Effect of hypophysectomy on liver nuclear ribonucleic acid synthesis in aging rats.

Changes in RNA synthesis in liver nuclei were observed at different ages and after hypophysectomy and hormone replacement in female Sprague-Dawley rats. As determined by the incorporation of [3H]UMP into an acid-insoluble product, RNA synthesis decreased by about 75% in intact rats from 6 months to 24 months of age. This decline with age was not observed in liver nuclei from 24-month-old rats that had been hypophysectomized at 12 months and maintained on a minimal hormone-replacement therapy. Thyroid hormones and somatotropin (growth hormone) had an additive effect on RNA synthesis in liver nuclei from these hypophysectomized rats. The same hormones had no significant effect on intact, age-matched rats. With advancing age, nuclei of intact rats had an increase in the pool of free RNA polymerase and an apparent decrease in the enzyme activity bound to nuclear chromatin. There was no change in total enzyme with age. In hypophysectomized, hormone-treated rats, free RNA polymerase activity decreased and chromatin-bound activity increased. There was no difference in total nuclear RNA polymerase activity between operated or intact rats. However, the ratio of the bound to the free activity was different. These results suggest that the ability of RNA polymerase to bind to chromatin may be involved in the age-related decrease in liver nuclear RNA synthesis of intact rats.     

Relationship between RNA polymerase I activity and ornithine decarboxylase in rat liver tissues.

In order to examine the relationship between RNA polymerase I and ornithine decarboxylase (ODC), three lines of experiments were performed, with the following results. The glucocorticoid-induced increase of RNA polymerase I in rat liver nuclei was not abolished by administration of inhibitors of ODC synthesis and activity, namely 1,3-diaminopropane and 2-difluoromethylornithine respectively. Anti-ODC antibody did not cross-react with RNA polymerase I solubilized from rat liver nucleoli, indicating the absence of a common protein sequence in these enzymes. The ODC preparation which was treated with transglutaminase in the presence of putrescine could not stimulate the activity of RNA polymerase I in nuclei of liver and prostate. All these results suggest that the increases in ODC protein or activity are not a prerequisite to the increase in RNA polymerase I after hormonal or physiological stimuli, but rather that the increases in both enzymes are separate responses to the primary stimuli.     

Intranucleolar localization of the RNA polymerase A activity in isolated nuclei of regenerating rat liver

Ultrastructural autoradiography was used to visualize RNA polymerase A activity in parenchymal cell nuclei isolated from normal and regenerating (3, 24, 36 and 48 h after partial hepatectomy) rat liver. High resolution autoradiography showed that the activity of RNA polymerase A which was not inhibited by α-amanitin in a concentration of 0.8 μg/ml, was restricted to the nucleolus. Both the distribution pattern and number of grains were similar in control liver and regenerating liver 3 h after hepatectomy. Twentyfour, 36, and 48 h after hepatectomy nucleoli were enlarged and labeling was distinctly increased. In all experimental groups the activity of RNA polymerase A was located within fibrillar components of the nucleolus. The association of enzyme activity with this component was especially distinct in later stages (36 and 48 h) of liver regeneration. These results suggest that the fibrillar component of the nucleolus contains the active template for ribosomal RNA (rRNA) synthesis in rat liver cell nuclei.     

Glucocorticoids modify the rate of ribosomal RNA synthesis in rat thymus cells by regulating the polymerase elongation rate

The mechanism by which glucocorticoids inhibit RNA polymerase A activity, and hence rRNA synthesis, in rat thymus cells has been investigated. Studies of the intranuclear distribution of RNA polymerase A between chromatin bound ("engaged") and unbound ("free") forms revealed that the steroid-mediated inhibition of the activity of the "engaged" form of the enzyme was not accompanied by significant changes in "free" pool activity. In the presence of rifamycin AF/0-13, an inhibitor of re-initiation of RNA polymerase A, the rate of [3H]UMP incorporation into RNA was slower in nuclei from steroid-treated cells than in those from control cells, although in both conditions similar plateau levels of UMP incorporation were attained. Direct measurements of the numbers of transcribing RNA polymerase A molecules and of elongation rates showed that the inhibition of pre-rRNA synthesis was the result of a decrease in enzyme elongation rate; no significant change was observed in the number of transcribing enzymes. The steroid-induced inhibition of pre-rRNA synthesis was selectively abolished by mild proteolysis of nuclei, suggesting the involvement of a labile, regulatory glucocorticoid-induced protein. It is concluded that glucocorticoid treatment of rat thymus cells decreases 45S rRNA synthesis primarily by decreasing the polyribonucleotide elongation rate of RNA polymerase A, possibly by modification of the enzyme.     

