Immunospecificity of nuclear antigens in chicken erythroid cells

Summary Specific antisera were produced against chicken reticulocyte dehistonized chromatin. The antisera reacts strongly with chicken reticulocyte chromatin, but only marginally with chicken erythrocyte chromatin. There is no reticulocyte antigen detected in chicken liver. Reticulocyte maturation is accompanied by a gradual decrease in the chromatin immunological activity and template capacity. The reduction of immunological activity is due to the change of chromatin conformation during erythrocyte maturation. Dehistonization and sonication of erythrocyte chromatin raises the erythrocyte chromatin immunological activity to levels similar to those of reticulocyte chromatin. The erythrocyte nuclear antigens are class specific, not being found in frog erythroid cell or murine Friend leukemia cell chromatins.     

Chromatin maturation depends on continued DNA-replication

The structure of [3H]thymidine pulse-labeled chromatin in lymphocytes differs from that of non-replicating chromatin by several operational criteria which are related to the higher nuclease sensitivity of replicating chromatin. These structural features of replicating chromatin rapidly disappear when the [3H]thymidine pulse is followed by a chase in the presence of an excess of non-radioactive thymidine. However, when the rate of DNA replication is reduced, as in cycloheximide-treated lymphocytes, chromatin maturation is retarded. No chromatin maturation is observed when nuclei from pulse-labeled lymphocytes are incubated in vitro in the absence of DNA precursors. In contrast, when these nuclei are incubated under conditions known to be optimal for DNA replication, the structure of replicating chromatin is efficiently converted to that of 'mature', non-replicating chromatin. We conclude that the properties of nascent DNA and/or the distance from the replication fork are important factors in chromatin maturation.     

Chromatin organization in relation to the nuclear periphery

In the limited space of the nucleus, chromatin is organized in a dynamic and non-random manner. Three ways of chromatin organization are compaction, formation of loops and localization within the nucleus. To study chromatin localization it is most convenient to use the nuclear envelope as a fixed viewpoint. Peripheral chromatin has both been described as silent chromatin, interacting with the nuclear lamina, and active chromatin, interacting with nuclear pore proteins. Current data indicate that the nuclear envelope is a reader as well as a writer of chromatin state, and that its influence is not limited to the nuclear periphery.     

Structure of the interphase chromatin in the ciliata Bursaria truncatella macronucleus. II. Loop organization of inactive chromatin clumps

Electron microscopic study of chromatin organization in isolated macronuclei of a ciliate Bursaria truncatella showed macronuclear chromatin to be organized in compact clumps 120--180 nm in diameter linked with each other by one or several chromatin fibres. Macronucleus being dispersed in a solution of low ionic strength, radial loops basically of nucleosomal structure start appearing around chromatin clumps. Long-time dispersing of macronuclear chromatin brings complete decompactization of chromatin clumps into a set of nucleosome fibres. The way the fibres of interphase chromatin are packed in a chromatin clump is discussed.     

Methylation of chromatin DNA.

E. coli DNA methylase has been used to methylate chromatin DNA in vitro. At saturation only 50% of the chromatin DNA becomes methylated. The methylated regions of chromatin correspond to that fraction of the chromatin which is sensitive to staphylococcal nuclease. Using in vitro methylated chromatin followed by nuclease digestion movement of chromatin proteins along the DNA can be detected. By this criterion, sonication of chromatin or precipitation with MnCl2 causes 10% of the previously uncovered methylated regions to become covered by protein. Reconstitution of methylated chromatin results in the randomization of the chromatin proteins. Using nuclei which were methylated in vitro we have demonstrated that a small degree of protein sliding does occur during the preparation of chromatin from nuclei. Finally, we have prepared open region DNA by polylysine titration. This procedure does not cause displacement of chromatin proteins.     

