Methylation of ribosomal RNA in growing and resting cultures of Paul's Scarlet Rose

The role of methylation of rRNA on the differential rate of ribosome accumulation was studied in exponentially growing and resting cultures of rose cells. The cells were labelled with [³H] uridine and pre-rRNA and rRNA were prepared from the nuclei and ribosomes. The results demonstrate that in resting cultures, in which the ribosome accumultaion was reduced, the pre-rRNA and rRNA were 50% and 75% less methylated respectively, than those of the growing cells.     

The isolation and analysis of polysomes and ribosomal RNA from cells growing in monolayer culture

A rapid procedure for the isolation of cytoplasmic ribosomes from monolayer cultures is described. A mixture of 1% Triton X-100 and 1% DOC (Na-deoxycholate) is used to extract cells directly on the tissue culture plate without prior treatment. The procedure lyses all cells leaving nuclei intact and results in over 90% recovery of cytoplasmic ribosomal RNA (rRNA). The extraction can be carried out in the absence of cycloheximide without alteration of polysome profiles.     

Regulation of RNA synthesis in plant cell culture: delayed synthesis of ribosomal RNA during transition from the stationary phase to active growth

Ribosomal RNA synthesis was studied during the early phases of growth activation in a cell suspension culture derived from peanut (Arachis hypogaea, L.) cotyledon. Upon dilution from stationary phase, these cells show a characteristic lag of 3 days before the commencement of cell division. An analysis of the nature of RNA synthesized during this early period of growth showed that the cells obtained immediately upon dilution from stationary phase synthesize primarily messenger RNA and essentially no ribosomal RNA. The synthesis of ribosomal RNA is delayed for about 24 hr after which it rises sharply resulting in a 2- to 3-fold accumulation of ribosomal RNA per cell during the subsequent 24-hr period. Both the messenger RNA and the ribosomal RNA were characterized by their cellular localization; by sucrose and CsCl gradient analyses, and by the determination of their base ratios.It would appear that a major facet of the lag phase in the cell growth is the diversion of a significant part of the RNA biosynthetic apparatus from the synthesis of messenger RNA to that of ribosomal RNA.     

Accelerated rates of ribosomal RNA synthesis during growth of contracting heart cells in culture

Contractile activity of neonatal cardiac myocytes stimulated hypertrophic growth as compared with nonbeating cells that were depolarized with 50 mM KCl. Growth of contracting myocytes was associated with an increased rRNA content as measured by the total RNA/DNA ratio. The fractional rates of rRNA synthesis (K8) and rRNA degradation were determined in contracting and nonbeating myocytes to assess their relative contributions in increasing rRNA content during growth. The values for K8 were calculated from the specific radioactivity of 3'-[3H]UMP in 18 and 28 S rRNA after purification by hybridization to cloned rDNA. The cellular [3H]UTP pool served as the precursor for rRNA synthesis in myocytes that were labeled with 50 microM [3H]uridine. K8 values for 18 and 28 S rRNA in contracting myocytes were accelerated by 59 and 53%, respectively, after 3 days as compared with nonbeating myocytes. Calculations of the rate of cellular rRNA synthesis, which took into account the increased content of myocyte rRNA, revealed that synthesis of both 18 and 28 S rRNA was accelerated 2-fold after 2 days of contraction. The derived values for degradation of 18 and 28 S rRNA were increased marginally in contracting myocytes, but cellular rRNA degradation rates averaged 57% higher. The difference between cellular rates of rRNA synthesis and degradation in contracting myocytes accounted for the 30% increase in rRNA content. These data demonstrated that increased rRNA content in contracting myocytes resulted from acceleration of the fractional rate of rRNA synthesis.     

Protein synthesis during the transition from the resting to the growing state in suspension cultures of Paul's Scarlet rose cells

Cells derived from Paul's Scarlet rose ( Rosa sp. ) were grown in the chemically defined medium of Nesius. When a stationary phase culture was diluted with fresh medium, growth was initiated after a pronounced lag period. DNA replication, as revealed by thymidine labeling and autoradiography, did not begin until 36 h, and mitotic figures were not observed until 48 h after dilution. A 10–15 fold increase in the rate of protein synthesis occurred during the lag period. This was brought about by a 3.5 fold increase in the amount of ribosomal RNA per cell, plus a doubling of both the percentage of ribosomes that are present as polyribosomes and the average number of ribosomes per polyribosome. The spectrum of polypeptides synthesized by these cells during the lag and early log periods of growth was examined. Polyribosomes were extracted from the cells at intervals preceding and accompanying the initiation of proliferative growth. The polyribosomes were translated in a wheat germ cell-free protein synthesizing system and the ³⁵S-methionine-labeled translation products were separated on polyacrylamide slab gels and by 2-dimensional gel electrophoresis. Comparatively few differences were observed between stationary phase, lag phase and log phase cells in terms of the spectrum of polypeptides synthesized in vitro. However, these various phases of the growth cycle could be characterized by a relatively high rate of synthesis of a few specific polypeptides. That is, while most proteins are synthesized throughout the growth cycle and even in non-growing cells at approximately the same relative rates, there are a few variable proteins whose synthesis marks a particular phase of the growth cycle.     

