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

Role of polyamine in the regulation of RNA synthesis in uterine nucleoli

Administration of estradiol (E2) to ovariectomized mature rats has been shown to result in synthesis of uterine polyamines in the same temporal manner as E2 regulation of nucleolar transcription. Data is presented on the in vivo and in vitro effects of polyamines on uterine nucleolar RNA synthesis. Transcervical intrauterine administration of putrescine (100 micrograms), spermidine (100 micrograms), or spermine (100 micrograms) resulted in an increased transcriptional activity of 93 and 82% in uterine nucleoli isolated from putrescine and spermidine treated animals, respectively. Spermine administration was without effect on uterine nucleolar transcription. The polyamine-induced increase in transcription was totally accounted for by an increased rate of elongation of previously initiated RNA chains. No effect on the number of nucleolar RNA chains in the act of synthesis was observed. Preincubation of uterine nucleoli, isolated from control animals (no E2) with putrescine, spermidine, or spermine in the presence, but not in the absence of ATP, resulted in 44, 83 and 31% increased nucleolar RNA synthesis, respectively. In vitro polyamine-induced nucleolar RNA synthesis was correlated with a polyamine activated phosphorylation of nucleolar proteins of 110,000 24,000, 18,000 and 14,000 Da. Results suggest that early E2 action may result in activation of the polyamine pathway which modulates nucleolar protein kinase activity; initiating an increase in nucleolar transcription.

Affinity chromatographic purification of nucleosomes containing transcriptionally active DNA sequences

The unfolding of nucleosome cores in transcriptionally active chromatin uncovers the sulfhydryl groups of histone H3, making them accessible to SH-reagents. This has suggested that nucleosomes from active genes could be retained selectively on organomercurial/agarose columns. When nucleosomes released from rat liver nuclei by limited digestion with micrococcal nuclease were passed through an Hg affinity column, a run-off fraction of compact, beaded nucleosomes was separated from a retained nucleosome fraction. Although both contained monomer-length DNA and a full complement of core histones, histones in the retained fraction were hyperacetylated. Dot blot hybridizations showed the Hg-bound nucleosome fraction to be enriched in DNA sequences transcribed by hepatocytes (serum albumin and transferrin genes), while a brain-specific gene (preproenkephalin) was not retained, but appeared in the nucleosomes of the run-off fraction. The results are discussed in light of other evidence linking hyperacetylation of histones H3 and H4 to conformational changes at the middle of the nucleosome core.

Binding of the glucocorticoid receptor complex to the nucleosomal core in the P1798 mouse lymphosarcoma

Binding of the glucocorticoid receptor complex to nucleosomes has been studied using the mouse P1798 lymphosarcoma. Cells were incubated with [3H]triamcinolone acetonide (TA), and nuclei prepared and digested with 3 different concentrations of micrococcal nuclease. After fractionation with EDTA and NaCl, it was observed that [3H]TA bound with similar specific radioactivity to mononucleosomes containing both core and linker DNA, of 183 +/- 5, and 168 +/- 4 base pair lengths, respectively, as well as to core size DNA, of 148 +/- 3 base pair length, suggesting that the glucocorticoid receptor bound to the core portion of the nucleosome. Steroid binding was found to be associated with regions of the nucleosome that were depleted in histone H1 and enriched in high mobility group (HMG) proteins 1 and 2; only negligible binding was noted in nucleosomes enriched in histone H1 and depleted in HMG proteins. In addition to binding to core nucleosomes, the glucocorticoid receptor complex was also shown to bind to a fraction sedimenting at 5-6 S on sucrose gradients characterized by subnucleosome and mononucleosome size DNA, as well as by core histones. While binding of the steroid receptor complex to linker regions of the nucleosome cannot be ruled out, this data would appear to present the first concrete evidence that glucocorticoid binding, at least in the P1798 lymphosarcoma, is to core nucleosomes. Some caution in interpretation of the results is indicated, however, on 2 points: (1) receptor redistribution during nuclease digestion cannot be ruled out; (2) only the binding of a small proportion of the steroid receptor complex may be physiologically relevant.

Torsional stress promotes the DNAase I sensitivity of active genes

Active genes are known to have an altered chromatin structure that is preferentially sensitive to digestion with DNAase I. We find that when chicken red blood cells are incubated in media containing the topoisomerase II inhibitor novobiocin, the preferential DNAase I sensitivity of the active beta-globin genes is reversed in vivo with as little as 20 min of drug treatment. Control experiments suggest that inhibition of a topoisomerase II is responsible for this alteration in active gene conformation. Reversal of DNAase I sensitivity can also be induced in vitro by partial cleavage of the nuclear DNA with staphylococcal nuclease. We propose that the altered structure around active genes is maintained by continuous DNA supercoiling and that in the absence of this superhelical tension active chromatin reverts to a less DNAase I-sensitive ground state.

