Cytoskeleton involvement in the distribution of mRNP complexes and small cytoplasmic RNAs

These studies were designed to determine whether small cytoplasmic RNAs and two different mRNAs (actin mRNA and histone H4 mRNA) were uniformly distributed among various subcellular compartments. The cytoplasm of HeLa S3 cells was fractionated into four RNA-containing compartments. The RNAs bound to the cytoskeleton were separated from those in the soluble cytoplasmic phase and each RNA fraction was further separated into those bound and those not bound to polyribosomes. The four cytoplasmic RNA fractions were analysed to determine which RNA species were present in each. The 7 S RNAs were found in all cytoplasmic fractions, as were the 5 S and 5.8 S ribosomal RNAs, while transfer RNA was found largely in the soluble fraction devoid of polysomes. On the other hand a group of prominent small cytoplasmic RNAs (scRNAs of 105-348 nucleotides) was isolated from the fraction devoid of polysomes but bound to the cytoskeleton. Actin mRNA was found only in polyribosomes bound to the cytoskeleton. This mRNA was released into the soluble phase by cytochalasin B treatment, suggesting a dependence upon actin filament integrity for cytoskeletal binding. A significant portion of several scRNAs was also released from the cytoskeleton by cytochalasin B treatment. Analysis of the spatial distribution of histone H4 mRNAs, however, revealed a more widely dispersed message. Although most (60%) of the H4 mRNA was associated with polyribosomes in the soluble phase, a significant amount was also recovered in both of the cytoskeleton bound fractions either associated or free of polyribosome interaction. Treatment with cytochalasin B suggested that only cytoskeleton bound, untranslated H4 mRNA was dependent upon the integrity of actin filaments for cytoskeletal binding.     

Translation and identification of the viral mRNA species isolated from subcellular fractions of vesicular stomatitis virus-infected cells.

The cytoplasm of vesicular stomatitis virus (VSV)-infected BHK cells has been separated into a fraction containing the membrane-bound polysomes and the remaining supernatant fraction. Total poly(A)-containing RNA was isolated from each fraction and purified. A 17S class of VSV mRNA was found associated almost exclusively with the membrane-bound polysomes, whereas 14,5S and 12S RNAs were found mostly in the postmembrane cytoplasmic supernatant. Poly(A)-containing VSV RNA synthesized in vitro by purified virus was resolved into the same size classes. The individual RNA fractions isolated from VSV-infected cells or synthesized in vitro were translated in cell-free extracts of wheat germ, and their polypeptide products were compared by sodium dodecyl sulfate-polyacrylamide slab gel electrophoresis. The corresponding in vivo and in vitro RNA fractions qualitatively direct the synthesis of the same viral polypeptides and therefore appear to contain the same mRNA species. By tryptic peptide analysis of their translation products, the in vivo VSV mRNA species have been identified. The 17S RNA, which is compartmentalized on membrane-bound polysomes, codes for a protein of molecular weight 63,000 (P-63) which is most probably a nonglycosylated form of the viral glycoprotein, G. Of the viral RNA species present in the remaining cytoplasmic supernatant, the 14.5S RNA codes almost exclusively for the N protein, whereas the 12S RNA codes predominantly for both the NS and M proteins of the virion.     

Two Classes of Cytoplasmic Viral RNA Synthesized Early in Productive Infection with Adenovirus 2

The RNA sequences and RNA size classes transcribed early in productive infection with adenovirus 2 were analyzed by RNA-DNA hybridization. Two independent procedures demonstrated that early cytoplasmic viral RNA is composed of two sequence classes, class I which is absent or present in greatly reduced quantities at 18 h, and class II which persists throughout the infection. When the sequences in early viral RNA were analyzed by hybridization-inhibition studies, the hybridization of early [(3)H]RNA was inhibited only 50% by RNA from cultures harvested late (18 h) in infection. Liquid hybridizations with radioactive viral DNA confirmed that early RNA includes two classes. Duplex formation of RNA with (32)P-labeled viral DNA was assayed by hydroxylapatite chromatography and resistance to S(1) nuclease digestion. Both methods showed that the cytoplasmic RNA present early in infection annealed 12 to 15% of the viral DNA; late cytoplasmic RNA hybridized 21 to 25% of the DNA. Mixtures of early plus late cytoplasmic RNAs hybridized 30 to 34% of the viral DNA, demonstrating the reduced concentration of early class I RNA in the late RNA preparations. Experiments were performed to correlate class I and class II early RNA with size-fractionated cytoplasmic RNA synthesized early in infection. Fractionation of RNA by gel electrophoresis or sucrose gradient centrifugation confirmed three major size classes, 12 to 15S, 19 to 20S, and 26S. Total cytoplasmic RNA and RNA selected on the basis of poly(A) content contained the same size classes of viral RNA. In standard electrophoresis conditions, the 19 to 20S viral RNA could be resolved into two size classes, and the distribution of 12 to 15S RNA also indicated the presence of more than one size component. Hybridization-inhibition studies under nonsaturating conditions were performed with 26S, 19 to 20S, and 12 to 15S viral RNAs fractionated by gel electrophoresis. Late RNA inhibited the hybridization of 26S RNA only 20%, 19 to 20S RNA was inhibited 45%, and 12 to 15S RNA was inhibited 50%. When 18 to 19S and 12 to 15S viral RNAs purified by sucrose gradient centrifugation were similarly analyzed, late RNA inhibited hybridization of 18 to 19S RNA 50%, and the annealing of 12 to 15S RNA was inhibited 70%.     

