Multiple structural features are responsible for the nuclease sensitivity of the active ovalbumin gene

The ovalbumin gene in chick oviduct nuclei or nucleosomes is digested preferentially by either DNase I or staphylococcal nuclease. Staphylococcal nuclease preferentially cuts between and within core particles of the oviduct ovalbumin gene; thus, the ovalbumin gene is more quickly degraded to mononucleosomes and the DNA within these monomers is digested to a nonhybridizable size significantly faster than the chicken globin gene. Mono- and oligonucleosomes generated by partial staphylococcal nuclease digestion at 0 degrees C, but not at 37 degrees C, retain equal sensitivity to DNase I. Most of this sensitivity persists when histone H1 and most of the non-histone chromosomal proteins are removed with 0.6 M NaCl. On the basis of these observations, we propose that nuclease sensitivity of the oviduct ovalbumin gene is due to covalent modifications of the core histones and that this sensitivity is amplified by interaction of other chromosomal proteins with these modified histones.     

A partial characterization of DNA fragments protected from nuclease degradation in histone depleted metaphase chromosomes of the Chinese hamster.

A small proportion (0.1-0.5%) of the total DNA content of native Chinese hamster metaphase chromosomes is protected from nucleolytic degradation following the removal of histones by extraction with either 0.2 N HCl or 2 M NaCl, and remains attached to the nonhistone protein core. Acid extraction followed by DNase I digestion leads to small fragments of 10-30 bases. Salt extraction followed by micrococcal nuclease digestion gives approx. 140 b.p. fragments which are undistinguishable in size from nucleosome core DNA fragments. Furthermore, DNase I treatment of salt extracted chromosomes gives DNA fragments containing single strands which are multiples of 10 bases in length, again characteristic of the nucleosome structure. Reassociation kinetics using the 32P-labelled 140 b.p. fragments as probes suggests they are enriched for rapidly reassociating sequences.     

Chromatin core particle unfolding induced by tryptic cleavage of histones.

Chromatin 'core particles' have been digested with trypsin to varying extents. The resulting particles are homogeneous by the criterion of ultracentrifuge boundary analysis. Sedimentation coefficients are lowered as cleavages are introduced into the histones, showing that an unfolding of the core particle occurs. This unfolding is further characterised by a lower melting temperature together with a premelting phase, higher molar ellipticity in the circular dichroism spectra at 280 nm and increased kinetics of digestion by both micrococcal nuclease and DNase I. Differences are also observed in the products of nuclease digestion. The most consistent interpretation of the data involves an unfolding process whereby free rods of DNA are released to extend from a nucleoprotein core.     

A correlation between nucleosome spacer region susceptibility to DNase I and histone acetylation.

Hepatoma tissue culture (HTC) cell nuclei were digested with either DNase I or micrococcal nuclease and the nucleohistone digestion products fractionated by gel electrophoresis or exclusion chromatography. Under appropriate conditions, gel electrophoresis demonstrates that for both nucleases, only cleavages within the nucleosome spacer regions and not within the nucleosome core lead to freely migrating nucleohistone particles. These particles consist of nucleosome cores, nucleosomes and nucleosome oligomers. Following DNase I digestion and fractionation by exclusion chromatography, analysis of the histones indicates a direct relationship between increased spacer region susceptibility to nuclease and increased nucleosomal histone acetylation. Evidently digestion sites outside the regions of DNA protected by core histones can reflect the degree of acetylation of core histones. Such a relationship is not found when micrococcal nuclease is used to digest the samples.     

