Rapid increase in poly(A) (+) mRNA content following inhibition of protein synthesis

When resting 3T6 cells undergo a serum-induced transition to the growing state, the cytoplasmic content of ribosomal, transfer and messenger RNA increase as the cells prepare for DNA synthesis. The normal linear increase in mRNA content occurs even when the production of ribosomes is blocked. In this paper we determine the effect of inhibiting protein synthesis on the increase in poly(A) (+) mRNA content. Resting cells were serum stimulated in the presence of cycloheximide or puromycin at levels which inhibit protein synthesis by greater than 95%. Cytoplasmic poly(A) (+) mRNA content was determined at various times thereafter. We found that mRNA content increased five to ten times more rapidly in drug treated cells than in control cells stimulated in the absence of inhibitors. mRNA content increased 50–70% by one hour, and 60–90% by two hours following stimulation in the presence of inhibitor, and remained more or less constant thereafter. In contrast, mRNA content increased linearly in control stimulated cultures and did not double until about 15 hours after stimulation. The rapid increase in mRNA content is most likely the result of inhibition of protein synthesis rather than a secondary effect of the drug since the same observations were made in growth stimulated cells if protein synthesis was blocked with either puromycin or cycloheximide. A similar effect was also observed with resting 3T6, exponentially growing 3T6 and growing HeLa cells following exposure to cycloheximide, although the magnitude of the increase was less than that observed with growth stimulated cells. Puromycin had negligible effect on mRNA content in resting or exponentially growing cells. The rapid increase in cytoplasmic poly(A) (+) mRNA content was not due to rapid unbalanced export of nuclear poly(A) (+) RNA into the cytoplasm since there was no decrease in nuclear poly(A) content following serum stimulation in the presence of cycloheximide.     

Changes in RNA metabolism and accumulation of presumptive messenger RNA during transition from the growing to the quiescent state of cultured mouse fibroblasts.

Mouse fibroblasts maintained in tissue culture regulate total protein and ribosomal RNA synthesis co-ordinately with changes in the cellular growth state. Here we show that changes in the rate of synthesis of nuclear non-polyadenylic acid-containing RNA and the rate of accumulation and breakdown of cytoplasmic ribosomal RNA also accompany the transition from the resting to the growing cellular growth state, while the rate of synthesis of nuclear poly (A)-containing RNA and the rates of accumulation and breakdown of cytoplasmic poly(A) containing RNA (presumptive messenger RNA) are, however, only marginally changed. The small net increase (20% to 30%) in the amount of presumptive mRNA is considerably less than the observed increase in protein synthesis (two to threefold) during this transition. We also isolated and characterized extra-polysomal poly(A)-containing ribonucleoprotein particles from quiescent cultures that were similar to those particles obtained by treatment of polyribosomes with EDTA. These experiments suggest that the early increase in protein synthetic activity when quiescent, cultured cells are induced to grow is partially caused by an increased attachment of pre-existing mRNA molecules to free ribosomes.     

Regulation of protein synthesis in human diploid fibroblasts: reduced initiation efficiency in resting cultures

The level of poly A+ RNA in growing cultures of human diploid fibroblasts is 1.8-fold times greater than in resting cultures. The level of functional ribosomes in growing cultures is 2.8 times that in resting cultures. Since transit times are similar in both types of cells, it can be concluded that the rate of protein synthesis in growing cultures is 2.8 times that in resting cultures. a reduced efficiency of mRNA translation at the level of initiation in resting cultures is proposed as a probable explanation for the fact that the decrease in protein synthesis rates is greater than the decrease in mRNA levels. This hypothesis is supported by the observations that: (a) poly A+ RNA is associated with smaller polysomes in resting than in growing cells, and (b) cycloheximide treatment of resting cells results in recruitment of nonpolysomal poly A+ RNA into polysomes and a shift of polysomal poly A+ RNA into larger polysomes.     

Differences in the cytoplasmic distribution of newly synthesized poly (A) in serum-stimulated and resting cultures of BALB/c 3T3 cells.

