RNA SYNTHESIS IN CULTURED CHICK EMBRYO CELLS IN GROWING AND CONFLUENT PHASES

RNA synthesis at the growing phase in monolayer cultures of chick embryo fibroblasts was compared with that at confluent phases by zonal sedimentation, base composition and hybridization experiments. The nuclei were isolated by treatment with Nonidet p-40. The ratio of RNA/DNA in isolated nuclei was higher at the growing phase than that of confluent. The rate of RNA synthesis was reduced in the cells at confluent phase to 15.1% of that at the growing phase. The sucrose density gradient sedimentation pattern of nuclear RNA was on the whole the same in both phases. According to the distribution of ¹⁴C-uridine incorporated into nuclear RNA, 45S ribosomal precursor RNA was more distinct for the growing cell, while the radioactivities were found to be polydispersed, including the RNA which sedimented faster than 28S RNA in the cells at confluent phase. The base compositions and hybridization analyses indicated that ribosomal RNA was synthesized more actively in the growing cells. About 50% of newly synthesized RNA was ribosomal in the growing cells but 35% in the confluent.
It was found that newly synthesized 18S and 28S ribosomal RNAs appeared in cytoplasm after 21 and 33 min lag periods respectively. These times were exactly same in both growing and confluent phases.     

Changes in RNA in relation to growth of the fibroblast: II. The lifetime of mRNA,rRNA, and tRNA in resting and growing cells

The stabilities of the principal classes of RNA have been studied in resting and exponentially growing mouse fibroblast lines 3T6 and 3T3. Cytoplasmic mRNA, labeled with tritiated uridine and isolated by virtue of its poly A content, is equally stable in resting and growing cells, displaying a half-life of about 9 hr. We conclude that the accumulation of poly A(+) mRNA during transition from resting to growing state is due not to an increase in its stability, but to an increase in its rate of formation.The stability of cytoplasmic rRNA was measured after labeling with ³H-methyl-methionine. In agreement with the results of previous studies, we found that rRNA is stable in growing cells and unstable in resting cells. Quite unexpectedly, the 18S and 28S rRNA of resting cultures were found to differ appreciably in turnover rate. In both 3T6 and 3T3, the half-life of 28S RNA is about 50 hr, and that of 18S RNA about 72 hr. For this reason, though growing cells should synthesize the two ribosomal subunits in equal numbers, resting cells should synthesize more of the larger subunits than of the smaller. tRNA is unstable under all conditions. Its half-life is 36 hr in resting cells and about 60 hr in growing cells.     

Dual pathways for ribonucleic acid turnover in WI-38 but not in I-cell human diploid fibroblasts.

The turnover rates of 3H-labeled 18S ribosomal ribonucleic acid (RNA), 28S ribosomal RNA, transfer RNA, and total cytoplasmic RNA were very similar in growing WI-38 diploid fibroblasts. The rate of turnover was at least twofold greater when cell growth stopped due to cell confluence, 3H irradiation, or treatment with 20 mM NaN3 or 2 mM NaF. In contrast, the rate of total 3H-protein turnover was the same in growing and nongrowing cells. Both RNA and protein turnovers were accelerated at least twofold in WI-38 cells deprived of serum, and this increase in turnover was inhibited by NH4Cl. These results are consistent with two pathways for RNA turnover, one of them being nonlysosomal and the other being lysosome mediated (NH4Cl sensitive), as has been suggested for protein turnover. Also consistent with the notion of two pathways for RNA turnover were findings with I-cells, which are deficient for many lysosomal enzymes, and in which all RNA turnover was nonlysosomal (NH4Cl resistant).     

