Differential solubilization of nuclear glucocorticoid receptors by DNAase I and DNAase II

This study analyzes the sensitivity of nuclear bound glucocorticoid receptors to solubilization from nuclei by DNAase I and DNAase II. Thymocytes were incubated with 10(-8) M [3H]dexamethasone, [3H]cortisol or [3H]triamcinolone acetonide, without or with 10(-6) M unlabelled dexamethasone, for 30 min at 37 degrees C and nuclei from these cells were digested with either DNAase I and DNAase II. DNAase I for 2 h at 3 degrees C leads to solubilization of 60% of the nuclear DNA and release of 10--20% triamcinolone acetonide-receptor, 30--40% dexamethasone-receptor and 85--90% cortisol-receptor. DNAase II at the same enzymatic concentration solubilizes only 10--20% of the nuclear DNA, but releases 40--50% triamcinolone-receptor, 60--70% dexamethasone-receptor and 100% cortisol-receptor. Release of nuclear bound dexamethasone-receptor by DNAase I parallels the solubilization of DNA, reaching maximum values by 2 h at 3 degrees C, whereas maximal release by DNAase II is obtained within 45 min when DNA solubilization is not complete. When nuclei initially extracted with DNAase I are re-extracted with DNAase II, greater than 65% of the DNAase I residual dexamethasone-receptors are solubilized, whereas DNAase I is ineffective in solubilizing DNAase II residual dexamethasone-receptors. DNAase I solubilizes only 30% of the 0.4 M KCl residual dexamethasone-receptor whereas DNAase II digests over 90% of this fraction. DNAase I extracts of nuclear dexamethasone-receptor chromatograph on G-100 Sephadex as a single radioactive peak just after the void volume, whereas DNAase II extracts of nuclear dexamethasone-receptor chromatograph as two peaks of radioactivity, one which is similar to the DNAase I solubilized receptor and a second broad peak of macromolecular bound radioactivity which is smaller in size.     

Visualization and quantitative analysis of complex formation between E. coli RNA polymerase and an rRNA promoter in vitro.

We have established conditions that stabilize the interaction between RNA polymerase and the rrnB P1 promoter in vitro. The requirements for quantitative complex formation are unusual for E. coli promoters: (1) The inclusion of a competitor is required to allow visualization of a specific footprint. (2) Low salt concentrations are necessary since complex formation is salt sensitive. (3) The addition of the initiating nucleotides ATP and CTP, resulting in a low rate of dinucleotide production, is required in order to prevent dissociation of the complexes. The complex has been examined using DNAase I footprinting and filter binding assays. It is characterized by a region protected from DNAase I cleavage that extends slightly upstream of the region protected by RNA polymerase in most E. coli promoters. We find that only one mole of active RNA polymerase is required per mole of promoter DNA in order to detect filter-bound complexes. Under the conditions measured, the rate of association of RNA polymerase with rrnB P1 is as rapid as, or more rapid than, that reported for any other E. coli or bacteriophage promoter.     

Isolation,characterization, and structure of the folded interphase genome of Drosophila melanogaster

The intact interphase genome of Drosophila melanogaster has been isolated by sucrose gradient centrifugation after gentle lysis of tissue culture cells in 0.9 M NaCl-0.4% Nonidet P40. The nonviscous folded DNA sediments as a single broad 5000S peak in a complex with RNA (a fraction of the nuclear nascent RNA) and protein (all of the four intranucleosome histones: H2A, H2B, H3, and H4).The folded DNA is supercoiled and can be relaxed to slower sedimenting forms either by intercalating ethidium or by nicking with DNAase I. Incomplete DNAase treatment gives partially relaxed complexes, indicating that each nick relaxes only a stretch of DNA (defined as a supercoiled DNA loop) without affecting the superhelical content of the rest of the genome. The concentration of superhelices in the Drosophila folded DNA is the same as in the E. coli and SV40 closed circular DNAs—that is, about one negative turn every 200 base pairs (bp) in 0.15 M NaCl at 26°C. The estimated average size of the supercoiled DNA loops, about 85,000 bp, equals the size of the larger Drosophila chromomeres.Ethidium intercalation in 0.9 M NaCl both removes the negative superhelical turns and dissociates the four histones from the DNA. The four histones are dissociated in equimolar concentrations, and the relative proportion of histones displaced from the DNA is a function of ethidium concentration. The histones are completely dissociated from the folded DNA at the ethidium concentration which removes all of the negative superhelices. Thus the data strongly suggest that the rotation of the Watson Crick helix which accompanies ethidium intercalation causes the loss of nucleosomes from the DNA.The results are interpreted in terms of a model for the folded Drosophila genome which has the DNA constrained (by both protein-DNA and RNA-DNA interactions) into independent supercoiled loops containing on the average 400 nucleosomes per loop. Each nucleosome is composed of a histone core with the DNA wound around it in a 360° left-handed toroidal supercoil; each nucleosome toroidal supercoil plus its relaxed internucleosome DNA contains, on the average, 200 bp.     

