Sub-nuclear fractionation. I. Procedure and characterization of fractions

A procedure for fractionation of nuclei from rat liver, Xenopus liver and Xenopus erythrocytes is described. It is based on mild sonication of isolated nuclei for 7–12 sec in a nearly isotonic medium, separation of nuclear sap and centrifugation on a discontinuous sucrose density gradient containing Na and K citrate. Nuclei are thus separated in a single operation into 8 fractions representing nucleoplasm, euchromatin, nucleoli, heterochromatin and nuclear membranes. The sub-nuclear fractions were characterized by chemical composition (DNA, protein, RNA and phospholipid), electron microscopy, thermal denaturation properties of chromatin, relative binding of ${}^3\text{H-actinomycin D}$, polyacrylamide gel electrophoresis of nuclear proteins and titration of membranes against Triton X-100. Approx. 10% of total DNA was recovered as heterochromatin associated with membranes but the bulk of nuclear membranes co-sedimented with the major euchromatin zones. Subnuclear fractions prepared in this way retain virtually all the RNA polymerase activity bound to chromatin [41].     

Differential subnuclear distribution of polyadenylate-rich ribonuclei acid during induction of egg-yolk protein synthesis in male Xenopus liver by oestradiol-17 beta.

A 4-8-fold increase in the rate of hepatic nuclear RNA synthesis occurred within 11 h after a single injection of oestradiol-17 beta to male Xenopus to induce egg-yolk protein synthesis. 2. By using a gentle procedure for fractionating nuclei into their major structurally different components [J. R. Tata& B. Baker (1974) Exp. Cell Res. 83. 111-124], it was found that the hormone-induced increase in the total amount of newly made RNA was associated with a 2-10-fold increase in the poly(A) content of nuclear RNA. 3. When the poly (A) content of nuclear RNA was determined by hybridization to poly[3H](U) or specific binding to oligo(dT)-cellulose, most of the increase (10-fold) in poly (A) content of newly synthesized RNA was associated with the euchromatin fractions, whereas the increase was less marked in the other subnuclear fractions. 4. Resolution of nuclear RNA into poly (A)-poor and poly(A)-rich RNA species by chromatography on oligo(dT)-cellulose, followed by polyacrylamide-gel electrophoresis with sodium dodecyl sulphate or in the pressence of 99% formamide, revealed that the hormone caused a preferential enhancement of high-molecular-weight (25S-60S) poly (A)-rich HnRNA (heterogeneous nuclear RNA,) much of which was associated with euchromatin and not with the nuclear sap. 5. Induction of vitellogenin in male frogs was in particular characterized by the appearance of a high-molecular-weight polyadenylated component exhibiting a peak at 35-36S, i.e. a molecular weight of approx. 2.05x10(6)+/-0.15x10(6). Although there is no evidence as yet that such a polyadenylated high-molecular-weight nuclear RNA species contains sequences corresponding to vitellogenin mRNA, it is possible that a high proportion of the most stable form of the putative nuclear precursor to vitellogenin mRNA induced by oestrogen in male Xenopus liver may be only marginally bigger than the cytoplasmic mRNA, and may at any one time be predominantly associated with the euchromatin fraction.     

Sub-nuclear fractionation. II. Intranuclear compartmentation of transcription in vivo and in vitro

DNA-dependent RNA polymerase activities were measured in subnuclear fractions obtained from rat liver by the procedure described in the preceding paper [14]. Most of the total nuclear enzyme was recovered in a form bound to chromatin with only small amounts as free enzyme in the nucleoplasm. The multiple eukaryotic RNA polymerases were resolved according to the endogenous template to which they were bound and which they continue to transcribe in vitro. The A and B forms of the enzyme were distinguished from each other by their differential sensitivities to α-amanitin, exogenous native and denatured DNA, thermal denaturation at 45 °, Mg²⁺ and Mn² ions, high ionic strength and by the binding of ${}^{14}\text{C-methyl}\text{-γ-}\text{amanitin}$. RNA polymerase B (α-amanitin-sensitive) was exclusively recovered in the nucleoplasmic and euchromatin fractions. RNA polymerase A was recovered in the dispersed nucleolar as well as in heterochromatin. By assaying in the presence of α-amanitin subnuclear fractions that had been pre-incubated at 45 °C a third enzyme (form C) was located exclusively in heterochromatin fractions. Only the euchromatin associated RNA polymerase B was capable of initiating the synthesis of new RNA chains in vitro on endogenous template at low ionic strength. Raising the ionic strength abolished initiation but accelerated chain elongation by this form of enzyme.When nuclear RNA was labelled in vivo, newly made RNA turned over rapidly in the nucleoplasm but accumulated in the euchromatin + membrane fraction. RNA in the nucleolar fraction accumulated gradually after a lag period, whereas a significant amount of rapidly-labelled nuclear RNA was recovered in the heterochromatin fractions. The distribution of RNA labelled in vivo compared with that of RNA polymerase activities suggested that RNA synthesized in vivo is rapidly translocated from its site of synthesis to some other sites within the nucleus.     

