Purification and characterization of a DNA synthesis inhibitor protein from mouse embryo fibroblasts

A DNA synthesis inhibitor protein was purified from the conditioned medium of cycloheximide treated mouse embryo fibroblasts. This protein has a molecular weight of 45,000 as determined by gel filtration and Polyacrylamide gel electrophoresis. The levels of the [³⁵S] methionine la belled 45 kDa protein in the medium and matrix were monitored across two cell cycles in synchronized cultures. The 45 kDa protein was present in higher levels in the medium of non-S-phase cells depicting a peak between the two S-phases. The DNA synthesis inhibitor protein was immunologically related to a chicken DNA-binding protein which showed similar cell cycle specific variations at the intracellular level. The purified 45 kDa protein inhibited DNA synthesis in murine and human cells. In mouse embryo fibroblasts, the DNA synthesis was inhibited to an extent of 86% by 0.25 μg/ml of the inhibitor, while higher amounts of the inhibitor were required to arrest DNA synthesis in human skin fibroblasts: in these cells, 4 μg/ml of the inhibitor inhibited DNA synthesis to an extent of 50%. The high levels of the 45 kDa protein in the medium of non-S phase cells and its DNA synthesis inhibitory potential suggest that this protein may be involved in the regulation of DNA synthesis during the cell cycle.     

Identification of a phosphoprotein specifically induced by the transforming DNA of rat neuroblastomas

DNAs from nitrosoethylurea-induced rat neuroblastomas transform NIH/3T3 mouse fibroblasts in a transfection assay. DNAs of such transformed cells can be used in a subsequent cycle of transfection to generate secondary foci that contain virtually no foreign genetic material besides the sequences carrying the rat neuroblastoma transforming function. These secondary neuroblastoma transfectants were injected into young mice and grew out into fibrosarcomas. Sera from these mice were examined for reactivity with any proteins which were induced specifically by the neuroblastoma transforming sequence. These sera precipitate a polypeptide of about 185,000 daltons from ³⁵S-methionine-labeled cell lysates of the rat neuroblastoma cells that served as DNA donors and in all transfection-derived primary and secondary foci. This protein is present in high levels in all neuroblastoma transfectant clones, but was not detectable in a variety of other transformed cells. Antisera were prepared from mice bearing tumors induced by transformed cells derived by transfection of DNAs from various tumor cell types unrelated to rat neuroblastoma. These antisera failed to immunoprecipitate the 185,000 dalton protein. These data indicate that the synthesis of the 185,000 dalton protein is specifically induced by the neuroblastoma transforming sequence. The protein may be encoded by the transforming sequence and may mediate transformation in this chemically induced tumor.     

contribution to the study of nuclear total proteins and DNA during the mitotic cycle in fibroblasts cultivated in vitro and in Ehrlich ascites cells

Summary The dry weight and total protein content of nuclei has been measured by interferometry in living or fixed cells cultivated in vitro (freshly prepared chick, mouse or rat embryo fibroblasts) and in fixed Ehrlich ascites tumor cells of the mouse growing in vivo. The DNA content was estimated by cytophotometry after Feulgen reaction in the same nuclei. The dry weight of nucleoli in fibroblasts and the dry weight and DNA content of chromosomes in dividing fibroblasts and Ehrlich tumor cells have also been measured.During the interphase in fibroblasts, the dry weight of the living nucleus and the nuclear total protein content as measured in fixed cells doubles during the preparation for mitosis, as the DNA content does. In chick and mammal fibroblasts and within the limits of accuracy of our measurements, the synthesis curves for nuclear proteins and DNA do not seem to be necessarily identical.In our fibroblasts, the nucleolar total dry weight per nucleus doubles during the interphase (nucleolar preparation for mitosis); it increases in proportion to the nuclear total protein content, even in polyploid nuclei.During the mitosis, the chromosomes contain all the DNA of the nucleus but some nuclear proteins (non chromosomal proteins) seem to move into the cytoplasm during the mitosis and return into the nucleus at the post-telophase.According to our observations, Ehrlich ascites mouse tumor cells are near-tetraploid as far as the number of chromosomes, nuclear total protein content and DNA content are concerned. During the preparation for mitosis, these amounts double but no necessary close time relation seems to link these premitotic syntheses. Prom this point of view, our results show no clear-cut differences between these tumor cells and the fibroblasts. Except the polyploidy, the behaviour of nuclear proteins and DNA during mitosis in the tumor cells is the same as that observed in our fibroblasts.The effects of various antimitotic agents on rat fibroblasts cultivated in vitro have also been studied with our cytochemical methods. Our measurements of nuclear protein, DNA and nucleolar material content have been made in cells in which mitosis was prevented by alkylating agents, beryllium sulphate, RNase or neutral DNase. The effects of colchicine on these cellular parameters have also been studied.     