In vitro DNA replication in association with the nuclear matrix of permeable mammalian cells

DNA replication has been studied in in vitro cultured bovine liver cells permeabilized in 0.02% Triton X-100. The Km for TTP was 20 microM. The initial incorporation rate at 10 microM TTP concentration was about 12% of the in vivo synthesis and declined very strongly within 1 h. A similar decline of the incorporation rate was found at 0.12 microM TTP concentration. DNAase I digestion of DNA-matrix complexes obtained from isolated nuclei in 2 M NaCl revealed that newly replicated DNA was preferentially bound to the nuclear matrix. A similar digestion with S1 nuclease caused a selective release of short duplexes of Okazaki fragments with the complementary parental strand. The results show that in vivo replication continues in permeabilized cells in an almost unchanged way, except for a gradual decline of its rate which is mainly due to inactivation of one or more essential components.     

Salt-dependent co-operative interaction of histone H1 with linear DNA

The nature of the complexes formed between histone H1 and linear double-stranded DNA is dependent on ionic strength and on the H1 : DNA ratio. At an input ratio of less than about 60% (w/w) H1 : DNA, there is a sharp transition from non-co-operative to co-operative binding at a critical salt concentration that depends on the DNA size and is in the range 20 to 50 mM-NaCl. Above this critical ionic strength the H1 binds to only some of the DNA molecules leaving the rest free, as shown by sedimentation analysis. The ionic strength range over which this change in behaviour occurs is also that over which chromatin folding is induced. Above the salt concentration required for co-operative binding of H1 to DNA, but not below it, H1 molecules are in close proximity as shown by the formation of H1 polymers upon chemical cross-linking. The change in binding mode is not driven by the folding of the globular domain of H1, since this is already folded at low salt in the presence of DNA, as indicated by its resistance to tryptic digestion. The H1-DNA complexes at low salt, where H1 is bound distributively to all DNA molecules, contain thickened regions about 6 nm across interspersed with free DNA, as shown by electron microscopy. The complexes formed at higher salt through co-operative interactions are rods of relatively uniform width (11 to 15 nm) whose length is about 1.6 times shorter than that of the input DNA, or are circular if the DNA is long enough. They contain approximately 70% (w/w) H1 : DNA and several DNA molecules. These thick complexes can also be formed at low salt (15 mM-NaCl) when the H1 : DNA input ratio is sufficiently high (approximately 70%).     

Chromatin structure as probed by nucleases and proteases: Evidence for the central role of hitones H3 and H4

We have examined the role played by each histone in forming the structure of the ν-body. When DNAase I, DNAase II, trypsin, and chymotrypsin attack chromatin, characteristic discrete DNA and protein digest fragments are produced. Using this restriction of accessibility as diagnostic for chromatin structure, we have examined complexes of DNA with virtually all possible combinations of histones. The results strongly support our previous conclusion (Camerini-Otero, Sollner-Webb, and Felsenfeld, 1976) that the arginine-rich histones are unique in their ability to create, with DNA, a structure with many features of native chromatin. Acting together, slightly lysine-rich histones then modify this complex into one very similar to native chromatin. An analysis of the rate constants of staphylococcal nuclease digestion also confirms that the complex of H3, H4, and DNA is crucial to the structure of the ν-body.     

Intercalation with DNA is a prerequisite for daunomycin, adriamycin and its congeners in inhibiting DNAase I

DNAase I from bovine pancreas is inhibited by Daunomycin, Adriamycin, Adriamycin-14-acetate and Adriamycin-14-octanoate, whereas it is not inhibited by N-trifluoroacetyladriamycin-14-valerate or N-trifluoroacetyl-adriamycin. The present study suggests that these inhibitors act not directly on the enzyme, but on DNA, forming stable complexes and thus interfering with enzyme activity. The correlation between DNA binding and enzyme inhibition is demonstrated by the fact that the compounds forming complexes with DNA inhibit DNAase I activity, whereas those which do not form complexes with DNA cause no inhibition.     