Density-inhibited, serum-stimulated, and SV40 virus-transformed BALB/c 3T3 cultures were compared with respect to the rates of accumulation of cytoplasmic RNA molecules and with respect to the distribution of newly synthesized messenger RNA (mRNA) between polyribosomes and the post-ribosomal cell fraction. mRNA was isolated and quantitated by virtue of its association with radioactive polyadenylate (poly(A))-synthesized during a 90 min exposure of the cultures to ³H-adenosine. The rate of accumulation of cytoplasmic poly(A) rose slowly after serum stimulation and reached a value of 1.8 times that of resting cultures at 12 h after serum stimulation, which was also the time of onset of DNA synthesis. A change in the cytoplasmic distribution of newly synthesized poly(A) occurred more rapidly than the change in the rate of its synthesis, however. Resting cultures contained 37% of newly synthesized cytoplasmic poly(A)-containing RNA large enough to be mRNA in the post-ribosomal cell fraction, whereas virtually all of this material was found in polyribosomes at 3, 6 and 12 h after stimulation and in transformed cultures. The relatively infrequently translated mRNA of resting cultures was shown to be functional by cycloheximide treatment. (All BALB/c 3T3 cultures, resting or stimulated, contained about 20% of newly synthesized cytoplasmic poly(A) as nearly pure poly(A) in molecules of 4–6 Svedbergs in size, presumably too small to be mRNA.) We conclude that serum stimulation of density-inhibited cultures resulted in a more efficient use of the protein-synthesizing ability of the cell, and that the change in efficiency preceded increases in numbers of ribosomes and mRNA molecules.     

Parallel changes in protein synthesis and messenger RNA content in growing and resting epithelial cells of Xenopus laevis

The regulation of cell growth can be achieved at many levels but ultimately the regulatory factors must alter protein synthesis since growing cells always exhibit an increased rate of protein synthesis compared to resting cells. Some studies using growing and nongrowing mammalian cells have shown that the rate of protein synthesis compared to resting cells. Some studies using growing and nongrowing mammalian cells have shown that the rate of protein synthesis is directly dependent on mRNA content. Other studies have shown that growing and resting cells have similar amounts of mRNA and that protein synthesis is regulated by the proportion of mRNA in polysomes. We have analyzed mRNA content in growing and resting epithelial cells of Xenopus laevis. Quantitation of poly(A)⁺ mRNA by uniform labeling with ³H-uridine and by ³H-poly(U)hybridization demonstrated a direct relationship between mRNA content and the relative rate of protein synthesis in growing and resting cells. Likewise, after serum stimulation of resting cells the increase in mRNA content closely paralleled the increase in protein synthesis. Our results suggest that control of protein synthesis in growing and nongrowing cells is exerted before the translational level.     

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.     

Protein synthesis in resting and growth-stimulated human peripheral lymphocytes : Evidence for regulation by a non-messenger RNA

Stimulation of lymphocyte growth is accompanied by an early increase in the rate of protein synthesis. This increase is dependent upon the flow of inactive free ribosomes into polysomes, which is limited by a rate-controlling step at initiation [2]. Addition of actinomycin D (actD) to lymphocytes caused a gradual reduction in protein synthesis in resting cells, but rapidly inhibited both the elevation of protein synthesis and the activation of free ribosomes which normally follow exposure to mitogens. Since actD does not affect protein synthesis in enucleated lymphocytes [4], the effect in intact cells must be mediated by a nuclear event, which available data indicate is RNA synthesis. ActD prevented the accumulation of 80S initiation complexes which normally occurs in resting lymphocytes treated with pactamycin and cycloheximide, showing that its locus of action was at some point in initiation. The decline in rate of protein synthesis began without detectable lag when resting lymphocytes were treated with actD. However, after growth stimulation, a delay of ca 50 min occurred before the protein synthetic rate declined in response to actD. These observations agree with the hypothesis that the concentration of some moderately short-lived RNA is rate-limiting for protein synthesis in resting lymphocytes, and that an early event in growth stimulation is a rise in the amount of this component to levels which are no longer rate-limiting. This permits an increased flow of ribosomes into polysomes and a consequent rise in protein synthesis. Available evidence indicates that the regulatory RNA is neither mRNA nor rRNA, but may either be one of the small cytoplasmic RNAs whose function is unknown, or tRNA_i^met.     

