In vitro synthesis and stability of RNA in isolated nuclei from bovine lymphocytes

Nuclei from Concanavalin A-stimulated lymphocytes (30 hr after Con A addition) incorporate up to 5 times more (3-H)UTP into RNA than nuclei from resting lymphocytes. The incorporation kinetics is linear for almost 60 min. 14–20% of the $\text{in vitro}$ labeled RNA is polyadenylated. Poly(A) (?)RNA from both types of nuclei sediments from 4–5S up to more than 30S on sucrose gradients. Nuclei from stimulated cells synthesize about double the amount of RNA larger than 18S than nuclei from resting cells. The same holds for poly(A) (+)RNA. Poly(A) (?) RNA labeled during 10 min in both types of nuclei is stable during a 30 min chase. Under the same conditions poly(A) (+)RNA in nuclei from resting cells is degraded to about 50% during the chase whereas it is stable in nuclei from stimulated cells.     

RNA synthesis in isolated HeLa cell nuclei

RNA synthesis has been studied in isolated nuclei of HeLa cells. The incubation medium has been optimized for RNA synthesis and the requirements for the presence of specific components previously used by other investigators has been examined. Nuclei isolated by centrifugation through 2 M sucrose synthesize RNA linearly for at least 1 h only at low temperature (25°C). Low molecular weight RNA is found in the supernatant fraction after incubation; this RNA accounts for about 10% of the RNA synthesized. The RNA which remains within nuclei is of high molecular weight and processing of this RNA into molecules of the size of cytoplasmic mRNA does not seem to occur in isolated nuclei. We have studied the effect of an inhibitor of protein-nucleic acid interaction — aurintricarboxylic acid — on RNA synthesis by isolated nuclei. At concentrations below 0.1 mM, this drug does not inhibit RNA synthesis effectively, whereas at concentrations above 0.1 mM it inhibits RNA synthesis by about 80%. In view of the proposed mechanism of action of aurintricarboxylic acid, we suggest that completion of nucleotide chains initiated before nuclei isolation accounts for 20% of the RNA synthesized in our system by isolated nuclei, whereas nucleotide chains initiated during the in vitro incubation account for 80% of the RNA synthesized.     

Separation of mercury substituted RNA synthesized in isolated rat liver nuclei

The population of RNA molecules synthesized in isolated rat liver nucleiin vitro in the presence of [³H]CTP and Hg-UTP was succesfully fractionated into at least two subfractions containing various proportions of mercury label. Fractionation was achieved either by step-wise chromatography of Hg-RNA on thiopropyl-Sepharose columns or by density gradient centrifugation in metrizamide. The fraction of RNA heavily labeled with Hg-UTP was composed mainly of 4-18S RNA and contained virtually all radioactivity derived from [-³²P]ATP or [-³²P]GTP. The slightly mercurated RNA fraction consisted mainly of longer RNA molecules (12->28S) and was not labeled with [-³²P]ATP or [-³²P]GTP. Labeling with -³²P nucleoside triphosphates was sensitive both to rifamycin AF/013 and heparin whereas labeling with [³H]CTP was fully resistant to the inhibitors and showed sensitivity to low doses of -amanitin. We assume that the observed subpopulation of heavily mercurated RNAs consists of RNA molecules initiated in vitro.     

RNA synthesis in isolated HeLa cell nuclei.

RNA synthesis has been studied in isolated nuclei of HeLa cells. The incubation medium has been optimized for RNA synthesis and the requirements for the presence of specific components previously used by other investigators has been examined. Nuclei isolated by centrifugation through 2 M sucrose synthesize RNA linearly for at least 1 h only at low temperature (25 degrees C). Low molecular weight RNA is found in the supernatant fraction after incubation; this RNA accounts for about 10% of the RNA synthesized. The RNA which remains within nuclei is of high molecular weight and processing of this RNA into molecules of the size of cytoplasmic mRNA does not seem to occur in isolated nuclei. We have studied the effect of an inhibitor of protein-nucleic acid interaction - aurintricarboxylic acid - on RNA synthesis by isolated nuclei. At concentrations below 0.1 mM, this drug does not inhibit RNA synthesis effectively, whereas at concentrations above 0.1 mM it inhibits RNA synthesis by about 80%. In view of the proposed mechanism of action of aurintricarboxylic acid, we suggest that completion of nucleotide chains initiated before nuclei isolation accounts for 20% of the RNA synthesized in our system by isolated nuclei, whereas nucleotide chains initiated during the in vitro incubation account for 80% of the RNA synthesized.     

In vitro RNA synthesis and expression of vitellogenin gene in isolated chicken liver nuclei.