Rat liver chromatin. Fractionation into eu- and heterochromatin with localization of ribosomal genes.

Purified, normal rat liver chromatin was sheared under controlled conditions in a Virtis “60” homogenizer and then separated into template-active (euchromatin) and template-inactive (heterochromatin) fractions by glycerol gradient centrifugation. The euchromatin portions of the glycerol gradients possessed greater than 90% of the in vitro template activity when estimated with Escherichia coli RNA polymerase and contained more than 90% of the nascent RNA formed in vivo. Inhibitor studies performed in vivo indicated that the leading edge of the heterochromatin portion of the glycerol gradients contains the genes coding for ribosomal RNA. Recentrifugation of putative eu- and heterochromatin fractions demonstrated that the isolation procedure produces fractions which are distinct and are characterized by little or no cross contamination. The data suggest that controlled shearing in conjunction with gradient centrifugation provides a means of fractionating with great fidelity the transcribable portions of the rat liver genome.     

Repetitive sequences and hairpin-like structures in giant RNA of pigeon erythroid cells

In giant molecules (>45 S) of HnRNA from pigeon bone marrow and peripheral blood erythroid cells a correlation is demonstrated between the amounts of hairpin-like structures and the sequences transcribed from the DNA repetitions. The same correlation is observed in the >45 S poly(A)⁺ and poly(A)^- subfractions.Abbreviations HnRNA heterogeneous nuclear RNA - poly(A)⁺ RNA RNA molecules containing polyadenylic acid sequences - poly(A)^- RNA RNA molecules which do not contain polyadenylic acid sequences - dsRNA double-stranded RNA - SDS sodium dodecylsulphate     

Chromatin and histones in mealy bug cell explants: activation and decondensation of facultative heterochromatin by a synthetic polyanion

In spermatogonial cells of the mealy bug, Planococcus citri, at interphase the five maternal chromosomes appear as diffuse euchromatin and the five paternal chromosomes are heterochromatic, genetically inactive, and incorporate tritiated uridine into RNA at a diminished rate. Testes squashes were treated with 2–10 mg/ml of the polyanion, polystyrene sulfonate (PSS). The gonial cell nuclei decondensed and after 15 minutes they became uniformly granular and similar in appearance to wholly euchromatic nuclei. When testis expiants were incubated with PSS (2–10 mg/ml) for from 15 to 120 minutes, all stages of deheterochromatization were recovered. The Feulgen reaction revealed that the uniform granules contained DNA; methyl-green-thionin staining indicated that the nucleolus contained RNA. When tritiated uridine was added after 15 minutes of PSS and then incubation continued, autoradiography revealed incorporation into euchromatin and decondensing heterochromatin. Incorporation of uridine increased with dosage of PSS up to 4 mg/ml. PSS (20 mg/ml) was toxic to the cells: They incorporated no uridine and were badly damaged. RNAase treated controls were also devoid of label.—PSS treated cells showed a negative alkaline-fast-green reaction for histone. In vitro a complex was formed between calf thymus histone and PSS which was soluble only above pH 8.5, but not separable on a Dowex acetate ion exchange column. These findings suggest that, probably by disrupting the structure of the DNA-histone complex, polystyrene sulfonate brings about structural decondensation of heterochromatin and enables it (and euchromatin) to incorporate tritiated uridine into RNA at an increased rate.     

The action of cordycepin on nascent nuclear RNA and poly(A) synthesis in regenerating liver.