Reduction in RNA synthesis following red cell-mediated microinjection of antibodies to RNA polymerase I

Antibody molecules directed against RNA polymerase I, the enzyme responsible for rRNA synthesis, were introduced into rat hepatoma cells by red cell-mediated microinjection. Access of the antibodies to the nucleolus, the site of rRNA synthesis, was facilitated by microinjecting mitotic cells. Using indirect immunofluorescence, anti-RNA polymerase I immunoglobulins, but not control immunoglobulins, were found localized in the nucleoli of microinjected cells. To assess whether intracellular antibodies could alter RNA synthesis, cultures were labeled with [3H] uridine at various times after microinjection. Reduction in RNA synthesis, relative to cells microinjected with non-immune immunoglobulins, was observed within three hours. These results demonstrate that antibodies introduced into the cytoplasm of mitotic cells via red cell-mediated microinjection have free access to nuclear components and that they remain functional within the nuclei of living cells.     

Modification of rat liver RNA polymerase I after in vivo stimulation by hydrocortisone or methylisobutylxanthine

Following in vivo administration of hydrocortisone or methylisobutylxanthine to rats, higher levels (1.5- to 2.3-fold) of RNA polymerase I activity are present in liver nuclei and nucleoli of the treated animals as compared to control animals. The elevated specific activity is retained after purification of the enzyme under conditions where the enzyme is dependent on exogenous template for activity. The elevated polymerase activity in nuclei, nucleoli, and soluble enzyme can be destroyed by mild trypsin treatment which results in a rapid decay of the specific activity to the control level. Under these conditions, the control polymerase I activity is stable. The results indicate that in vivo stimulation by hydrocortisone or methylisobutylxanthine results in a conversion of the enzyme to a form that is catalytically more active but has an increased sensitivity to proteolysis.     

Nucleolar and nucleoplasmic RNA polymerase activity in different regions of rat brain during postnatal development.

RNA polymerase activities of whole nuclei, of isolated and purified nucleoli and of the nucleoplasmic fractions obtained from cerebral hemispheres, cerebellum and brain stem of rat at different days of postnatal development have been determined. In the whole nuclei the fraction of RNA polymerase which is sensitive to alpha-amanitin, is strongly affected by salt concentration; at low ionic strength most of the activity is resistant to the drug while at high ionic strength the enzymatic activity shows a greater sensitivity to the drug. In isolated nucleoli RNA synthesis is not inhibited at all by alpha-amanitin. The biosynthesis of RNA, at low ionic strength, is inhibited by low doses of actinomycin D, whereas at high ionic strength it is remarkably inhibited only by higher doses of the drug. The sensitivity of the reaction to alpha-amanitin and actinomycin D provide good evidence that UTP or GTP incorporation into RNA in purified nuclei and nucleoli, is dependent on RNA polymerases acting on DNA template and is not dependent on homopolymer formation. These results show that in the whole brain nuclei at low ionic strength there is a preferential synthesis of rRNA, whereas at high ionic strength the synthesis of heterogenous RNA predominates. In isolated nucleoli the synthesis of RNA is restricted to rRNA.     

Control of rRNA transcription in liver of mice exposed to nutritional changes: initiation frequency may be a regulatory mechanism

Shortly after feeding protein-depleted mice on a meal containing proteins, the RNA polymerase I activity in isolated liver nuclei shows a two fold to threefold activation over the basal value in nuclei of either normal or protein-depleted mice. This activation can be accounted for by the increase in the number of growing rRNA chains. Moreover, the template-bound RNA polymerase I fraction in nuclei from re-fed mice is about three times that from protein-depleted animals. An excess of template- unbound enzyme was found in liver nuclei from animals under either nutritional condition. Shortly after inhibition of protein synthesis by pactamycin administration to re-fed mice, the number of transcribing RNA polymerase I molecules in liver nuclei decreases to the basal level found in nuclei from protein-depleted mice, while in the latter, protein synthesis inhibition has no effect. These results support the suggestion that short-lived proteins may enhance the initiation frequency by RNA polymerase I after re-feeding.     