NUCLEOLAR-DERIVED RIBONUCLEIC ACID IN CHROMOSOMES, NUCLEAR SAP, AND CYTOPLASM OF CHIRONOMUS TENTANS SALIVARY GLAND CELLS

The distribution of monodisperse high molecular weight RNA (38, 30, 28, 23, and 18S RNA) was studied in the salivary gland cells of Chironomus tentans. RNA labeled in vitro and in vivo with tritiated cytidine and uridine was isolated from microdissected nucleoli, chromosomes, nuclear sap, and cytoplasm and analyzed by electrophoresis on agarose-acrylamide composite gels. As shown earlier, the nucleoli contain labeled 38, 30, and 23S RNA. In the chromosomes, labeled 18S RNA was found in addition to the 30 and 23S RNA previously reported. The nuclear sap contains labeled 30 and 18S RNA, and the cytoplasm labeled 28 and 18S RNA. On the basis of the present and earlier analyses, it was concluded that the chromosomal monodisperse high molecular weight RNA fractions (a) show a genuine chromosomal localization and are not due to unspecific contamination, (b) are not artefacts caused by in vitro conditions, but are present also in vivo, and (c) are very likely related to nucleolar and cytoplasmic (pre)ribosomal RNA. The 30 and 23S RNA components are likely to be precursors to 28 and 18S ribosomal RNA. The order of appearance of the monodisperse high molecular weight RNA fractions in the nucleus is in turn and order: (a) nucleolus, (b) chromosomes, and (c) nuclear sap. Since both 23 and 18S RNA are present in the chromosomes, the conversion to 18S RNA may take place there. On the other hand, 30S RNA is only found in the nucleus while 28S RNA can only be detected in the cytoplasm, suggesting that this conversion takes place in connection with the exit of the molecule from the nucleus.     

An excess of the small ribosomal subunits and a higher rate of turnover of the 60 S than of the 40 S ribosomal subunits in L cells grown in suspension culture.

A considerable excess of small ribosomal subunits was observed in L cells grown in suspension culture. The ratio between the small and large ribosomal subunits in the cytoplasm was estimated to be 1.17 ± 0.05 for cells dividing every 20 to 24 hours.The 60 S ribosomal subunits were turning over much faster than the 40 S subunits. Half-lives of 155 ± 20 hours for 18 S ribosomal RNA and 82 ± 15 hours for 28 S ribosomal RNA were observed under conditions where the cell number doubled every 24 hours and the viability was 95%. By correcting for cell death the half-lives of 18 S and 28 S ribosomal RNA were estimated to be approximately 300 hours and 110 hours, respectively. During storage of isolated ribosomes the small ribosomal subunits were degraded faster than the large subunits. This shows that the degradation of 60 S subunits was not an artifact taking place during the isolation procedure.It is postulated that the small ribosomal subunits are protected by protein to a greater extent than the 60 S subunits in these rapidly growing cells in suspension culture. The protection may take place both in the nucleus during synthesis, thus avoiding degradation (“wastage”) of nascent subunit precursors, and later in the cytoplasm. A calculation has been carried out to show that the observed excess of small subunits may be accounted for on the basis of a 1:1 synthesis of the small and large ribosomal subunits in the nucleus and different degradation rates in the cytoplasm. The results do not exclude the possibility of a difference in the “wastage” of 18 S and 28 S ribosomal RNA in the nucleus in addition to the difference in the turnover rates in the cytoplasm.     

Characterization of ribonucleoprotein particles released from isolated nuclei of regenerating rat liver in two different in vitro systems.

