DNA methylation: correlation with DNase I sensitivity of chicken ovalbumin and conalbumin chromatin.

To analyse the relationship between DNA undermethylation at some sites in the ovalbumin and conalbumin gene regions (1) and the expression of these genes in chick oviduct, digestions with HhaI, which differentiates between methylated and unmethylated HhaI restriction sites, was performed on DNA isolated from chicken erythrocyte or oviduct chromatin treated with DNase I which degrades preferentially "active" chromatin. This was followed by analysis with ovalbumin- and conalbumin-specific hybridization probes. We conclude that the residual DNA methylation found at some sites of the ovalbumin and conalbumin gene regions is derived from the fraction of cells in which the chromatin of these genes is not in an "active" form. On the other hand, the ovalbumin and conalbumin sites which are partially unmethylated in erythrocyte DNA correspond to chromatin regions which are not DNase I-senitive. We have also detected a site about 1 kb downstream from the 3' end of the conalbumin gene that is hypersensitive to DNase I in all tissues tested.     

Differences in DNase I sensitivity and methylation within the human beta-globin gene domain and correlation with expression

We have analysed the chromatin features of DNA regions encompassing human epsilon, G gamma, A gamma, delta and beta globin structural genes in fetal and adult erythroid cells on the one hand and adult lymphocytes on the other. Highly purified nuclei from these cells were submitted to DNase I digestion and the kinetic data were obtained from the percentage of residual hybridization of defined regions in Southern blots. Our results, as others have shown by different approaches, indicate that the structural genes of the beta-globin cluster are generally more sensitive to DNase I in the erythroid cells than in non-erythroid cells. Thus a domain of DNase I sensitivity related to the committed state is defined. In addition we show that within this DNase-I-sensitive beta cluster domain, individual genes of the cluster are arranged in subdomains of differential DNase I sensitivity, which correlate with their expression status. Furthermore the differential expression of the two fetal genes in the fetal stage is shown to be directly proportional to the degree of hypomethylation of these genes.     

Overall changes in chromatin sensitivity to DNase I during differentiation

The DNase I sensitivity of total chromatin was studied in fixed cells and nuclei isolated from proliferating and terminally differentiated cells, by measuring the incorporation of labelled nucleotides into DNase-sensitive sites, and electrophoresis of DNA isolated from DNase-treated nuclei. The unfixed nuclei were sensitive to digestion at around 10 micrograms/ml, the fixed cells at 30 ng/ml DNase I concentration. Proliferating Rauscher leukemia cells were more digestible than normal spleen cells. The DNase I sensitivity of the human HL60 leukemia line decreased upon DMSO-induced differentiation but still exceeded the digestibility of nuclei from normal human peripheral blood. A novel flow-cytometric technique was developed to study DNase sensitivity at the cell level. It confirmed the relative resistance of differentiated cells to DNase I and ruled out the possibility that this could be due to an altered distribution of cell cycle phases. The overall DNase I sensitivity of chromatin was compared with the sensitivity of the c-myc gene and the myc-associated hypersensitive sites. The latter sites were detected at 1 microgram/ml DNase I in HL60 nuclei. They disappeared partially upon DMSO-induced differentiation. At 10 micrograms/ml, myc was degraded in both growing and differentiating HL60, but not in HPB cells. These data suggest that a progressive condensation of the chromatin occurs during terminal differentiation which gradually involves specific genes that need to be inactivated.     

Core histone hyperacetylation co-maps with generalized DNase I sensitivity in the chicken beta-globin chromosomal domain.

The distribution of core histone acetylation across the chicken beta-globin locus has been mapped in 15 day chicken embryo erythrocytes by immunoprecipitation of mononucleosomes with an antibody recognizing acetylated histones, followed by hybridization probing at several points in the locus. A continuum of acetylation was observed, covering both genes and intergenic regions. Using the same probes, the generalized sensitivity to DNase I was mapped by monitoring the disappearance of intact genomic restriction fragments from Southern transfers. Close correspondence between the 33 kb of sensitive chromatin and the extent of acetylation indicates that one role of the modification could be the generation and/or maintenance of the open conformation. The precision of acetylation mapping makes it a possible approach to the definition of chromosomal domain boundaries.     

A phosphatase inhibitor enhances the DNase I sensitivity of active chromatin

Although it is well-known that active domains of chromatin have elevated DNase I sensitivity, it can be difficult to observe preferential sensitivity in many cell types. We show that the DNase I sensitivity of active chromatin is enhanced some 10-fold by treating nuclei with the phosphatase inhibitor p-(chloromercuri)benzenesulfonic acid (CMBS) whereas DNase I sensitivity in inactive domains is only 3-fold higher. We further show that CMBS-enhanced DNase I sensitivity is associated with at least two histone modifications. First, the negatively charged CMBS molecule becomes covalently attached to the thiol groups on histone H3. Second, histone H2A phosphorylation is significantly elevated in treated nuclei. The phosphorylation data along with other results point to the possibility that H2A phosphorylation plays a role in enhancing preferential DNase I sensitivity. Whatever the mechanism, CMBS treatment of nuclei followed by DNase I digestion provides a novel and reproducible assay for probing the chromatin structure of active domains.     

