Studies on differentiation without cleavage in Chaetopterus variopedatus: requirements for nucleic acid and protein synthesis

Activation of unfertilized Chaetopterus eggs by treatment with an excess of KCl may lead to the production of unicellular ciliated larvae (Lillie's differentiation without cleavage). The effects of a number of inhibitors of protein (puromycin, cycloheximide, emetin), RNA (actinomycin D), and DNA (hydroxyurea) synthesis of differentiation without cleavage and on normal development have been studied in Chaetopterus. Incorporation of radioactive leucine, uridine, and thymine has been followed by biochemical methods and by autoradiography. The DNA content of the large polyploid nucleus has been estimated by cytophotometry. The initial pseudocleavage period of differentiation without cleavage is characterized by a burst in DNA and protein synthesis; the inhibitors have little or no effect on this burst and on pseudocleavage itself. Protein and DNA synthesis levels off during the following phase (segregation), but the inhibitors become more effective. RNA synthesis is almost linear for 20 h. These results are compared with those obtained on eggs from other species.     

Studies on Differentiation Without Cleavage in Chaetopterus variopedatus

Activation of unfertilized Chaetopterus eggs by treatment with an excess of KCl may lead to the production of unicellular ciliated larvae (Lillie's differentiation without cleavage). The effects of a number of inhibitors of protein (puromycin, cycloheximide, emetin), RNA (actinomycin D), and DNA (hydroxyurea) synthesis on differentiation without cleavage and on normal development have been studied in Chaetopterus . Incorporation of radioactive leucine, uridine, and thymine has been followed by biochemical methods and by autoradiography. The DNA content of the large polyploid nucleus has been estimated by cytophotometry. The initial pseudocleavage period of differentiation without cleavage is characterized by a burst in DNA and protein synthesis; the inhibitors have little or no effect on this burst and on pseudocleavage itself. Protein and DNA synthesis levels off during the following phase (segregation), but the inhibitors become more effective. RNA synthesis is almost linear for 20 h. These results are compared with those obtained on eggs from other species.     

Diurnal variations in endogenous RNA polymerase activity and amounts of nuclear non-histone protein,DNA and cytoplasmic protein in rat liver

Summary From rats fed ad libitum and kept under a 12+12 h light/dark regimen, the DNA dependent RNA polymerase activity of liver cell nuclei was determined every four hours. From identical rats, nuclear non-histone protein and DNA, and cytoplasmic protein was determined by Feulgen-Naphtol Yellow S cytophotometry of isolated liver cells. The minimum: maximum ratio of the RNA polymerase activity is 0.77; the min:max ratio of nuclear non-histone protein is 0.84. These two parameters have identical time courses with a gradual decline during the light period and a sharp rise after the onset of the dark period. The variations in nuclear DNA content, estimated as the amount of Feulgen stain bound, closely parallel those of the RNA polymerase activity and nuclear non-histone protein content (min:max=0.96). The amount of cytoplasmic protein per cell also varies throughout the day, but its time curve lags behind those of nuclear nonhistone content and RNA polymerase activity. These results are consistent with the concept of nuclear non-histone proteins as de-repressors of the DNA template in differentiated, non-proliferating cells, and support the validity of using Feulgen-Naphthol Yellow S cytophotometry of nuclear non-histone proteins as an estimate of gene expression in such cells.     

Diurnal variations in endogenous RNA polymerase activity and amounts of nuclear non-histone protein, DNA and cytoplasmic protein in rat liver.

From rats fed ad libitum and kept under a 12 + 12 h light/dark regimen, the DNA dependent RNA polymerase activity of liver cell nuclei was determined avery four hours. From identical rats, nuclear non-histone protein and DNA, and cytoplasmic protein was determined by Feulgen-Naphthol Yellow S cytophotometry of isolated liver cells. The minimum: maximum ratio of the RNA polymerase activity is 0.77; the min:max ratio of nuclear non-histone protein is 0.84. These two parameters have identical time courses with a gradual decline during the light period and a sharp rise after the onset of the dark period. The variations in nuclear DNA content, estimated as the amount of Feulgen stain bound, closely parallel those of the RNA polymerase activity and nuclear non-histone protein content (min:max = 0.96). The amount of cytoplasmic protein per cell also varies throughout the day, but its time curve lags behind those of nuclear non-histone content and RNA polymerase activity. These results are consistent with the concept of nuclear non-histone proteins as de-repressors of the DNA template in differentiated, non-proliferating cells, and support the validity of using Feulgen-Naphthol Yellow S cytophotometry of nuclear non-histone proteins as an estimate of gene expression in such cells.     