Studies on the control of ribosomal RNA synthesis in HeLa cells.

In many eucaryotic systems protein synthesis is coupled to ribosomal RNA synthesis such that shut-down of the former causes inhibition of the latter. We have investigated this stringency phenomenon in HeLa cells. The protein synthesis inhibitors cycloheximide and puromycin cause inactivation of both processes but valine starvation totally inhibits only the processing of 45-S RNA. DNA-dependent RNA polymerases from A, B and C (or I, II and III respectively) were extracted, separated partially by DEAE-cellulose chromatography and their activity levels determined. These do not decrease significantly during inhibition of protein synthesis. To find out whether or not form A is bound to its template under these conditions, proteins were removed from chromatin with the detergent sarkosyl. This does not affect bound RNA polymerase. Inhibition of protein synthesis caused up to 50% reduction in endogenous alpha-amanitin-insensitive chromatin-RNA-synthesising activity. This reduced level of activity was not affected by sarkosyl treatment. Levels in normal cells were stimulated. This result indicates that the form A RNA polymerase is not bound to its template when protein synthesis is inhibited.     

Coordination of ribosomal RNA synthesis in vertebrate cells

Xenopus embryo cells and HeLa cells were investigated under various conditions to test for coordinate synthesis of high molecular weight (28S and 18S) and low molecular weight (5S) rRNA. Xenopus embryos initiate 28S and 18S rRNA synthesis at gastrulation (Brown and Littna, '64); we found that 5S rRNA synthesis is coordinately initiated with the 28S and 18S rRNAs at the same time in development. Dissociated Xenopus blastula cells were cultured in vitro for several hours to condition the medium; post-gastrula cells were then grown in the conditioned medium to test for the existence of an inhibitor of rRNA synthesis. No inhibitor was detected. Low doses of actinomycin D profoundly inhibit the synthesis of 28S and 18S rRNA in HeLa cells, while 5S rRNA synthesis is less affected by this treatment. Therefore, actinomycin D does not produce a coordinate inhibition of all rRNA species. Similar effects of the antibiotic were found in cultured amphibian cells. Synchronized HeLa cells reinitiating RNA synthesis following mitosis also respond to actinomycin D in a non-coordinate manner.     

Evidence for ribosomal RNA synthesis in pollen tubes in culture

The evidence is presented that pollen tubes ofNicotiana tabacum L. cultivated in shaken suspension do synthesize 5S, 18S and 28S RNA. Following incubation of pollen tubes in the presence of radioactive uracil or uridine, RNA was isolated from total pollen tube material after the removal of 4S RNA, from polysomes and from 80S ribosomal particles, and fractionated by density gradient centrifugation and MAK column chromatography. The results obtained further suggest a higher rate of 5S RNA synthesis with respect to 18S+28S RNA.     

Control of ribosomal RNA synthesis in Escherichia coli. III. Cytoplasmic factors for ribosomal RNA synthesis.

The ribosomal RNA synthesis in a cell-free system containing the nucleoids and the cytoplasmic fraction prepared from Escherichia coli cells has been investigated. The addition of the "4S" fraction from the cytoplasm to the isolated nucleoids induces RNA synthesis by a new chain initiation. In this system a preferential initiation or rRNA chains occurs. The experimental results suggest that the 4S fraction contains at least two activities, one for releasing RNA-polymerases from the nucleoids, and another for the frequent initiation of rRNA chains. No restriction of the rRNA synthesis has been observed in the nucleoids and the 4S fraction from the amino acid-starved rel+ cells. The rRNA synthesized in the above system is detected at about 23S and 16S rRNA regions.     

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.     

Effect of actinomycin D on RNA synthesis in a stationary culture of Chinese hamster cells stimulated to proliferate]

The study of the effects of actinomycin D on stationary cultures of Chinese hamster cells and those stimulated by medium changing has revealed that RNA synthesis is more sensitive in the latter, the difference in the first place being attributed to the rate of labeled uridine incorporation into cell nucleoli. There is no significant difference in H3-actinomycin D uptake between stationary and stimulated cells, but the latter incorporate more labeled actinomycin D into their nuclei. A pronounced variation in sensitivity to actinomycin D is observed during the prereplicative period of stimulated cells. The first part of this period is more sensitive, which may be due to the necessity for stimulated cells to synthesize a great number of ribosomes to enter the mitotic cycle and to proceed through it.     

Secondary structure of total protein and 23S RNA in 50S ribosomal subunits and in the isolated state

Optical and sedimentational studies of isolated 23S RNA, total proteins and some RNP-complexes of the 50S subunits were carried out. It is shown that the secondary structure content of 23S RNA in the ribosome is lower than in the isolated state. Ribosomal proteins stabilize the 23S RNA structure and make it more compact. At the same time they cause some unwinding effect on the secondary structure of the 23S RNA and possibly fix some segments of the 23S RNA in the conformation necessary for its function. In turn, the 23S RNA increased somewhat the level of the total ordered secondary structure in the ribosomal proteins. There was no considerable change of the ratio between the alpha- and beta-structures in the proteins.