suggest that replication can modulate protein-DNA interactions during viral infection or upon cell differentiation.     

Preferential binding of adriamycin and nogalamycin to DNase-I hypersensitive sites of Sarcoma-180 chromatin

Binding of nogalamycin and adriamycin with Sarcoma-180 ascites tumor cell chromatin was studied by a spectrofluorometric method. There was significant reduction in the number of available drug binding sites per nucleotide when the chromatin was digested with DNase I for a period which releases only 7% of the chromosomal DNA. Results indicate preferential binding of these drugs with DNase I hypersensitive sites of chromatin. The DNase-I hypersensitive sites of chromatin were shown to correlate to the sequences required for gene expression. Further digestion with DNase I increases availability of drug binding sites, probably due to relaxation of the compact chromatin.     

Chromatin structure of a 3-methylcholanthrene-induced cytochrome P-450 gene

Plasmids carrying fragments of a cytochrome P-450 gene, inducible by 3-methylcholanthrene, were used to study the chromatin structure of this gene in the liver of normal and carcinogen-treated rats. Digestion with micrococcal nuclease revealed that the gene is not present in the typical 200 base pair nucleosomal structure. By use of indirect end-label hybridization, four DNase I hypersensitive sites were mapped in the 5'-terminal region of the gene. An S1 nuclease sensitive site is located close to a DNase I site. Gene induction by treatment with 3-methylcholanthrene does not result in detectable changes in the DNase I hypersensitive sites. Rat thymus chromatin does not contain DNase I hypersensitive sites in the P-450 gene, suggesting that in the liver the chromatin structure is altered so as to allow tissue-specific expression of the gene. This paper is the first study on the chromatin structure of a gene coding for a member of the cytochrome P-450 family of enzymes. The implications of our results to the understanding of gene regulation of the P-450 genes are discussed.     

Chromatin structure of the cytochrome P-450c gene changes following induction

The chromatin structure of cytochrome P-450c and P-450d genes, which in the liver are highly inducible by 3-methylcholanthrene, was studied in normal and carcinogen-treated rats by using a cDNA probe specific for P-450c and a genomic probe that recognizes both genes. Digestion with micrococcal nuclease revealed that the active genes are not present in the typical 200 base pair nucleosomal structure. Gene induction is associated with a rearrangement of the nuclear organization of the genes. By use of indirect end-label hybridization, three DNase I hypersensitive sites were mapped, one in the 5'-terminal region and two in the 3' region of the P-450c gene. Gene induction, by treatment with 3-methylcholanthrene, changes the location of the DNase I site present in the 5' region without affecting the sites present in the 3' region. Rat thymus chromatin does not contain these DNase I hypersensitive sites, suggesting that, in the liver, the chromatin structure is altered so as to allow tissue-specific expression of the P-450c gene. The chromatin structure of the highly inducible P-450c gene is compared to that of the P-450m gene, which is induced to a significantly smaller extent and is constitutively expressed.     

Condensation of chromatin into chromosomes preserves an open configuration but alters the DNase I hypersensitive cleavage sites of the transcribed gene

DNase I was used to probe the molecular organization of the chicken ovalbumin (OV) gene and glyceraldehyde 3-phosphate dehydrogenase (GPD) gene in interphase nuclei and in metaphase chromosomes of cultured chicken lymphoblastoid cells (MSB-1 line). The OV gene was not transcribed in this cell line, whereas the GPD gene was constitutively expressed. The GPD gene was more sensitive to DNase I digestion than the OV gene in both interphase nuclei and metaphase chromosomes, as determined by Southern blotting and liquid hybridization techniques. In addition, we observed DNase I hypersensitive sites around the 5' region of the GPD gene. These hypersensitive sites were not always at the same locations between the interphase nuclei and metaphase chromosomes. Our results suggest that chromatin condensation and decondensation during cell cycle alters nuclease hypersensitive cleavage sites.     

Moloney murine leukemia virus-induced tumors: recombinant proviruses in active chromatin regions.

The DNase I sensitivity of chromosomal DNA regions carrying integrated proviral genomes of Moloney (M-MuLV) and AKR Murine Leukemia Virus (AKR-MuLV), and the cellular homologue of the mos-gene (c-mos) of Moloney Sarcoma Virus (MSV) were studied in tumor tissues of leukemic mice. The genetically transmitted sequences of M-MuLV, AKR-MuLV, and the c-mos gene are all in DNase I resistant chromatin conformations in M-MuLV-induced tumors. Each M-MuLV-induced tumor contained at least one somatically acquired integrated recombinant MuLV genome that displayed two main characteristic features of active chromatin: a) a configuration hypersensitive to DNase I, and b) extensive hypomethylation. DNase I hypersensitive sites were mapped at the junction of cellular sequences and the 5'-viral large terminal repeat (LTR). Expression of a recombinant MuLV seems therefore to be a necessary feature to maintain the transformed state.     

