Synthesis of low molecular weight RNA components in cells with a temperature-sensitive polymerase II

AF 8 cells are a mutant cell line of baby hamster kidney cells with a temperature-sensitive polymerase II activity. When these cells grow at the non-permissive temperature (40 degrees C) the syntheseis of low molecular weight RNA components D, C and A is preferentially inhibited, whereas the synthesis of rRNA, tRNA, 5 S RNA and component L is affected only a little or not at all. These results indicate that polymerase II catalyzes the synthesis of components D, C and A.     

Isolation and characterization of an alpha-amanitin-resistant rat myoblast mutant cell line possessing alpha-amanitin-resistant RNA polymerase II.

Cultures of the rat skeletal muscle myoblast cell line, L6, were treated with the mutagen ethylmethanesulfonate and grown in the presence of alpha-amanitin, an inhibitor of RNA polymerase II in vitro. One clonal cell line, Ama102, resistant tc the cytotoxic action of 2 mu-g/ml of alpha-amanitin was isolated and extensively characterized. Ama102 cells were about 30-fold more resistant to alpha-amanitin than their Ama+ parent cells based on a comparison of the concentration of alpha-amanitin required to reduce their plating efficiencies to similar extents. The RNA polymerase activities from Ama+ and Ama102 cells were solubilized and separated by DEAE-Sephadex chromatography. Whereas all of the Ama+ RNA polymerase II activity was inhibited by 0.1 mu-g/ml of alpha-amanitin, about 30% of the activity in the Ama102 RNA polymerase II peak was resistant to this concentration of alpha-amanitin and was inhibited only by much higher concentrations (25 mu-g/ml) of alpha-amanitin. This alpha-amanitin-resistant activity in Ama102 cells was identified as a bona fide RNA polymerase II by its chromatographic behavior on DEAE-Sephadex, salt optimum, preference for denatured DNA as template, insensitivity to inhibition by potassium phosphate, thermal inactivation kinetics, and inactivation by anti-RNA polymerase II antiserum. Both RNA polymerase IIa and IIb from Ama102 cells exhibited the partial alpha-amanitin resistance, as did this activity when purified further on phosphocellusose. Unlike the parental Ama+ cells, Ama102 cells neither fused at confluence nor showed an increase in the specific activity of creatine kinase. The altered sensitivity of the Ama102 RNA polymerase II to alpha-amanitin appears to account for the drug-resistant phenotype of these cells.     

Occurrence and properties of low molecular weight RNA components from cells at different taxonomic levels.

1. The occurrence and gel electrophoretic properties of low molecular weight RNA components (LMW RNA) have been studied in species at different taxonomic levels. The LMW RNA components apart from tRNA, 5S RNA and 5.5S RNA are called LMW*RNA. 2. The major components of LMW*RNA in mammalian cells are L, A, C and D, accounting for 0.1-0.7% of cellular RNA. The gel electrophoretic migration of components L, C, and D is similar in different mammals but the migration of component A shows differences. 3. Amphibia, reptiles and birds contain L, A, C and D in about the same amounts as mammals but slight differences in migration are seen for L, C and D. Component A is absent from the nucleated red blood cells of the chicken and the frog. 4. Sea urchins contain three LMW*RNA components with migrations different from L, A, C and D. These components account for about 0.1% of the cellular RNA. 5. Insects contain only one LMW*RNA component, migrating as component L. 6. Tetrahymena, Physarum and Mycoplasmas have one component which may be a counterpart to component L in higher cells. Yeast shows no LMW*RNA components. 7. In the multicellular species the occurrence and gel electrophoretic migration of LMW*RNA components are not related to tumorigenicity, developmental stage or origin of tissue.     

Formation of low molecular weight RNA species in HeLa cells

It has been previously shown that newly synthesized nuclear low molecular weight RNA species C and D are first detected in the cytoplasm for a few minutes before they are finally found in the nucleus. The following are some of the observations made in the present study, regarding the formation of C and D RNA: (1) The 5′ end cap ribose methylation of the C RNA precursor is complete in its cytoplasmic stage; the internal ribose methylation of the precursor seems to be completed about the time of its apparent transition from cytoplasm to nucleus. (2) The few nucleotides lost from the D RNA precursor during maturation seem to be excised sometime near its apparent cytoplasmic → nuclear transition. Newly synthesized C RNA also appears to lose some of its non-conserved nucleotides about the time of that transition, while the other extra nucleotides are lost later, in the nucleus. (3) The maturation of C and D RNA is inhibited early during suppression of protein synthesis by cycloheximide, while their synthesis is not. (4) The cytoplasmic precursors of C and D RNA are not associated with ribonucleoprotein particles as large as those reported for mature C and D RNA, although they do not appear to be free in the cytoplasm. (5) When the cellular UTP pool is depleted by exposure of the cells to amino sugars, and the synthesis of C, D, and other RNA species decreases, the level of[³H]uridine labeling of C and D RNA increases, while that of 4 S and 5 S RNA does not. These data are compatible with the existence of more than one nuclear UTP pool.     

