Regulation of DNA synthesis by the higher-order chromatin structure

Mouse erythroleukemia cells were treated with the topoisomerase II poison VP-16, the intrastrand crosslinking agent cis-DDP, and the ribonucleotide reductase inhibitor hydroxyurea. In all cases, the rate of DNA synthesis decreased as a result of the treatment. To study the mechanism of inhibition of DNA chain elongation, we determined DNA synthesis in a cell-free replication system containing isolated nuclei and cytoplasmic extracts. The rate of DNA synthesis in the reactions containing nuclei isolated from untreated cells and extracts from cells treated with the three drugs were slightly reduced and did not show significant differences between the drugs. In the systems containing nuclei from cells treated with cis-DDP, DNA synthesis was again slightly inhibited; synthesis in nuclei treated with hydroxyurea was enhanced, and synthesis in the systems containing nuclei from cells treated with VP-16 was significantly reduced. DNA synthesis was reduced to the same extent in a system containing nuclei isolated from untreated cells that had been briefly sonicated to introduce a limited number of double-strand breaks in the DNA. As VP-16 and sonication mediate changes in chromatin topology, these results suggest that, along with the trans-acting signal transduction pathways, there is a topologic mechanism for regulation of DNA synthesis in the S phase of the cell cycle.     

Studies on the stability of the higher-order structure of rat liver chromatin containing high-mobility-group proteins

The stability of the higher-order structure of chromatin containing high-mobility-group (HMG) proteins has been studied in rat liver nuclei by mild micrococcal nuclease digestion at low temperature and fractionation by sucrose gradient centrifugation. Nuclei preparation and digestion, chromatin solubilization and analysis have been carried out in two ionic conditions, 140 mM and 40 mM monovalent cation concentration, avoiding drastic changes in ionic conditions and temperature during preparation and analysis. During the time course of digestion at 140 mM ionic strength a material stable at 80 S appears, whose DNA is cleaved at values around 12 nucleosomes. The distribution of HMG proteins in different chromatin fractions was analyzed by immunodot using antibodies elicited against proteins HMG-1, HMG-2, and HMG-14 and 17. It appears that these proteins have a distribution distinctly different from the bulk of chromatin. They are never found in the chromatin fragments that keep their internucleosomal interactions, indicating that these proteins tend to accumulate in points where the chromatin has a less stable structure.     

The role of charge neutralization and cooperative binding of linker histone in the higher-order structure of chromatin

The binding mode and stoichiometry of interaction between soluble rat liver chromatin and histone H1 (H1) were studied. H1 binding to chromatin is cooperative. Chromatin accepts 3.6 molecules of H1/nucleosome at 0 M salt, close to the required ratio for neutralization of 90% of the charges on the phosphate groups of chromatin (4.0 H1 molecules/nucleosome). The proposal is put forward that critical charge neutralization (90%) has a significant influence on the irregular appearance of chromatin.     

Organization of internucleosomal DNA in rat liver chromatin

A detailed analysis of the length distribution of DNA in nucleosome dimers trimmed with exonuclease III and S1 nuclease suggests that the previously described variation of internucleosomal distance in rat liver occurs, at least for a subset of the nucleosomes, by integral multiples of the helical repeat of the DNA. Results obtained upon digestion of chromatin with DNase II further suggest that lengths of internucleosomal DNA are integral multiples of the helical repeat of the DNA plus approximately 5 bp. Restraints imposed by these features on the arrangement of nucleosomes along the fiber are discussed.     

Possible nucleosome arrangements in the higher-order structure of chromatin

Consideration has been given to possible sequences of nucleosomes which can produce a ‘thick fibre’-like structure. Only a few basic requirements were imposed: (i) the thick fibre is a regular single helix with about 7 nucleosomes per turn; (ii) the nucleosomes are equidistant along the polynuclesome chain; (iii) the helix is flexible having variable pitch. It was found that in addition to the straightforward sequential arrangement there is only one other nonsequential arrangement which satisfies these requirements. This is a helix with around 8 nucleosomes per turn in which all nucleosomes are identically placed. It is possible in the region of 200 to 218 ± 10 base pairs (b.p.) DNA repeats lengths. The linker DNA is straight or almost straight and crosses the internal ‘hollow’ cylinder which is not occupied by nucleosomes. This structure satisfies the experimental data for the distance distribution function, and the observed mass per unit length and changes noted in the mass per unit length. Further, if it is assumed that the core particle axis of symmetry is in the plane of the two linkers and bisects them then this makes the core particles oblique to the thick fibre radii with alternate angles of ± 20 to 30°. This orientation of the nucleosomes can explain the DNA digestion patterns obtained with DNase II and with DNase I.     

The mechanism of action of the deoxyribonuclease of rat liver chromatin on DNA]

A mechanism of action of DNAase, isolated by chromatin extraction with 0.4 M NaCl, on DNA is described. The enzyme is an endonuclease, it does not require the presence of double-stranded regions in the DNA molecule, does not distinct single-stranded breaks in DNA, and it preferably attacks single-stranded DNA. It hydrolyses DNA for 3'-phosphodiester bonds to octane nucleotides which are resistant to the enzyme activity. The action of the enzyme on DNA does not depend on the position of terminal phosphates. Chromatin DNAase is not specific to DNAs from different origins.     