Transcriptionally active chromatin

Eukaryotic chromatin has a dynamic, complex hierarchical structure. Active gene transcription takes place on only a small proportion of it at a time. While many workers have tried to characterize active chromatin, we are still far from understanding all the biochemical, morphological and compositional features that distinguish it from inactive nuclear material. Active genes are apparently packaged in an altered nucleosome structure and are associated with domains of chromatin that are less condensed or more open than inactive domains. Active genes are more sensitive to nuclease digestions and probably contain specific nonhistone proteins which may establish and/or maintain the active state. Variant or modified histones as well as altered configurations or modifications of the DNA itself may likewise be involved. Practically nothing is known about the mechanisms that control these nuclear characteristics. However, controlled accessibility to regions of chromatin and specific sequences of DNA may be one of the primary regulatory mechanisms by which higher cells establish potentially active chromatin domains. Another control mechanism may be compartmentalization of active chromatin to certain regions within the nucleus, perhaps to the nuclear matrix. Topological constraints and DNA supercoiling may influence the active regions of chromatin and be involved in eukaryotic genomic functions. Further, the chromatin structure of various DNA regulatory sequences, such as promoters, terminators and enhancers, appears to partially regulate transcriptional activity.

Binding of benzo[a]pyrene to different chromatin domains following activation at the nuclear membrane

When isolated liver nuclei from methylcholanthrene-treated rats are incubated with benzopyrene, covalent adducts are formed between DNA and the ultimate carcinogen, benzopyrene diol epoxide. Brief digestion with DNaseI, or micrococcal nuclease has been used to demonstrate that benzopyrene metabolites bind more readily to DNA in chromatin regions with a more open, active conformation than to inactive chromatin.

Immunochemical study of chromatin non-histone proteins. II. Localization of immunogenic tissue-specific proteins in nuclease-hypersensitive sites of chromatin

Localization of immunogenic tissue-specific and tissue-non-specific non-histone proteins in thymocyte chromatin has been investigated using antibodies against rat thymus and liver chromatin. After chromatin digestion by DNAase II and subsequent fractionation with 2 mM MgCl2, the Mg2+-soluble fraction interacts with both types of antibodies 5-6 times more effectively than Mg2+-insoluble chromatin. The experiments on chromatin digestion with DNAase I indicate that tissue-specific and tissue-non-specific proteins, reacting with antibodies, are released only upon hydrolysis of the first 1-3% of DNA. Further digestion with DNAase I causes no additional solubilization of these proteins. The chromatin fraction enriched in immunogenic proteins is also released upon autolytic digestion of chromatin with endogenous nuclease. The data obtained suggest that by their function tissue-specific and tissue-non-specific antigenic determinants belong to the same class of non-histone proteins localized in the chromatin sites hypersensitive to nucleases. The possible role of these proteins in regulation of the transcription is discussed.

The effect of a high mobility group protein (HMG 17) on the structure of acetylated and control core HeLa cell chromatin

The effect of binding a high mobility group protein (HMG 17) on the stability and conformation of acetylated and control HeLa high molecular weight core chromatin (stripped of H1 and non-histone chromosomal proteins) was studied by circular dichroism and thermal-denaturation measurements. Previously it had been shown that conformational differences exist between native whole chromatin derived from butyrate-treated (acetylated) and control HeLa cells and that these conformational differences disappear by removing H1 and non-histone chromosomal proteins ( Reczek , P.R., Weissman , D., Huvos , P.E. and Fasman, G.D. (1982) Biochemistry 21, 993-1002). The circular dichroism spectra and the thermal denaturation profiles of control and acetylated core chromatin were found to be similar. The circular dichroism properties of HMG 17 reconstituted highly acetylated and control core chromatin indicated the same alteration of chromatin structure at low ionic strength (1 mM sodium phosphate/0.25 mM EDTA, pH 7.0). The magnitudes of the decrease in ellipticity were proportional to the amount of HMG 17 bound and were found to be the same for both the acetylated and control core chromatin. Thermal denaturation profiles confirmed this change in structure induced by HMG 17 on control and highly acetylated core chromatin. The thermal denaturation profiles, which were resolved into three component transitions, exhibited a shifting of hyperchromicity from the lower melting transitions to the higher melting transitions, with a concomitant rise in Tm, on HMG 17 binding to both control and acetylated chromatin. The natures of the interactions of HMG 17 at higher ionic strength (50 mM NaCl/0.25 mM EDTA/1 mM sodium phosphate, pH 7.0) with acetylated and control core chromatin were slightly different, as measured by circular dichroism; however, a decrease in ellipticity was observed for both samples upon binding of HMG 17. These observations suggest that acetylation coupled with HMG 17 binding to core chromatin does not loosen chromatin structure. HMG 17 binding to control and acetylated core chromatin produces an overall stabilization and compaction of chromatin structure.