DNA-dependent RNA polymerase activity of isolated zooflagellates (Crithidia oncopelti) nucleoli

A fraction of nucleoli is isolated from zooflagellates (Crithidia oncopelti) nuclei, its DNA-dependent RNA polymerase activity is studied at different temperature, ionic strength and Mg2+, Mn2+ and antibiotic concentrations. The effect of some factors and alpha-amantine on RNA polymerase activity of exonucleolar chromatin was studied as a control. A comparison of heat denaturation of nucleoli and chromatin RNA polymerase activities within the temperature range 30--55 degrees C has revealed a higher thermosensitivity of nucleoli RNA polymerase. Substitution of Mg2+ with equivalent amount of Mn2+ results in a considerable decrease of rRNA synthesis in nucleoli. Nucleoli RNA polymerase activity in the presence of Mg2+ is sensitive to the elevation of ionic strength from 0.12 to 1.30 u; chromatin RNA polymerase activity in the presence of Mn2+ is maximal at high ionic strength (1.30 mu). alpha-Amantine and cycloheximide at high concentrations (10 and 200 mkg/ml) practically do not affect RNA polymerase activity of nucleoli. Nucleoli RNA polymerase of zooflagellates (Crithidia oncopelti) is similar to the A-form of the enzyme in higher eukaryotes.     

Transcription of isolated nuclei and nucleoli by exogenous RNA polymerase A and B.

Both forms A and B RNA polymerases solubilised from rat liver nuclei transcribed templates within these organelles when added exogenously to freshly prepared nuclei. The enzymes initiated more efficiently in the presence of KCL than ammonium sulphate and required manganese rather than magnesium as the divalent cation. Form A enzyme initiated most successfully at 375 mM KC6, activity was proportional to the amount of template added and continued linearly for at least 30 min. Form B enzyme initiated with two ionic strength optima, 125 mM and 500 mM KCl. Activity in the latter case was critically dependent on the enzyme: nuclei ratio. In both instances incorporation of nucleotide precurors was linear for less than 20 min. Form A enzyme synthesised products with a size distribution mainly larger than 18 S; form B enzyme synthesised products of mainly less than 5 S at 125 mM KCl and about 10 S at 500 mM KCl. Subfractionation of nuclei indicated that exogenous RNA polymerase A activity and form B at 125 mM KCl were occurring in nucleoli; form B activity at 500 mM KCl was nucleoplasmic. Measurements of U : G ratios in the RNA products suggested that exogenous form A was synthesising species with similar base ratios to the ribosomal RNA precurosrs. Both enzymes formed rifamycin AF/0-13 resistant complexes with nucleolar templates. Size analyses of products showed that whereas form B enzyme synthesised very small RNA species, RNA polymerase A produced a range of species of similar sizes to the ribosomal RNA precurosors.     

Lipopolysaccharide-mediated induction of RNA polymerase I activity and amount in murine B lymphocytes

The effect of lipopolysaccharide on RNA polymerase I activity in primary cultures of murine B lymphocytes has been examined. In cells treated with mitogen for 48 h, the activity of RNA polymerase I was approximately 15 times greater than in control cells. In situ localization of RNA polymerase I using indirect immunofluorescence indicated that there was at least a 10-fold increase in the amount of this enzyme associated with nucleoli of 48 h mitogen-treated cells relative to control cells. Immunoblotting experiments demonstrated a similar increase in the concentration of the 190-kDa subunit bound to DNA; the concentrations of the other polymerase I-associated polypeptides did not correlate with rRNA synthesis. Assuming 1 mol of the 190-kDa polypeptide/mol of polymerase I, it was estimated that 2,300 and 30,000 molecules of enzyme were associated with rDNA in the unstimulated and stimulated B cell, respectively. Thus, an increased cellular concentration of the 190-kDa subunit of RNA polymerase I and its association with ribosomal DNA may be a crucial step in rRNA synthesis.     

Inhibition of RNA synthesis in animal cells by sodium selenite

The effect of selenium-containing compounds on RNA synthesis in rat liver cells was studied in vivo. All the selenium derivatives under study inhibited the rRNA synthesis in liver cells. The most potent inhibiting effect was exerted by sodium selenite. It was shown that in a cell-free system of RNA biosynthesis sodium selenite selectively inhibited the activity of RNA-polymerase I in isolated nuclei and purified enzyme preparations of normal and tumour cells. A feasible mechanism of inhibition of the RNA-polymerase I activity by selenium and a hypothesis on the anticarcinogenic effect of selenium are postulated.     

Uptake and incorporation of 3H-orotic acid in isolated perfused rat liver

3H-orotic acid incorporation into RNA and the level of RNA polymerase activity in isolated rat liver perfused for 5 hrs were investigated. In spite of a dramatic decrease in 3H-orotic acid uptake by liver cells during perfusion, a constant rate of RNA synthesis was observed. Moreover, RNA polymerase I and II activities were not affected by a 5-hr perfusion. It is suggested that isolated perfused rat liver can be used to study direct effects of hormones and drugs on RNA synthesis.