Coexistence of two chromatin structures in sperm nuclei of the bivalve molluscProtothaca thaca

The chromatin of the spermatozoa from the bivalve molluscProtothaca thaca, has a peculiar composition in which coexist core histones with sperm-specific proteins H1 and Pt1, the latter being a protein exhibiting features intermediate between histones and protamines. In this paper, we report an analysis of chromatin organization using micrococcal nuclease digestion, salt fractionation of soluble chromatin derived from nuclease digestion and crosslinking experiments. The results obtained indicate that it is possible to obtain two types of chromatin, one which is soluble, more accessible to micrococcal nuclease action and which does not contain Pt1, and another insoluble type, more resistant to micrococcal nuclease and enriched in protein Pt1. The crosslinking experiments show that the protein Pt1 interacts with itself and with core histones but not with sperm-specific H1. These results have led us to propose a special structural arrangement for this chromatin. Based in the data reported here we propose the coexstence in the genome ofP. thaca of two interspersed chromatin domains, one nucleosomal and the other nonnucleosomal containing protein Pt1.     

Reduced repeat length of nascent nucleosomal DNA is generated by replicating chromatin in vivo

Micrococcal nuclease digestion of nuclei from sea urchin embryos revealed transient changes in chromatin structure which resulted in a reduction in the repeat length of nascent chromatin DNA as compared with bulk DNA. This was considered to be entirely the consequence of in vivo events at the replication fork (Cell 14, 259, 1978). However, a micrococcal nuclease-generated sliding of nucleosome cores relative to nascent DNA, which might account for the smaller DNA fragments, was not excluded. In vivo [3H]thymidine pulse-labeled nuclei were fixed with a formaldehyde prior to micrococcal nuclease digestion. This linked chromatin proteins to DNA and thus prevented any in vitro sliding of histone cores. All the nascent DNAs exhibiting shorter repeat lengths after micrococcal nuclease digestion, were resolved at identical mobilities in polyacrylamide gels of DNA from fixed and unfixed nuclei. We conclude that these differences in repeat lengths between nascent and bulk DNA was generated in vivo by changes in chromatin structure during replication, rather than by micrococcal nuclease-induced sliding of histone cores in vitro.     

Altered chromatin structure of cerebral nuclei in experimental diabetes mellitus.

To determine whether diabetes alters chromatin structure in vivo, micrococcal nuclease digestion kinetics were analyzed in cerebral cortical and hepatic nuclei of streptozotocin-induced diabetic rats. Cerebral nuclei of diabetic rats maintained for 6 weeks were less susceptible to micrococcal nuclease digestion compared with control rats. Insulin treatment reversed diabetes-related changes in nuclease digestion kinetics. There were no changes in the kinetics of digestion in hepatic nuclei. The reduced digestibility of cerebral DNA in diabetes could not be attributed to altered DNA fluorescence spectra, or altered distribution of most abundant chromatin proteins that were either solubilized or that remained insoluble immediately following nuclease digestion. It is concluded that chronic, uncontrolled hyperglycemia can alter chromatin structure of some tissues in vivo, and this change is probably related to subtle alterations in DNA-protein interactions.     

Structure of eukaryotic chromatin. Evaluation of periodicity using endogenous and exogenous nucleases.