Following a 5 min pulse of [5- 3H]orotic acid via the protal vein, the specific radioactivity of non-poly(A)heterogeneous nuclear RNA (HnRNA) reaches a peak at 12 h after partial hepatectomy. In contrast, poly(A)-HnRNA was maximally elevated only at 2 h after operation. After intraportal injection of cordycepin (3'-deoxyadenosine) 1 min before [5-3H]orotic acid, a dose-dependent inhibition of nuclear HnRNA and rRNA occurred. Fractionation of HnRNA on poly(U)-Sepharose following 20 mg/kg of cordycepin revealed that a 65% reduction occurred in the labeling of poly(A)-HnRNA while non-polyactivity of UTP in control and cordycepin-treated animals indicated no significant alterations in these parameters. Assessment of poly(A) size using poly(A)-HnRNA annealed with oligo(dT)10 as template primer for Escherichia coli DNA polymerase I, showed that 20 mg/kg of cordycepin inhibited nuclear polyadenylylation by 43%; no alteration in the binding of poly(A)-HnRNA to Millipore filters occurred at this dose of cordycepin. These results indicate that cordycepin is a non-selective inhibitor of nuclear RNA and poly(A)synthesis in regenerating rat liver.     

Spatial distribution of mRNA during pre-fertilization ovule development in Capsella bursa-pastoris

Summary In situ hybridization of sections of the ovary and ovule of Capsella bursa-pastoris with ³H-polyuridylic acid [³H-poly(U)] showed the presence of polyadenylic acid-containing RNA [poly(A) + RNA] in the cells of the placenta and nucellus. During megasporogenesis there was a decrease in ³H-poly(U) binding activity of the nucellar cells concomitant with the appearance of poly(A) + RNA in the integuments. As the typical eight-nucleate embryo sac was formed, ³H-poly(U) binding was not apparent around the quartet of nuclei at the chalazal end, while it persisted at the micropylar end. Both the egg and synergids as well as the chalazal proliferating tissue showed high concentrations of poly(A) + RNA in their cytoplasm. The results suggest a role for transient localizations of poly(A) + RNA during female sporogenesis and gametogenesis in C. bursa-pastoris.     

Intranuclear distribution of rat liver ribosomal RNA]

A method is described for the isolation of pure liver nuclei with minimal cytoplasmic contaminants, loss of nuclear RNA and degradation of nuclear RNA. The RNA components are extracted in three distinct fractions by subsequent treatment with phenol at 4 degrees, 50 degrees and 85 degrees C. The total and 14C-orotate labelled RNA components in the three nuclear RNA fractions are characterized by nucleotide composition, poly(A)-RNA content and agar-gel electrophoresis. The results show that the RNA in three fractions correspond to the nucleosol, nucleolus and chromatin compartments of the nucleus. The nuclear HnRNA components are exclusively in the 85 degrees C RNA. Nuclear ribosomal RNA is extracted in the 4 degrees C and 50 degrees C RNA fractions. These two nuclear RNA fractions are distinct in constituent pre-rRNA species and the rate of labelling of their rRNA components. The amount of the pre-rRNA and rRNA species is determined. The results show that the nucleolus-nucleosol and nucleosol-cytoplasm transitions of ribosomal subparticles are markedly slower processes than the preceeding steps of ribosome biogenesis.     

Rates of RNA chain growth in developing sea urchin embryos

The average time necessary to add a nucleotide onto growing RNA chains (step time) has been determined for several developmental stages of Strongylocentrotus purpuratus embryos. One procedure involved quantitation of isolated nucleosides derived from the 3′ end of newly synthesized chains plus total rates of nucleotide incorporation. The former values provide the number of growing chains so that rates of incorproation per RNA chain may be calculated. A second procedure involves determinations of the times required for RNA molecules of given size classes to become fully labeled. These times may be equated to the synthetic times for the particular size class [Bremer, H., and Yuan, D. (1968). RNA chain growth-rate in Escherichia coli. J. Mol. Biol.38, 163–180]. The step times for blastula and pluteus embryos is 6–9 nucleotides/sec at 15°C, which would result in an average synthetic time for heterogeneous nuclear RNA (HnRNA) molecules of about 2 × 10⁶ daltons of 12–18 min. The half-life of HnRNA in this species of sea urchins is 15–20 min, implying a transient existence for large HnRNA molecules.     