DNase I sensitivity of integrated simian virus 40 DNA.

We undertook an analysis of integrated simian virus 40 (SV40) DNA to learn whether the DNase I-sensitive region is retained in the integrated array of mouse transformants. Our results indicate that full-length integrated SV40 chromatin retains a DNase I-hypersensitive region at the same point as in nonintegrated SV40 chromatin. Thus, the lack of a DNase I-hypersensitive region is not likely to be the reason for nonpermissivity of SV40 in mouse cells. In addition, results reported here indicate that a deletion of about 200 base pairs of DNA in the region of the DNase I-hypersensitive site severely reduces the sensitivity of integrated SV40 chromatin. This result is similar to a previously reported result obtained with deletion mutants of SV40 analyzed in the lytic cycle. It is the first report of a DNA lesion affecting DNase I hypersensitivity of a mammalian chromosome.     

Chromatin structure of the chicken beta-globin gene region. Sensitivity to DNase I, micrococcal nuclease, and DNase II

We have examined in some detail the chromatin structure of a 6.2 kilobase pair (kbp) chromosomal region containing the chicken beta-globin gene. The chromatin structure was probed with three nucleases, DNase I, micrococcal nuclease, and DNase II, and the rate of digestion of specific subfragments of the region was compared with the rate of bulk DNA digestion. We have characterized the rate of digestion of each fragment in terms of a sensitivity factor which measures the sensitivity of a fragment to a particular nuclease relative to bulk DNA. The sensitivity factors were determined by a least squares curve fitting method based on target analysis. In nuclei isolated from 14-day-old chicken embryo red blood cells, the entire 6.2-kbp region shows approximately a 10- to 20-fold increase in sensitivity to DNase I, a 3-fold increased sensitivity to micrococcal nuclease, and a 6-fold increased sensitivity to DNase II. In addition to the adult beta-globin gene, this region contains 5' and 3' flanking sequences, the 5' half of the inactive, embryonic globin gene, epsilon, and some repeated sequences. There is no obvious correlation between these genetic elements and the overall chromatin structure as measured by the nuclease sensitivity. This same region shows little or no special sensitivity in nuclei isolated from 14-day-old chicken embryo brain. Furthermore, fragments of the inactive ovalbumin gene show little or no sensitivity in either red blood cells or brain. These results support the conclusion that the entire 6.2-kbp region is largely packaged as active chromatin in 14-day-old chicken embryo red blood cells.     

Methylation state and DNase I sensitivity of chromatin containing Moloney murine leukemia virus DNA in exogenously infected mouse cells

The nature of Moloney murine leukemia virus (M-MuLV)-specific proviral DNA in exogenously infected mouse cells was studied. M-MuLV clone A9 cells, NIH-3T3 fibroblasts productively infected with M-MuLV, were used. These cells contain 10 to 15 copies of M-MuLV proviral DNA. The state of methylation of M-MuLV proviral DNA was examined by cleaving A9 cell DNA with restriction endonucleases which have the dinucleotide CpG in their cleavage sequences. Analysis with such enzymes, which recognized nine different sites in M-MuLV DNA, indicated that most if not all of the M-MuLV proviruses in A9 cells were completely unmethylated. An individual proviral integration was examined, using as probe adjacent single-copy cellular sequences. These sequences were obtained from a lambda phage recombinant clone containing an M-MuLV provirus from the A9 cells. This individual integration also showed no detectable methylation. In contrast, endogenous MuLV-related sequences present in NIH-3T3 cells before infection were largely methylated. The configuration chromatin containing M-MuLV proviruses was also investigated by digesting A9 nuclei with DNase I, followed by restriction analysis of the remaining DNA. Endogenous MuLV-related DNA was in chromatin relatively resistant to DNase I digestion, whereas the majority of M-MuLV-specific proviruses were in domains of intermediate DNase I sensitivity. Two proviral copies hypersensitive to DNase I digestion were identified. Analogy to the DNase I sensitivity of expressed and nonexpressed globin genes suggested that the proviral copies containing DNase I-hypersensitive sites were transcribed.     

Differential accessibility of DNA in extended and condensed chromatin to pancreatic DNase I

Pancreatic DNase I has been used to study the interaction between DNA and chromosomal proteins in extended and condensed chromatin fractions isolated from mouse and Chinese hamster livers. It was found that DNase digests extended chromatin at a faster rate than condensed chromatin, and the evidence suggests that the chromosomal proteins are more tightly complexed to the DNA in condensed than in extended chromatin. This difference in DNA-protein interaction in extended and condensed chromatin may be related to the functional difference which characterizes these fractions, and might be one of the factors underlying the production of bands on metaphase chromosomes.     

In vivo analysis of DNase I hypersensitive sites in the human CFTR gene.