S phase mouse embryo fibroblasts secrete varying amounts of a 45,000 dalton protein

Synchronized cultures of mouse embryo fibroblasts upon release from hydroxyurea (HOU) arrest, secreted several proteins of which a polypeptide of molecular weight 45,000 (45K) was barely visible in the conditioned medium of cells that synthesized DNA at peak levels. The quantity of the 45K protein was higher in the medium of HOU arrested cells and the level got progressively reduced as the cells entered into the DNA synthetic phase. Conditioned media containing the 45K protein inhibit DNA synthesis when added to synchronized cultures. These results suggest that the 45K secreted protein may be involved in the autocrine regulation of turning-off of DNA synthesis at the end of S phase.     

An adenovirus early region 1A protein is required for maximal viral DNA replication in growth-arrested human cells.

Two closely related adenovirus early region 1A proteins are expressed in transformed cells. The smaller of these, which is 243 amino acids in length, is required for the transformation of primary rat cells and for the transformation of immortalized rat cells to anchorage-independent growth. This protein is not required for productive infection of exponentially growing HeLa cells but is required for maximal replication in growth (G0)-arrested human lung fibroblasts (WI-38 cells). To determine the function of this protein in viral replication in these G0-arrested cells, we compared viral early mRNA, early protein, and late protein synthesis after infection with wild type or a mutant which does not express the protein. No differences were found. However, viral DNA synthesis by the mutant was delayed and decreased to 20 to 30% that of wild type in these cells. Viral DNA synthesis was much less defective in growing WI-38 cells, and in the transformed human HeLa cell line it occurred at wild-type levels. Furthermore, the mutant which can express only the 243-amino-acid early region 1A protein induced cellular DNA synthesis in G0-arrested rat cells to the same level as wild-type virus. A mutant which can express only the 289-amino-acid early region 1A protein induced less cellular DNA synthesis in G0-arrested rat cells. We propose that the early region 1A 243-amino-acid protein alters the physiology of arrested permissive cells to allow maximal viral DNA replication. In nonpermissive rodent cells, the 243-amino-acid protein drives G0-arrested cells into S phase. This activity is probably important for the immortalization of primary cells.     

Cellular and metabolic specificity in the interaction of adhesion proteins with collagen and with cells

Fibronectin mediates the adhesion of fibroblasts to collagen substrates, binding first to the collagen and then to the cells. We report here that the interaction of the cells with the fibronectin-collagen complex is blocked by specific gangliosides, GD_{1 a} and GT₁, and that the sugar moieties of these gangliosides contain the inhibitory activity. The gangliosides act by binding to fibronectin, suggesting that they may be the cell surface receptor for fibronectin. Evidence is presented that other adhesion proteins or mechanisms of attachment exist for chondrocytes, epidermal cells, and transformed tumorigenic cells, since adhesion of these cells is not stimulated by fibronectin. Chondrocytes adhere via a serum factor that is more temperature-sensitive and less basic than fibronectin. Unlike that of fibroblasts chondrocyte adhesion is stimulated by low levels of gangliosides. Epidermal cells adhere preferentially to type IV (basement membrane) collagen but at a much slower rate than fibroblasts or chondrocytes. This suggests that these epidermal cells synthesize their own specific adhesion factor. Metastatic cells cultured from the T241 fibrosarcoma adhere rapidly to type IV collagen in the absence of fibronectin and do not synthesize significant amounts of collagen or fibronectin. Their growth, in contrast to that of normal fibroblasts, is unaffected by a specific inhibitor of collagen synthesis. These data indicate the importance of specific collagens and adhesion proteins in the adhesion of certain cells and suggest that a reduction in the synthesis of collagen and of fibronectin is related to some of the abnormalities observed in transformed cells.     

Cellular functions are required for the synthesis and integration of avian sarcoma virus-specific DNA.