The effect of saffron on intracellular DNA, RNA and protein synthesis in malignant and non-malignant human cells.

Extract of saffron (Crocus sativis) has previously been shown to inhibit colony formation and cellular DNA and RNA synthesis by HeLa cells in vitro. In order to compare the sensitivity of malignant and non-malignant cells to saffron, we examined the effect of the extract on macromolecular synthesis in three human cell lines: A549 cells (derived from a lung tumor), WI-38 cells (normal lung fibroblasts) and VA-13 cells (WI-38 cells transformed in vitro by SV40 tumor virus). We found that the malignant cells were more sensitive than the normal cells to the inhibitory effects of saffron on both DNA and RNA synthesis. There was no effect on protein synthesis in any of the cells.     

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.     

The role of increased proteolysis in the atrophy and arrest of proliferation in serum-deprived fibroblasts

When cultured fibroblasts are deprived of serum, the degradation of long-lived proteins and RNA increases, the cells stop proliferating, and they decrease in size. To determine the role of the increased protein catabolism in these responses, we studied the effects of inhibitors of intralysosomal proteolysis in Balb/c 3T3 cells. When these cells were placed in serum-deficient medium (0.5% serum), the rate of degradation of long-lived proteins increased about twofold within 30 min. This increase was reduced by 50-70% with inhibitors of lysosomal thiol proteases (Ep475 and leupeptin) or agents that raise intralysosomal pH (chloroquine and NH4Cl). By contrast, these compounds had little or no effect on protein degradation in cells growing in 10% serum. Thus, in accord with prior studies, lysosomes appear to be the site of the increased proteolysis after serum deprivation. When 3T3 cells were deprived of serum for 24-48 hours, the rate of protein synthesis and the content of protein and RNA and cell volume decreased two- to fourfold. The protease inhibitor, Ep475, reduced this decrease in the rate of protein synthesis and the loss of cell protein and RNA. Cells deprived of serum and treated with Ep475 for 24-48 hours had about twice the rate of protein synthesis and two- to fourfold higher levels of protein and RNA than control cells deprived of serum. The Ep475-treated cells were also about 30% larger than the untreated cells. Thus, the protease-inhibitor prevented much of the atrophy induced by serum deprivation. The serum-deprived fibroblasts also stopped proliferating and accumulated in the G1 phase of the cell cycle. The cells treated with Ep475 accumulated in G1 in a manner identical to untreated serum-deprived cells. Other agents which inhibited protein breakdown in serum-deprived cells also did not prevent the arrest of cell proliferation. Thus the enhancement of proteolysis during serum deprivation appears necessary for the decrease in size and protein synthesis, but probably not for the cessation of cell proliferation. When cells deprived of serum in the presence or absence of Ep475 were stimulated to proliferate by the readdition of serum, the larger Ep475-treated cells began DNA synthesis 1-2 hours later than the smaller untreated cells. Thus, after treatment with Ep475, the rate of cell cycle transit following serum stimulation was not proportional to the cell's size, protein, or RNA content, or rate of protein synthesis.     

Cell division and nucleolar ribonucleic acid synthesis in synchronous cultures

Summary Nucleolar RNA synthesis is inhibited and cell division delayed in synchronous cultures of mouse fibroblasts (strain L-929) treated with actinomycin D (0.04 μg per ml). The gradual loss of actinomycin D from the cells during a 2-hr period following incubation is accompanied by an increase in the rate of nucleolar RNA synthesis to the control level. Following this the rate of protein synthesis is decreased by 25% for approximately 9 hr. The length of time that nucleolar RNA and protein synthesis are inhibited accounts for the delay in mitosis 1 1/2 cell cycles later. These data support the contention that certain proteins produced during one interphase are prerequisite for division in a subsequent cycle.     

