Internucleosome interactions: detecting the dinucleosome fragmentation of chromatin using micrococcal nuclease. Heterogeneity of nucleosomes and localization of histone H1

The content of histone H1 (H1/H4 ratio) in dinucleosomes with the DNA of various length liberated from L-cell nuclear chromatin by micrococcal nuclease was analyzed. It was found that the histone H1 content in the dichromatosome is two times as low as that in the largest dinucleosome and in the complete mononucleosome. The set of chromatin fragments liberated from the Triton X-100 pretreated nuclei differs considerably from that of chromatin sites devoid of histone H1 (the de novo replicating chromatin and the chromatin formed on the undermethylated DNA). A scheme for asymmetric distribution of histone H1 with molecules oriented along the nucleosomal fibril, which reflects the peculiarities of chromatin fragmentation by micrococcal nuclease with predominant liberation of the dichromatosome, is proposed.     

Expansion of chicken erythrocyte nuclei upon limited micrococcal nuclease digestion. Correlation with higher order chromatin structure

A sensitive method for measuring nuclear volumes with a Coulter counter is described. It has been applied to the digestion of chicken erythrocyte nuclei by micrococcal nuclease and DNase I. Early in digestion, micrococcal nuclease induced a 20% increase in the effective spherical volume of the nuclei, followed by a gradual reduction. At the peak of nuclear swelling, about 17% of the chromatin was soluble after lysis and its average chain length was about 18 kilobase pairs (kb). DNase I digestion did not give rise to a corresponding expansion of the nuclei. Several preparation conditions, including the treatment of nuclei with 0.2% Triton X-100, led to a loss of the expansion effect upon subsequent micrococcal nuclease digestion. The results support the domain theory of higher order chromatin structure. In the context of this model, the observed maximum nuclear expansion correlates with an average of one nuclease scission per domain.     

Superstructural differences between chromatin in nuclei and in solution are revealed by kinetics of micrococcal nuclease digestion.

Digestion of chromatin in nuclei by micrococcal nuclease, measured as the change in the concentration of monomer-length DNA with time, displays Michaelis-Menten kinetics. Redigestion of soluble chromatin prepared from nuclei by micrococcal nuclease treatment, however, is apparently first order in enzyme and independent of chromatin concentration. This qualitative difference results from an increase in the apparent second order rate constant, kcat/Km, for liberation of monomer DNA: the apparent Km for soluble chromatin is lower by close to 3 orders of magnitude than that for chromatin in nuclei, whereas kcat decreases by less than 1 order of magnitude. Neither the integrity of the nuclear membrane nor the presence of histone H1 contributes to the high Michaelis constant characteristic of chromatin in nuclei. Moreover, differences due to the buffers used for digestion and redigestion are minimal. Low catalytic efficiency is, however, correlated with the presence of higher order chromatin superstructure. Micrococcal nuclease added to soluble chromatin under nondigesting conditions at low ionic strength (I = 0.002) co-sediments with chromatin in sucrose gradients. In 0.15 M NaCl, added nuclease no longer sediments with chromatin and redigestion kinetics become first order in both enzyme and substrate. Kinetic analysis of this type may afford an assay for native, higher order structures in chromatin. Our results suggest that micrococcal nuclease binds to soluble chromatin through additional interactions not present in nuclei, which may be partly ionic in nature.     

Non-histone proteins of soluble nucleoproteins released from mouse myeloma nuclei by mild micrococcal nuclease digestion

Mono- and dinucleosomes preferentially cleaved from mouse myeloma chromatin by very mild micrococcal nuclease digestion at 0 degree C are soluble and are released from nuclei under near-physiological conditions in which normal nucleosomes containing Hl are insoluble. These nucleosomes are highly enriched in RNA, high-mobility-group proteins and a unique subset of other non-histone proteins. They are nearly devoid of histone Hl and contain DNA significantly less methylated than whole myeloma DNA, indicating that they comprise a subset of genomic sequences. Previously we have shown that this fraction is enriched in transcribed DNA sequences. Non-histone proteins that co-sedimented with readily solubilized nucleosomes included many of the most basic, low-to-moderate molecular weight chromosomal proteins. Many of these proteins were also preferentially acetylated in vivo. The residual, pelleted chromatin was highly enriched in high molecular weight proteins (greater than 60 000), and very depleted in medium molecular weight proteins. Readily solubilized nucleoproteins sedimenting like mononucleosomes were partly resolved by electrophoresis, under non-denaturing conditions, into several subfractions differing significantly in non-histone protein contents. Methods described here should be useful for identifying and isolating non-histone proteins bound to nucleosomes and other chromatin regions that are structurally and functionally unique.     

