Changes in non-histone chromatin proteins during the storage of chromatin

We have described here the changes in stored chicken reticulocyte chromatin which take place among non-histone protein fractions based on SDS-polyacylamide gel electrophoresis and hybridization of globin cDNA with RNAs transcribed on native and reconstitited chromatin templates.     

Histone acetyltransferase in chromatin. Extraction of transferase activity from chromatin

Previous work has attempted to localize nuclear histone acetyltransferase activity in the cromatin. Evidence was presented indicating that the transfer of ¹⁴C-acetate from ¹⁴C-acetyl CoA to histones in chromatin was an enzymatic process. We now report on the extraction of part of the histone acetyltransferase activity from rat liver chromatin, employing a procedure originally described for extraction of DNA-dependent RNA polymerase. The K_m of the extracted transferase activity for the substrate acetyl CoA was 5 × 10⁻⁷, the Q₁₀: 1.8 and the optimal pH: 7.1. Serum albumine, protamine and polylysine were poor substrates as compared to histones. Activity of extracted or heated chromatin was not restored upon incubation in the presence of extract. Also the selectivity exhibited by the transferase activity in unextracted chromatin towards arginine-rich histones, was much less pronounced in the extracts prepared from it. It is possible that the influence of steric factors contributing to this specificity in native chromatin is lost upon isolation of the enzyme from it. Alternatively, a less specific isoenzyme may have been extracted.     

Effects of fast neutrons on chromatin: dependence on chromatin structure

The effects of fast neutrons (10-100 Gy) on chromatin extracted from normal (liver of Wistar rats) and tumor (Walker carcinosarcoma maintained on Wistar rats) tissues were compared. The spectroscopic assays used were (i) chromatin intrinsic fluorescence, (ii) time-resolved fluorescence of chromatin - proflavine complexes, and (iii) fluorescence resonance energy transfer (FRET) between dansyl chloride and acridine orange coupled to chromatin. For both normal and tumor chromatin, the intensity of intrinsic fluorescence specific for acidic and basic proteins decreased with increasing dose. The relative contributions of the excited-state lifetime of proflavine bound to chromatin were reduced upon fast-neutron irradiation, indicating a decrease in the proportion of chromatin DNA available for ligand binding. The Forster energy transfer efficiencies were also modified by irradiation. These effects were larger for chromatin from tumor tissue. In the range 0-100 Gy, fast neutrons induced alterations in DNA and acidic and basic proteins, as well as in global chromatin structure. The radiosensitivity of chromatin extracted from tumor tissue seems to be higher than that of chromatin extracted from normal tissue, probably because of its higher euchromatin (loose)--heterochromatin (compact) ratio.     

Synthesis of chromatin phospholipids

The presence of a phospholipid fraction associated with chromatin has been demonstrated by biochemical technique in rat hepatocytes. The composition of this fraction determined by chromatography with respect to that of the nuclei is characterized by low content of phosphatidylserine and high content in phosphatidylethanolamine. Also the synthesis and turnover studied after injection of [32P]O4(2-) show a different behaviour: the peak of activity is after 6 hrs in nuclei and microsomes, whereas in chromatin it occurs after 9 hrs. A second peak is evident after 24 hrs in chromatin and microsome phospholipids. Differences have been also shown by analyzing the single phospholipid radioactivity in time. The behaviour of chromatin phospholipids has also been studied during DNA premitotic synthesis in regenerating liver. It has been shown that there is no difference in synthesis in relation to that of DNA in nuclear phospholipids, whereas the specific activity of chromatin phospholipids begins to increase twelve hours after hepatectomy and continues throughout the period of the first mitotic wave, thus bringing to a summation with the beginning of the second wave. The role of this phospholipid fraction in relation to DNA synthesis and gene expression is discussed.     

Macroautophagy-aided elimination of chromatin

How tumor cells process damaged or unwanted DNA is a matter of much interest. Recently, Rello-Varona et al. (Cell Cycle 2012; 11:170–76) reported the involvement of macroautophagy (hereon autophagy) in the elimination of micronuclei (MN) from osteosarcoma cells. Prior to that, diminution of whole nuclei from multinucleated TP53-mutant tumor cells was described. Here, we discuss these two kinds of chromatin autophagy evoked after genotoxic stress in the context of the various biological processes involved: (1) endopolyploidy and the ploidy cycle; (2) the timing of DNA synthesis; (3) DNA repair; (4) chromatin:nuclear envelope interactions; and (5) cytoplasmic autophagy. We suggest that whereas some MN can be reunited with the main nucleus (through interactions with envelope-limited chromatin sheets) and participate in DNA repair, failure of repair serves as a signal for the chromatin autophagy of MN. In turn, autophagy of whole sub-nuclei in multi-nucleated cells appears to favor de-polyploidization, mitigation of aneuploidy with its adverse effects, thereby promoting the survival fitness of descendents and treatment resistance. Thus, both kinds of chromatin autophagy provide tumor cells with the opportunity to repair DNA, sort and resort chromatin, reduce DNA content, and enhance survival.     

Genomic views of chromatin

With the availability of complete genome sequences for a number of organisms, a major challenge has become to understand how chromatin and its epigenetic modifications regulate genome function. High-throughput microarray and sequencing technologies are being combined with biochemical and immunological enrichment methods to obtain genome-scale views of chromatin in a variety of organisms. The data pinpoint novel, genomic elements and expansive chromatin domains, and offer insight into the functions of histone modifications. In parallel, state-of-the-art imaging techniques are being used to investigate higher-order chromatin organization, and are beginning to bridge our understanding of chromatin biology with that of chromosome structure.     

Nucleomeric organization of chromatin

Chromatin in the nuclei fixed in tissue and in the nuclei isolated by low ionic strength solutions in the presence of Mg2+ is represented by globular (nucleomeric) fibrils, 20-25 nm in diameter. The staphylococcal or endogenous nuclear nuclease splits the chromatin fibrils resulting in fragments corresponding to nucleomers and their multimers. Upon removal of firmly bound Mg2+ the nucleomers unfold to form chains consisting of 4-6-8 nucleosomes. Mild hydrolysis of nuclear chromatin by staphylococcal nuclease results in a split-off of mono-, di- and trimers of nucleomers sedimenting in a sucrose density gradient in the presence of EDTA as particles with the sedimentation coefficients of 37, 47 and 55S, respectively. The sedimentation coefficient for the mononucleomer in a sucrose density gradient with MgCl2 is 45S. Determination of the length of DNA fragments of chromatin split-off by staphylococcal nuclease showed that the nucleomer consists of 8 nucleosomes, while the dimer and trimer of the nucleomer consists of 14-16 and 21-24 nucleosomes, respectively. The nucleomeric monomer undergoes structural transition from the compact (45S) to the "loose" state (37S) after removal of Mg2+. This transition is completely reversible, when the nucleomer contains histone H1. The removal of the latter or dialysis of the nucleomer against EDTA in low ionic strength solutions results in a complete unfolding of the nucleomer into a nucleosomal chain fragment. A model for the nucleomer fibril structure in which the helical organization of the nucleosomal chain in the nucleomer (2 turns with 4 nucleosomes in each) is alternated with the impaired helical bonds between the nucleomers is discussed. The functional significance of the nucleomeric organization of chromatin may be an additional restriction of the site-specific recognition of DNA in chromatin with the possibility of local (at the level of one nucleomer) changes in chromatin conformation excluding this restriction.