Cell division and nucleolar ribonucleic acid synthesis in synchronous cultures

Summary Nucleolar RNA synthesis is inhibited and cell division delayed in synchronous cultures of mouse fibroblasts (strain L-929) treated with actinomycin D(0.04 μ per ml). The gradual loss of actinomycin D from the cells during a 2-hr period following incubation is accompanied by an increased in the rate of nucleolar RNA synthesis to the control level. Following this the rate of protein synthesis is decreased by 25% for approximately 9 hr. The length of time that nucleolar RNA and protein synthesis are inhibited accounts for the delay in mitosis 1 1/2 cell cycles later. These data support the contention that certain proteins produced during one interphase are prerequisite for division in a subsequent cycle.     

Effects of inhalation anesthetics halothane, sevoflurane, and isoflurane on human cell lines

Cytotoxic and antiproliferative effects of halothane, isoflurane, and sevoflurane in anesthetic doses on human colon carcinoma (Caco-2), larynx carcinoma (HEp-2), pancreatic carcinoma cells (MIA PaCa-2), poorly differentiated cells from lymph node metastasis of colon carcinoma (SW-620), and normal fibroblasts were investigated. Cells were exposed to anesthetic gas mixture consisting of O(2): N2O (35:60 vol.%), halothane (1.5 vol.%) or isoflurane (2.0 vol.%) or sevoflurane (3.0 vol.%), and CO(2) (5 vol.%), for 2, 4, and 6 h. Cytotoxicity of anesthetics was analyzed by validated tetrazolium dye assay MTT test. All anesthetics expressed cytotoxic effects on treated tumor cells in time and cell line dependent manner. Growth suppression in cells exposed to halothane was enhanced in HEp-2 (to 67.7%), Caco-2 (to 76.3%), and SW620 cells (to 80.9%), and was minimal in normal fibroblasts (to 89.4%). Antiproliferative activity of halothane was measured via radioactive precursors incorporation assay. In Caco-2 cells treated by halothane, decrease in DNA synthesis (52.4%, p=0.001), RNA synthesis (39.2%, p<0.001), and protein synthesis (19.2%, p=0.004) was observed. In HEp-2 cells, DNA and RNA syntheses were decreased to 72.5% and 79.9%, whereas protein synthesis was 14.0% of control (p<0.001). In SW620 cells, protein synthesis after 4 h was 24.4% (p=0.007). A DNA fragmentation was observed in Caco-2 and MIA PaCa-2 cells. Exposition of phosphatidylserine on outer lipid bilayer plasma membrane of tumor cell treated by halothane proved apoptosis as mode of cell death.     

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.     

A potent DNA synthesis inhibitor expressed by the immortal cell line SUSM-1

We have previously reported the production of DNA synthesis inhibitor proteins by both quiescent and senescent human diploid fibroblasts. Young, proliferating fibroblasts do not produce such inhibitors, but are capable of responding to either the quiescent or senescent cell DNA synthesis inhibitors. Recently, we have analyzed the immortal cell line SUSM-1 (derived from normal liver fibroblasts following exposure to carcinogen) for inhibitory activity. We have found that SUSM-1 cells produce a factor capable of inhibiting DNA synthesis in young fibroblasts. Crude extracts prepared from SUSM-1 cells inhibit DNA synthesis in a dose-dependent manner at concentrations 10-fold lower than those of either senescent or quiescent fibroblast cell extracts. SUSM-1 cells are incapable of responding to the inhibitor they produce, as are three other immortal human cell lines tested. One immortal cell line, HeLa, does respond to the SUSM-1 inhibitor, though to a lesser degree than observed with normal young fibroblasts. One hypothesis is that the DNA synthesis inhibitor protein(s) of senescent cells plays a role in determining the finite in vitro life span of normal cells. The results reported here suggest that SUSM-1 cells may have escaped senescence through loss of a receptor or cofactor for the inhibitor protein(s).     