Digestion of insect chromatin with micrococcal nuclease, DNase I and DNase I combined with single-strand specific nuclease S1.

The chromatin of the lepidopteran Ephestia kuehniella was digested by micrococcal nuclease, DNase I and S1-nuclease combined with DNase I pretreatment. The resulting DNA fragments were analyzed by gel electrophoresis and compared with the DNA fragments of rat liver nuclei obtained by the same process. Extensive homology was revealed between insect and mammalian chromatin structure. The combined DNase I- S1-nuclease digestion yields double-stranded DNA fragments of lengths from 30 to 110 base-pairs. These DNA fragments are not obtained from nuclei predigested extensively with micrococcal nuclease. The results are discussed with respect to the internal structure of the chromatin subunit.     

Digestion by micrococcal nuclease of mouse submandibular-salivary-gland chromatin.

Nucleic prepared from mouse submandibular salivary gland show marked fragility during isolation. Hwever, intact nuclei relatively free from cytoplasmic contamination were obtained by homogenization in buffers containing 0.88 M-sucrose, Ca2+, spermine, spermidine and the proteinase inhibitor aprotinin, followed by centrifugation through 2.2 M-sucrose. The kinetics of digestion by the micrococcal nuclease of chromatin in these nuclei are similar to those of chromatin from mouse liver nuclei. Base-pair size analysis of the solubilized DNA from both organs shows a stable high-molecular weight species of chromatin, which is further digested to mononucleosome and subnucleosome species. With extensive digestion the chromatin becomes insoluble. The mononucleosomes produced from salivary-gland chromatin after the inhibition of endogenous proteinase activity exhibit an s20,w value of 11S and contain histones H1, H2A, H2B, H3 and H4.     

Copper-rich nucleoprotein generated by micrococcal nuclease

Nuclei from calf thymus tissue digested with micrococcal nuclease under nonchelating conditions yielded soluble nucleoprotein enriched in copper. Following limited digestion, the ratio of μg Cu:mg DNA was inversely related either to percent solubility of chromatin or to levels of enzyme maintaining an enzyme:A ₂₆₀ ratio of 0.059. The enzyme appeared to cleave preferentially regions of chromatin where copper is localized, releasing no additional metal upon further digestion. Moreover, the highest copper: DNA ratio was always associated with the least-digested sample. The distribution between copper and angiotensin II (AII) in chromatin fragments following slight nuclease digestion suggests a possible link between copper and nuclear AII binding. When nuclei are incubated with AII prior to digestion and dialysis, solubilized chromatin contained about three times more copper than buffer control. Metal profiles generated from gel (A-5 M) chromatography for these samples were distinctive: copper peaks appeared near or adjacent to linker DNA regions, and in the case of AII, coincided with fragments containing specific AII receptors; thus, there appears to be an enrichment of copper in these active nucleoprotein fragments.     

Studies on nuclease digestion of chromatin phosphorylated in vivo

We have previously shown that, by culturing cells in hypertonic media, histone 2A becomes hyperphosphorylated (Pantazis, P., West, M. H. P., and Bonner, W. M. (1984) Mol. Cell. Biol. 4, 1186-1188). In the present study we have probed the effect of this histone modification on the overall chromatin structure by micrococcal nuclease and DNase I digestion. Although no significant quantitative differences in the extent of hydrolysis were observed between control and hyperphosphorylated chromatin by micrococcal nuclease, DNase I digested hyperphosphorylated chromatin at a 3- to 4-fold higher rate than unmodified chromatin.     

