Agar gel chromatography of rat liver ribosomal ribonucleic acids.

Ribosomal RNA (28s rRNA) of rat liver is selectively retained in 2 or 4% squashed agar gels equilibrated at 24–25°C with a sodium dodecyl sulfate-Tris-EDTA buffer containing 0.7 m NaCl. The absorbed polynucleotide could be recovered by elution with 0.1 m NaCl in the same buffer. Agar-gel electrophoresis and nucleotide composition indicate that the separation is close to quantitative. Column beds of 100–200 ml were used in the range of 3–6 mg of RNA. The procedure is simple, rapid and reproducible and gives excellent separation of 28 and 18s rat liver rRNA.     

Quantitative analysis of rat liver nucleolar and nucleoplasmic ribosomal ribonucleic acids.

rRNA from detergent-purified nuclei was fractionated quantitatively, by two independent methods, into nucleolar and nucleoplasmic RNA fractions. The two RNA fractions were analysed by urea/agar-gel electrophoresis and the amount of pre-rRNA (precursor of rRNA) and rRNA components was determined. The rRNA constitutes 35% of total nuclear RNA, of which two-thirds are in nucleolar RNA and one-third in nucleoplasmic RNA. The identified pre-rRNA components (45 S, 41 S, 39 S, 36 S, 32 S and 21 S) are confined to the nucleolus and constitute about 70% of its rRNA. The remaining 30% are represented by 28 S and 18 S rRNA, in a molar ratio of 1.4. The bulk of rRNA in nucleoplasmic RNA is represented by 28 S and 18 S rRNA in a molar ratio close to 1.0. Part of the mature rRNA species in nucleoplasmic RNA originate from ribosomes attached to the outer nuclear membrane, which resist detergent treatment. The absolute amount of nuclear pre-rRNA and rRNA components was evaluated. The amount of 32 S and 21 S pre-rRNA (2.9 x 10(4) and 2.5 x 10(4) molecules per nucleus respectively) is 2-3-fold higher than that of 45 S, 41 S and 36 S pre-rRNA.     

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.     

Differential stability of 28s and 18s rat liver ribosomal ribonucleic acids

Rat liver ribosomal RNA (rRNA) free from nuclease contaminants was isolated by a modification of the phenol technique. The 28s and 18s rRNA species were separated by preparative agar-gel electrophoresis. The two rRNA species were heated at different temperatures under various conditions and the amount of undegraded rRNA was determined by analytical agar-gel electrophoresis. The 18s rRNA remained unaltered after heating for up to 10min. at 90 degrees in water, acetate buffer, pH5.0, or phosphate buffer, pH7.0. Under similar or milder conditions 28s rRNA was partially degraded, giving rise to a well-delimited 6s peak and a heterogeneous material located in the zone between 28s and 6s. The dependence of degradation of 28s rRNA on the temperature and the ionic strength of the medium was studied. The greatest extent of degradation of 28s rRNA was observed on heating at 90 degrees in water. It is suggested that the instability of rat liver 28s rRNA is due to two factors: the presence of hidden breaks in the polymer chain and a higher susceptibility of some phosphodiester bonds to thermal hydrolysis.     

Quantitative alterations in the nucleolar and nucleoplasmic ribosomal ribonucleic acids in regenerating rat liver

A quantitative analysis of the nuclear pre-rRNA (precursor to rRNA) and rRNA in normal and 12h-regenerating rat liver was carried out, and the absolute amounts of the identified pre-rRNA and rRNA species in the nucleolus and nucleoplasm were determined. Characteristic changes in the pre-rRNA and rRNA pool sizes in regenerating liver are found which reveal alternations in both pre-rRNA processing and nucleocytoplasmic transition of ribosomes.     