Intercellular information transfer in the immunogenesis process. VIII. Analytical separation on agar and polyacrylamide gel of RNA fractions from the spleens of immunized and intact rats

RNA isolated from the spleens of intact rats and from rats with immunized sheep red cells was fractionated through three steps: 1 - extraction from phenol nuclei at 50-55 degrees and 65-75 degrees C, 2 - calcium-phosphate chromatography, 3 - agar electrophoresis. Eight agar fractions were obtained of the spleens of immunized rats, an increased RNA content was manifested in at least three agar fractions: the first (4 S), the third (21 S) and the eighth (26 S) ones. The first and the eighth immune RNA fractions, as it was shown earlier, induce the synthesis of antibodies in the rat transplantable lymphosarcoma cell. The first agar fraction of nuclear RNA from the spleens of immunized and intact rats were additionally separated using PAAG electrophoresis. The 4 S agar RNA fraction appears to be rather heterogeneous. It contains 4 S, 4.5 S, 5 S, 5.8 S, U1, U2 and 8 SII fractions, which are low-molecular nuclear RNAs, the 4 S subfraction prevailing. It is suggested that the 4 S PAAG subfraction is most active in the synthesis of antibodies induced by the heterogeneous agar 4 S RNA.     

Polyadenylated RNA in the lower eukaryote Physarum polycephalum.

Utilizing a method which quantitatively extracts high molecular weight RNA, including intact precursor as well as mature ribosomal RNAs, adenylated molecules have been isolated from nuclear- and cytoplasmic-enriched fractions of Physarum microplasmodia labeled with [3H]-uridine. Electrophoretic analysis of denatured adenylated RNA from the nuclear-enriched fraction indicated the presence of a population of large molecules not found in the cytoplasmic-enriched fraction.     

RNA synthesis by villus and crypt cell nuclei of rat intestinal mucosa

Rat intestinal mucosa was separated by eversion and vibration to provide a sequence of fractions from predominantly villus cells to predominantly crypt cells. The proportions of these cell types in each fraction were computed from the concentrations of alkaline phosphatase (villus cells) and thymidine kinase (crypt cells) in each population. The isolated mucosal fractions varied from about 90% villus cells to 90% crypt cells. Following injection of the rats with [³H]thymidine, the nuclei were isolated from each mucosal cell fraction and the amount of radioactivity incorporated into DNA was measured as an index of crypt cell abundance. The isolated nuclei were also incubated with ribonucleoside triphosphates and the amount of RNA synthesized was measured. Nuclei labeled with [³H]thymidine were found only in fractions rich in crypt cells, whereas capacity for RNA synthesis remained very active in mucosal fractions consisting predominantly of villus cells. It is concluded that non-dividing villus cells continue to make RNA.     

Characterization of the Solubilized GABA and Benzodiazepine Receptors from Various Regions of Bovine Brain

GABA and benzodiazepine receptors were solubilized from bovine cerebral cortex, cerebellum, and hippocampus and then partially purified by gel filtration and characterized. The apparent molecular weights of all these receptors were determined to be 600,000-650,000 by gel filtration, the sedimentation coefficients being 11.0-11.3 S by sucrose density gradient centrifugation. [3H]Muscimol was bound to two classes of sites in fractions from all three regions, and [3H]flunitrazepam bound to one class of sites. A comparison of the ratios of Bmax for flunitrazepam binding to Bmax for muscimol binding revealed that the fractions from the hippocampus exhibited a much higher ratio of benzodiazepine binding sites than were detected in fractions from the cortex and cerebellum. GABA agonist and antagonist inhibited [3H]muscimol binding to the fractions from these regions, at similar concentrations. Benzodiazepine agonists and antagonists also inhibited [3H]flunitrazepam binding in these three fractions, with similar potency. CL 218,872, however, inhibited [3H]flunitrazepam binding in the cerebellar fraction with the lowest IC50 value and that in th hippocampal fraction with the highest IC50 value. Hill coefficients for CL 218,872 inhibition were 0.98, 0.64, and 0.58 for cerebellum, cortex, and hippocampus, respectively.     