Chromatin proteins of rat preputial-gland: acute changes in response to estrogen

The effects of estradiol-17 beta (E2 beta) at 2 or 15 min in vivo on chromatin proteins of rat preputial-gland were analyzed by a battery of electrophoretic methods. Among histones, E2 beta/control ratios for major bands of H1 decreased substantially between 2 and 15 min. In contrast, ratios of H4 increased (P less than 0.01), whereas, except for losses by 2 min in a H2B-like component and in H3.1, other core histones were unchanged. Among 0.35 M NaCl-soluble proteins, components at 34K-mol. wt and less than 21K -mol wt were increased after 2 min of E2 beta. The bulk of the hormone-responsive low-molecular weight proteins was basic in charge. Electrophoretic correlates of 6 basic lysosomal proteins corresponded to those of low-molecular weight salt-soluble chromatin proteins. Selective proteolysis initiated in vivo by E2 beta depleted some tightly-bound nonhistone proteins.

DNAase I and cellular factors that affect chromatin structure

The use of DNAase I as a probe of chromatin structure is frequently fraught with problems of irreproducibility. We have recently evaluated this procedure, documented the sources of the problems, and standardized the method for reproducible results (Prentice and Gurley (1983) Biochim. Biophys. Acta 740, 134-144). We have now used this probe to detect differences in chromatin structure between cells blocked (1) in G1 phase by isoleucine deprivation, or (2) in early S phase by sequential use of isoleucine deprivation followed by release into the presence of hydroxyurea. The cells blocked in G1 phase have easily-digestible chromatin, while cells blocked in early S phase have chromatin which is much more resistant to DNAase I. These differences were found to be the result of diffusible factors found in the cytoplasm and nuclei of G1- and S-phase cells, respectively. The G1 cells contained a cytoplasmic factor which modulates the chromatin structure of S-phase nuclei to a more easily digestible state, while cells blocked in S phase contain a nuclear factor which modulates the chromatin structure of G1 nuclei to a state more resistant to digestion. DNAase I is much more sensitive to these cell cycle-specific chromatin changes than is micrococcal nuclease. The results indicate that, under controlled conditions, DNAase I should be a valuable probe for detecting chromatin structural changes associated with cell cycle traverse, differentiation, development, hormone action and chemical toxicity.

Nuclease digestibility of chromatin is affected by nuclei isolation procedures

Experiments using nucleases as probes of chromatin structure take place in two stages: (1) nuclei isolation, and (2) nuclease digestion. The parameters of the nuclease digestion stage are usually strictly controlled because of nuclease sensitivity to them. However, there have been no reports on whether parameters in the nuclei isolation stage affect the subsequent nuclease digestions. We have evaluated a typical nuclei isolation technique with respect to how changes in the isolation parameters affect nuclease digestion kinetics. Our observations point out that various parameters encountered in the nuclei isolation stage have a significant effect on the subsequent nuclease digestion kinetics of DNAase I. These parameters include the concentration of cells, divalent cations and phosphatase inhibitors. The pH, concentration of NaCl and concentration of detergent had little effect. Micrococcal nuclease was relatively unaffected by changes in the nuclei isolation parameters. The importance of this report lies in the demonstration that lack of control of seemingly insignificant parameters, such as cell concentration during the nuclei isolation stage, leads to subsequent irreproducible results in the DNAase I digestion. These findings indicate that great care must be exercised in the nuclei isolation stage if reproducible work is to be performed with DNAase I.

Responses to androgens of rat ventral prostate nuclear androgen-binding sites sensitive and resistant to micrococcal nuclease

Rat ventral prostate nuclei were separated into three major fractions by mild digestion with micrococcal nuclease and two fractions by extensive digestion. All fractions contained androgen-binding sites. Almost 50% of nuclear binding sites were resistant to enzymic digestion when only 5-15% of total DNA was resistant. Under milder digestion conditions, 21% of nuclear binding sites were associated with an intermediate fraction, representing 16% of total nuclear DNA, which was enriched in specific androgen-regulated gene sequences. This fraction was rapidly degraded by more extensive digestion. The nuclease sensitivity of these particular genes was markedly influenced by castration and the administration of dihydrotestosterone to castrated animals. The nuclear content of both nuclease-resistant and -sensitive androgen-binding sites was decreased by castration. Whereas the administration of androgen to animals castrated 1 day previously preferentially replenished nuclease-resistant sites, nuclease-sensitive sites, including those associated with transcriptionally active regions, had apparent priority when androgen was supplied to animals castrated 7 days previously. The significance of these observations to the regulation of nuclear processes and the possible interrelationships of nuclease-sensitive and -insensitive sites are discussed.

The ovalbumin gene is associated with the nuclear matrix of chicken oviduct cells

The DNA in a eucaryotic nucleus is arranged into a series of supercoiled loops that are anchored at their bases to the nuclear matrix. Using nuclease digestion, one can progressively cleave DNA from the loops, thereby isolating residual DNA that is progressively closer to the nuclear matrix anchorage sites. We have determined that the ovalbumin gene is preferentially associated with the nuclear matrix of chicken oviduct cells, but is not preferentially associated with the nuclear matrix of chicken liver cells. As a control, the beta-globin gene, which is not transcribed in oviduct cells, was found not to be preferentially associated with the oviduct nuclear matrix. The observation that the transcriptionally active ovalbumin gene is preferentially associated with the nuclear matrix may have significant implications for gene expression and the organization of nuclear DNA into supercoiled-loop domains.