Isolation and characterisation of a 167 bp core particle isolated from stripped chicken erythrocyte chromatin

We have digested chicken erythrocyte soluble chromatin, both unstripped and stripped of histones H1 and H5 with either 0.6 M NaCl or DNA-cellulose, with micrococcal nuclease (MNase). Digestion of unstripped chromatin to monomeric particles initially paused at 188 bp DNA; continued digestion resulted in another pause at 177 before the 167 bp chromatosome and 146 bp core particle were obtained. Digestion of stripped chromatin to monomeric particles paused transiently at 177 bp; continued digestion resulted in marked pauses at 167 and 156 before the 146 bp core particle was obtained. These results suggested that 167 bp DNA representing two complete turns are bound to the histone octamer. Histone H1/H5 binds an additional two helical turns of DNA, thereby protecting up to 188 bp DNA against nuclease digestion. Monomeric particles containing 167 bp DNA were isolated from stripped chromatin and found by DNase I digestion to be a homogeneous population with a 10 bp DNA extension to either end relative to the 146 bp core particle. Thermal denaturation and circular dichroism spectroscopy showed stronger histone-DNA interactions and increased DNA winding as the length of DNA attached to the core histone octamer was decreased. Thermal denaturation also showed three classes of histone-DNA interaction: the core particle containing 167 bp DNA had tight binding of ten helical turns of DNA, intermediate binding of two helical turns and looser binding of four helical turns.     

The assembly of an H2A2,H2B2,H3,H4 hexamer onto DNA under conditions of physiological ionic strength

A novel nucleohistone particle is generated in high yield when a complex of DNA with the four core histones formed under conditions that are close to physiological (0.15 M NaCl, pH 8) is treated with micrococcal nuclease. The particle was found to contain 102 base pairs of DNA in association with six molecules of histones in the ratio 2H2A:2H2B:1H3:1H4 after relatively brief nuclease treatment. Prolonged nuclease digestion resulted in a reduction in the DNA length to a sharply defined 92-base pair fragment that was resistant to further degradation. Apparently normal nucleosome core particles containing two molecules each of the four core histones in association with 145 base pairs of DNA and a particle containing one molecule each of histones H2A and H2B in association with approximately 40 base pairs of DNA were also generated during nuclease treatment of the histone-DNA complexes formed under physiological ionic strength conditions. Kinetic studies have shown that the hexamer particle is not a subnucleosomal fragment produced by the degradation of nucleosome core particles. Furthermore, the hexamer particle was not found among the products of nuclease digestion when histones and DNA were previously assembled in 0.6 M NaCl. The high sedimentation coefficient of the hexameric complex (8 S) suggests that the DNA component of the particle has a folded conformation.     

Changes in chromatin structure at the replication fork. DNase I and trypsin-micrococcal nuclease effects on approximately 300- and 150-base pair nascent DNAs

DNase I, trypsin, and micrococcal nuclease are used to further probe the structure of nascent deoxyribonucleoprotein (DNP) fractions which appear after in vivo 20-s pulse labeling of sea urchin embryos with [3H]thymidine. We present evidence that the large nascent DNP which protects the approximately 300-base pair large nascent DNA consists of at least one nucleosome core. This is based on fractionation in denaturing polyacrylamide gels of DNA extracted from large nascent DNP fractions of a micrococcal nuclease + DNase I digest of nuclei. The data also suggest the existence of a DNase I-hypersensitive site(s) within the large nascent DNP; this is consistent with the hypothesis that the latter consists of closely packed dinucleosome cores. Histone H1 and non-histone proteins do not account for the previously reported unusual hyperresistance of the large nascent DNA against micrococcal nuclease. The protection offered this approximately 300-base pair nascent DNA was not eliminated by an 0.2-microgram/ml trypsin pretreatment which removes the above proteins from the chromatin. However, 5-10 micrograms/ml of trypsin, which remove a portion of the NH2 termini of the four core histones of nucleosomes, eliminate the hyperresistance of the large nascent DNA to subsequent micrococcal nuclease digestion, while nascent and bulk monomer DNAs remain unaffected. This indicates histone-histone and/or histone-DNA interactions within the large nascent DNP which differ from those of nascent and bulk mononucleosome cores.     

