Role of RNA and protein synthesis and turnover in the heat-induced increase in nuclear protein

The proteins which become associated with nuclei during hyperthermic exposure were characterized by labeled amino acid incorporation. Actinomycin-D (Act-D) or cycloheximide (CHM) pretreatment was used to determine whether concurrent RNA or protein synthesis is required for hyperthermia to induce the increase in nuclear protein content. Prior to heat exposure exponentially growing HeLa cells were (i) pulse labeled for 1 h, (ii) labeled for 36 h, or (iii) labeled for 24 h followed by 17 h chase. The nuclear specific activity (CPM/microgram protein) of [3H]lysine-labeled proteins did not change under any of the labeling conditions, whereas that of [3H]leucine-containing proteins increased significantly with (i) but not with (ii) or (iii), while that of [3H]tryptophan-labeled protein increased significantly with (i) and (ii) but not with (iii). Act-D treatment 1 h prior to and during heating did not affect nuclear protein increase, while CHM-treated cells showed generally less nuclear protein content (70% of control at 60 min) but nevertheless significant nuclear protein increase upon heating (60% increase at 60 min from 0 min). These results suggest that those proteins associated with nuclei following heat exposure are nonhistones with a high turnover rate, and the process dose not require the synthesis of RNA or proteins.     

Effect of Inactivation by Hydroxylamine on Early Functions of Poliovirus

Evidence is presented that poliovirus particles with a single lethal hit by hydroxylamine do not induce in host cells either inhibition of cellular protein synthesis or viral ribonucleic acid (RNA) replication. The RNA of these viruses is not replicated even if the cells are simultaneously infected with both active and inactivated viruses. The damaged viral RNA seems to have lost both its template function and its function in the translation of normal viral proteins.     

PROTEIN and RNA SYNTHESES and PRECURSOR UPTAKE WITH ISOLATED NERVE and GLIAL CELLS

Protein and RNA syntheses were investigated with bulk isolated nerve and glial cells from rabbit brain. For polypeptide synthesis, ‘intact’ cells were incubated with [³H]leucine under various conditions and the results were compared with those of polyribosomal polypeptide synthesis. For RNA synthesis ‘intact’ cells were incubated with [³H]uridine or [³H]guanosine and the results were compared with those of DNA-dependent RNA polymerase assay. The bulk isolated ‘intact’ nerve cells were more active in protein synthesis than the ‘intact’ glial cells, while the latter synthesized RNA more actively than the former, although both polyribosomal polypeptide synthesis and DNA-dependent RNA polymerase activity were higher with the nerve cells, indicating a higher potential for the nerve cells. The observed discrepancy of RNA synthesis was explained by the significantly less active uptake of nucleosides with the nerve cells. Both protein and RNA syntheses with ‘intact’ cells were sensitive to hypoxic or glucose-deficient conditions. While both the nerve and glial cells were sensitive to hypoxia to a similar extent, the nerve cells were more sensitive to glucose deficiency. It was suggested that the bulk isolated nerve and glial cells still retain certain integral cell functions as viable cells, and can be utilized for various physiological and pharmacological investigations provided caution is exercised in their application and in the interpretation of the results.     

Mitochondrial RNA and protein synthesis in enucleated African green monkey cells

The behavior of extramitochondrial protein synthesis and of mitochondrial RNA and protein synthesis was examined in the cytoplasts of African green monkey kidney cells (TC-7 subline) at different times following enucleation by cytochalasin B. The rate of incorporation of [³H]isoleucine into protein of the soluble cytoplasmic fraction decreased in an approximately exponential fashion, with a half-life of about five hours, during the first 26 hours after enucleation. Discrete mitochondrial 16 S, 12 S and 4 S RNA components were identified among the products of cytoplast RNA synthesis. The rates of [³H]uridine incorporation into the 16 and 12 S RNA components as well as into total RNA declined progressively after enucleation to a barely detectable level by the 20th hour. By contrast, the rate of chloramphenicol-sensitive [³H]isoleucine incorporation into protein (due to mitochondrial protein synthesis) did not undergo a substantial decline for at least 20 hours in TC-7 cytoplasts; instead, a reproducible transient stimulation occurred in the first hours following enucleation. The products of mitochondrial protein synthesis pulse-labeled in nucleated cells and in cytoplasts 24 hours after enucleation exhibited similar electrophoretic profiles.     