BACKGROUND: The cystic fibrosis transmembrane conductance regulator gene (CFTR) shows a complex pattern of expression. The regulatory elements conferring tissue-specific and temporal regulation are thought to lie mainly outside the promoter region. Previously, we identified DNase I hypersensitive sites (DHS) that may contain regulatory elements associated with the CFTR gene at -79.5 and at -20.5 kb with respect to the ATG and at 10 kb into the first intron. MATERIALS AND METHODS: In order to evaluate these regulatory elements in vivo we examined these DHS in a human CFTR gene that was introduced on a yeast artificial chromosome (YAC) into transgenic mice. The 310 kb human CFTR YAC was shown to restore the pheno-type of CF-null mice and so is likely to contain most of the regulatory elements required for tissue-specific expression of CFTR. RESULTS: We found that the YAC does not include the -79.5 kb region. The DHS at -20.5 kb is present in the chromatin of most tissues of the transgenic mice, supporting its non-tissue-specific nature. The DHS in the first intron is present in a more restricted set of tissues in the mice, although its presence does not show complete concordance with CFTR expression. The intron I DHS may be important for the higher levels of expression found in human pancreatic ducts and in lung submucosal glands. CONCLUSION: These data support the in vivo importance of these regulatory elements.     

DNase I sensitivity of nuclear DNA measured by flow cytometry

The DNase I digestion kinetics of DNA in isolated nuclei (from HeLa or murine mammary carcinoma, 67 cells) were assayed flow cytometrically by measuring the changes in ethidium bromide (EtBr) fluorescence following various digestion time intervals. The DNase I digestion curve was characterized by an initial 25-30% increase in fluorescence upon addition of the enzyme, a rapid reduction in fluorescence to approximately 50-55% in 30 minutes, and a limit digest of 45-50% beyond 45 minutes. Throughout digestion, the DNA histogram retained its characteristic bimodal shape, showing that histogram rearrangement was not responsible for the changes in EtBr fluorescence. Irradiation with 5 X 10(6) rads (137Cs-gamma-rays) or exposure to 50 mM EDTA caused an increase in EtBr fluorescence similar to that caused by DNase I, suggesting that DNA nicking and/or chromatin loosening were responsible for this increase. Residual DNA assayed by the solubilization of 14C-TdR (thymidine)-labeled DNA indicated a similar kinetic pattern without the initial increase. However, at the limit digest, the fraction of DNA remaining trichloroacetic acid (TCA) insoluble (10%) was smaller than that measured by loss of EtBr fluorescence (50% of initial, 40% of maximum). Part of this difference was due to the presence of TCA soluble DNA trapped within the nuclear matrix (15-20%). This trapped DNA was released when the digested nuclei were exposed to 0.5-1.0 M NaCl just prior to EtBr staining. Exposure of HeLa cells to three agents that are believed to cause changes in chromatin structure resulted in alterations in the DNase I digestion kinetics measured flow cytometrically.(ABSTRACT TRUNCATED AT 250 WORDS)     

Signals in chicken beta-globin DNA influence chromatin assembly in vitro.

We have confirmed the result that chicken beta-globin gene chromatin, which possesses the characteristics of active chromatin in erythroid cells, has shortened internucleosome spacings compared with bulk chromatin or that of the ovalbumin gene, which is inactive. To understand how the short (approximately 180-bp) nucleosome repeat arises specifically on beta-globin DNA, we have studied chromatin assembly of cloned chicken beta-globin DNA in a defined in vitro system. With chicken erythrocyte core histones and linker histone H5 as the only cellular components, a cloned 6.2-kb chicken beta-globin DNA fragment assembled into chromatin possessing a regular 180 +/- 5-bp repeat, very similar to what is observed in erythroid cells. A 2-kb DNA subfragment containing the beta A gene and promoter region, but lacking the downstream intergenic region between the beta A and epsilon genes, failed to generate a regular nucleosome array in vitro, suggesting that the intergenic region facilitates linker histone-induced nucleosome alignment. When the beta A gene was placed on a plasmid that contained a known chromatin-organizing signal, nucleosome alignment with a 180-bp periodicity was restored, whereas nucleosomes on flanking plasmid sequences possessed a 210-bp spacing periodicity. Our results suggest that the shortened 180-bp nucleosome spacing periodicity observed in erythroid cells is encoded in the beta-globin DNA sequence and that nucleosome alignment by linker histones is facilitated by sequences in the beta A-epsilon intergenic region.     

Quantitation of DNase I sensitivity in Xenopus chromatin containing active and inactive globin, albumin and vitellogenin genes.

The disappearance of defined restriction fragments of the beta 1-globin, an albumin and the A1 vitellogenin gene was quantitated after DNase I digestion and expressed by a sensitivity factor defined by a mathematical model. Analysis of naked DNA showed that the gene fragments have similar but not identical sensitivity factors. DNase I digestion of chromatin revealed for the same gene fragments sensitivity factors differing over a much wilder range. This is correlated to the activity of the genes analyzed: the beta 1-globin gene fragment is more sensitive to DNase I in chromatin of erythrocytes compared to hepatocytes whereas the albumin gene fragment is more sensitive to DNase I in chromatin of hepatocytes. The A1 vitellogenin gene has the same DNase I sensitivity in both cell types. Comparing the DNase I sensitivity of the three genes in their inactive state we suggest that different chromatin conformations may exist for inactive genes.