Further investigations on the property of chromatins from apical and axial parts of cauliflower inflorescence

To evaluate the importance of histone F1 for RNA synthesis in cauliflower in relation to the differentiation between apical and axial tissues, the F1 fraction from apical chromatin was removed and the property of the residual (F1-depleted) chromatin was investigated compared to that of axial chromatin. It was found that the derivative melting profile of the residual chromatin was quite similar to that of the axial chromatin, and the nucleotide composition of RNA synthesized with the residual chromatin as template was also like that of the axial chromatin. The phosphate content of the histone F1 fraction isolated from apical chromatin was markedly lower than that of the F1 fraction from axial chromatin. Further, it was ascertained from MAK-column chromatography of [¹⁴C]uridine incorporation into RNA synthesized in excised tissues that axial chromatin in situ has a much higher template activity for RNA synthesis than does apical chromatin. It was postulated that the higher RNA synthesizing activity in the axial part of the cauliflower head can be attributed mainly to the presence of active chromatin in which the histone F1-depleted region is more prevalent than it is in apical chromatin.     

Purification and properties of tyrosinases from Vibrio tyrosinaticus

Rat liver chromatin which has been briefly sonicated is fractionated by treatment with low concentrations of magnesium ion. At 1.5 mm Mg²⁺, where approximately 20–25% of the chromatin remains soluble after low-speed centrifugation, chemical and physical analysis of the Mg-soluble and Mg-insoluble chromatin fractions show that the fractions possess markedly different properties. The Mg-soluble chromatin has more protein and RNA than the Mg-insoluble chromatin. The histone composition of the two fractions as shown by electrophoretic analysis is similar, but many of the acidic proteins are qualitatively and quantitatively different. The molecular weight of the Mg-soluble chromatin is less than that of the insoluble chromatin based on sedimentation behavior and gel filtration experiments. The soluble chromatin has nearly twice the template activity for RNA synthesis in vitro with added RNA polymerase as the Mg-insoluble chromatin and contains approximately 80% of the in vivo rapidly labeled RNA found in the total chromatin preparation. In addition the Mg-soluble chromatin has a significantly greater amount of “accessible” DNA (62%) as measured by polylysine binding than Mg-insoluble chromatin (48%). The data suggest that (a) fractionation of chromatin preparations can be achieved by titration with Mg²⁺, and (b) chromatin soluble in low concentrations of Mg²⁺ may be enriched in actively transcribed portions of the genome.     

Chromatin compaction and the efficiency of formation of DNA-protein crosslinks in gamma-irradiated mammalian cells.

Chromatin has been prepared from Chinese hamster V79 cell nuclei by successive suspension and sedimentation in buffers of decreasing ionic strength. For buffer concentrations from 50 to 1 mM, the resultant chromatin maintained a normal histone content, nucleosomal organization, and attachment to the nuclear matrix; however, as the buffer concentration was reduced from 50 to 10 and 1 mM, the higher-order chromatin structures became increasingly relaxed. Fully expanded chromatin is 5- to 10-fold more susceptible to the induction of DNA-protein crosslinks (DPCs) by gamma radiation than is chromatin residing in living interphase cells. As much as 60-70% of expanded chromatin can be induced to form DPCs as compared to a maximum of about 20% of cellular DNA. For expanded chromatin, the maximum level of induced DPCs is two to three times higher than would be expected if only matrix-associated DNA were induced to form DPCs. Therefore, DNA in distal regions of chromatin loops must also be induced to form DPCs with histones or other nonhistone chromosomal proteins. The hypersensitivity of isolated chromatin to radiation-induced production of DPCs appears to be related to the expansion of chromatin conformation rather than to the removal of intracellular radical scavengers for the following reasons: (a) there is an inverse relationship between the buffer concentration in which the chromatin is suspended and DPC formation, and (b) the induction of a more compact 30-nm chromatin fiber from the expanded 10-nm chromatin fiber in the presence of a low concentration of MgCl2 results in a marked reduction in DPC formation. The formation of radiation-induced DPC seems to occur at maximum efficiency in fully expanded chromatin, since DPC formation cannot be further stimulated by the addition of Cu2+, which can catalyze the production of OH by Fenton chemistry. It is concluded that radiation-induced DNA damage production is greatly influenced by chromatin conformation, and that chromatin as it exists in the cell is a relatively poor substrate for DNA-protein crosslinking in comparison to completely expanded chromatin.     