Intranuclear distribution of mouse liver nuclear DNA polymerase

Adult mouse liver nuclei and their subfractions corresponding to heterochromatin, nucleoli, membranes, and euchromatin were studied for DNA-polymerase activity. The intact nuclei and the two heavy nuclear fractions contained rather low activity while the two light fractions (membranes and euchromatin) had no activity at all. In the two heavy fractions, the activity was stimulated by β-mercaptoethanol and depressed by p-hydroxymercuribenzoate and by omission of one or more nucleotides. A nuclease activity, detected in the intact nuclei, may also be present in the nuclear subfractions. DNA-polymerase activity in the heavy fractions of mouse liver nuclei is discussed in relation to other published results.     

Effect of 5-bromodeoxyuridine on heterogeneous nuclear RNA in rat hepatoma cells.

Heterogeneous nuclear RNA HnRNA) was isolated from untreated and 5-bromodeoxyuridine (BrdUrd) treated hepatoma tissue culture (HTC) cells. analysis of this RNA by either electrophoresis on polyacrylamide-agarose gels or centrifugation in sucrose gradients demonstrated that BrdUrd caused a shift in the labeled HnRNA population toward a smaller size distribution. This effect was produced by concentrations of BrdUrd which specifically lower the level of the differentiated enzyme tyrosine aminotransferase, but do not greatly affect cell growth. Differential binding to oligo(dT) cellulose was used to fractionate HnRNA further into classes containing poly(A) (alpha), oligo(A) (beta) or neither category of A-rich sequences (gamma). BrdUrd did not alter the relative rates of uridine incorporation into the three classes. The shift in the labeled HnRNA population due to BrdUrd was observed in all three subclasses of HnRNA.     

On the size relationship between nuclear and cytoplasmic RNA in sea urchin embryos

The approximate sizes of heterogeneous nuclear (HnRNA) and cytoplasmic RNA of sea urchin embryos were determined by DMSO density gradient centrifugation and acrylamide-formamide gel electrophoresis. The data suggest that the sizes of these molecules are smaller than those estimated under nondenaturing conditions. The size of most of the nuclear RNA ranges from 0.5 to 3 × 10⁶ daltons, while that of the cytoplasmic RNA ranges from 0.1 to 2 × 10⁶ daltons. Both nuclear and cytoplasmic RNA of sea urchin embryos may have a minor fraction (5–10%) of very large species with molecular weights up to 4 to 5 × 10⁶ daltons.The idea that the size of HnRNA may be larger in organisms higher on the evolutionary scale is discussed.     

Interactions of mercury and copper with constitutive heterochromatin and euchromatin in vivo and in vitro.

Mouse liver nuclei were fractionated into (condensed) heterochromatin and (noncondensed) euchromatin by differential centrifugation of sonicated nuclei. The fractions were subsequently characterized as unique nuclear species by thermal denaturation derivative profile analysis, which revealed the heterochromatin fraction enriched in satellite DNA and by endogenous metal content, which displayed partitioning of mercury in euchromatin over heterochromatin by a 10:1 ratio, with a comparatively uniform distribution of copper in both fractions. Fractionation of nuclei following in vivo challenge with copper showed enrichment of copper in heterochromatin, relative to euchromatin, while in vivo exposure to mercury resulted in a 20-fold accumulation of mercury in euchromatin, relative to heterochromatin. Using gel filtration and equilibrium dialysis to measure in vitro binding under relatively physiologic conditions of pH (6.0-7.0) and ionic strength (standard saline citrate or saline), the condensed and noncondensed chromatin fractions exhibited binding specificities toward mercury and copper similar to that observed in the in vivo metal challenge experiments. The level of mercury which binds to euchromatin in vitro, when measured either in physiologic [standard saline citrate (SSC)] or in dilute (1:100 SSC) salt solutions, was comparable (approximately 3 mug of Hg/mg of DNA) to that of in vivo euchromatin-bound mercury after 1 month of challenge with dietary metal. In contrast, copper showed little or no preference for the nuclear fractions in dilute salt solutions and displayed patterns which mimic in vivo binding only at higher ionic strengths (saline). Removal of proteins from the chromatin fractions resulted in a loss of binding specificity toward both metals. Therefore, the binding selectivity of condensed and noncondensed chromatin toward both mercury and copper appears to arise from protein or from protein-DNA associations. The state of chromatin condensation is especially critical in the case of copper.