The ribonucleoprotein particles released from isolated nuclei of regenerating rat liver in two in vitro systems were studied and the following results were obtained. 1. When the isolated nuclei of regenerating rat liver labeled in vivo with [14C] orotic acid were incubated in medium containing ATP and an energy-regenerating system (medium I) release of labeled 40-S particles was observed. Analysis of these 40-S particles showed that they contained heterogeneous RNA but no 18 S or 28 S ribosomal RNAs and their buoyant density in CsCl was 1.42-1.45 g/cm3, suggesting that they were nuclear informosome-like particles released during incubation. 2. When the same nuclei were incubated in the same medium fortified with dialyzed cytosol, spermidine and yeast RNA (medium II), release of labeled 60-S and 40-S particles was observed. Using CsCl buoyant density gradient centrifugation, two components were found in the labeled ribonucleoprotein particles released from nuclei in this medium. The labeled 60-S particles were found to contain 28-S RNA as the main component and their buoyant density in CsCl was 1.61 g/cm3, suggesting that they were labeled large ribosomal subunits. The labeled 40-S particles contained both 18 S RNA and heterogeneous RNA and they formed two discrete bands in CsCl, at 1.40 and 1.56 g/cm3, suggesting that they contained small ribosomal subunits and nuclear informosome-like particles. 3. These results clearly indicate that addition of dialyzed cytosol, spermidine and low molecular yeast RNA to medium I causes the release of ribosomal subunits or their precursors from isolated nuclei in the in vitro system.     

Characterization of Rapidly Labeled Ribonucleic Acid from Dwarf Peas

The ribonucleic acid synthesized by excised shoots of dwarf pea (Pisum sativum L. cv. Progress No. 9) during short labeling periods has been characterized. Thirty percent of the total (32)P(i) incorporated in 1 hour is found in the ribosomal fraction. This labeled RNA was polydisperse (6-18 Svedberg units) and after chromatography on a methylated albumin-kieselguhr column about 80% of the radioactivity appeared in two peaks. One of these appeared on the shoulder of heavy ribosomal RNA ("mRNA") while the other was tenaciously bound to the column (TB-RNA). In the presence of high NaCl concentration, about half of the polydisperse RNA interacted with ribosomal RNA and eluted as "mRNA" while the remainder eluted as TB-RNA. This interaction in the presence of salt seems to result in the alteration of secondary structure because the "mRNA" fraction had a high sedimentation coefficient (45-50 Svedberg units). The polydisperse RNA approaches DNA in low cytidylate and guanylate content. After short periods of labeling TB-RNA showed higher adenylate content than "mRNA." The radioactivity from the "mRNA" peak can be chased, and these counts may represent a class of shortlived messenger RNA molecules with an average half-life of 10 to 15 minutes. The other component, TB-RNA, could not be chased and accumulated radioactivity during the chase period.     

RNA SYNTHESIS IN CHINESE HAMSTER CELLS : I. Differential Synthetic Rate for Ribosomal RNA in Early and Late Interphase

The incorporation of methionine-methyl-¹⁴C into 18S ribosomal RNA of cultured Chinese hamster ovary cells in early and late interphase has been determined by zone-sedimentation analysis of phenol-extracted RNA preparations. Synchronized cell cultures were prepared for these studies by thymidine treatment and by mechanical selection of mitotic cells. The specific activity of 18S RNA labeled in late interphase was found to be 1.1–1.2 times that of 18S RNA labeled in early interphase. Upon correction for increase in RNA mass, the rate of methylation of 18S RNA in late interphase is about 1.9 times that in early interphase.     

Wasting of 18 S ribosomal RNA by human myeloma cells cultured in adenosine.

When human myeloma cells are pulsed for one hour with 3H-uridine and chased for six hours in fresh medium containing unlabeled uridine, the processing of 45 S rRNA precursor into the stable 28 S and 18 S rRNA components can be followed. However, when the cells are chased in exogenous adenosine instead of uridine, the accumulation of 18 S rRNA is selectively inhibited. Cells pulsed with 3H-adenosine and chased in the absence of exogenous nucleosides exhibit normal rRNA precursor processing, while cells pulsed simultaneously with 3H-uridine and 3H-adenosine and chased with uridine and adenosine are deficient in labeled 18 S rRNA. Consequently, the inhibition of 18 S rRNA accumulation by adenosine is not an artifact of labeling nor is it relieved by an equal molar concentration of uridine. The wasting of 18 S rRNA in human myeloma cells is similar to that reported to occur in normal lymphocytes during the quiescent state.     