Structure of transcriptionally-active chromatin subunits.

Rat liver chromatin is organized into regions of DNA which differ in degree of susceptibility to attack by the endonucleases DNase I and DNase II. The most nuclease-sensitive portion of chromatin DNA is enriched in transcribed sequences. This fraction may be separated from the bulk of chromatin by virtue of its solubility in solutions containing 2 mM MgCl2. Both transcribed and nontranscribed regions of chromatin are organized into repeating units of DNA and histone, which appear as 100 A beads in the electron microscope. The length of DNA in the repeat unit is the same for these two classes of chromatin (198 +/- 6 base pairs in rat liver); however, the subunits of active, Mg++-soluble chromatin differ from the nucleosomes of inactive regions of chromatin in several respects. Active subunits are enriched in nascent RNA and nonhistone protein and exhibit higher sedimentation values than the corresponding subunits of inactive chromatin.     

Degradation of HeLa cell chromatin by neocarzinostatin and its chromophore

Chromatin is the in vivo target site for neocarzinostatin, a DNA strand scission antitumor drug. The effect of neocarzinostatin and its active chromophore component on HeLa cell chromatin is described here. Chromatin consisting of a mixture of mono-, di-, tri- and larger nucleosome fragments is prepared by micrococcal nuclease digestion of HeLa cell nuclei. Drug-induced conversion of chromatin to smaller sized fragments is measured by electrophoresis of the DNA on non-denaturing 4% polyacrylamide gels. Chromatin breakdown measured under these conditions is double-stranded in nature. In the presence of 2 mM dithiothreitol, neocarzinostatin causes degradation of large chromatin fragments and a loss of distinct nucleosome peaks. Detection of chromatin breakdown by neocarzinostatin is dependent upon the concentration of chromatin in the assay. When chromatin is increased from 14 to 70 micrograms/ml, changes in the larger fragments caused by 100 micrograms/ml neocarzinostatin become less obvious are are almost undetectable at 140 micrograms/ml chromatin. No change is observed when chromatin is treated with either neocarzinostatin or its chromophore in the absence of dithiothreitol. For detectable levels of chromatin degradation, 10 micrograms/ml neocarzinostatin is required compared to only 2.5 microgram/ml chromosome (expressed in microgram equivalent neocarzinostatin). Such degradation also occurs more rapidly with chromophore than with neocarzinostatin. Digestion of chromatin with neocarzinostatin continues for at least 30 min at 37 degrees C, while similar degradation caused by chromophore is complete in 1 min. Neocarzinostatin levels which actively degrade isolated chromatin can also effect release of soluble chromatin from intact nuclei. The released chromatin can serve as a substrate for micrococcal nuclease digestion. Such chromatin studies should prove useful in characterizing the mechanism of action of DNA reactive drugs such as neocarzinostatin.     

30nm染色质纤维结构与表观遗传调控

真核生物的DNA以染色质形式通过逐级折叠压缩形成高级结构存在于细胞核中。染色质高级结构直接参与了真核基因的转录调控和其它与DNA相关的生物学事件,因此研究染色质高级结构对了解表观遗传学分子机制有着至关重要的作用。近些年,研究者们针对30 nm染色质高级结构提出了两个模型:螺线管模型和Zig-Zag模型。2014年,我们利用体外染色质组装体系重建了30 nm染色质纤维,运用高精度冷冻电镜技术得到了分辨率为11?的30 nm染色质纤维的精细结构,提出了30 nm染色质高级结构的左手双螺旋Zig-Zag模型。本文综述了30 nm染色质纤维结构研究方面的相关进展,并对30 nm染色质高级结构的表观遗传调控机理以及单分子成像和操纵技术在研究30 nm染色质高级结构中潜在的应用作出讨论和展望。     

Increased susceptibility of activated rat liver chromatin to DNAse I

Rat liver chromatin activated by partial hepatectomy is more susceptible to the action of DNAse I than control chromatin isolated from intact liver. The study on the transfer of chromatin material to the acid-soluble fraction reveals a higher rate of activated chromatin degradation. Activated chromatin shows also an increased capacity for ethidium bromide (EB) binding as estimated from the isotherms of adsorption. The difference in EB binding between activated and control chromatin is abolished after DNAse I treatment. Conditions of mild digestion with DNAse I have been found under which the number of binding sites for EB per nucleotide decreases to almost the same level in activated and non-activated chromatin. The results suggest a preferential degradation of those DNA sequences in activated chromatin that are responsible for the increase in the ligand binding.     