Nutritional regulation of differentiation and synthesis of an exocytoplasmic deoxyriboendonuclease in Streptomyces antibioticus

Streptomyces antibioticus produces a cell-wall-located deoxyriboendonuclease (DNAase) the synthesis of which in submerged and surface cultures is related to the growth rate. DNAase synthesis always preceded aerial mycelium formation in surface cultures. Production of aerial mycelium began at the end of exponential growth or in the early stationary phase; it was absent in cultures grown on nutrient agar/glucose or in media with a high concentration of casein hydrolysate. These nutritional conditions also impaired production of the DNAase. External DNA substrates were not degraded by mycelium producing the DNAase. These observations lead us to suggest a role for the enzyme in the developmental cycle of S. antibioticus.     

Nick translation of mammalian DNA

The labelling of mouse DNA by nick translation with DNA polymerase I has been investigated with respect to the time of incubation, requirement for DNAase I, size of the product, and uniformity of labelling, and the hybridisability and stability of the resultant labelled probes. Total mouse DNA and reannealed unique mouse DNA sequences can be labelled by nick translation in the presence of [3H]dCTP and [3H]TTP to a specific activity of 7 . 10(6)--20 . 10(6) cpm/microgram DNA. The hybridisation characteristics of nick-translated whole DNA with an excess of unlabelled mouse-embryo driver DNA indicates that no preferential labelling of repetitive or unique DNA sequence classes occurs. In addition, the proportion of unique DNA sequences labelled by nick translation which hybridises with polyadenylated nuclear RNA from Friend cells is the same as that of unique DNA sequences isolated from cells labelled with [3H]thymidine in vivo, indicating that few (if any) of the unique DNA sequences are unrepresented in the nick-translated probe. Probes which contain [3H]dTMP are unstable, and show a considerable reduction in hybridisability over a period of 6 months at --20 degrees C. The decrease is accompanied by an increase in the number of mismatched sites in duplexes containing the labelled probe (as shown by thermal stability measurements of hybrid molecules) and a decrease in the rate of hybridisation of the probe with total mouse DNA. In contrast, DNA which is labelled with [3H]dCMP alone is stable, and does not show any decrease in hybridisability on prolonged storage.     

Features of the structure of replicating and non-replicating chromatin in chicken erythroblasts.

The digestion by DNAase I of DNA synthesised by isolated chicken erythroblasts was examined in isolated nuclei. It was found that newly synthesised DNA was susceptible to DNAase I but matured to a relatively resistant form with increasing time after replication as observed in mammalian systems. The presence of trypsin in the digestion exposed all of the DNA to DNAase I action. Examination of the digestion products showed that the newly replicated DNA differed little from the more mature form in the structure of the DNA-protein complex but that the difference in susceptibility was probably a result of a differential rate of access of the DNAase to the new and old DNA.     

Effects of deoxyribonuclease I and micrococcal nuclease on the release of dexamethasone-receptor complex from nuclei of sensitive and insensitive hepatoma cell lines

(1) Fu5 cells were sensitive to the glucocorticoid inhibition of cell growth and the hormonal induction of tyrosine aminotransferase (but not fructose-1,6-bisphosphatase and glycogen synthase). AH-130 and AH-7974 cells were insensitive to both effects. (2) The release of [3H]dexamethasone radioactivity from the nuclei of Fu5 and AH-130 cells preincubated with [3H]dexamethasone increased as the KCl concentration increased from 0 to 0.4 M, with no significant difference between the two cell lines. (3) The radioactivity was more sensitively released in Fu5 nuclei than in AH-130 nuclei upon treatment with DNAase I. The release of radioactivity was always larger than the release of DNA in both cell nuclei. In contrast to DNAase I, micrococcal nuclease treatment did not show any difference between the two cell lines in the release of radioactivity from nuclei, always showing a release of radioactivity equal to that of DNA.     

Methylation of DNAase-digestible DNA and of RNA in chromatin from rats treated with dimethylnitrosamine.

After injecting rats with di[14C]methylnitrosamine we have prepared liver chromatin and have examined firstly, the methylation level of the DNAase I-degradable fraction of the DNA and secondly, the level of methylation and the stability of methylated sites in chromatin RNA. Our results show that the level of 7-methylguanine in the degradable DNA is about 1.3 times that of whole DNA; therefore in the 20% or so of the DNA which is undegradable by DNAase I, the level must be very low or zero. Experiments using chromatin from rats injected with unlabelled dimethylnitrosamine plus [3H]thymidine show that the specific activity is similar in the DNAase I degradable and undegradable fractions, suggesting that there is no preferential repair in the latter region. In chromatin RNA, the level of 7-methylguanine is higher than that of whole DNA and decreases fairly rapidly within 30 h after dimethylnitrosamine treatment. Our results indicate that this decrease is due to some type of excision or repair process rather than to normal turnover.     