Inhibition of cell division in amoebae: the incorporation of tritiated precursors into Amoeba proteus after the injection of non-homologous cytoplasm.

The injection of non-homologous cytoplasm into any strain of large free-living amoebae leads to a 60% inhibition of division amongst recipient cells. When the post-microsomal supernatant fraction of Amoeba discoides was injected into A. proteus, this inhibition of division was as high as 95%. The incorporation of tritiated precursors, either [3H]uridine or 3H-amino acids, into these inhibited amoebae was studied at various times after the injection of the inhibitory material using autoradiography. When cells were grown in [3H]uridine, autoradiographs indicated that RNA synthesis had ceased 2 days after the injection of non-homologous material. However, if [3H]uridine was injected into the inhibited cells, some synthesis of RNA could be detected up to 4 days after the injection of inhibitor. These results suggested that uptake of [3H]uridine was impaired and that one site of action of the inhibitory molecules was RNA synthesis for membrane components. Experiments with a variety of 3H-amino acids suggested that protein synthesis continued for at least 9 days after the injection of non-homologous cytoplasm, and that in these cells some informational RNA molecules were long-lived. There seemed to be accumulation of material containing [3H]lysine in the nuclei of control cells taken at random from cultures, and this was seen in the nuclei of inhibited cells 1 day after injection. However, 2 days after the injection of inhibitor, no accumulation of [3H]lysine-containing material was found in the nuclei.     

Inhibition of protein and nucleic acid synthesis of animal cells in vitro mediated by high molecular weight inhibitors in human liver extract.

1. The addition of human liver extract to HeLa cells induces a reversible inhibition of the incorporation of [3H] thymidine into the DNA, [3H] uridine into the RNA, and 14C-labelled amino acids into the protein of HeLa cells. The inhibitory effects appear after treatment for 1 h and reach a maximum after 4-8 h. These effects do not depend on a defective precursor penetration, isotopic dilution or degradation of labelled precursor (thymidine-degrading enzymes were inactivated by the addition of unlabelled thymine), reduced activity of thymidine and uridine kinase, medium impairment, or an impairment of the cell-membrane function. 2. The nucleic acid synthesis-inhibiting activity of the extract seems to be dependent on cellular protein synthesis but independent of RNA synthesis which indicates that the inhibitors act in an indirect way. Furthermore, the inhibitors seem to lack the tissue-specific character of chalones. 3. The extract contains separate inhibitors of DNA, RNA and protein synthesis. These inhibitors were found to have different physical-chemical characteristics and to be macromolecules with a protein or conjugated protein character (mol. wt. approx. 90 000). 4. The possibility that the activity of the high molecular weight inhibitors resides in low molecular weight factors (bound to protein carriers) was tested: No true low molecular weight inhibitors could be liberated by extraction with trichloroacetic acid/organic solvents or by dialysis/enzymatic treatments. Nucleosides such as thymidine, uridine, and cytidine, however, were liberated and could be shown to interfere with the uptake of [3H] thymidine/[3H] uridine.     

Heat shock protein 27 stimulates recovery of RNA and protein synthesis following a heat shock

Constitutive expression of human hsp27 resulted in a 100-fold increase in survival to a single lethal heat shock in CHO cells without effecting the development of thermotolerance. A possible mechanism for the thermoprotective function of hsp27 may be increased recovery of protein synthesis and RNA synthesis following a heat shock. A lethal heat shock (44°C, 30 min) results in a 90% reduction in the rate of protein synthesis in non-tolerant cells. Control transfected cells recovered protein synthesis to a pre-heat shock rate 10 h after the heat shock; while cell lines that constitutively express human hsp27 recovered 6 h after the heat shock. Thermotolerant cells had a 50% reduction in protein synthesis, which recovered within 7 h following the heat shock. The same lethal heat shock (44°C, 30 min) reduced RNA synthesis by 60% in the transfected cell lines, with the controls recovering in 7 h; while the hsp27 expressing cell lines recovered within 5 h. Thermotolerant cells had a 40% reduction in RNA synthesis and were able to recover within 4 h. The enhanced ability of hsp27 to facilitate recovery of protein synthesis and RNA synthesis following a heat shock may provide the cell with a survival advantage. J. Cell. Biochem. 66:153–164, 1997. © 1997 Wiley-Liss Inc.     

