The nuclease sensitivity of active genes.

Brief micrococcal nuclease digestion of chick embryonic red blood cells results in preferential excision and solubilization of monomer nucleosomes associated with beta-globin sequences and also 5'-sequences flanking the beta-globin gene. Both regions are DNAse-I sensitive in nuclei. Such salt-soluble nucleosomes are enriched in all four major HMG proteins but HMG1 and 2 are only weakly associated. These nucleosomes appear to have lost much of the DNAse-I sensitivity of active genes. The HMG14 and 17-containing salt-soluble nucleosomes separated by electrophoresis are not DNAse-I sensitive and contain inactive gene sequences as well as active sequences. Reconstitution of HMG proteins onto bulk nucleosomes or chromatin failed to reveal an HMG-dependent sensitivity of active genes as assayed by dot-blot hybridization and it was found that the DNAse-I sensitivity of ASV proviral sequences as assayed by dot-blot hybridization was not HMG-dependent. These results indicate that higher order chromatin structures might be responsible for nuclease sensitivity of active genes.     

Differential nuclease sensitivity of the ovalbumin and beta-globin chromatin regions in erythrocytes and oviduct cells of laying hen.

We have monitored the differential nuclease sensitivity of defined regions of the chicken genome in different cells using a method which combines restriction enzyme digestion and blotting to diazobenzyloxymethyl (DBM)-paper (see Ref. 11). By using different specific probes and by scanning the bands on the autoradiograms, it is possible to compare on the same blot the digestion patterns of similar-sized fragments from different regions of the genome corresponding to "active" and reference "inactive" genes. We have demonstrated the preferential sensitivity to DNaseI and micrococcal nuclease digestion of the ovalbumin gene region in hen oviduct chromatin. The beta-globin gene region (containing both an adult and an embryonic gene) is also preferentially digested by DNaseI in hen mature erythrocyte nuclei, but at a lower rate than the ovalbumin gene region in oviduct. These observations raise the possibility that there may be several types of preferential nuclease sensitivities, all characterized by increased rates of digestion but to different levels, the highest corresponding to the very actively transcribing genes.     

Gamma rays and bleomycin nick DNA and reverse the DNase I sensitivity of beta-globin gene chromatin in vivo.

The active beta-globin genes in chicken erythrocytes, like all active genes, reside in large chromatin domains which are preferentially sensitive to digestion by DNase I. We have recently proposed that the special structure of chromatin in active domains is maintained by torsional stress in the DNA (Villeponteau et al., Cell 39:469-478, 1984). This hypothesis predicts that nicking of the DNA within any such chromosomal domain in vivo will relax the DNA and lead to loss of the special DNase I-sensitive state. Here we have tested this prediction by using gamma irradiation and bleomycin treatment to cleave DNA within intact chicken embryo erythrocytes. Both treatments cause reversal of DNase I sensitivity. Moreover, reversal occurs at approximately one nick per 150 kilobase pairs for both agents despite their entirely unrelated modes of cell penetration and DNA attack. These results suggest that the domain of DNase I sensitivity surrounding the beta-globin genes comprises 150 kilobase pairs of chromatin under torsional stress and that a single DNA nick in this region is sufficient to reverse the DNase I sensitivity throughout the entire domain.     

A structure of potentially active and inactive genes of chicken erythrocyte chromatin upon decondensation.

In the presence of 3 mM MgCl2 DNase I cleavage of bulk, globin and ovalbumin gene chromatin in chicken erythrocyte nuclei generates fragments which are multiples of a double-nucleosome repeat. However, in addition to the dinucleosomal periodicity beta-globin gene chromatin was fragmented into multiples of a 100 b.p. interval which is characteristic for partially unfolded chromatin. This distinction correlates with higher sensitivity of beta-globin domain to DNase I and DNase II as compared to the inactive ovalbumin gene. At 0.7 mM MgCl2 where these DNases fragment bulk chromatin into series of fragments with a 100 b.p. interval, the difference in digestibility of the investigated genes is dramatically decreased. When chromatin has been decondensed by incubation of nuclei in 10 mM Tris-buffer, DNase II generates a typical nucleosomal repeat, and the differential nuclease sensitivity of the analyzed genes is not observed. The data suggest that higher nuclease sensitivity of potentially active genes is due to irregularities in higher order chromatin structure.     

Digestion of insect chromatin with micrococcal nuclease, DNase I and DNase I combined with single-strand specific nuclease S1.