Analysis of the changes in the structure and hydration of the nucleosome core particle at moderate ionic strengths

In order to better understand the conformational changes induced in the nucleosome core particle by changes in the ionic strength of the media in the range from 0.1 to 0.6 M NaCl, we have conducted a very detailed structural analysis, combining circular dichroism, DNase I digestion, and sedimentation equilibrium. The results of such analysis indicate that the secondary structure of both DNA and histones exhibits small (approximately 5%) but noticeable changes as the salt increases within this range. In the case of DNA, the data are consistent with a trend toward a more relaxed secondary structure. The DNase I pattern of digestion is also altered by the salt and suggests a DNA relaxation around the flanking ends. From the hydrodynamic measurements, we also observe a significant change in the virial coefficients of the particle as the salt increases, which in turn are in very good agreement with the theoretically expected values. Furthermore, the preferential hydration parameter is also found to increase with the salt. We believe that the self-dependent conformational change of the nucleosome core particle is the result of the conjunction of all these subtle changes. Yet, from the present data, their exact relationship to the tertiary structure of the whole particle at the different ionic strengths cannot be exactly defined.     

Folding of DNA by histones which lack their NH2-terminal regions

HeLa chromatin core particles were digested with trypsin to excise the NH2-terminal histone regions. The resulting nucleoprotein complexes were dissociated in 2.5 M NaCl; the DNA and polypeptides were then allowed to reassemble by lowering the NaCl concentration. Eighty per cent of the DNA reassociated with the polypeptides. The reassembled nucleoprotein complexes sediment at 9.7 S, have a molecular elipticity at 280 nm of 3000 degrees cm2/dmol of PO4, and contain DNase I-susceptible sites at 10 nucleotide intervals. The pattern of products generated by cross-linking the polypeptides with dimethylsuberimidate is very similar to the pattern generated by cross-linking native core particles. The results indicate that histones which lack their HN2-terminal regions retain both the features necessary for correct protein-protein interactions and the ability to fold DNA into a nucleoprotein complex resembling the chromatin core particle.     

Association of nucleosome core particle DNA with different histone oligomers. Transfer of histones between DNA-(H2A,H2B) and DNA-(H3,H4) complexes

In non-denaturing low ionic strength gels, the titration of core DNA with H2A,H2B produces five well-defined bands. Quantitative densitometry and cross-linking experiments indicate that these bands are due to the successive binding of H2A,H2B dimers to core DNA. Only two bands are obtained with DNA-(H3,H4) samples. The slower of these bands is broad and presumably corresponds to two complexes containing one and two H3,H4 tetramers, respectively. In gels of higher ionic strength, DNA-(H2A,H2B) samples produce an ill-defined band, suggesting that the lifetime of the complexes containing H2A,H2B is relatively short. However, the low intensity of the free DNA band observed in these gels indicates that most of the DNA is associated with H2A,H2B. In agreement with this, our results obtained using different techniques (sedimentation, cross-linking, trypsin and nuclease digestions, and thermal denaturation) demonstrate that the association of H2A,H2B with core DNA occurs in free solution in both the absence and presence of NaCl (0.1 to 0.2 M). The low mobilities of DNA-(H2A,H2B) complexes, together with sedimentation and DNase I digestion results, indicate that the DNA in these complexes is not folded into the compact structure found in the core particle. Furthermore, non-denaturing gels have been used to study the dynamic properties of DNA-(H2A,H2B) and DNA-(H3,H4) complexes in 0.2 M-NaCl. Our results show that: (1) H2A,H2B and H3,H4 can associate, respectively, with DNA-(H3,H4) and DNA-(H2A,H2B) to produce complexes containing the four core histones; (2) DNA-(H2A,H2B) and DNA-(H3,H4) are able to transfer histones to free core DNA; (3) an exchange of histone pairs takes place between DNA-(H2A,H2B) and DNA-(H3,H4) and produces complexes with the same histone composition as that of the normal nucleosome core particle; and (4) although both histone pairs can exchange, histones H2A,H2B show a higher tendency than H3,H4 to migrate from one incomplete core particle to another. The complexes produced in these reactions have the same compact structure as reconstituted core particles containing the four core histones. Our kinetic results are consistent with a reaction mechanism in which the transfer of histones involves direct contacts between the reacting complexes. The possible participation of these spontaneous reactions on the mechanism of nucleosome assembly is discussed.     

Self-assembly of single and closely spaced nucleosome core particles.

