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.     

Porcine follitropin. The amino-acid sequence of the beta subunit

By treatment with tRNA in the presence of 1 mM MgCl2, a chromatin preparation was obtained containing all five major histone fractions but lacking a considerable portion of non-histone proteins. This chromatin preparation as well as chromatin extracted with 0.6 M NaCl (depleted of H1 histone and some non-histone proteins) were characterized in respect of solubility and chromatin DNA accessibility. Both samples possessed practically the same solubility in the presence of 0.15 M NaCl and 1 mM MgCl2. The solubility of tRNA-treated chromatin in 5 and 10 mM MgCl2 was higher than that of salt-extracted chromation. The accessibility of the DNA of these chromatin preparations was tested with DNA-dependent RNA polymerase of Escherichia coli as a probe, using procedure that permits measurement of binding site frequency. Both tRNA-treated and salt-extracted chromatin contained as many as 33% and untreated chromatin as few as 4% of the number of binding sites found on protein-free DNA. These results demonstrate that at least in part the non-histone proteins are responsible for salt-induced insolubility and low DNA accessibility of chromatin, thus revealing the importance of non-histone proteins in the maintenance of an overall chromatin structure.     

Localization of antigens in the chromatin of normal rat liver cells, not detectable in hepatoma chromatin

Antibodies against rat liver chromatin interact with homologous chromatin as well as with chromatin of Zajdela ascite hepatoma and solid hepatoma 27, but not with the nuclear matrix isolated from these hepatomas. Rat liver chromatin regions hypersensitive to DNAase I and endogenous Mg2+-dependent nuclease are enriched with immunogenic nonhistone proteins. Using antiliver IgG pretreated with chromatin of Zajdela ascite hepatoma and solid hepatoma 27, it was shown that liver chromatin antigens that are not detectable in hepatoma cells are localized in hypersensitive to nucleases chromatin regions buy not in actively transcribed ones.     

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.     

Fractionation of micrococcal nuclease-digested chromatin solubilized at physiologic ionic strength

When mouse brain nuclei are optimally digested with micrococcal nuclease, most of the chromatin is soluble in a 180 mM salt/1 mM EDTA buffer [1]. At this ionic concentration, chromatin maintains its native structure [2]. In an attempt to selectively extract different fractions of chromatin from digested nuclei, we have examined the differential solubility of chromatin in the 180 mM salt buffer containing concentrations of MgCl2 ranging from 2 to 0 mM. The results suggest that digested chromatin may be fractionated into specific soluble chromatin fractions which correspond to nuclease-sensitive chromatin, bulk chromatin, and heterochromatin. These soluble fractions have a high molecular weight (up to 20 kbp), and contain a full complement of histones as well as a complex assortment of non-histone proteins. The residual insoluble fraction may be equivalent to a native, nuclear matrix-bound chromatin fraction.     

Thermal denaturation of sheared and unsheared chromatin by absorption and circular dichroism measurements.

Thermal denaturation of chromatin is observed by simultaneously monitoring absorption and circular dichroism at 276 nm as functions of temperature. Either observation indicates that sheared chromatins shows less thermal stability than native chromatin. The temperature-dependent ellipticities at 276 nm of these chromatins show features not seen in the absorption curves: the ellipticity of unsheared chromatin increases with temperature, while this increase is abolished or greatly reduced in the same chromatin after shearing. After its first thermal transition (prior to the helix-coli transition) the unsheared chromatin achieves the same ellipticity as sheared chromatin.     

A comparative study of chromatin from lymphocyte nuclei upon activation of transcription by irradiation from an He-Ne-laser or phytohemagglutinin]

The influence of He-Ne laser radiation (632.8 nm, 56 J/m2, t = 10 s) and phytohaemagglutinin (PHA, 2 micrograms/ml) on chromatin structure in human lymphocytes was studied by electron microscopy using ultrathin cell sections. Morphometric analysis of extranuclear condensed chromatin masses was performed 1 h after the irradiation or after the beginning of PHA treatment. In the irradiated cells the following insignificant changes were revealed: decrease in the relative area of the nucleoplasmic chromatin, increase in the relative area of decondensation zones as well as increase in the number of clumps of nucleoplasmic chromatin and relative length at their boundary with nucleoplasma. The tendency of these morphological changes may be interpreted as functional activation of extranucleolar RNA synthesis in response to irradiation by red laser light. Action of PHA results in significant changes of the surfaces of chromatin clumps, namely increase in relative length of nucleoplasmic chromatin boundary and decrease in relative length of perimembranous chromatin boundary with nucleoplasma as well as some less expressed delamination of the chromatin masses from the nuclear membrane. These essential changes may reflect chromatin activation by proliferative stimulus. Peculiarities of the ultrastructural reorganisation in the condensed chromatin after irradiation and PHA-treatment probably reflect the differences in the processes of gene activation caused by the two agents.     

Distribution of estradiol receptor and vitellogenin gene in chick liver chromatin fractions.