Superstructural differences between chromatin in nuclei and in solution are revealed by kinetics of micrococcal nuclease digestion.

Digestion of chromatin in nuclei by micrococcal nuclease, measured as the change in the concentration of monomer-length DNA with time, displays Michaelis-Menten kinetics. Redigestion of soluble chromatin prepared from nuclei by micrococcal nuclease treatment, however, is apparently first order in enzyme and independent of chromatin concentration. This qualitative difference results from an increase in the apparent second order rate constant, kcat/Km, for liberation of monomer DNA: the apparent Km for soluble chromatin is lower by close to 3 orders of magnitude than that for chromatin in nuclei, whereas kcat decreases by less than 1 order of magnitude. Neither the integrity of the nuclear membrane nor the presence of histone H1 contributes to the high Michaelis constant characteristic of chromatin in nuclei. Moreover, differences due to the buffers used for digestion and redigestion are minimal. Low catalytic efficiency is, however, correlated with the presence of higher order chromatin superstructure. Micrococcal nuclease added to soluble chromatin under nondigesting conditions at low ionic strength (I = 0.002) co-sediments with chromatin in sucrose gradients. In 0.15 M NaCl, added nuclease no longer sediments with chromatin and redigestion kinetics become first order in both enzyme and substrate. Kinetic analysis of this type may afford an assay for native, higher order structures in chromatin. Our results suggest that micrococcal nuclease binds to soluble chromatin through additional interactions not present in nuclei, which may be partly ionic in nature.     

Chromatin Compaction Protects Genomic DNA from Radiation Damage

Genomic DNA is organized three-dimensionally in the nucleus, and is thought to form compact chromatin domains. Although chromatin compaction is known to be essential for mitosis, whether it confers other advantages, particularly in interphase cells, remains unknown. Here, we report that chromatin compaction protects genomic DNA from radiation damage. Using a newly developed solid-phase system, we found that the frequency of double-strand breaks (DSBs) in compact chromatin after ionizing irradiation was 5–50-fold lower than in decondensed chromatin. Since radical scavengers inhibited DSB induction in decondensed chromatin, condensed chromatin had a lower level of reactive radical generation after ionizing irradiation. We also found that chromatin compaction protects DNA from attack by chemical agents. Our findings suggest that genomic DNA compaction plays an important role in maintaining genomic integrity.     

The histone chaperone Asf1p mediates global chromatin disassembly in vivo

The packaging of the eukaryotic genome into chromatin is likely to be mediated by chromatin assembly factors, including histone chaperones. We investigated the function of the histone H3/H4 chaperones anti-silencing function 1 (Asf1p) and chromatin assembly factor 1 (CAF-1) in vivo. Analysis of chromatin structure by accessibility to micrococcal nuclease and DNase I digestion demonstrated that the chromatin from CAF-1 mutant yeast has increased accessibility to these enzymes. In agreement, the supercoiling of the endogenous 2mu plasmid is reduced in yeast lacking CAF-1. These results indicate that CAF-1 mutant yeast globally under-assemble their genome into chromatin, consistent with a role for CAF-1 in chromatin assembly in vivo. By contrast, asf1 mutants globally over-assemble their genome into chromatin, as suggested by decreased accessibility of their chromatin to micrococcal nuclease and DNase I digestion and increased supercoiling of the endogenous 2mu plasmid. Deletion of ASF1 causes a striking loss of acetylation on histone H3 lysine 9, but this is not responsible for the altered chromatin structure in asf1 mutants. These data indicate that Asf1p may have a global role in chromatin disassembly and an unexpected role in histone acetylation in vivo.