Cross-linking of proteins in nuclei and DNA-depleted nuclei from Friend erythroleukemia cells.

Reversible cross-linking of proteins in nuclei and DNA-depleted nuclei from Friend erythroleukemia cells was used as a probe to determine whether the protein structure was preserved following treatment with DNAase I. Interactions between histones were analyzed through cross-linking with 2-iminothiolane or dimethyl 3,3'-dithiobispropionimidate. No alterations in the interactions between intranucleosomal histone proteins resulted from digestion of the nuclear DNA. There was, however, a diminished extent of cross-linking of histone H1 to itself and to the intranucleosomal histones in DNA-depleted nuclei. The interactions of a group of nonhistone proteins with histone H3 could be monitored by cross-linking through the formation of disulfide bonds caused by oxidation of nuclei with H2O2. These interactions were not markedly affected by treatment of the nuclei with DNAase I. However, differences were observed in the extent of cross-linking of some of these proteins when cross-linking in nuclei from undifferentiated cells was compared to that in nuclei from cells which had been induced to differentiate with dimethylsulfoxide.     

Evidence for the existence of a stable association between nascent DNA and the nuclear membrane of HeLa cells.

Nascent DNA-nuclear membrane complexes isolated from HeLa cells and solubilized in a sodium dodecyl sulfate-urea solution were examined by gel electrophoresis, column chromatography, isopycnic centrifugation, and by extraction with chloroform/methanol. Radioactivity attributable to [3H]DNA co-migrated with three protein peaks during electrophoresis. This radioactivity was eliminated by prior treatment with DNAase. In addition, all of the radioactivity attributable to nascent DNA eluted with a specific protein on Sepharose 4B columns. This DNA - protein complex banded at a density of 1.58 gm/cm3 in sucrose-CsCl gradients. Treatment with DNAase, phospholipase A and C, and dilute alkali disrupted the complex. Moreover, 93% of the radioactivity attributable to protein and 70% of that attributable to DNA could be extracted from the complex with a chloroform/methanol solution. The results suggest that nascent DNA may be in a stable association with a proteolipid moiety of the nuclear membrane.     

Identification of RNA molecules which contain 5 S ribosomal RNA and transfer RNA in an RNAase E-RNAase P- double mutant strain of Escherichia coli

In the analysis of DNAase II digestion of chromatin, as described in the preceding paper, interactions between adjacent nucleosomes play an important part. In order to understand the mechanism of DNAase II cleavage we next investigated the role of histone H1 in these interactions and characterized the nucleoprotein particles arising in the course of DNAase II action.H1-free chromatin prepared by three different procedures, using either 0.6 m-NaCl, transfer RNA or an ion-exchange resin, can be cleaved by DNAase II only at the internucleosomal cleavage site leading to 200-bp² digestion patterns regardless of the ionic conditions. When H1 was added back to the three chromatin preparations the 100-bp cleavage pattern could be restored only with material prepared by the resin method at low concentrations of salt. Addition of polylysine instead of H1 has the same effect, but only with material prepared by that method. A direct correlation between extended and condensed states of chromatin as monitored by electron microscopy and DNAase II cleavage in the 200 and 100-bp modes, respectively, could be established.The continuity of the nucleosome chains in DNAase II-digested chromatin is maintained in spite of intranucleosomal cleavage in the terminal section of the core DNA, even in the absence of H1. Addition of 3 m-urea, however, disrupts the nucleosome chains at the intranucleosomal cleavage sites and leads to the formation of novel nucleoprotein particles as seen in sucrose gradient centrifugations. Those sedimenting between mononucleosomes and dinucleosomes contain, almost exclusively, DNA of 300 bp (mouse) or 315 bp (chicken erythrocyte). They can be formed from particles sedimenting in the absence of urea in the dinucleosome region by either a dissociation process or a massive conformational change.On the basis of the results presented here and in the preceding paper a mechanism for DNAase II cleavage of chromatin in the 200-bp and 100-bp modes is proposed and discussed in the context of structural features of chromatin recognized by DNAase II.     