Phenol Extraction Op 28 S Ribosomal RNA Prom Rat Liver Cytoplasm

A simple and reproducible phenol method for the isolation of 28 S ribosomal RNA from rat liver cytoplasm, free from poly(A)-RNA is described. The procedure is based on the observation that at lower pH of the homogenate (pH 5.5) 28 S ribosomal RNA is extracted, while 18 S ribosomal RNA remains in the interphase layer.

Isolation of pure 28 S or 18 S ribosomal RNA in preparative amounts requires density gradient cen-trifugation or preparative gel electrophoresis. In this communication a rapid and reproducible method for the isolation of 28 S ribosomal RNA is proposed.     

Changes in nucleic acid and protein synthesis during starvation and spherule formation inPhysarum polycephalum

Summary The synthesis of protein and nucleic acids was studied by isotope incorporation and dilution in the plasmodia ofPhysarum polycephalum during periods of growth and differentiation (spherule formation). The total protein content decreased during starvation, but protein synthesis still occurred, probably at the expense of proteins previously synthesized during growth. Studies on leucine incorporation showed that protein synthesized during growth had a greater turnover than did protein formed by starving cultures, when both types of cultures were transferred to starvation conditions. Protein synthesis after prolonged starvation was rapidly and markedly decreased following the inhibition of RNA synthesis, whereas no such direct dependence on RNA synthesis was observed in growing cultures or during early starvation.The kinetics of RNA synthesis and the types of RNA formed were also shown to differ in growth and starvation. RNA turnover was low in growing cultures but substantial in starving cultures that were returned to growth medium. Qualitative differences in pulse-labeled RNA extracted from growing or starving cultures were revealed by methylated-albumin-kieselguhr column chromatography and sucrose gradient centrifugation. In starving cultures proportionately more labeled RNA was found in the lighter, non-ribosomal region of the gradient, and RNA from this region hybridized with denatured DNA to a greater extent than did other RNA fractions.This work was supported in part by Grant CA-07175 from the National Cancer Institute and by a grant from the Alexander and Margaret Stewart Trust Fund. The authors express their appreciation to Dr. H. Kubinski for helpful suggestions.One of us (H.W.S.) was in part supported by the Deutsche Forschungsgemeinschaft.     

Distances between 3' ends of ribosomal ribonucleic acids reassembled into Escherichia coli ribosomes

The three ribonucleic acids (RNAs) from Escherichia coli ribosomes were isolated and then labeled at their 3' ends by oxidation with periodate followed by reaction with thiosemicarbazides of fluorescein or eosin. Ribosomal subunits reconstituted with the labeled RNAs were active for polyphenylalanine synthesis. The distances between the 3' ends of the RNAs in 70S ribosomes were estimated by nonradiative energy transfer from fluorescein to eosin. The percentage of energy transfer was calculated from the decrease in fluorescence lifetime of fluorescein in the quenched sample compared to the unquenched sample. Fluorescence lifetime was measured in real time by using a mode-locked laser for excitation and a high-speed electrostatic photomultiplier tube for detection of fluorescence. The distances between fluorophores attached to the 3' ends of 16S RNA and 5S RNA or 23S RNA were estimated to be about 55 and 71 A, respectively. The corresponding distance between the 5S RNA and 23S RNA was too large to be measured reliably with the available probes but was estimated to be greater than 65 A. Comparison of the quantum yields of the labeled RNAs free in solution and reconstituted into ribosomal subunits suggests that the 3' end of 16S RNA does not interact appreciably with other ribosomal components and may be in a relatively exposed position, whereas the 3' ends of the 5S RNA and 23S RNA may be buried in the 70S ribosomal subunit.     

