Structural state of active and inactive genes during chromatin decondensation

Chromatin structure of globin and ovalbumin genes in chicken erythrocyte nuclei has been investigated by means of the "nuclease criterion" (described earlier). In intact nuclei (i.e. in the presence of 3 mM MgCl2) DNase I cleaves chromatin of both genes generating fragments multiple of a double-nucleosome repeat (2N-periodicity). However, in the case of the globin gene, apart from the 2N-periodicity, fragments were observed that are multiple of 100 b.p. and are characteristic for partially unfolded chromatin. This distinction in nuclease cleavage patterns correlates with a higher sensitivity of the globin gene as compared with the inactive ovalbumin gene. At 0.5-0.7 mM MgCl2 the transition from dinucleosomal fragmentation with DNase I and DNase II to fragmentation via a 100 b.p. interval occurs and the difference in digestibility of both genes is dramatically increased. If chromatin has been decondensed by incubation of nuclei in 10 mM Tris-buffer DNase Il generates an usual nucleosomal repeat, and in this ionic conditions one may not observe any difference in nuclease sensitivity of the analyzed genes. The data allow to suggest that the high nuclease sensitivity of potentially active genes can be conditioned by more relaxed arrangement of nucleosomes in higher order chromatin structure.     

Nascent DNA in nucleosome like structures from chromatin

We have used chromatin sensitivity to cleavage by micrococcal nuclease as a probe for differences between chromatin containing nascent DNA and that containing bulk DNA. Micrococcal nuclease digested the nascent DNA in chromatin of swimming blastulae of sea urchins more rapidly to acid-soluble nucleotides than the DNA of bulk chromatin. A part of the nascent DNA occurred in micrococcal nuclease-resistant structures which were either different from, or temporary modifications of, the bulk nucleosomes. This was inferred from the size differences between bulk and nascent DNA fragments in 10% polyacrylamide gels after micrococcal nuclease digestion of nuclei from a mixture of ¹⁴C-thymidine long- and ³H-thymidine pulse-labeled embryos. Bulk monomer and dimer DNA fragments contained about 170 and 410 base pairs (bp), respectively, when 18% of the bulk DNA had been rendered acid-soluble. At this level of digestion, “nascent monomer DNA” fragments of about 150 bp as well as 305 bp “large nascent DNA fragments” were observed. Increasing levels of digestion indicated that the large nascent DNA fragment was derived from a chromatin structure which was more resistant to micrococcal nuclease cleavage than bulk dimer chromatin subunits. Peaks of ³H-thymidine-labeled DNA fragments from embryos which had been pulse-labeled and then chased or labeled for several minutes overlapped those of ¹⁴C-thymidine long-labeled monomer, dimer and trimer fragments. This indicated that the chromatin organization at or near the replication fork which had temporarily changed during replication had returned to the organization of its nonreplicating state.     

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.     

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.     

The chromatin structure of specific genes: II. Disruption of chromatin structure during gene activity.

We have compared the chromatin structure in the active and inactive states at loci encoding the major heat shock protein in Drosophila. DNAase I and micrococcal nuclease were used as probes of higher order organization and nucleosomal integrity. Such integrity is gauged here by the characteristic pattern of discrete DNA fragments produced at specific chromosomal loci by nucleolytic cleavage. The specific fragment patterns are visualized by gel electrophoresis, Southern blotting onto nitrocellulose sheets, hybridization with 32P-labeled cloned DNA containing the heat shock genes and autoradiography. Using this criterion, a disruption in nucleosomal and possibly in higher order organization are observed as indicated by a relative loss or smearing of the characteristic discrete DNA fragment patterns from the heat shock loci in the active state. The fragment patterns are restored when cells are allowed to recover from heat shock and these loci return to the inactive state.     

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.     

A 21 KDa protein resides in the nucleosomes of micrococcal nuclease sensitive liver chromatin of Atlantic salmon treated with estradiol

Atlantic salmon was treated with 17-beta-estradiol to induce the process of vitellogenesis in liver. When the isolated liver nuclei were incubated with micrococcal nuclease at increasing enzyme/DNA ratios a 21 KDa protein appeared in the nuclease sensitive chromatin, the S-fraction. After HPLC gel filtration the 21 KDa protein resided with the oligo- and mononucleosomes. The S-fraction contained vitellogenin gene sequences at low nuclease/DNA ratios. The sequences were detectable also in the mononucleosomes derived from the S-fraction. After hormone treatment the vitellogenin gene exposed a higher sensitivity to micrococcal nuclease than the hormone-untreated controls. The results indicate that the 21 KDa protein took part in the hormone-mediated changes in gene expression by modulating the structure of estradiol responsive chromatin domains including the vitellogenin gene.     

The variation with age of the structure of chromatin in three cell types from rat liver.

The organization of chromatin in three rat liver nuclear populations, namely diploid stromal, diploid parenchymal, and tetraploid parenchymal nuclei, which were separated by zonal centrifugation, was studied by digestion with micrococcal nuclease and pancreatic deoxyribonuclease in 3-week-old rats in which the parenchymal cells contain diploid nuclei and in 2-and 4-month-old rats with a high proportion of tetraploid nuclei. Digestion by micrococcal nuclease allowed the estimation of DNA-repeat length in chromatin. Parenchymal nuclei have shorter repeat length than stromal nuclei and DNA-repeat length increases with the age in all three nuclei populations. The kinetics of digestion by micrococcal nuclease showed that nuclei with shorter repeat length are more sensitive to micrococcal nuclease and that the sensitivity of chromatin decreases with age for all the types of nuclei in this study. The kinetics of digestion by pancreatic deoxyribonuclease showed that sensitivity of chromatin is related to the repeat length and that the sensitivity decreases with the ages.