Non-histone proteins in fractionated chromatin before and after DNAse II treatment

Chromatin from spleen cells of normal, non-immunized mice and from mice 3 days after immunization with human immunoglobulin G was fractionated at increasing salt concentrations into three fractions: 0.35 M NaCl-soluble, 2 M NaCl-soluble and a residual fraction, dissociated in 2 M NaCl/5 M urea. The residual fraction of chromatin, homogeneous by ultracentrifugation and containing only 25% of the total chromatin DNA, was associated with proteins strongly labeled with [3H]tryptophan, [3H]methionine and [3H]leucine. This fraction was more sensitive to DNAase II treatment than was native, non-fractionated chromatin and it contained approx. 40% Mg2+-soluble DNA sequences. The template activity of the residual fraction was 6--7-times higher than that of non-fractionated chromatin. Fraction A, characteristic for non-immunized spleen cells, was present in three chromatin fractions and after DNAase II treatment it remained only in the residual fraction, which suggests that this fraction is associated with genes non-transcribed in non-immunized mice. Fractions I and B1 were found mainly in the residual fraction, and only in smaller amounts in the 0.35 M NaCl-soluble fraction. After DNAase II treatment, fractions I and B1 in chromatin from immunized mice disappeared, which suggests that these fractions may be associated with active transcribed sequences during the immune reaction.     

Studies of ColE1-plasmid DNA and its interactions with histones: sedimentation velocity studies of monodisperse complexes reconstituted with calf-thymus histones.

Complexes between the four calf-thymus histones (H2A, H2B, H3 and H4) and colE1-plasmid DNA have been reconstituted using the procedure of Oudet et al. ((1975), Cell 4, 281-300). The sedimentation rates of the complexes formed were studied under a variety of conditions. In 0.4 MNaCL, 0.1 M Tris pH 7.50, 0.01 M EDTA and 0.02 M NaHSO3, the final dialy-sis-solvent in the reconstitution procedure, the sedimentation coefficients s23 were found to increase when the complexes were reconstituted at increasing histone to DNA ratios. True plateau regions were reached in the case of the relaxed circular and linear forms of the plasmid DNA. The sedimenting boundaries observed for the complexes at saturation are sharp, reflecting a narrow distribution of sedimentation coefficients and a homogeneity of the complex comparable to that of the uncomplexed DNA. Studies of the dependence of s 23 on the concentration of the complex at constant DNA to histones ratio have been undertaken at salt concentrations between 0.4 and 1.5 M NaCL in the above solvent. The formation of the complexes is reversible, at least at the higher ionic strengths. At salt concentrations below 0.36 M the complex precipitates from solution. Omission of histone H4 from the reconstitution mixture abolishes complex formation.     

Sequence-specific positioning of core histones on an 860 base-pair DNA. Experiment and theory

Previous experiments have shown that the locations of the histone octamer on DNA molecules of 140 to 240 base-pairs (bp) are influenced strongly by the nucleotide sequence. Here we have studied the locations of the histone octamer on a relatively long DNA molecule of 860 bp, using two different nucleases, micrococcal and DNAase I. Data were obtained from both the protein--DNA complexes and from the naked DNA at single-bond resolution, and then were analyzed by densitometry to yield plots of differential cleavage, which show clearly the changes in cutting due to the addition of protein. Our results show that the placement of core histones on the 860 bp molecule is definitely non-random. The digestion data provide evidence for five nucleosome cores, the centers of which lie in defined locations. In all but one of these protein--DNA complexes, the DNA adopts a unique, highly preferred rotational setting with respect to the protein surface. Another protein--DNA complex is unusual in that it protects 200 bp from digestion, yet is cut in its very center as if it were split into two parts. The apparent average twist of the DNA within all of these protein--DNA complexes is 10.2(+/- 0.1) bp, as measured by the periodicity of DNAase I digestion. This value is in excellent agreement with the twist of 10.21(+/- 0.05) bp deduced from the periodicity of sequence content in chicken nucleosome core DNA. In addition, we observe a discontinuity in the periodic cutting by DNAase I of about -1 to -3 bonds in going from any nucleosome core to the next. The most plausible interpretation of this discontinuity is that it reflects the angle by which adjacent protein--DNA complexes are aligned. Thus, any nucleosome may be related to its neighbor by a left-handed rotation in space of -1/10.2 to -3/10.2 helix turns, or -35 degrees to -105 degrees. Repeated many times, this operation would build a long, left-handed helix of nucleosomes similar to that described by many workers for the packing of nucleosomes in chromatin. In order to look for any long-range influences on the positioning of the histone octamer in the 860 bp molecule (as would be expected if the nucleosomes have to fit into some higher-order structure), we have examined the locations of the histone octamer on five different isolated short fragments of the 860-mer, all of nucleosomal length.(ABSTRACT TRUNCATED AT 400 WORDS)