RNA associated with nonhistone chromosomal proteins of dog liver

The nonhistone chromosomal proteins were separated on Sephadex G-200 into 3 fractions of which two were associated with 3S RNA. The RNA eluted with fraction I (guanine + cytosine content 54%) is tightly bound to the proteins from which it can be separated only after digestion with pronase. The RNA associated with fraction III (guanine + cytosine content 64%) can be separated from the proteins directly by chromatography on DEAE-Sephadex A 25. No dihydropyrimidines have been detected in any of the two RNAs.     

Fractionation of constituents of ribonucleoproteins containing heterogeneous nuclear ribonucleic acid.

A method of fractionation of hnRNP constituents adaptable to large-scale preparation is presented. It is based on differential resistance to salt dissociation of the two classes of units of hnRNP, the 30--50S monoparticles and the heterogeneous complexes. The monoparticle proteins were released from hnRNP by 0.4 M NaCl. They were separated from the salt-resistant RNP corresponding to the heterogeneous complexes in three steps: chromatography on DEAE-cellulose, high-speed centrifugation, and Bio-Gel chromatography. The latter chromatography permitted a first fractionation of monoparticle proteins according to molecular weight. Such fractions may serve for purification of individual proteins of molecular weight below 80 000. After the two first steps, two fractions of salt-resistant RNP were obtained. In addition to heterogeneous RNA up to 30 S, small nuclear RNAs were detected which represented 6% of total RNA. The protein pattern was complex, and no clear-cut segregation of groups of proteins could be observed between the two fractions. They were both highly enriched in phosphoproteins as compared to nomoparticle proteins. In another fraction corresponding to the void volume of Bio-Gel chromatography, one-third of the RNA was small nuclear RNA. It is suggested that this fraction contains snRNP in addition to free proteins of molecular weight above 80 000 and to salt-resistant RNP similar to those described above but of small size.     

Epstein-Barr virus RNA. VIII. Viral RNA in permissively infected B95-8 cells

More than 50 RNAs expressed by Epstein-Barr virus late in productive infection have been identified. B95-8-infected cells were induced to a relatively high level of permissive infection with the tumor promotor 12-O-tetradecanoylphorbol-13-acetate. Polyadenylated RNAs were extracted from the cell cytoplasm, separated by size on formaldehyde gels, transferred to nitrocellulose, and hybridized to labeled recombinant Epstein-Barr virus DNA fragments. Comparison of RNAs from induced cultures with RNAs from induced cultures also treated with phosphonoacetic acid to inhibit viral DNA synthesis identifies two RNA classes: a persistent early class of RNAs whose abundance is relatively resistant to viral DNA synthesis inhibition and a late class of RNAs whose abundance is relatively sensitive to viral DNA synthesis inhibition. The persistent early and late RNAs are not clustered but are intermixed and scattered through most of segments UL and US. The cytoplasmic polyadenylated RNAs expressed during latent infection were not detected in productively infected cells, indicating that different classes of viral RNA are associated with latent and productive infection. Non-polyadenylated small RNAs originally identified in cells latently infected with Epstein-Barr virus are expressed in greater abundance in productively infected cells and are part of the early RNA class.     

Analysis of cytoplasmic RNA and polyribosmomes from feline leukemia virus-infected cells.

Cytoplasmic virus-specific RNA and polyribosomes from a chronically infected feline thymus tumor cell line, F-422, were analyzed by using in vitro-synthesized feline leukemia virus (Rickard strain) (R-FeLV) complementary DNA (cDNA) probe. By hybridization kinetics analysis, cytoplasmic, polyribosomat, and nuclear RNAs were found to be 2.1, 2.6, and 0.7% virus specific, respectively. Size classes within subcellular fractions were determined by sucrose gradient centrifugation in the presence of dimethyl sulfoxide followed by hybridization. The cytoplasmic fraction contained a 28S size class, which corresponds to the size of virion subunit RNA, and 36S, 23S, and 15 to 18S RNA species. The virus-specific 36S, 23S, and 15 to 18S species but not the 28S RNA were present in both the total and polyadenylic acid-containing polyribosomal RNA. Anti-FeLV gamma globulin bound to rapidly sedimenting polyribosomes, with the peak binding at 400S. The specificity of the binding for nascent virus-specific protein was determined in control experiments that involved mixing polyribosomes with soluble virion proteins, absorption of specific gamma globulin with soluble virion proteins, and puromycin-induced nascent protein release. The R-FeLV cDNA probe hybridized to RNA in two polyribosomal regions (approximately 400 to 450S and 250S) within the polyribosomal gradients before but not after EDTA treatment. The 400 to 450S polyribosomes contained three major peaks of virus-specific RNA at 36S, 23S, and 15 to 18S, whereas the 250S polyribosomes contained predominantly 36S and 15 to 18S RNA. Further experiments suggest that an approximately 36S minor subunit is present in virion RNA.