Enrichment of transcribed and newly replicated DNA in soluble chromatin released from nuclei by mild micrococcal nuclease digestion

A chromatin fraction solubilized from mouse myeloma nuclei under near-physiological ionic conditions by very mild micrococcal nuclease digestion at 0°C is enriched at least 7-fold in DNA complementary to total myeloma polyadenylated mRNA, and 15-fold in DNA originating near the replication fork (labeled within 30 s). Newly replicated DNA recovered in solubilized chromatin after brief labeling was incorporated mainly into particles sedimenting with, or faster than, mononucleosomes. A rapid decrease in enrichment of newly replicated DNA in readily released, soluble chromatin with increasing labeling times indicated that newly replicated chromatin matured within 90 s to a form that was partitioned similarly to bulk chromatin by this fractionation method. Previous studies showed that chromatin readily solubilized from myeloma nuclei is enriched in high-mobility-group (HMG) and other non-histone proteins, RNA and single-stranded DNA; and depleted in H1 and 5-methylcytosine, relative to bulk chromatin (Jackson, J.B., Pollock, J.M., Jr., and Rill, R.L. (1979) Biochemistry 18, 3739–3748). Mild digestion of chicken erythrocyte nuclei with micrococcal nuclease yielded a soluble chromatin fraction (1–2% of the total DNA) with similar properties. This fraction was enriched at least 6-fold in DNA complementary to chicken globin mRNA, relative to total erythrocyte DNA.     

Cesium chloride gradients of chromatin after treatment with micrococcal nuclease

Cesium chloride equilibrium density centrifugation shows that treatment of rat liver nuclei with low concetrations of micrococcal nuclease for extremely short periods of time results in the appearance of chromatin fractions of low protein/DNA ratio and even free DNA. The DNA of these chromatin fractions is shorter than the DNA moiety of one chromatin subunit. The amount of high buoyant density material is decreased with increasing digestion time. We conclude that this material belongs to the minor chromatin fraction which is not organized according to the subunit model.     

Aggregation of fragmented chromatin associated with the synthesis of products of its treatment with nuclease

Isolated cell nuclei were incubated with nucleases followed by extraction of chromatin with a low salt buffer. With an increase of nuclear chromatin degradation with DNAse I or micrococcal nuclease, solubilization of deoxyribonucleoprotein (DNP) by a low salt buffer increases, reaching a maximum upon hydrolysis with 2-4% nuclear DNA and then decreases appreciably after extensive treatment with nucleases. Soluble fragmented chromatin aggregates in the course of treatment with DNAase. I. Addition to gel chromatin preparations of exogenous products of nuclease treatment of isolated nuclei leads to its aggregation. Pretreatment of nuclear chromatin with RNAase prevents solubilization of DNP by low ionic strength solutions. Some experimental data obtained with the use of severe nuclease treatment are discussed; for a correct interpretation of these data the aggregation of fragmented chromatin by products of its nuclease degradation should be taken into consideration.     

Fractionation of nucleosomes by salt elution from micrococcal nuclease- digested nuclei

The solubilization of nucleosomes and histone H1 with increasing concentrations of NaCl has been investigated in rat liver nuclei that had been digested with micrococcal nuclease under conditions that did not substantially alter morphological properties with respect to differences in the extent of chromatin condensation. The pattern of nucleosome and H1 solubilization was gradual and noncoordinate and at least three different types of nucleosome packing interactions could be distinguished from the pattern. A class of nucleosomes containing 13-- 17% of the DNA and comprising the chromatin structures most available for micrococcal nuclease attack was eluted by 0.2 M NaCl. This fraction was solubilized with an acid-soluble protein of apparent molecular weight of 20,000 daltons and no histone H1. It differed from the nucleosomes released at higher NaCl concentrations in content of nonhistone chromosomal proteins. 40--60% of the nucleosomes were released by 0.3 M NaCl with 30% of the total nuclear histone H1 bound. The remaining nucleosomes and H1 were solublized by 0.4 M or 0.6 M NaCl. H1 was not nucleosome bound at these ionic strengths, and these fractions contained, respectively, 1.5 and 1.8 times more H1 per nucleosome than the population released by 0.3 M NaCl. These fractions contained the DNA least available for micrococcal nuclease attach. The strikingly different macromolecular composition, availability for nuclease digestion, and strength of the packing interactions of the nucleosomes released by 0.2 M NaCl suggest that this population is involved in a special function.     

Artifacts accompanying digestion of chromatin with micrococcal nuclease

DNA in the micrococcal nuclease limit digest of chromatin is completely resistant to DNAse II. At least part of this resistance is not a property of the untreated chromatin, but is acquired in the course of digestion.     