We have used two experimental strategies to test the role of cellular functions in the synthesis and integration of virus-specific DNA in cells infected by avian sarcoma virus.First, quail embryo fibroblasts, placed in stationary phase (G₀) by prolonged serum starvation, did not support the efficient synthesis of viral DNA during the first 24–48 hr after infection. Synthesis of viral DNA was impaired according to at least two parameters: the amount of DNA was diminished, particularly the amount of the plus-strand DNA (identical in polarity to the viral genome); and the length of both minus and plus strands was reduced in the stationary cells. In parallel cultures fed with fresh serum, over two thirds of the cells were able to reenter the cell cycle within 24 hr, and viral DNA of normal size was synthesized.Second, density labeling of viral and cellular DNA with BUdR was used to determine whether cellular DNA synthesis was required for integration of viral DNA. In both quail embryo fibroblasts released from G₀ by serum replacement and randomly growing duck embryo fibroblasts, viral DNA was integrated only into cellular DNA replicated during the infection.Our results indicate that serum-starved cells lack a factor (or factors) required for the efficient and complete synthesis of ASV-specific DNA. We have not been able to establish whether such factor(s) are present in growing cells only during S phase. Integration of viral DNA appears to require cellular DNA synthesis; this may be due to a requirement for a factor (or factors) present in adequate concentration only during S phase or to a requirement for the structural changes in cellular DNA that accompany replication.     

Biosynthesis and secretion of collagen in normal and SV-40 virus-transformed human embryonal fibroblasts

The biosynthesis and secretion of collagen proteins was studied in cultures of normal human embryo fibroblasts at different passages and growth stages as well as in cultures of human embryo fibroblasts transformed by oncogenic virus SV-40. It was found that normal fibroblasts maintain at a constant level the collagen synthesis throughout 20 passages, which is typical of proliferating and resting cells. Virus-transformed cells produce 3-4 times less collagen proteins on a per cell count. Normal and transformed fibroblasts do not differ in terms of total protein synthesis. Secretion of collagen and non-collagen proteins in transformed cell cultures appeared to be much lower than in normal cell cultures. Study of synthesized proteins by polyacrylamide gel electrophoresis showed that both types of cells secrete collagen proteins predominantly as polymers containing interchain S-S bonds of 3-helix molecules. Study of the protein-synthesizing activity of two polysomal fractions, i.e. membrane bound and free polysomes, isolated from the cells of both types in a cell-free system showed that membrane-bound polysomes from transformed fibroblasts synthesize collagen much less actively in comparison with normal cells. However, in transformed cells free polysomes, in contrast with normal cells, are active participants of a cell-free collagen protein synthesis.     

Differences in Turnover Rates of Vinculin and Talin Caused by Viral Transformation and Cell Density

Vinculin and talin are two major components of focal contacts which interact with each other. In order to understand how the relative levels of these proteins are maintained under various conditions, the synthesis rates and half-lives of vinculin and talin in chick embryonic fibroblasts were determined by autoradiography combined with immunoblotting. High cell density and transformation by Rous sarcoma virus decreased the vinculin synthesis rate by 40%. Upon viral transformation, the synthesis rate of talin decreased by 30%. In contrast to vinculin, the synthesis rate of talin was not affected by cell density. The effect of cell density on the synthesis rate of vinculin was retained after viral transformation, suggesting that cell density and viral transformation affect vinculin synthesis by two independent mechanisms. The synthesis rate of vinculin was approximately two to three times greater than that of talin under all conditions tested. The half-lives of vinculin and talin remained constant at different cell densities in untransformed cells (t_1/2= 18–21 h), but transformation slightly decreased half-lives of both proteins (t_1/2= 16–18 h). These results suggest that the decreased expression of vinculin and talin in transformed chick fibroblasts can be attributed mainly to changes in their biosynthesis rates rather than degradation. This may contribute to a decrease in the number of focal contacts in transformed cells.     

Transformed cells have lost control of ribosome number through their growth cycle.