Divergent Effects of Acute Depolarization on Somatostatin Release and Protein Synthesis in Cultured Fetal and Neonatal Rat Brain Cells

The influence of membrane depolarization on somatostatin secretion and protein synthesis by fetal and neonatal cerebrocortical neurons was studied. Cortical cells obtained by mechanical dispersion were maintained as monolayer cultures for 8 days. The ability of fetal cerebrocortical and hypothalamic cells to release immunoreactive somatostatin (IR-SRIF) was confirmed. Total protein synthesis was determined by the incorporation of [3H]phenylalanine into trichloroacetic acid-precipitable proteins. To study the effect of acute depolarization on protein synthesis, cells were incubated for 30 min with [3H]phenylalanine or [3H]leucine and the depolarizing agent. In fetal cerebrocortical cells, potassium (30 and 56 mM) decreased protein synthesis and RNA levels and increased IR-SRIF release. Depolarization by veratridine, a sodium channel activator, induced a similar effect. The effect of veratridine on IR-SRIF and protein synthesis was reversed by tetrodotoxin, a sodium channel blocker, or verapamil, a calcium channel blocker. These findings suggest that protein synthesis by cerebrocortical cells is decreased in fetal brain cells by membrane depolarization and is dependent on Na+ and Ca2+ entry into cells. In postnatal (day 7) cerebrocortical cells, depolarization induced by high potassium concentrations led to a concomitant increase in protein synthesis, RNA content, and somatostatin release. These findings indicate that depolarization of the cellular membrane is coupled to an increase in protein synthesis in neonatal, but not in fetal, dispersed brain cells.     

Mode of Action of Vibriocin

The mechanism of action of vibriocin, a bacteriocin produced by Vibrio comma, was investigated. Its lethal action (as defined by the loss in colony-forming ability) was reversed by tryptic digestion within 7 to 10 min after adsorption. The bacteriocin had a pronounced inhibitory effect on deoxyribonucleic acid (DNA) synthesis, whereas ribonucleic acid (RNA) and protein synthesis continued, although at a reduced rate. Chloramphenicol protected sensitive bacteria from the lethal action. Degradation of bacterial DNA prelabeled with (3)H-thymidine, as measured by changes in acid-precipitable radioactivity, occurred 10 min after treatment with vibriocin. The bacteriocin per se had no detectable deoxyribonuclease activity. Observation of vibriocin-treated cells by phase-contrast microscopy, measurement of ultraviolet light-absorbing capacity of extracellular fluid, and (42)K-efflux studies indicated a damaged bacterial membrane. This impairment of membrane function occurred in the presence of chloramphenicol and thus, unlike the lethal effect of vibriocin, was independent of protein synthesis.     

Indomethacin inhibits the insulin-induced increases in RNA and protein synthesis in L6 skeletal muscle myoblasts

Rates of accretion of RNA and protein and rates of protein synthesis were measured in sub-confluent cultures of L6 myoblasts. Insulin (100 microU/ml) stimulated protein synthesis by 15% within 30 min and by 40% at two and six hours. By six hours insulin also increased the accretion of RNA (+15%). The cyclo-oxygenase inhibitor indomethacin did not reduce the basal rate of RNA or protein accretion in L6 cells but reduced the rate of protein synthesis by 16%. When added together with insulin, indomethacin inhibited the hormonally-stimulated rate of protein synthesis and also significantly reduced the accretion of RNA. Indomethacin still reduced the effects of insulin on protein synthesis when added to the cells two hours after the hormone. Synthesis of RNA measured by the incorporation of [3H]-uridine was also stimulated by insulin but was inhibited by indomethacin only when the drug was present throughout the incubation. Inhibition of protein synthesis by cyclo-oxygenase inhibitors may be the result of both a direct action on translational efficiency and an effect on RNA synthesis.     