Self-assembly of DNA with the four core histones but in the absence of H1 generates nucleosome core particles which are spaced randomly over large distances. Closely spaced core particles, however, exhibit a preferred short linkage which is not a multiple of 10 base pairs. They bind about 140 base pairs whereas apparently shorter DNA lengths per nucleosome observed after digestion with micrococcal nuclease are the result of degradation from the ends. The DNA length of one superhelical turn in the core particle is 83 +/- 4 base pairs. Single core particles may bind more DNA than closely spaced core particles but probably less than two full turns of 168 base pairs. The internal structures of single and of native core particles are very similar as judged by their amount of DNA, sedimentation coefficient, appearance in the electron microscope, and digestion with DNase I. In addition to core particles, a particle is described which sediments at 9 S and consists of 108 base pairs of DNA bound to the histone octamer. It appears to be the smallest stable "core particle" but it is not a degradation product of the 146-base-pair core particle. Digestion of end-labeled 9 S and nucleosome core particles with DNase I shows distinct differences.     

Histones H2a, H2b, H3, and H4 form a tetrameric complex in solutions of high salt.

In 2 M NaCl, histones H2b, H2a, H3, and H4 form a heterotypic tetrameric complex made up of one chain of each histone. This complex has been analyzed by hydrodynamic techniques. It is indistinguishable from histones in chromatin by its resistance to trypsin, pattern of reactivity with 125I. and ability to form specific crosslinked products after treatment with formaldehyde. It is proposed that this complex is responsible for protecting the small DNA fragments produced by exhausting nuclease digestion of nuclei and that on the average two of these complexes protect the larger 180-200 base pair unit produced by partial treatment of nuclei with nuclease.     

Sea urchin sperm chromatin structure as probed by pancreatic DNase I: Evidence for a novel cutting periodicity

Chromatin from mature sea urchin spermatozoa is highly compacted and composed almost entirely of DNA and the five histones, although sperm H1, H2A, and H2b histones differ from those found in embryo or somatic cell nuclei. Release of acid-soluble DNA during pancreatic DNase I digestion is 20-fold slower from sperm nuclei than from embryonic nuclei. Following DNase I digestion, most sperm nuclear DNA remains at high molecular weight, although there appears to be some release of 10 base oligomer fragments. Size analysis of the higher molecular weight DNA reveals a series of fragments that indicate a cutting periodicity of approximately 500 base pairs. This pattern remains when electrophoretic separation is carried out under denaturing conditions. The 500 base pair cleavage pattern was not detected in digestions of embryonic nuclei. Nucleosomes reconstituted with fractionated core histones from sperm gave, upon digestion, a characteristic 10 base “ladder,” with no resistant high molecular weight DNA. Micrococcal nuclease and DNase II digested sperm nuclei to produce DNA fragments with a calculated repeat length of 248 ± 3 and 246 ± 6 base pairs, respectively. The structural basis for the 500 base pair cutting periodicity in sperm nuclei may reside in the unique sperm H1 histone.     

Structure of chromatin containing extensively acetylated H3 and H4

I have grown HeLa cells in 5 mM sodium n-butyrate leading to extensive in vivo histone acetylation, and have characterized the structure of chromatin containing the modified histones. Nuclear DNA in butyrate-treated cells is digested 5-10 fold more rapidly by DNAase I than the DNA of control cells. Staphylococcal nuclease degrades the two nuclear samples to acid-soluble material with identical rates; this nuclease, however, does excise nucleosomes with extensively acetylated histones from the nucleoprotein chain preferentially. The physical properties of unsheared chromatin and isolated core particles from control and butyrate-treated cells are closely similar, as are the rates of digestion of core particles from the two cell preparations by DNAase I. Determination of the relative susceptibilities of cleavage sites for DNAase I demonstrates that the site 60 bases from the ends of the DNA resistant in control cells, becomes susceptible to the nuclease in core particles containing acetylated histones. Similarly, the 5' terminal phosphate at the end of DNA in core prticles is removed by staphylococcal nuclease 2-3 fold faster in particles containing acetylated histones than in particles from control cells.     