MACROMOLECULAR SYNTHESES RELATED TO THE REPRODUCTIVE CYST OF TETRAHYMENA PATULA

Macromolecular syntheses in encysted Tetrahymena patula were studied using Feulgen fluorescence cytophotometry, autoradiography, and inhibitors of RNA and protein synthesis. Cycloheximide significantly depressed protein synthesis and D-actinomycin effectively blocked RNA synthesis. Under these conditions, the cells within the cyst were unable to divide. Both cytophotometric measurements and autoradiographic data with tritiated thymidine show that DNA synthesis does not occur during the encystment divisions. Excysted cells placed in nutrient broth medium showed a prolonged generation time after the first cell growth cycle, and by the third generation the mean DNA content per cell was almost triple that of starved excysted cells. These findings indicate that (a) the encystment divisions require RNA and protein synthesis, which are apparently effected through turnover, (b) the encystment division cycles occur in the absence of DNA synthesis, and (c) excysted cells placed in culture medium may go through more than one DNA replication per cell cycle.     

Regulation of the G1 leads to S phase transition in chick embryo fibroblasts with alpha-keto acids and L-alanine.

Temporal inhibition of protein synthesis with cycloheximide prevents subsequent insulin, but not serum-stimulated DNA synthesis in G1-arrested chick embryo fibroblasts (CEF). The inhibition is measured by the incorporation of 3H-thymidine into acid insoluble material and confirmed by chemical estimate of the DNA content of inhibited and uninhibited cells. Cycloheximide treatment is without effect if the cell cultures are maintained at 4 degrees C while exposed to the drug. Several alpha-keto acids (pyruvate, oxaloacetate, alpha-ketobutyrate) at 0.5-1 mM concentrations restore DNA synthesis in previously inhibited cells when combined with insulin. L-alanine (D-alanine is inert) is even more effective than the keto acids in stimulating DNA synthesis after cycloheximide treatment. Glucose transport was unaffected by cycloheximide treatment while lactate levels in medium from inhibited, insulin-stimulated CEF were reduced 70% compared to uninhibited counterparts. We speculate that cycloheximide treatment may lead to the decay of a glycolytic enzyme which compromises the ability of inhibited cells to synthesize pyruvate from glucose, and thus induces an exogenous requirement for alpha-keto acid or L-alanine. A serum component(s) with a molecular weight of about 100 permitted insulin-stimulated DNA synthesis in inhibited cells.     

Correlation between cell enlargement and nucleic acid and protein content of HeLa cells in unbalanced growth produced by inhibitors of DNA synthesis

HeLa cells in monolayer cultures were treated with the following inhibitors of DNA synthesis: mitomycin C, nitrogen mustard, fluorodeoxyuridine, hydroxyurea, arabinofuranosylcytosine and high concentrations of thymidine. The concentration of each inhibitor used was, in most cases, just sufficient to arrest cell multiplication and all produced unbalanced growth in the sense that the synthesis of RNA and protein were only partially inhibited while DNA synthesis stopped. This resulted in approximately 100% increases in RNA and protein content per cell in 48 hours and, since cell volume also increased by 100% during this time, the concentration of RNA and protein per unit cell volume remained constant. It was concluded that cell protein content may be used as an accurate index of variation in cell size in HeLa cells treated with inhibitors of DNA synthesis.     

Studies on the mode of action of a bacteriocin produced by Bacillus stearothermophilus

Thermocin 10 was purified by elution from a carboxymethyl cellulose column. The eluted thermocin was homogeneous and yielded single bands with identical relative mobility when stained for protein or glycoprotein. Thermocin 10 inhibited RNA synthesis 3 min after its addition. Cell motility, oxygen uptake, ATP synthesis, and DNA synthesis were inhibited 10 min after the addition of thermocin 10. Total cell protein was reduced to one quarter of its normal content in cells treated with thermocin.     