An investigation of the stability of messenger RNAs in cell-free,translational systems from uninfected and mengovirus-infected Ehrlich ascites tumor cells

The stabilities and translation of Ehrlich ascites tumor cell poly(A)-containing mRNA and mengovirus RNA in fractionated cell-free protein synthesizing systems from uninfected and mengovirus-infected Ehrlich ascites tumor cells were studied. During incubation of the systems about 20% of the input RNA is reduced in size and associated with ribosomes engaged in polypeptide synthesis; the remainder is rapidly degraded by RNases. At the end of active translation, both mRNA and nascent proteins are bound to polysomes which are of the same size as those formed during active protein synthesis. The kinetics of protein synthesis closely follow those of RNA hydrolysis. The stabilities of mengovirus RNA and poly(A)-containing mRNA from Ehrlich ascites tumor cells are the same in both systems.     

Regulation of ribosomal protein mRNA content and translation in growth-stimulated mouse fibroblasts

When resting (G₀) mouse 3T6 fibroblasts are serum stimulated to reenter the cell cycle, the rates of synthesis of rRNA and ribosomal proteins increase, resulting in an increase in ribosome content beginning about 6 h after stimulation. In this study, we monitored the content, metabolism, and translation of ribosomal protein mRNA (rp mRNA) in resting, exponentially growing, and serum-stimulated 3T6 cells. Cloned cDNAs for seven rp mRNAs were used in DNA-excess filter hybridization studies to assay rp mRNA. We found that about 85% of rp mRNA is polyadenylated under all growth conditions. The rate of labeling of rp mRNA relative to total polyadenylated mRNA changed very little after stimulation. The half-life of rp mRNA was about 11 h in resting cells and about 8 h in exponentially growing cells, values which are similar to the half-lives of total mRNA in resting and growing cells (about 9 h). The content of rp mRNA relative to total mRNA was about the same in resting and growing 3T6 cells. Furthermore, the total amount of rp mRNA did not begin to increase until about 6 h after stimulation. Since an increase in rp mRNA content did not appear to be responsible for the increase in ribosomal protein synthesis, we determined the efficiency of translation of rp mRNA under different conditions. We found that about 85% of pulse-labeled rp mRNA was associated with polysomes in exponentially growing cells. In resting cells, however, only about half was associated with polysomes, and about 30% was found in the monosomal fraction. The distribution shifted to that found in growing cells within 3 h after serum stimulation. Similar results were obtained when cells were labeled for 10.5 h. About 70% of total polyadenylated mRNA was in the polysome fraction in all growth states regardless of labeling time, indicating that the shift in mRNA distribution was species specific. These results indicate that the content and metabolism of rp mRNA do not change significantly after growth stimulation. The rate of ribosomal protein synthesis appears to be controlled during the resting-growing transition by an alteration of the efficiency of translation of rp mRNA, possibly at the level of protein synthesis initiation.     

Effects of retinoic acid on protein synthesis in cultured melanoma cells

Retinoic acid reduces the growth rate of mouse S91 melanoma cells in culture and increases the proportion of cells in the G₁ phase of the cell cycle. Because of the integral role protein synthesis has been shown to play in growth control we studied the effect of retinoic acid on the protein synthesis machinery with a cell-free system developed from the melanoma cells. This system was capable of translating endogenous mRNA, exogenous globin mRNA, and the synthetic template poly(U). Of the above activities of the protein synthesis system only the translation of endogenous mRNA was reduced significantly in the cell-free system prepared from retinoic acid-treated cells. Analyses of the amount and function of RNA revealed that treatment with retinoic acid leads to reductions in total RNA content, in the proportion of ribosomes in polysomes, in the amount of poly(A)RNA, and in the amount of polysome-associated mRNA. All these effects of retinoic acid contribute to the decrease in protein synthesis activity of treated cells. Two-dimensional electrophoresis anlaysis of L-[³⁵S]methionine-labeled proteins produced by untreated and treated cells revealed only a few quantitative differences. We suggest that retinoic acid-induced suppression of protein synthesis activity may be the cause for growth inhibition.     