Intranuclear localization of the Ki-67 reactive antigen in HeLa cells. Flow cytometric analysis

The intranuclear localization of the Ki-67 reactive antigen was immunocytochemically investigated using flow cytometry. HeLa S3 cells were immunocytochemically stained with the monoclonal antibody, Ki-67, after in situ treatments with various kinds of compounds, namely: HCl; NaCl; RNase; S1 nuclease and DNase I. The only treatment that markedly diminished the immunofluorescence intensity of the cells was exposure to DNase I. Nuclear fluorescence was no longer observed in the cells digested with relatively high concentrations of DNase I. These results suggest that the antigen recognized by Ki-67 is closely associated with DNA, but is not directly associated with either the nuclear matrix or histones.     

Intranuclear localization of the Ki-67 reactive antigen in HeLa cells. Flow cytometric analysis

The intranuclear localization of the Ki-67 reactive antigen was immunocytochemically investigated using flow cytometry. HeLa S3 cells were immunocytochemically stained with the monoclonal antibody, Ki-67, after in situ treatments with various kinds of compounds, namely: HCl; NaCl; RNase; Sl nuclease and DNase I. The only treatment that markedly diminished the immunofluorescence intensity of the cells was exposure to DNase I. Nuclear fluorescence was no longer observed in the cells digested with relatively high concentrations of DNase I. These results suggest that the antigen recognized by Ki-67 is closely associated with DNA, but is not directly associated with either the nuclear matrix or histones.     

The reactive SH1 and SH2 cysteines in myosin subfragment 1 are cross-linked at similar rates with reagents of different length

Nuclei prepared from confluent and mitotically arrested populations of human diploid fibroblast-like cells of different $\text{in}\text{vitro}$ ages were subjected to digestion by micrococcal nuclease and DNase I. There was no age or culture state variation in the susceptibility of DNA to micrococcal nuclease digestion. There was, however, an age related inhibition of DNA digestion by DNase I in nuclei from older confluent but not older arrested cells. It is suggested that this is the result of an age related masking by nucleosome core histones which limits the accessibility of DNA to enzymatic activities in older confluent cells.     

Effect of histone acetylation on structure and in vitro transcription of chromatin.

n-Butyrate treatment of growing Hela cells produces a dramatic increase in the levels of histone acetylation. We have exploited this system to study the effect of histone acetylation on chromatin structure. Chromatin containing highly acetylated histones is more rapidly digested to acid-soluble material by DNase I, but not by micrococcal nuclease. The same pattern of nuclease sensitivity was exhibited by in vitro-assembled chromatin consisting of SV40 DNA Form I and the 2 M salt-extracted core histones from butyrate-treated cells. Using this very defined system, it was possible to demonstrate that acetylated nucleosomes do not have a greatly diminished stability. Stability was measured in terms of exhange of histone cores onto competing naked DNA or sliding of histone cores along ligated naked DNA. Finally, it was shown that acetylated nucleosomes are efficient inhibitors of in vitro RNA synthesis by the E. coli holoenzyme as well as by the mammalian polymerases A and B.     

The effect of histone hyperacetylation on the nuclease sensitivity and the solubility of chromatin

We have examined the effects of histone hyperacetylation upon nuclease digestion of nuclei and subsequent fractionation of chromosomal material in the presence of MgCl2. DNase I shows a maximum sensitivity towards hyperacetylated nuclei at somewhat elevated ionic strengths (150-200 mM NaCl), whereas micrococcal nuclease exhibits no specificity for acetylated nuclei over a broad range of ionic strengths. Fractionation in the presence of MgCl2 of hyperacetylated nuclei digested with micrococcal nuclease results in a substantial increase in the amount of soluble chromatin relative to that obtained with control nuclei. This increased yield of Mg2+-soluble chromatin results from the recruitment into this fraction of oligonucleosomes containing extremely hyperacetylated histones. These results suggest that contiguous nucleosomes containing highly acetylated histones may be altered in their ability to interact with themselves and with other nucleosomes.