Effect of a medium with a low serum content on protein synthesis and secretion and RNA and DNA synthesis in a skin fibroblast culture from patients with rheumatoid arthritis and systemic scleroderma

Synthesis and secretion of protein, as well as synthesis of RNA and DNA by skin fibroblasts of patients with systemic sclerodermia (SSD) and rheumatoid arthritis (RA) upon prolonged culturing of fibroblasts in the medium with low (0.5-1%) serum content differ markedly in their direction and intensity from protein, RNA and DNA synthesis by skin fibroblasts of healthy donors (HD) and by fetal fibroblasts. It has been found that skin fibroblasts of patients with RA and SSD, as well as those of HD, secrete 75-80% of protein synthesized by fibroblasts de novo upon their culturing in DMEM medium with 1% human serum. Under the same conditions, on days 2-5 of culturing, RNA synthesis in the fibroblasts of patients with RA and SSD was increased 3-4-fold, while DNA synthesis was increased 2-3-fold. Collagenolytic and caseinolytic activity in the culture medium of skin fibroblasts from HD and patients with RA reached maximal levels on days 3-5. High protein secretion was observed in DMEM serum-free medium in the presence of vitamin mixture upon culturing skin fibroblasts of patients with SSD. The results obtained show that skin fibroblasts from HD differ in their functional activity from those of patients with rheumatic disorders. It might be suggested, therefore, that the mechanism of protein secretion plays an important role in the maintenance of constant intracellular protein levels in resting cells.     

Tritium-arrested human diploid fibroblasts maintain balanced RNA and protein metabolism

Incorporation of ³H precursors into the protein or RNA of exponentially growing human diploid fibroblasts (WI38) inhibited DNA synthesis and cell division for a dose-related period. During this period of “tritium-arrest”, which can last for at least a month, the cells remain viable by morphologic criteria and maintain balanced RNA and protein metabolism. The cultures are eventually overgrown by a dose-related fraction of the population which retains DNA synthetic capacity. Tritium-arrested cell populations are suggested as a possible model for the study of metabolism in non-dividing cells.     

Reversible inhibition of nucleolar function in fibroblasts treated in vitro with adriamycin]

In chick embryo fibroblasts treated in vitro with adriamycin, the mitotic activity is strongly depressed, the nucleoli are altered, nucleolar RNA synthesis is inhibited and the RNA content is lowered. These effects can be concomitantly and spontaneously reversible, but the mitotic activity does not resume.     

Differences in inhibition by IDF45 (an inhibitory diffusible factor) of early RNA synthesis stimulation induced by pp60 v-src and various mitogens.

Factors inhibiting cell growth have been isolated from different cell types. However, little information is available concerning their mode of action. A novel growth inhibitory factor of 45 kDa (IDF45) was recently purified to homogeneity from medium conditioned by 3T3 cells. This molecule was able to inhibit DNA synthesis and the growth of chick embryo fibroblasts (CEF) in a reversible manner. By contrast, DNA synthesis stimulated by v-src expression in CEF was poorly inhibited by IDF45. In order to gain further insight into the IDF45 mode of action in normal and transformed CEF, we compared the effects of IDF45 on early stimulation of RNA synthesis induced in CEF by different mitogenic factors and by v-src gene expression. Stimulation, by serum, of RNA synthesis was inhibited by IDF45; however, inhibition increased when cells were preincubated with IDF45 before addition of serum and cell labeling for 2 h. IDF45 was also able to inhibit partially the stimulation of RNA synthesis induced by PMA and PDGF but was unable to inhibit stimulation of RNA synthesis induced by insulin and v-src expression. By contrast, stimulation of RNA synthesis induced by IGF-I was rapidly 100% inhibited by IDF45. The effect of IDF45 on DNA synthesis stimulated by the different mitogens was also determined and was correlated with the effect of IDF45 on RNA synthesis. These results suggest that the modes of action of IDF45 on stimulation of RNA synthesis by v-src and by insulin are similar. Our present results agree with others showing the bifunctional activity of IDF45 as an IGF-binding protein and as an inhibitory molecule in DNA stimulation induced by serum.