Zinc deficiency and the Euglena gracilis chromatin: formation of an alpha-amanitin-resistant RNA polymerase II

Both the single DNA-dependent RNA polymerase found in zinc-deficient (-Zn) Euglena gracilis and the RNA polymerase III from zinc-sufficient (+Zn) cells have been isolated by methods previously used to purify polymerases I and II [Falchuk, K. H., Mazus, B., Ulpino, L., & Vallee, B. L. (1976) Biochemistry 15, 4468; Falchuk, K. H., Mazus, B., Ulpino, L., & Vallee, B. L. (1977) Biochem. Biophys. Res. Commun. 74, 1206]. Like class II polymerases, the enzyme from -Zn organisms elutes from DNA-cellulose and phosphocellulose with 0.6 M NaCl and 0.35 M NH4Cl, respectively. It is inhibited by 8-hydroxyquinoline, 8-hydroxyquinoline-5-sulfonic acid, alpha,alpha'-bipyridyl, dipicolinic acid, and 1,10-phenanthroline (OP); 4,7-phenanthroline, the nonchelating analogue, does not inhibit. The pKI(OP) of this enzyme is identical with that of polymerase II but distinct from those of polymerases I and III. Elemental analysis confirms that zinc is the functional metal while copper, manganese, iron, and magnesium are absent. However, the -Zn enzyme is at least 4 orders of magnitude more resistant to alpha-amanitin (alpha-A) than the class II polymerase. Further, its response to alpha-A is unlike that of either polymerase I or polymerase III. Thus, -Zn cells contain a single, alpha-amanitin-resistant (alpha-Ar) RNA polymerase, whose behavior otherwise resembles that of the alpha-amanitin-sensitive polymerase II.     

Intracellular distribution of low molecular weight RNA species in HeLa cells

Intracellular distributions of the low molecular weight RNA species of HeLa cells were determined by a nonaqueous method of cell fractionation, in which lyophilized cells were homogenized and centrifuged in anhydrous glycerol. The nonaqueous method was used to avoid artifactual extraction of weakly bound nuclear RNA during cell fractionation. We found that the mature small RNA species K, A, C, and D were almost entirely (greater than 95%) nuclear, and that mature 4S tRNA was partially (5-10%) nuclear. Our results gave higher nuclear content of the mature species K, A, C, and 4S than was shown previously with conventional aqueous cell fractionation. The nonaqueous method also gave higher nuclear proportions of some short-lived precursors to mature small RNAs. We found that approximately one-half of recently synthesized pre-4S RNA and more than one-half of recently synthesized 5S RNA were nuclear, whereas these species had been thought to be cytoplasmic from previous work. The species C' and D', precursors to the stable nuclear species C and D respectively, were found to be partially nuclear, also in contrast to earlier work. The stable cytoplasmic species L (oncornavirus 7S RNA) was found to be mostly nuclear shortly after synthesis.     

Changes in RNA polymerase II in a cell cycle-specific temperature-sensitive mutant of hamster cells

tsAF8 cells are a temperature-sensitive mutant of BHK cells that arrest at the nonpermissive temperature in the G₁ phase of the cell cycle. The activity of solubilized RNA polymerase II and its ability to bind [³H]-γ-amanitin decrease in tsAF8 cells at 40.6°, with a half-life of ～ 10 hr. No appreciable changes occur in these two parameters in tsAF8 cells at 34° or in BHK cells at either 34° or 40.6°. Protein synthesis is not appreciably affected for at least 24 hr after tsAF8 cells are shifted to 40.6°. These results indicate that in tsAF8 cells at the nonpermissive temperature, there is a defect in either the synthesis, the assembly, or the stability of RNA polymerase II, and that the loss of RNA polymerase II molecules is not due to widespread cellular damage.     

Purification using polyethylenimine precipitation and low molecular weight subunit analyses of calf thymus and wheat germ DNA-dependent RNA polymerase II

DNA-dependent RNA polymerase II from calf thymus has been successfully purified using polythylenimine precipitation. Thus, 5-6 mg of nearly homogeneous homogeneous trna polymerase II (greater than 96% pure) can be prepared from 1 kg of calf thymus with three chromatography steps following extraction and precipitation of the enzyme from the polyethylenimine pellet. This procedure eliminates the high salt extraction of chromatin previously used in purification of this enzyme and makes possible the large scale preparation of mammalian RNA polymerase II. Calf thymus polymerase II prepared by this method is greater than 90% form IIb and consists of ten different subunits having the following molecular weights: 180 000; 145 000; 36 000; 25 000; 20 000; 18 500; 16 000; 15 000; 12 000; 11 500. The homologous enzyme isolated from wheat germ is greater than 90% form IIa and contains subunits of the following molecular weights: 206 000; 145 000; 44 000-47 000; 24 500; 21 000; 19 000; 17 000; 14 000; 13 500. The wheat germ and calf thymus enzymes exhibit similar subunits structures, but the molecular weights of individual subunits are clearly different between the enzymes. Wheat germ RNA polymerase II is 50% inhibited by 0.271 microng/mL of alpha-amanitin, a level 30-fold higher than that found for calf thymus RNA polymerase II. These enzymes are further distinguished by the absence of antigenic cross reactivity.     

Effects of alpha-amanitin, cycloheximide, and thioacetamide on low molecular weight nuclear RNA.

Studies were made on the effects of alpha-amanitin, cycloheximide, and thioacetamide on synthesis and content of low molecular weight nuclear RNA. Cycloheximide, an inhibitor of protein synthesis and the synthesis of 45S pre-rRNA and 5S RNA, also inhibited synthesis of nuclear U1 and U3 RNAs. alpha-Amanitin, an inhibited the synthesis of U1 and U2 low molecular weight nuclear RNA. Thioacetamide, which induces nucleolar hypertrophy and increased nucleolar RNA polymerase activity, markedly increased synthesis of 5.8S RNA and U3 RNA. These results show that syntheses of individual low molecular weight nuclear (LMWN) RNAs are controlled by different regulatory mechanisms. In particular, there appears to be a specific relationship between U3 RNA and functional states of the nucleolus.