Accumulation of different percursor ribonucleoprotein particles by various cold sensitive, antibiotic resistant mutants

An analysis was carried out of precursor ribonucleoprotein particles produced by cold sensitive (subunit assembly defective) mutants from $\text{Escherichia coli}$ which are either resistant to spectinomycin alone or to both spectinomycin and streptomycin. It was found that while most spectinomycin-resistant mutants accumulated precursor particles sedimenting at 26-28S and around 30S, several streptomycin-spectinomycin double resistant mutants accumulated a 21S particle. Precursor 26-28S and 30S particles contain 17S precursor RNA which can be chased into mature RNA by a temperature shift-up. The nature of accumulation of precursor particles was discussed in relation to the scheme of biosynthesis of the 30S ribosomal subunit.     

Exploration of RNA 3' terminal locations in rat ribosome.

The locations of the 3' ends of RNAs in rat ribosome were studied by a fluorescence-labeling method combined with high hydrostatic pressure and agarose electrophoresis. Under physiological conditions, only the 3' ends of 28 S and 5.8 S RNA in 80 S ribosome could be labeled with a high sensitive fluorescent probe - fluorescein 5-thiosemicarbazide (FTSC), indicating that the 3' termini of 28 S and 5.8 S RNA were located on or near the surface of 80 S ribosome. The 3' terminus of 5 S RNA could be attacked by FTSC only in the case of the dissociation of the 80 S ribosome into two subunits induced by high salt concentration (1 M KCl) or at high hydrostatic pressure, showing that the 3' end of 5 S RNA was located on the interface of two subunits. However, no fluorescence-labeled 18 S RNA could be detected under all the conditions studied, suggesting that the 3' end of 18 S RNA was either located deeply inside ribosome or on the surface but protected by proteins. It was interesting to note that modifications of the 3' ends of ribosomal RNAs including oxidation with NaIO4, reduction with KBH4 and labeling with fluorescent probe did not destroy the translation activity of ribosome, indicating that the 3' ends of RNAs were not involved in the translation activity of ribosome.     

Ribosomal RNA Turnover in Contact Inhibited Cells

CONTACT inhibition of animal cell growth is accompanied by a decreased rate of incorporation of nucleosides into RNA^1–3. Contact inhibited cells, however, transport exogenously-supplied nucleosides more slowly than do rapidly growing cells^4,5, suggesting that the rate of incorporation of isotopically labelled precursors into total cellular RNA may be a poor measure of the absolute rate of RNA synthesis by these cells. Recently, Emerson⁶ determined the actual rates of synthesis of ribosomal RNA (rRNA) and of the rapidly labelled heterogeneous species (HnRNA) by labelling with ³H-adenosine and measuring both the specific activity of the ATP pool and the rate of incorporation of isotope into the various RNA species. He concluded that contact inhibited cells synthesize ribosomal precursor RNA two to four times more slowly than do rapidly growing cells, but that there is little if any reduction in the instantaneous rate of synthesis of HnRNA by the non-growing cells. We have independently reached the same conclusion from simultaneous measurements on the specific radioactivity of the UTP pool and the rate of ³H-uridine incorporation into RNAs (unpublished work of Edlin and myself). However, although synthesis of the 45S precursor to ribosomal RNA is reduced two to four times in contact inhibited cells, the rate of cell multiplication and the rate of rRNA accumulation are reduced ten times. This suggests either “wastage”⁷ of newly synthesized 45S rRNA precursor, or turnover of ribosomes in contact inhibited cells Two lines of evidence suggest that “wastage” of 45S RNA does not play a significant role in this system. (1) The rate of synthesis of 45S RNA in both growing and contact inhibited cells agrees well with that expected from the observed rates of synthesis of 28S and 18S RNAs (unpublished work of Edlin and myself). Emerson has made similar calculations⁶. (2) 45S RNA labelled with a 20 min pulse of ³H-uridine is converted in the presence of actinomycin D to 28S and 18S RNAs with the same efficiency (approximately 50%) in both growing and contact inhibited cells. These results indicate that, in order to maintain a balanced complement of ribosomal RNAs, contact inhibited cells must turn over their ribosomes. We present evidence here that rRNA is stable in rapidly growing chick cells, but begins to turn over with a half-life of approximately 35–45 h as cells approach confluence and become contact inhibited.