DNA isolated from (a) liver chromatin digested in situ with endogenous Ca2+, Mg2+-dependent endonuclease, (b) prostate chromatin digested in situ with micrococcal nuclease or pancreatic DNAase I, and (c) isolated liver chromatin digested with micrococcal nuclease or pancreatic DNAase I has been analyzed electrophoretically on polyacrylamide gels. The electrophoretic patterns of DNA prepared from chromatin digested in situ with either endogenous endonuclease (liver nuclei) or micrococcal nuclease (prostate nuclei) are virtually identical. Each pattern consists of a series of discrete bands representing multiples of the smallest fragment of DNA 200 +/- 20 base pairs in length. The smallest DNA fragment (monomer) accumulates during prolonged digestion of chromatin in situ until it accounts for nearly all of the DNA on the gel; approx. 20% of the DNA of chromatin is rendered acid soluble during this period. Digestion of liver chromatin in situ in the presence of micrococcal nuclease results initially in the reduction of the size of the monomer from 200 to 170 base pairs of DNA and subsequently results in its conversion to as many as eight smaller fragments. The electrophoretic pattern obtained with DNA prepared from micrococcal nuclease digests of isolated liver chromatin is similar, but not identical, to that obtained with liver chromatin in situ. These preparations are more heterogeneous and contain DNA fragments smaller than 200 base pairs in length. These results suggest that not all of the chromatin isolated from liver nuclei retains its native structure. In contrast to endogenous endonuclease and micrococcal nuclease digests of chromatin, pancreatic DNAase I digests of isolated chromatin and of chromatin in situ consist of an extremely heterogeneous population of DNA fragments which migrates as a continuum on gels. A similar electrophoretic pattern is obtained with purified DNA digested by micrococcal nuclease. The presence of spermine (0.15 mM) and spermidine (0.5 mM) in preparative and incubation buffers decreases the rate of digestion of chromatin by endogenous endonuclease in situ approx. 10-fold, without affecting the size of the resulting DNA fragments. The rates of production of the smallest DNA fragments, monomer, dimer, and trimer, are nearly identical when high molecular weight DNA is present in excess, indicating that all of the chromatin multimers are equally susceptible to endogenous endonuclease. These observations points out the effects of various experimental conditions on the digestion of chromatin by nucleases.     

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.     

Sequence specific cleavage of African green monkey alpha-satellite DNA by micrococcal nuclease

The sequence specificity of micrococcal nuclease complicates its use in experiments addressed to the still controversial issue of nucleosome phasing. In the case of alpha-satellite DNA containing chromatin from African green monkey (AGM) cells cleavage by micrococcal nuclease in the nucleus was reported to occur predominantly at only one location around position 126 of the satellite repeat unit (Musich et al. (1982) Proc. Natl. Acad. Sci. USA 79, 118-122). DNA control experiments conducted in the same study indicated the presence of many preferential cleavage sites for micrococcal nuclease on the 172 bp long alpha-satellite repeat unit. This difference was taken as evidence for a direct and simple phase relationship between the alpha-satellite DNA sequence and the position of the nucleosomes on the DNA. We have quantitatively analyzed the digestion products of the protein-free satellite monomer with micrococcal nuclease and found that 50% of all cuts occur at positions 123 and 132, 5% at position 79, and to a level of 1-3% at about 20 other positions. We also digested high molecular weight alpha-satellite DNA from AGM nuclei with micrococcal nuclease. Again cleavage occurred mostly at positions 123 and 132 of the satellite repeat unit. Thus digestion of free DNA yields results very similar to those reported by Musich et al. for the digestion of chromatin. Therefore no conclusions on a possible phase relationship can be drawn from the chromatin digestion experiments.     

Analysis of DNA double- and single-strand breaks by two dimensional electrophoresis: action of micrococcal nuclease on chromatin and DNA, and degradation in vivo of lens fiber chromatin.

We describe a novel system for two dimensional electrophoresis at neutral and alkaline pH for determining the double-stranded and single-stranded lengths of DNA. With this system we analysed the mode of micrococcal nuclease digestion of DNA in cellular and SV40 viral chromatin and of supercoiled SV40 DNA. The enzyme reaction occurred in two steps : the enzyme first introduced single-strand breaks, then converted these to double-strand breaks by an adjacent cleavage on the opposite strand. Digestion of cellular chromatin DNA occurred by a similar mechanism. Chromatin fragments produced by limited micrococcal nuclease action contained many single-strand breaks, which may be important when this method is used to prepare chromatin fragments for biochemical and biophysical studies. Nucleosome monomer to tetramer produced at later stages of digestion contained few if any single-strand breaks.     