Properties of total and poly(A) RNA from exponentially growing and from resting cultures of Tetrahymena thermophila

Total RNA was extracted from exponentially growing and resting cultures of Tetrahymena thermophila. Poly(A)-containing RNA was separated by oligo(dT) affinity chromatography. The following characteristics of both preparations were studied: the changes in sedimentation profiles of newly made RNAs as a function of time, the length of the poly(A) segment, and the capacity of polyadenylated mRNA to code for proteins in vitro. The time-dependent sedimentation profiles of both kinds of RNA changed strikingly with the modes of growth: poly(A)⁺ RNA from heterodisperse in log phase into uniformly and slowly sedimenting in stationary phase, and total RNA from typical ribosomal into heterodisperse with a maximum in the pre-rRNA region. As revealed by the temperature regime developed by Ihle et al. [1] about 80% of all poly(A) RNA molecules carried a poly(A) stretch of less than 50 nucleotides. There was a tendency of the class 0–20 nucleotides to become more frequent in the stationary phase. The polyadenylated mRNAs were translated in the reticulocyte in vitro system. At least one protein of about 26 000 D was translated only in presence of mRNA of growing cells and not with that from resting cells. Another of 3 500 D was found only with mRNA from resting cultures. Three other proteins were translated with different rates according to the culture growth rate. The results demonstrate that the RNA isolated from different phases of culture growth have different dynamic as well as coding properties related to rate of cell multiplication.     

Quantitative changes in total RNA, total poly(A), and ribosomes in early mouse embryos

To obtain information on the amounts and major classes of RNA stored in the mouse egg and accumulated during cleavage, we determined the contents of total RNA, total poly(A), and ribosomes from the 1-cell stage to blastocyst. Using purified RNA for assay, we obtained an RNA content of 0.35 ng in the unfertilized egg, 0.24 ng in 2-cell, 0.69 ng in 8- to 16-cell, and 1.47 ng in early bastocyst (32 cells). As derived from EM morphometry, the number of ribosomes accounts for 60–70% of the total RNA content at all these stages; the marked increase in ribosomal number during cleavage is attributable entirely to new synthesis. Hybridization with [³H]poly(U) in solution yielded a poly(A) content of 0.7 pg for the unfertilized egg and 0.83 pg for the 1-cell embryo. The poly(A) content dropped sharply, to 0.26 pg per embryo, by the late 2-cell stage and increased to 0.44 pg in 8- to 16-cell embryos and 1.42 pg in early blastocysts. Hybridization in situ gave a similar pattern and also revealed a heavy labeling of embryo nuclei from the 2-cell onward but very little, if any, labeling of the pronuclei of 1-cell embryos, suggesting an absence, or low level, of poly(A)+ RNA synthesis at the 1-cell but an active synthesis at the 2-cell and later stages. These findings and other available evidence(e.g., R. Bachvarova and V. De Leon, 1980, Develop. Biol.74, 1–8) suggest that the mouse embryo inherits a large supply of maternal mRNA but that the bulk of this RNA is eliminated in the 2-cell embryo. In situ hybridization was used to study the relative concentration of poly(A) in ovarian oocytes. In growing oocytes, the cytoplasmic concentration of poly(A) remains about the same, suggesting that the accumulation of poly(A)+ RNA is proportional to oocyte growth. The poly(A) content declines about twofold between the time of completion of oocyte growth and fertilization. The germinal vesicle continues to be labeled up to the time of ovulation, raising the possibility that poly(A)+ RNA synthesis (and presumably turnover) occurs in fully grown oocytes.     