Previous studies on the synthesis and function of the protein synthetic machinery through the growth cycle of normal cultured hamster embryo fibroblasts (HA) were extended here to a series of four different clonal lines of polyoma virus-transformed HA cells. Under our culture conditions, these transformed cells could enter a stationary phase characterized by no mitotic cells, very low rates of DNA synthesis, and arrest in a post-mitotic pre-DNA synthetic state. Cellular viability was initially high in stationary phase but, unlike normal cells, transformed cells slowly lost viability. The rate of protein synthesis in the stationary phase of the transformed cells fell to 25-30% of the exponential rate. Though this reduction was similar to that seen in normal cells, it was accomplished by different means. The specific reduction in the ribosome complement per cell to values below that of any cycling cell seen in normal cells, was not seen in any of the transformed lines. This observation, which implies a loss of normal control of ribisome synthesis through the growth cycle after transformation, was confirmed in normal Chinese hamster embryo fibroblasts and transformed CHO cell lines. Normal control of ribosome synthesis was restored in L-73 and LR-73, growth control revertants of one of the transformed CHO lines. The transformed lines reduced their protein synthetic rates in stationary phase either by a greater reduction in the proportion of functioning ribosomes than that seen in normal cells or by a decrease in the elongation rate of functioning ribosomes; the latter effect was not seen in the normal cells. A model for growth control of normal cells and its derangement in transformed cells is presented.     

Sequence of activation of template biosynthesis in normal and transformed human cells after synchronization by a double thymidine block

The sequence of matrix biosyntheses of DNA, RNA and various proteins in normal and transformed human fibroblasts in the first mitotic cycle after synchronization of cells by double thymidine block was studied. Two important regularities of synthesis of acid-soluble histone-like and acid-insoluble proteins in normal and transformed cells were established. In normal fibroblasts, the synthesis of both acid-soluble and acid-insoluble proteins is minimal before DNA replication and maximal in the G2-phase; that in transformed cells is maximal after removal of the thymidine block and decreased in the G2-phase. In normal fibroblasts, the synthesis of acid-insoluble proteins is maximal before, while that of acid-soluble ones--after the maximum of DNA synthesis. In transformed cells the situation is opposite. RNA synthesis in normal and transformed cells is stimulated at the end of the G2-phase. In normal cells, protein synthesis is coupled with the activation of RNA synthesis, whereas in transformed fibroblasts protein synthesis occurs, in all probability, in the next mitotic cycle. These differences are especially well-pronounced in the expression of some LMG proteins. It is concluded that in transformed cells the regulatory control over the coupling of matrix biosyntheses is impaired.     

Effect of dimethyl sulfoxide on mouse embryo fibroblasts: inhibition of plasminogen activator inhibitor deposition and interference with early events of serum-stimulated growth

Quiescent and serum-stimulated cultures of Swiss mouse embryo fibroblasts (MEF) showed alterations in cell morphology including an enlargement in size upon treatment with 2% dimethyl sulfoxide (DMSO). Treatment of MEF and monkey kidney epithelial cells (MK2) with 2% DMSO at the early periods of serum-stimulated growth inhibited RNA, protein and DNA synthesis. DMSO treatment of cells at late stages of serum-stimulated growth (MEF after 1 hr and MK2 cells after 3 hr of stimulation) had little effect on DNA and protein synthesis although cell enlargement occurred in these cells. When the [35S]methionine labelled proteins of the control and the DMSO treated cells were analysed by high resolution polyacrylamide gel electrophoresis, no apparent difference was observed in the pattern of intracellular proteins of these cells. In contrast, the extracellular levels of two serum-induced secreted proteins of MEF (Mr 48,000 and 26,000) were dramatically reduced by DMSO treatment. The DMSO sensitive 48 kDa protein was found to be the major component of the extracellular matrix, while the 26 kDa protein was not. The 48 kDa protein was identified as plasminogen activator inhibitor (PAI-1). Densitometric quantitation showed a gradual accumulation of this protein in the matrix of serum-stimulated cells. The deposition of this protein in the matrix was inhibited by DMSO. Flow-cytometric quantitation of indirect immunofluorescence indicated higher intracellular levels of the 48 kDa protein in fetal calf serum (FCS) + DMSO treated cells, suggesting that the low level of this protein in the medium of DMSO treated cells is probably due to lack of transport of this protein from the cells into the medium.     

Lack of a correlation between polyamine synthesis and DNA synthesis by cultured rat liver cells and fibroblasts

Growth stimulation of either fetal rat liver cells or rat embryo fibroblasts in culture results in considerable increases in intracellular polyamine levels as cells proceed through the cell cycle. Treatment of such cell cultures with appropriate levels of two inhibitors of polyamine synthesis, namely α-hydrazino ornithine and methylglyoxal bis(guanylhydrazone), can essentially completely block these increases in cellular polyamine content. Under such conditions, where the elevation in intracellular polyamine content is prevented, cell cultures are nevertheless able to initiate DNA synthesis and subsequently synthesize DNA at rates comparable to untreated control cultures that have been growth-stimulated. These two cell types therefore contain sufficient polyamines when in a resting state (G₁) to enable them to enter from G₁ into S phase and traverse S phase at normal rates in the absence of further polyamine synthesis. The recruitment of cells into the first cell cycle, through serum stimulation of growth, therefore appears not to be mediated or regulated by the increases in intracellular levels of polyamines that occurs under these conditions. Conversely, the arrest of growth of these cell types resulting from serum deprivation is not mediated by a limitation of intracellular polyamine content.     