The chromatin of the lepidopteran Ephestia kuehniella was digested by micrococcal nuclease, DNase I and S1-nuclease combined with DNase I pretreatment. The resulting DNA fragments were analyzed by gel electrophoresis and compared with the DNA fragments of rat liver nuclei obtained by the same process. Extensive homology was revealed between insect and mammalian chromatin structure. The combined DNase I- S1-nuclease digestion yields double-stranded DNA fragments of lengths from 30 to 110 base-pairs. These DNA fragments are not obtained from nuclei predigested extensively with micrococcal nuclease. The results are discussed with respect to the internal structure of the chromatin subunit.     

Nuclease sensitivity of active chromatin.

The active regions of chicken erythrocyte nuclei were labeled using the standard DNase I directed nick translation reaction. These nuclei were then used to study the characteristics and, in particular, the nuclease sensitivity of active genes. Although DNase I specifically attacks active genes, micrococcal nuclease solubilizes these regions to about the same degree as the total DNA. On the other hand micrococcal nuclease does selectively cut the internucleosomal regions of active genes resulting in the appearance of mononucleosomal fraction which is enriched in active gene DNA. A small percentage of the active chromatin is also released from the nucleus by low speed centrifugation following micrococcal nuclease treatment. The factors which make active genes sensitive to DNase I were shown to reside on individual nucleosomes from these regions. This was established by showing that isolated active mononucleosomes were preferentially sensitive to DNase I digestion. Although the high mobility group proteins are essential for the maintenance of DNase I sensitivity in active regions, these proteins are not necessary for the formation of the conformation which makes these genes preferentially accessible to micrococcal nuclease. The techniques employed in this paper enable one to study the chromatin structure of the entire population of actively expressed genes. Previous studies have elucidated the structure of a few special highly prevalent genes such as ovalbumin and hemoglobin. The results of this paper show that this special conformation is a general feature of all active genes irregardless of the extent of expression.     

Protection of expressed immunoglobulin genes against nuclease cleavage.

Fragmentation of the actively transcribed kappa immunoglobulin gene in mouse myeloma nuclei with micrococcal nuclease and the restriction nuclease Bsp RI reveals a chromatin structure without the regularity of repeating nucleosomes found in bulk chromatin. Such regularity is restored about 2.2 kb 3' of the coding region. An only moderately increased micrococcal nuclease sensitivity and a 65% average protection of the Bsp RI sites indicates a DNA-protein interaction in the transcribed region which is not very different from that of an inactive gene. As determined by indirect endlabeling the frequency of Bsp RI cleavage both, after very mild and exhaustive digestion, varied moderately from site to site along the gene. In addition, it was not in each case the same at analogous sites on both alleles which are both transcribed. Thus, the experiments demonstrate differences between the chromatin structures of the genes which may be related to regulatory phenomena and thereby corroborate earlier findings made with DNAase I.     

Organization of the thyroid hormone receptor in the chromatin of C6 glial cells: Evidence that changes in receptor levels are not associated with changes in receptor distribution

The association of [¹²⁵I]T3-receptor complexes with C6 cell chromatin was analysed after a limited digestion with micrococcal nuclease (MN) or DNase I. Both nucleases solubilized up to 60–70% of receptor and 0.4 M KCl extracted 70%, of the non-digested receptor, thus showing that only a residual fraction of receptor is associated with the nuclear matrix. With DNase I the receptor was released 2–3-fold faster than the bulk of chromatin, whereas a preferential release of receptor over total chromatin was not observed with MN. The digestion of receptor with DNase I and MN occurred 14- and 6-fold faster, respectively, than the appearance of PCA-soluble chromatin. Preincubation for 48 h with 4 nM T3 of 2 mM butyrate significantly altered receptor levels but did not change sensitivity to the nucleases. These results suggest that the thyroid hormone receptor is associated with chromatin highly sensitive to nuclease digestion, and that changes in receptor number are not associated with changes in its distribution in chromatin.     

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.     

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.     

Expansion of chicken erythrocyte nuclei upon limited micrococcal nuclease digestion. Correlation with higher order chromatin structure

A sensitive method for measuring nuclear volumes with a Coulter counter is described. It has been applied to the digestion of chicken erythrocyte nuclei by micrococcal nuclease and DNase I. Early in digestion, micrococcal nuclease induced a 20% increase in the effective spherical volume of the nuclei, followed by a gradual reduction. At the peak of nuclear swelling, about 17% of the chromatin was soluble after lysis and its average chain length was about 18 kilobase pairs (kb). DNase I digestion did not give rise to a corresponding expansion of the nuclei. Several preparation conditions, including the treatment of nuclei with 0.2% Triton X-100, led to a loss of the expansion effect upon subsequent micrococcal nuclease digestion. The results support the domain theory of higher order chromatin structure. In the context of this model, the observed maximum nuclear expansion correlates with an average of one nuclease scission per domain.