Effect of irradiation and endogenous nucleases on rat liver chromatin

These assessment of the consequences of irradiation on chromatin is complicated by endogenous nucleases. Isolation and prolonged storage of rat liver nuclei in buffers containing divalent metal ions activates these enzymes and promotes the degradation of chromatin. Irradiation of rat liver nuclei to dose levels of 20,000 rad under conditions in which endogenous nucleases are inhibited and analysis of the irradiated chromatin by sucrose density gradient centrifugation gave no evidence for monosomes or oligosomes. When chromatin from irradiated nuclei was digested with micrococcal nuclease, the levels of monosomes and oligosomes were identical to those of micrococcal nuclease, the levels of monosomes and oligosomes are identical to suggest that irradiation results in neither a direct fragmentation of linkers nor the sensitization of linkers for subsequent cleavage by micrococcal nuclease. Histones isolated from monosomes of irradiated and unirradiated nuclei were intact, showing no fragmentation or loss of residues, as judged by sodium dodecyl sulfate-polyacrylamide electrophoresis.     

Physical-chemical properties of the estrogen receptor solubilized by micrococcal nuclease

The physical-chemical properties of the nuclear estrogen receptor from MCF-7 cells were determined. The receptor was solubilized by micrococcal nuclease. Nuclei were isolated from cells previously exposed to 10 nM [3H]estradiol. The amount of receptor released was parallel to the extent of chromatin solubilized, which suggested that the receptor is homogeneously distributed on the chromatin. Following mild nuclease digestion the excised receptor sedimented as an abundant 6-7 S form and as a less abundant approximately 12 S species. The 6-7 S form represented the receptor excised in association with linker DNA, while the approximately 12 S may represent receptor bound to linker DNA which remained associated with the nucleosome. Increasing the extensiveness of digestion resulted in one receptor form sedimenting at 5.6 S. Additional digestion with DNase I did not affect the sedimentation coefficient of the receptor. Sedimentation of the micrococcal nuclease hydrolysate in a 0.4 M KCl sucrose gradient resulted in a 4.2 S receptor form. The same receptor form was extracted from undigested nuclei with 0.4 M KCl. Using Sephadex G-200 column chromatography we have determined the Stokes radii (Rs), molecular weight (Mr) and frictional ratio (f/fo) for the 5.6 S and 4.2 S receptor forms. For the 5.6 S form: Rs = 7.04 nm, Mr = 163,000 and (f/fo) = 1.80. For the 4.2 S receptor, Rs = 4.45 nm, Mr = 77,000 and (f/fo) = 1.46. The ability of the nuclease solubilized 5.6 S receptor to bind DNA was tested using DNA-cellulose column and highly polymerized DNA. About 40% of the applied receptor bound to the column and could be eluted by high salt concentrated buffer. The 5.6 S receptor form was sedimented on sucrose gradient by the highly polymerized DNA. These results suggested that the receptor is bound in chromatin as a dimer or as a monomer in association with other protein(s) which complexed it with DNA.     

The effects of salt concentration and H-1 depletion on the digestion of calf thymus chromatin by micrococcal nuclease.

We have removed histone H1 specifically from calf thymus nuclei by low pH treatment, and studied the digestion of such nuclei in comparison with undepleted nuclei. By a number of criteria the nuclei do not appear damaged. The DNA repeat-length in nuclear chromatin is found to be the same (192 +/- 4 bp) in the presence or absence of H1. These experiments demonstrate that the core histone complex of H2A, H2B, H3, and H4 can itself protect DNA sequences as long as 168 bp from nuclease. Our interpretation is that this represents an important structural element in chromatin, carrying two full turns of superhelical DNA. Depending on conditions of digestion this 168 bp fragment may be metastable and is normally rapidly converted by exonucleolytic trimming to the well-known "core-particle" containing 145 bp. Larger stable DNA fragments observed indigestion of H-1 depleted nuclei appear to arise from oligomers assembled from 168 bp cores in close contact exhibiting trimming of 0-20 bp at the ends. Electrophorograms of undepleted nuclear digests reveal oligomer bands in several size classes, each corresponding to one or more combinations of 168 bp particles, H1-protected spacers of about 20 bp length, and particles with ends trimmed to varying degrees.