CELL SPECIFICITY OF CHALONE-TYPE INHIBITORS OF DNA SYNTHESIS RELEASED BY BLOOD LEUCOCYTES AND ERYTHROCYTES

Inhibitors of DNA synthesis released into balanced salt solution by rat erythrocytes and by rat leucocytes have been found to possess target-cell-specific properties which would be expected of chalones. When assayed in short-term in vitro cultures the erythrocyte product reduced DNA synthesis (as measured autoradiographically) in erythroblasts present in populations of bone-marrow cells but did not affect the DNA synthesis in myeloid or lymphoid cells. The leucocyte product, under the same culture conditions, reduced DNA synthesis in leucocyte precursor cells. The grain counts over nuclei of different cell types were recorded as well as the DNA labelling index. Results so far obtained cannot ascribe the erythrocyte-chalone-produced reduction in labelling index to a blockage of entry into S phase. This cell-specific inhibitor may reduce continuing DNA synthesis in S phase cells to undetectable levels, compared with synthesis in control media. The leucocyte product, however, most probably prevents entry of leucocyte precursor cells into S phase. Possible relevance of these inhibitors as components of physiological control mechanisms or as therapeutic agents is discussed.     

Opposite and selective effects of epidermal growth factor and human platelet transforming growth factor-beta on the production of secreted proteins by murine 3T3 cells and human fibroblasts

Growth regulators such as epidermal growth factor (EGF) and type beta transforming growth factor (TGF-beta) regulate the synthesis and secretion of certain proteins by cells in culture. The secretion pattern of each cell line and the effect of growth regulators on the secretion pattern are unique. EGF increased the secreted and intracellular levels of mitogen-regulated protein (MRP) and major excreted protein (MEP) by Swiss 3T3 cells. MRP is related by sequence to prolactin. MEP is a thiol protease located intracellularly in the lysosomes. EGF also selectively induced a 52,000-dalton mitogen-induced protein (MIP 52) secreted by human fibroblasts. Two types of TGF-betas were tested for their effects on the expression of secreted proteins in mouse and human fibroblasts: TGF-beta from human platelets and a growth inhibitor (GI/TGF-beta) secreted by BSC-1 cells. Each selectively decreased the levels of the two secreted proteins induced by growth factors in mouse embryo 3T3 cells and one secreted protein induced by growth factors in human fibroblasts. Platelet TGF-beta and GI/TGF-beta also induced one 48,000-dalton protein secreted by human fibroblasts. Synthesis of DNA and the incorporation of [35S]methionine into total protein in Swiss 3T3 cells were not affected by platelet TGF-beta or GI/TGF-beta. Thus, the inhibitory effect of platelet TGF-beta on the synthesis and secretion of these three proteins is due to a specific effect of platelet TGF-beta on the regulation of MRP and MEP that does not interfere with the ability of EGF to stimulate DNA or protein synthesis.     

Effects of factors derived from a tumor clonal cell line on DNA synthesis of transformed and non transformed cells

Conditioned medium from neoplastic thyroid cell cultures, extracts of tumors developed by identical cells in isogeneic Fisher 344 rats and serum from those tumor-bearing animals, were tested in pulse thymidine labelled experiments on a transformed and two non transformed cell lines. Tumor extract and conditioned medium inhibited DNA synthesis. Tumor-bearing rat serum increased DNA synthesis in a cerebellar transformed cell line, but no in chick embryo fibroblasts or in aorta non transformed cells.     