Synthesis and maturation of ribosomal ribonucleic acids in isolated HeLa cell nuclei. A tracer study on the topology of the 45S precursor of ribosomal ribonucleic acids

The synthesis and processing of RNA by isolated HeLa cell nuclei was studied at low ionic strength in the presence of alpha-amanitin. The RNA polymerase reaction, with endogenous template and enzyme, rapidly reaches a plateau dependent on the amount of nuclei. Evidence is presented that incorporation of [(3)H]UMP proceeds only in growing RNA chains, whereas initiation of new RNA chains is arrested. The product formed contains all the main components of the 45S pre-rRNA (precursor of rRNA) maturation pathway (45S, 32S and 20S pre-rRNA; 28S and 18S rRNA). Most of the labelled material is in the mature rRNA components and their immediate precursors, even at very short times of incubation (2min). Small, but definite, 5S and 4S RNA peaks are also observed. At shorter incubation times a substantial amount of [(3)H]UMP is incorporated into RNA molecules in the 24S and 10-16S zones. This RNA material is considered to represent the non-conserved segments of 45S pre-rRNA in the process of nucleolytic degradation. A model for the tracer study of the topology of 45S pre-rRNA, on arrest of rRNA initiation, is discussed. The experimental evidence obtained supports the following structure of 45S pre-rRNA: 5'-end-28S rRNA unit-18S rRNA unit-nonconserved segment-3'-end.     

The circular dichroism of ribosomal ribonucleic acids.

1. The c.d. (circular dichroism) of Drosophila melanogaster rRNA (42% G+C) and of G+C-rich fragments (78% G+C) obtained by partial hydrolysis of rabbit L-rRNA (the largest RNA species isolated from the large subribosomal particle) were measured and found to differ substantially. 2. To interpret these spectra a relation between c.d. of bihelical RNA and % G+C was derived, namely delta epsilonfG = AFG2+bfG+c, where deltaepsilonfG is the c.d. of RNA characterized by a mole fraction, fG, of guanine nucleotides and a, b and c are constants. 3. A frame of reference was established by studying the c.d. of a range of rRNA species, including S-rRNA (the RNA species isolated from the smaller subribosomal particle) and L-rRNA of Escherichia coli. 4. It was found for the rRNA species studied that 0.60+/-0.05 of residues appear to form bihelical secondary structure. 5. A higher helical content, 0.66+/-0.05, was found for the G+C-rich fragment of L-rRNA. The difference in the c.d. of rabbit L-rRNA and of D. melanogaster rRNA is attributable to the dependence of c.d. of the bihelical parts on %G+C. 6. The minimum in c.d. at 295 nm increases with increasing %G+C. The c.d. of rRNA was compared with that of the parent subparticle in this region of the spectrum, where high precision may be attained.     

Regulation of specific rat liver messenger ribonucleic acids by triiodothyronine

A plasmid cDNA library was constructed using poly(A+) RNA isolated from the livers of rats treated with 3,5,3'-triiodothyronine (T3) and fed a high carbohydrate diet. This library was screened by differential colony hybridization with [32P]cDNA probes made from hypothyroid and hyperthyroid rat liver poly(A+) RNA to obtain clones representing T3-inducible mRNAs. Using plasmid cDNAs to 4 different T3-inducible mRNAs, we have studied by hybridization assay the responses of these mRNAs to different thyroidal steady states and to a high carbohydrate diet. The fold of induction (hypothyroid to hyperthyroid) varied from about 4.0 (mRNA 5-8D) to 13.2 (mRNA 4-12B). The linearity of response with regard to nuclear receptor occupancy was estimated by assessing the relative mRNA levels in a euthyroid state. Three of the mRNAs demonstrated nonlinear responses with the largest portion of the induction occurring in the euthyroid to hyperthyroid transition. An induction by the high carbohydrate diet was clearly seen for only one mRNA (5-8D) suggesting that these two pathways of induction are independent. In a study of the response kinetics of each mRNA to a nuclear receptor saturating dose of T3 in hypothyroid animals, an increase was seen within 4 h (the earliest time point examined) for one of the mRNAs. The other 3 mRNAs did not increase significantly until 8 h after the T3 dose. Northern analysis showed a single mRNA corresponding to each of these 4 clones with sizes ranging from about 1375 to 7600 bases. Two mRNAs (5-9E and 4-12B) were shown by hybrid-selected translation to code for proteins of molecular mass of about 27 and 46 kDa, respectively. The availability of several different cDNA probes to T3 responsive liver mRNAs should facilitate future studies on the mechanism of action of this hormone.