Pulsed-field gel electrophoresis analysis of higher-order chromatin structures of Zea mays. Highly methylated DNA in the 50 kb chromatin structure

We have investigated the presence of higher-order chromatin structures in different maize tissues. Taking advantage of the pulsed-field gel electrophoresis technique to analyse large DNA fragments from intact nuclei and cells, we have determined the size distribution of the high-molecular-weight DNA fragments obtained from chromatin degradation by endogenous nucleases in isolated nuclei. Chromatin digestion leads to the appearance of stable DNA fragments of about 50 kb in all the tissues examined, suggesting the folding of DNA in higher-order chromatin domain structures. It has been reported that such chromatin domains are formed by loops of the 30 nm fibres anchored to the nuclear matrix by a complex set of proteins, including DNA topoisomerase II. Treatment of maize protoplasts with the calcium ionophore A23187 and the antitumour drug VM-26, which specifically inhibit the religation of the cleaved DNA in the topoisomerase II reaction, also produces the 50 kb structure. Analysis of the DNA contained in the 50 kb chromatin structure shows a higher degree of methylation than in bulk maize chromosomal DNA. The role of methylated DNA in the chromatin folding is discussed.     

Analysis of nucleosome arrangement on satellite DNA of rat liver chromatin

The arrangement of nucleosomes on the nucleotide sequence of satellite DNA of Oceanian rat (Rattus rattus) has been studied. Nucleosome cores were prepared from rat liver nuclei with micrococcal nuclease, exonucleaseIII and nuclease Sl. From the total population of core DNA fragments, the satellite-containing fragments were selected by molecular cloning and the complete nucleotide sequence of these clones was determined. The data show that nucleosomes occupy a number of preferred positions on satellite DNA. These positions are strictly defined. Thus location of nucleosomes along the satellite sequence is non-random. Such finding may have important biological significance.     

In vitro translocation of secretory proteins possessing no charges at the mature domain takes place efficiently in a protonmotive force-dependent manner.

The effect of charges existing on the mature domain of secretory proteins on the efficiency and protonmotive force dependence of translocation into everted membrane vesicles of Escherichia coli was studied. Model secretory proteins devoid of charges on the mature domain were constructed at the DNA level using proOmpF-Lpp as the starting protein. The chargeless presecretory proteins thus constructed were translocated and processed for the signal peptide much faster than proOmpF-Lpp and the rate of translocation was appreciably enhanced by imposition of the protonmotive force. Not only the membrane potential but also delta pH were effective in stimulating the rate of translocation of the chargeless proteins. The results indicate that the mature domain does not have to be charged for the secretory translocation and that the major requirement of the protonmotive force for the secretory translocation is not for the movement, including an electrophoretic one, of charged regions of the mature domain. All of the proOmpF-Lpp derivatives thus constructed were translocated efficiently into everted membrane vesicles in a SecA-dependent manner, irrespective of their size. The mature domain of the smallest one was 45 amino acid residues in length. Contrary to the views previously presented by other workers, these results suggest that there is no sharp boundary at the reported regions for the translocation of presecretory proteins across the cytoplasmic membrane or for the requirement of SecA.     

Higher order chromatin structure at the X-inactivation center via looping DNA

In mammals, the silencing step of the X-chromosome inactivation (XCI) process is initiated by the non-coding Xist RNA. Xist is known to be controlled by the non-coding Xite and Tsix loci, but the mechanisms by which Tsix and Xite regulate Xist are yet to be fully elucidated. Here, we examine the role of higher order chromatin structure across the 100-kb region of the mouse X-inactivation center (Xic) and map domains of specialized chromatin in vivo. By hypersensitive site mapping and chromosome conformation capture (3C), we identify two domains of higher order chromatin structure. Xite makes looping interactions with Tsix, while Xist makes contacts with Jpx/Enox, another non-coding gene not previously implicated in XCI. These regions interact in a developmentally-specific and sex-specific manner that is consistent with a regulatory role in XCI. We propose that dynamic changes in three-dimensional architecture leads to formation of separate chromatin hubs in Tsix and Xist that together regulate the initiation of X-chromosome inactivation.     

Repair of depurinated DNA with enzymes from rat liver chromatin.

DNA from T7 phage containing AP (apurinic/apyrimidinic) sites was repaired by the successive actions of three chromatin enzymes [AP endodeoxyribonuclease, DNAase IV (5'----3'-exodeoxyribonuclease) and DNA polymerase-beta] prepared from rat liver and T4-phage DNA ligase. Since DNA ligase is also found in rat liver chromatin, all the activities used for the successful repair in vitro are thus present in the chromatin of a eukaryotic cell. Our results show, in particular, that the chromatin DNAase IV is capable of excising the AP site from the DNA strand nicked by the chromatin AP endodeoxyribonuclease. We did not try to combine all the enzymes, since competition between some of them might have prevented the repair; we have, for instance, shown that DNA ligase can seal the incision 5' to the AP site made by the AP endodeoxyribonuclease. Changes in chromatin structure during repair might perhaps prevent this competition when nuclear DNA is repaired in the living cell.     