The distribution of estradiol receptor and vitellogenin gene was studied in estradiol stimulated chick liver chromatin fractions prepared by limited DNAse II digestion and MgCl2 precipitation. The receptor was found in all fractions, undigested chromatin (P1), Mg2+ insoluble chromatin (P2) and Mg2+ soluble chromatin (S2). This last fraction was rich in acidic proteins, had a high protein:DNA ratio (7.0 w/w), contained 28% of rapidly labelled RNA, 20% of the receptor, 3-5% of chromatin DNA and showed a 2 fold enrichment of vitellogenin DNA sequences over unfractionated chromatin as well as P1 and P2 DNA. On isopycnic metrizamide gradients, all chromatin fractions showed a receptor peak banding at 1.23 g/cm3, the density of nucleoproteins. Hybridization experiments showed that the DNA banding at this density in fraction S2 was enriched 4 fold in vitellogenin DNA sequences over unfractionated chromatin as well as P1 and P2 DNA. These results suggest an association of hormone receptor complex with nucleoprotein structures of an apparently active chromatin fraction.     

The globular domain of histone H5 is internally located in the 30 nm chromatin fiber: an immunochemical study.

The location of the globular domain of histone H5 relative to the axis of the 30 nm chromatin fiber was investigated by following the accessibility of this region of the molecule in chicken erythrocyte chromatin to specific antibodies as a function of chromatin structure. Antibodies to the globular domain of H5 as well as their Fab fragments were found to react with chromatin at ionic strengths ranging from 1-80 mM NaCl, the reaction gradually decreasing upon increase of salt concentration. If, however, Fab fragments were conjugated to ferritin, no reaction of the complex with chromatin was observed at salt concentrations higher than 20 mM. The accessibility of the globular part of H5 in unfolded chromatin to the Fab-ferritin complex was also demonstrated with trypsin-digested chromatin. The experiments were carried out by both solid-phase immunoassay and inhibition experiments. The data obtained are consistent with a structure in which the globular domain of H5 is internally located in the 30 nm chromatin fiber.     

Changes in the accessibility of chromatin antigenic determinants induced by different influences

The accessibility of protein antigenic determinants of rat thymocyte chromatin was studied in a reaction of complement fixation, using antisera from animals immunized with chromatin or non-histone proteins and control sera containing natural antichromatin IgG. It was shown that the bulk of the antigenic determinants of intact chromatin are inaccessible for antibodies. The reactivity of chromatin in the complement fixation assay increases after ultrasonication or irradiation in vitro as well as the enzymatic cleavage of chromatin down to nucleosomes and their oligomers in dying thymocytes in vivo. This effect can mainly be due to changes of chromatin compactization.     

综述: 表观遗传之染色质重塑

真核细胞中的染色质重塑因子种类繁多,多数以蛋白多聚体的形式存在于细胞中．不同的染色质重塑因子在特定时间定位于特定的核小体上,通过改变染色质结构,影响基因转录活性,进而确保细胞内各种生物学过程的正确运行．另外,染色质重塑因子根据所含功能结构域的不同,大致分为SWI/SNF、ISWI、CHD和INO80四大家族,不同的染色质重塑因子之间既有蛋白质结构和酶活性的相似性,各自又有其特异性．本综述的宗旨在于全面概括和总结染色质重塑因子的分类、结构特点以及其在细胞内的生物学功能,为深入研究染色质重塑因子的生物学功能,尤其是在发育和疾病发生中的作用机制提供理论基础．     

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.     

Plant chromatin: development and gene control

It is increasingly clear that chromatin is not just a device for packing DNA within the nucleus but also a dynamic material that changes as cellular environments alter. The precise control of chromatin modification in response to developmental and environmental cues determines the correct spatial and temporal expression of genes. Here, we review exciting discoveries that reveal chromatin participation in many facets of plant development. These include: chromatin modification from embryonic and meristematic development to flowering and seed formation, the involvement of DNA methylation and chromatin in controlling invasive DNA and in maintenance of epigenetic states, and the function of chromatin modifying and remodeling complexes such as SWI/SNF and histone acetylases and deacetylases in gene control. Given the role chromatin structure plays in every facet of plant development, chromatin research will undoubtedly be integral in both basic and applied plant biology.     

Prime, repair, restore: the active role of chromatin in the DNA damage response

The view of DNA packaging into chromatin as a mere obstacle to DNA repair is evolving. In this review, we focus on histone variants and heterochromatin proteins as chromatin components involved in distinct levels of chromatin organization to integrate them as real players in the DNA damage response (DDR). Based on recent data, we highlight how some of these chromatin components play active roles in the DDR and contribute to the fine-tuning of damage signaling, DNA and chromatin repair. To take into account this integrated view, we revisit the existing access-repair-restore model and propose a new working model involving priming chromatin for repair and restoration as a concerted process. We discuss how this impacts on both genomic and epigenomic stability and plasticity.