Disruption of the typical chromatin structure in a 2500 base-pair region at the 5' end of the actively transcribed ovalbumin gene.

We examined the chromatin organizations of approximately 3 kb of DNA in the 5'-end flanking region of the ovalbumin gene in chicken erythrocyte and oviduct cell nuclei. With specific DNA probes and an indirect end-labeling technique, we analysed the pattern of the DNA fragments obtained after micrococcal nuclease digestion and generated comparative maps of the nuclease cuts. This region of the chicken genome displays a "typical" chromatin arrangement in erythrocyte nuclei, with nucleosomes apparently positioned at random. In contrast, in oviduct nuclei, the same region has an "altered" chromatin structure, and lacks a typical nucleosomal array. The existence of specifically positioned proteins and of alterations in the DNA secondary structure in this region of the oviduct chromatin is suggested by comparison of the nuclease cleavage maps which reveals specific changes: disappearance of nuclease cuts present in "naked" and erythrocyte chromatin DNAs, and appearance of new cuts absent from these DNAs.     

Undermethylation of DNA in mononucleosomes solubilized by micrococcal nuclease digestion of HeLa cell nuclei

To examine the distribution of 5-methylcytosine in chromatin DNA, DNA of HeLa cells was labeled with [3H-methyl]methionine and [14C] thymidine and analyzed after extensive digestion of the nuclei with micrococcal nuclease. When the chromatin solubilized with the nuclease was fractionated on a sucrose density gradient, DNA in mononucleosomes was considerably depleted in 5-methylcytosine, as compared with polynucleosomes. Electrophoretic separation of DNA from the chromatin also revealed the depletion of 5-methylcytosine in the mononucleosomal size of DNA. This was confirmed by the chromatographic analysis of 5-methyldeoxycytidine after enzymatic digestion of the DNA to nucleosides. Thus the DNA in mononucleosomes solubilized by extensive micrococcal nuclease digestion is depleted in 5-methylcytosine, suggesting that 5-methylcytosine is preferentially missing from the DNA in the nucleosome core particles.     

Different conformations of ribosomal DNA in active and inactive chromatin in Xenopus laevis

The chromatin structure of the ribosomal DNA in Xenopus laevis was studied by micrococcal nuclease digestions of blood, liver and embryonic cell nuclei. We have found that BglI-restricted DNA from micrococcal nuclease-digested blood cell nuclei has an increased electrophoretic mobility compared to the undigested control. Micrococcal nuclease digestion of liver cell nuclei causes a very slight shift in mobility, only in the region of the spacer containing the "Bam Islands". In contrast, the mobility of ribosomal DNA in chromatin of embryonic cells, under identical digestion conditions, remains unaffected by the nuclease activity. Denaturing gels or ligase action on the nuclease-treated DNA abolishes the differences in the electrophoretic mobility. Ionic strength and ethidium bromide influence the relative electrophoretic migration of the two DNA fragment populations, suggesting that secondary structure may play an important role in the observed phenomena. In addition, restriction analysis under native electrophoretic conditions of DNA prepared from blood, liver and embryonic cells shows that blood cell DNA restriction fragments always have a faster mobility than the corresponding fragments of liver and embryo cell DNA. We therefore propose that nicking activity by micrococcal nuclease modifies the electrophoretic mobility of an unusual DNA conformation, present in blood cell, and to a lesser extent, in liver cell ribosomal chromatin. A possible function for these structures is discussed. The differences of the ribosomal chromatin structures in adult and embryonic tissues may reflect the potential of the genes to be expressed.     

Self redigestion of native chromatin

Chromatin prepared by micrococcal nuclease digestion of nuclei and fractionated by sucrose density gradient ultracentrifugation selfredigests to a higher percentage of monomer DNA at a rate which depends on the enzyme concentration in the initial digestion. Thus, micrococcal nuclease becomes part of the native chromatin structure. A degree of caution should therefore be exercised when handling material prepared by this technique.     

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.