Repair of O6-methyl-guanine residues in DNA takes place by a similar mechanism in extracts from hela cells,human liver,and rat liver

Extracts from HeLa S₃ cells, human liver, and rat liver were found to contain an activity that transfers the methyl group from O⁶-methyl-guanine residues in DNA to a cysteine residue of an acceptor protein. The molecular weights of the acceptor proteins in HeLA cells and human liver are 24,000 ± 1,000 and 23,000 ± 1,000. respectively. Assuming that each acceptor molecule is used only once, the average number of acceptor molecules in HeLa cells was calculated to be about 50,000. The extracts also contained 3-methyl-adenine-DNA glycosylase activity and 7-methyl-guanine-DNA glycosylase activity, although the latter activity was not detected in extracts from human liver in our assay system. Thus, the three major alkylation products resulting from the effect of methylating agents, such as N-methyl-N-nitroso urea, can all be repaired in animal cells. Pretreatment of HeLa cells with N-methyl-N′-nitro-N-nitrosoguanidinc (0.1 μg/ml) strongly reduced the capacity of HeLa cell extracts to repair O⁶-methyl-guanine residues, while the activity of three DNA-N-glycosylases was essentially unaltered. This inactivation was not caused by a direct methylation of the enzyme by the carcinogen. The results demonstrate that the mechanism of repair of O⁶-methyl-guaninc residues, in DNA is strikingly similar in E coli and animal cells, including humans.     

Hydrodynamic shearing by VirTis blending conserves nucleosome structure of rat liver chromatin

The effects of VirTis shearing on chromatin subunit structure were investigated by enzymatic digestion, thermal denaturation, and electron microscopy. While initial rates of micrococcal nuclease and DNase I digestion were greater postshearing, limit digest values were similar to those for unsheared chromatin. Fractionated chromatin digestion kinetics varied with sedimentation. Digestion of all chromatins produced monomer and dimer DNA fragment lengths, but only unsheared chromatins exhibited higher order nucleosome oligomer lengths. Mononucleosomes and core particles were resolved in digests of sheared and gradient fractions analyzed by electrophoresis. All chromatins exposed to DNase I showed discrete 10-base pair nicking patterns. The presence of nucleosomes was confirmed by electron microscopy. Electron microscopy and histone content of gradient fractions showed that nucleosome density along the chromatin axis increased in rapidly sedimenting fractions. Thermal denaturation detected no appreciable generation of protein-free DNA fragments as a result of shearing. The results indicate that VirTis blending conserves subunit structure with loss of less than 12–15% of nucleosome structure.     

Hydrodynamics-based transfection of the liver: entrance into hepatocytes of DNA that causes expression takes place very early after injection

BACKGROUND: The mechanism of gene transfer into hepatocytes by the hydrodynamics-based transfection procedure is not clearly understood. It has been shown that, after a hydrodynamic injection, a large proportion of plasmid DNA remains intact in the liver where it is bound to plasma membrane and suggested that this DNA could be responsible for the efficiency of the transfection. METHODS: We have investigated the problem by giving mice a hydrodynamic injection of isotonic NaCl, followed at different time intervals by a conventional injection of DNA, cold or labelled with (35)S, with cDNA of luciferase as a reporter gene. Then, we determined the consequences of that dual injection on luciferase expression and on DNA uptake by the liver and its intracellular fate. By such experiments, it is possible to establish the time dependency of the induction of liver changes caused by a hydrodynamic injection on the one hand and the expression and DNA uptake and fate on the other. Moreover, some experiments have been performed on primary cultures of hepatocytes isolated after a hydrodynamic injection of DNA. RESULTS: When DNA is given to mice by a conventional injection a few seconds after an hydrodynamic injection of isotonic NaCl, luciferase expression in the liver is considerably lower than that observed after a single hydrodynamic injection of the plasmid. On the other hand, as assessed by the rate of DNA degradation and by centrifugation results obtained after injection of (35)S-DNA, the uptake and the intracellular fate of the bulk of DNA are similar whether DNA is administered by a single hydrodynamic injection or by a conventional injection given up to at least 2 h after a hydrodynamic injection of isotonic NaCl. Hepatocytes isolated a few minutes after a hydrodynamic injection exhibit a maximal expression that does not depend on the large amount of DNA that remains bound to the plasma membrane for a relatively long time. CONCLUSIONS: Our results show that the efficiency of hydrodynamics-based transfection depends on a process that takes place very quickly after injection and is not linked to a delay of DNA degradation and the persistence of a large proportion of DNA bound to hepatocytes of the plasma membrane, strongly suggesting that expression after a hydrodynamic injection is caused by a small proportion of DNA molecules that rapidly enter the cytosol probably by plasma membrane pores generated by the hydrodynamic pressure.