Correlation Between DNase I Hypersensitive Site Distribution and Gene Expression in HeLa S3 Cells

Mapping DNase I hypersensitive sites (DHSs) within nuclear chromatin is a traditional and powerful method of identifying genetic regulatory elements. DHSs have been mapped by capturing the ends of long DNase I-cut fragments (>100,000 bp), or 100-1200 bp DNase I-double cleavage fragments (also called double-hit fragments). But next generation sequencing requires a DNA library containing DNA fragments of 100-500 bp. Therefore, we used short DNA fragments released by DNase I digestion to generate DNA libraries for next generation sequencing. The short segments are 100-300 bp and can be directly cloned and used for high-throughput sequencing. We identified 83,897 DHSs in 2,343,479 tags across the human genome. Our results indicate that the DHSs identified by this DHS assay are consistent with those identified by longer fragments in previous studies. We also found: (1) the distribution of DHSs in promoter and other gene regions of similarly expressed genes differs among different chromosomes; (2) silenced genes had a more open chromatin structure than previously thought; (3) DHSs in 3'untranslated regions (3'UTRs) are negatively correlated with level of gene expression.     

The DNA intercalator, ethidium bromide, alters the pattern of DNAse I hypersensitive sites of the beta A-globin gene in chicken erythrocytes

We have analysed the effects of a DNA intercalator, ethidium bromide (EB), on chromatin structure in nuclei from both chicken mature erythrocytes (RBC) and reticulocytes (Ret). A differential release of nuclear proteins was obtained from both types of nuclei exposed to EB. Among these proteins, a species of 45 kDa is the major component. Furthermore, in the 10 mM EB-treated nuclei, the pattern of DNAse I hypersensitive sites (DHS) around the chicken beta A-globin gene were significantly altered, i.e., the original set was replaced by a new set of DHS. We have discussed the implications of our observations, in the light of current concepts of functional aspects of the conformational heterogeneity of DNA in both protein-DNA interactions and chromatin structure, as well as the effects of DNA intercalators on DNA conformation.     

Albumin and alpha-fetoprotein gene transcription in rat hepatoma cell lines is correlated with specific DNA hypomethylation and altered chromatin structure in the 5'' region.

We examined DNA methylation and DNase I hypersensitivity of the alpha-fetoprotein (AFP) and albumin gene region in hepatoma cell lines which showed drastic differences in the level of expression of these genes. We assayed for methylation of the CCGG sequences by using the restriction enzyme isoschizomers HpaII and MspI. We found two methylation sites located in the 5' region of the AFP gene and one in exon 1 of the albumin gene for which hypomethylation is correlated with gene expression. Another such site, located about 4,000 base pairs upstream from the AFP gene, seems to be correlated with the tissue specificity of the cells. DNase I-hypersensitive sites were mapped by using the indirect end-labeling technique with cloned genomic DNA probes. Three tissue-specific DNase I-hypersensitive sites were mapped in the 5' flanking region of the AFP gene when this gene was transcribed. Similarly, three tissue-specific DNase I-hypersensitive sites were detected upstream from the albumin gene in producing cell lines. In both cases, the most distal sites were maintained after cessation of gene activity and appear to be correlated with the potential expression of the gene. Interestingly, specific methylation sites are localized in the same DNA region as DNase I hypersensitive sites. This suggests that specific alterations of chromatin structure and changes in methylation pattern occur in specific critical regulatory regions upstream from the albumin and AFP genes in rat hepatoma cell lines.     

DNase-chip: a high-resolution method to identify DNase I hypersensitive sites using tiled microarrays

Mapping DNase I hypersensitive sites is an accurate method of identifying the location of gene regulatory elements, including promoters, enhancers, silencers and locus control regions. Although Southern blots are the traditional method of identifying DNase I hypersensitive sites, the conventional manual method is not readily scalable to studying large chromosomal regions, much less the entire genome. Here we describe DNase-chip, an approach that can rapidly identify DNase I hypersensitive sites for any region of interest, or potentially for the entire genome, by using tiled microarrays. We used DNase-chip to identify DNase I hypersensitive sites accurately from a representative 1% of the human genome in both primary and immortalized cell types. We found that although most DNase I hypersensitive sites were present in both cell types studied, some of them were cell-type specific. This method can be applied globally or in a targeted fashion to any tissue from any species with a sequenced genome.