Optimal conditions for prolonged in vitro synthesis of RNA in isolated chicken liver nuclei have been described. It is shown by incorporation of gamma32P-GTP into RNA, analysis of the product on sucrose density gradient, and digestion with alkaline phosphatase and ribonuclease A that there is reinitiation of RNA synthesis. Polynucleotide kinase activity has been ruled out as explanation for the incorporation of gamma32P-GTP. alpha-Amanitin inhibits RNA synthesis by about 50%. Nuclei prepared from estradiol-treated chicks have twice the RNA synthesis activity as the controls. RNA is synthesized in the presence of Hg-UTP and the mercurated product separated by affinity chromatography on sulfhydryl-Sepharose column under stringent conditions. Vitellogenin mRNA sequences are measured by hybridization with DNA complementary to vitellogenin mRNA. Estradiol treatment leads to a 10-fold increase in vitellogenin mRNA sequences.     

Initiation of RNA synthesis in isolated rat liver nuclei

Isolated rat liver nuclei were incubated under conditions when RNA polymerase I or RNA polymerase II was preferentially active. It was shown that [gamma-32P] ATP and [gamma-32P] GTP were incorporated into phenol extractable, TCA-precipitable material. RNase, actinomycin D, heparin and, in the case of RNA-polymerase II, alpha-amanitine inhibited precursor incorporation. These data are interpreted as evidence in favour of the initiation of RNA synthesis in isolated rat liver nuclei.     

Analysis of RNA synthesized in isolated nuclei of Ehrlich ascites tumor cells

The molecular size and poly-A content of RNA synthesized in isolated nuclei of Ehrlich ascites tumor cells were measured. KCl was found to be essential for synthesis of high molecular weight RNA: when 0.4 M KCl was added to the reaction mixture, the average molecular size of the RNA formed was 14S; without KCl the average molecular size was 5S. A significant amount of poly-A sequences was found in RNA synthesized in the presence of alpha-amanitin, suggesting that RNA polymerase I and/or III may synthesized some RNA containing poly-A in isolated nuclei.     

In vivo and in vitro synthesis of adenovirus type 2 early proteins.

The synthesis of adenovirus type 2 (Ad2)-induced early polypeptides was examined in vivo and in vitro by a combination of sodium dodecyl sulfate-polyacrylamide gel electrophoresis alone and specific immunoprecipitation followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Analysis of total [35S]methionine-labeled polypeptides synthesized in vivo at 3 h postinfection allowed us to detect in infected cells at lease 13 distinct polypeptides that are either absent or less conspicuous in extracts from mock-infected cells. These Ad2-induced early polypeptides have molecular weights ranging from 72 x 10(3) to 10.5 x 10(3) and have accordingly been designated as E72K to E10.5K. Nine of the in vivo synthesized early polypeptides can be precipitated specifically from infected cell extracts by antisera with specificity against early adenovirus proteins. In vitro translation of mRNA extracted from mock-infected cells and from Ad2-infected cells was carried out in preincubated Ehrlich ascites cell extracts. All the early Ad2-induced polypeptides identified in the extracts from infected cells labeled in vivo were also detected among the polypeptides immunoprecipitated specifically from the in vitro reaction mixtures programmed by RNA extracted at 4 h postinfection from Ad2-infected cells.     

RNA synthesis in isolated polytene nuclei from Chironomus tentans

An RNA synthesizing system with isolated polytene nuclei from Chironomus tentans is described. This system allows one to monitor the effect of salt concentration on chromosome structure and to assign in vitro RNA synthesis to structural modifications of the chromosome (i.e. nucleoli, Balbiani rings and puffs).-At a salt concentration of 0.15 M monovalent cations (standard salt medium=SSM) chromosomal structure appears to be best preserved during in vitro incubation. At low and high ionic strength the bands decondense and the microscopically visible chromosomal structure is lost completely. These three states of condensation and decondensation are distinguished with respect to RNA synthesis: (1) in low salt overall RNA synthesis is depressed, (2) in SSM ribosomal RNA synthesis predominates and continues for 30 min, (3) in high salt RNA synthesis is stimulated 3–4 fold again. This stimulation is due solely to chromosomal, non-ribosomal RNA synthesis, which proceeds in high salt for more than 10 h, though new initiation of RNA chains is prevented. Molecular weight determinations of the RNA synthesized demonstrate a time dependent increase in size of the newly synthesized molecules under these conditions. — Autoradiographs of nuclei incubated in SSM reveal prominent label in nucleoli, significant label in Balbiani rings and rather reduced activity at other sites. Addition of various exogenous RNA polymerases does not markedly alter this pattern. Autoradiographs of nuclei incubated in high salt exhibit extensive RNA synthesis spread over the chromosomes. Preparations of autoradiographs from isolated chromosomes show that the high salt induced label is localized in single bands. Though the majority of bands is still unlabelled, the actual number of bands exhibiting incorporation in high salt is higher than in any individual functional state in vivo. These results are discussed in terms of activated and preactivated genes.