Ultrastructural cytochemical, immunocytochemical and in situ hybridization methods with polyuridine probes detect mRNA in human mast cell granules

Mature human mast cells are classical secretory cells that are filled with secretory-storage granules but are poorly endowed with visible free or membrane-bound cytoplasmic ribosomes. We recently reported close associations of ribosomes and various components essential to RNA metabolism in and close to human mast cell granules using multiple ultrastructural imaging methods. In view of these findings and an increased awareness of RNA sorting and localization to specific subcellular sites and organelles, we used human mast cells purified from non-tumour portions of lung samples resected at surgery for carcinoma and ultrastructural methods to investigate this further. Poly(U) probes were used to detect direct en grid binding, and radiolabelled as well as non-radiolabelled poly(U) probes were used in in situ hybridization protocols to detect poly(A)-positive pre-mRNA and mRNA in nuclear, cytoplasmic and granular compartments of mature human mast cells. Negative controls verified specificity of label; expected nuclear and cytoplasmic locations of poly(A)-positive RNA served as positive controls for each sample. These findings lend support to the hypothesis that site-specific synthesis in secretory-storage granules may occur in secretory cells.     

Inhibition of dihydrofolate reductase gene expression following serum withdrawal or db-cAMP addition in methotrexate-resistant mouse fibroblasts

We have used a methotrexate (MTX)-resistant mouse 3T6 cell line (M50L3), that overproduces dihydrofolate reductase (DHFR) and its mRNA by a factor of 300, to study the mechanism for turning off DHFR gene expression following withdrawal of serum factors or elevation of the intracellular level of cAMP. When resting (G0) M50L3 cells are serum-stimulated to reenter the cell cycle, the level of DHFR activity begins to increase at about the same time the cells begin synthesizing DNA. The increase in enzyme activity is preceded by increases in the synthesis rate of the enzyme, and the content and production rate of DHFR mRNA. These increases, as well as entry into S phase, are blocked when the cells are serum-stimulated in the presence of dibutyryl cyclic AMP (db-cAMP) and theophylline. In this study, we found that when these drugs were added, or the serum stimulus was withdrawn during S phase (20 h following stimulation), the subsequent increase in DHFR level was blocked. Immunoprecipitation of DHFR from pulse-labelled cells showed that both treatments led to a rapid decrease in synthesis rate of the enzyme. The effect on total protein synthesis was much less than on DHFR synthesis. In DNA-excess filter hybridization experiments, we found that the content of cytoplasmic DHFR mRNA decreased in parallel with the synthesis rate of the enzyme. This was due in part to a decrease in the production rate of DHFR mRNA relative to total mRNA. In addition, drug addition or serum withdrawal led to a significant destabilization of DHFR (as well as total) mRNA. About 85% of poly(A)(+) DHFR mRNA was associated with polysomes in resting, growing, or cAMP-treated cells, suggesting that DHFR gene expression was not controlled at the translational level under these conditions.     

Changes in RNA in relation to growth of the fibroblast. I. Amounts of mRNA,rRNA, and tRNA in resting and growing cells

The established cell lines 3T6 and 3T3 contain more of both rRNA and mRNA when they are growing than when they are resting, but mRNA is increased more than rRNA. During conversion of 3T6 cultures from resting to growing state, mRNA, rRNA, and tRNA accumulate long before DNA synthesis begins. The increases in rRNA and tRNA are coordinate, but mRNA accumulates earlier and to a greater extent than the others. The rate of protein synthesis in cultures in transition from resting to growing state increases faster than their content of rRNA and appears proportional to the amount of mRNA rather than to the number of ribosomes. The doubling of mRNA content that takes place before any cells begin to synthesize DNA should be considered in relation to the absence of change in the overall rate of synthesis of HnRNA during the same period.