Regulation of polyamine biosynthesis in normal and transformed hamster cells in culture

Several aspects of polyamine biosynthesis were compared in low-passage hamster embryo fibroblasts and transformed hamster fibroblasts. Earlier studies had demonstrated a larger and longer-lasting induction of ornithine decarboxylase activity in transformed cells than in hamster embryo fibroblasts. The increases in intracellular polyamine concentrations after serum stimulation were much greater in chemically transformed HE68BP cells than in normal hamster fibroblasts. Treatment of confluent cultures with the tumor promoter, 12-O-tetradecanoylphorbol-13-acetate, greatly potentiated ornithine decarboxylase induction by fresh medium in HE68BP cells, but not in hamster fibroblasts. A similar synergistic effect was observed when transformed cells, but not normal cells, were treated with the combination of insulin and promoter. HE68BP cells were capable of growth in medium containing serum concentrations as low as 0.5%, whereas only concentrations of 5% or more supported the growth of hamster embryo fibroblasts. Low serum concentrations induced ornithine decarboxylase in HE68BP cells but not in normal cells, and a given serum concentration always produced a greater induction of ornithine decarboxylase in transformed than in normal cells.Another enzyme involved in polyamine synthesis, $\text{S-}\text{adenosyl-}\text{L}\text{-methionine}$ decarboxylase was induced in normal and transformed cells by serum-containing medium or tetradecanoylphorbol acetate, but in contrast to ornithine decarboxylase, no synergistic effect was seen in transformed cells exposed to the combination of fresh medium and the tumor promoter. A macromolecular inhibitor of ornithine decarboxylase was readily detected in hamster fibroblast cultures treated with high concentrations of putrescine, but little or none of this inhibitor was found in HE68BP cultures. In both cell types, however, serum induction of ornithine decarboxylase was inhibited under conditions of excess putrescine.The results demonstrate several differences between normal and transformed hamster cells in the regulation of polyamine synthesis.     

Immortalized phenotype and the presence of active oncogenes correlate with the capacity of culture cells to induce reactivation of DNA synthesis in macrophage nuclei in heterokaryons

Several types of culture cells with limited life span (rat embryo fibroblasts, rat chondrocytes and mouse premacrophages) were found to be unable to induce the reactivation of DNA synthesis in the nuclei of non-dividing differentiated cells (mouse peritoneal resident macrophages) in heterokaryons. By contrast, malignant HeLa cells have this ability. In heterokaryons formed by fusion of mouse macrophages with HE239 cells (Syrian hamster fibroblasts transformed with a ts mutant of the SV40 virus), DNA synthesis in macrophage nuclei is reactivated only at the permissive temperature (33° C), at which viral T antigen is stable. Immortalization of rat chondrocytes by transfection with p53 gene enables to induce DNA synthesis in macrophage nuclei upon fusion. All the evidence indicates that the function of immortalizing oncogenes is necessary for the resumption of the DNA synthesis in macrophage nuclei in heterokaryons.     

Mammalian cells do not have a stringent response

A key attribute of the stringent response of bacteria is the rapid inhibition of ribosomal RNA synthesis mediated by unusual nucleotides in response to uncharged tRNA. The question as to whether mammalian cells show a stringent response analogous to that of bacteria was critically tested by the effective rapid amino acid starvation of both normal and transformed cells. Rapid starvation giving a high proportion of uncharged tRNA for leucine was produced within 7 minutes of expression of a nonleaky ts leucyl tRNA synthetase mutation in transformed CHO cells (tsH1) and in its normal growth control revertant (L-73). To control for the effect of temperature alone, tsrevertants of tsH1 and L-73 were included in the study, and to control for effects due simply to the inhibition of protein synthesis, the translational elongation inhibitor cycloheximide was used. In addition, rapid starvation for histidine was effected by incubation of both the CHO cell lines and of freshly explanted normal Chinese hamster embryo fibroblasts in histidine-free medium containing high concentrations of histidinol. The rate of preribosomal RNA synthesis and the extent of its maturation to mature rRNA was measured using (³H-methyl) methionine as a donor of methyl groups during synthesis and methylation of pre-rRNA. There was no effect on pre-rRNA synthesis of the rapid generation of uncharged tRNA for 45 minutes for any of the cell types tested. A nonspecific inhibition of maturation of 18S rRNA and late (3 hour) inhibition of pre-rRNA synthesis was observed, but could be mimicked by the inhibition of protein synthesis to comparable levels with cycloheximide. Less severe amino acid starvation resulting in a more physiological inhibition of protein synthesis to 30% also had no specific effect on pre-rRNA synthesis and maturation. Intracellular nucleotide pools were also examined for the appearance of unusual nucleotides such as guanosine tetraphosphate or pentaphosphate and for changes in the levels of normal nucleotides after severe amino acid starvation. No such changes could be detected. We conclude that although mammalian cells may have some biochemical reactions which respond to uncharged tRNA, they do not possess a macromolecular control system analogous to the stringent response of bacteria.