On the relation between recovery from potential lethal and sublethal radiation lesions of yeast cells

Summary Tetraploid yeast cells were used to study the time course of recovery from potential lethal lesions by delayed plating after a single dose of gamma-radiation and recovery from sublethal lesions by using two fraction dose technique. The mean lifetime of potential lethal and sublethal lesions in comparable conditions are the same. The elimination of lethals in the first steps of recovery process is accompanied by transition of lethally damaged cells into sublethally damaged ones.Sublethals are in principle completely reversible. As potential lethals consist of sublethals the number of which are critical the former immediately after irradiation also are complete reversible in principle. In a time course a definite fraction of potential lethals is fixed into true irreversible lethals. This pattern is in close agreement with the common model of formation of two-hit chromosome aberration.     

Radioautographic visualization of differences in the pattern of [3H]uridine and [3H]orotic acid incorporation into the RNA of migrating columnar cells in the rat small intestine

The epithelium of rat small intestine was radioautographed to examine whether RNA is synthesized by the salvage pathway as shown after [3H]uridine injection or by the de novo pathway as shown after [3H]orotic acid injection. The two modes of RNA synthesis were thus investigated during the migration of columnar cells from crypt base to villus top, and the rate of synthesis was assessed by counting silver grains over the nucleolus and nucleoplasm at six levels along the duodenal epithelium--that is, in the base, mid, and top regions of the crypts and in the base, mid, and top regions of the villi. Concomitant biochemical analyses established that, after injection of either [5-3H]uridine or [5-3H]orotic acid: (a) buffered glutaraldehyde fixative was as effective as perchloric acid or trichloracetic acid in insolubilizing the nucleic acids of rat small intestine; (b) a major fraction of the nucleic acid label was in RNA, that is, 91% after [3H]uridine and 72% after [3H]orotic acid, with the rest in DNA; and (c) a substantial fraction of the RNA label was in poly A+ RNA (presumed to be messenger RNA). In radioautographs of duodenum prepared after [3H] uridine injection, the count of silver grains was high over nucleolus and nucleoplasm in crypt base cells and gradually decreased at the upper levels up to the villus base. In the rest of the villus, the grain count over the nucleolus was negligible, while over the nucleoplasm it was low but significant. After [3H]-orotic acid injection, the number of silver grains over the nucleolus was negligible at all levels, whereas over the nucleoplasm the number was low in crypt cells, but high in villus cells with a peak in mid villus. The interpretation is that, except for a small amount of label incorporated into DNA from either precursor by crypt cells, the bulk of the label is incorporated into RNA as follows. In the crypts, cells make almost exclusive use of uridine, that is, of the salvage pathway, for the synthesis of ribosomal RNA in the nucleolus and of messenger and transfer RNA in the nucleoplasm. However, when cells pass from crypt to villus, they mainly utilize orotic acid--i.e., the de novo pathway--for the synthesis of messenger and transfer RNA within the nucleoplasm.     

In vitro DNA and RNA synthesis by human platelets.

In vitro incorporation of [Me-3H] thymidine and [5-3H] uridine into human platelets was demonstrated. Thymidine incorporation was inhibited by three specific inhibitors of DNA synthesis: hydroxyurea, cytosine arabinoside and daunomycin. The effect was dose-dependent. Uridine uptake by platelets was found to be inhibited by specific inhibitors of RNA synthesis such as actinomycin D, rifampicin and vincristine, the effect of actinomycin D being dose dependent. The drug also led to a time-dependent inhibition of protein synthesis when preincubated with platelets. The platelet RNA profile on polyacrylamide gel was demonstrated to be similar to that of embryonic mouse erythroblast RNA. Synthesis of all three fractions, 28 S, 18 S and 4 S, was inhibited by actinomycin D. These findings show that human platelets are capable of DNA and RNA synthesis, and that these activities play a role in controlling protein synthesis in these cells. Detectable amounts of DNA have been found in whole human platelets, and in isolated mitochondria derived from these cells. Isolated platelet mitochondria incorporated [3H] thymidine and [3H] uridine into their macromolecules. These activities were inhibited by daunomycin and by both rifampicin and actinomycin D, respectively. These results support the assumption that DNA and RNA synthesis found in intact cell preparations takes place most probably in platelet mitochondria.     

Quantitative aspects of repair of potentially lethal damage in mammalian cells.

Stationary cultures of Ehrlich ascites tumour cells have been irradiated with X-rays and then immediately or after a time interval trep plated to measure the survival. The increase in survival observed after delayed plating is interpreted as repair of potentially lethal damage. A cybernetic model is used to analyse these data. Three states of damage are assumed for the cells. In state A the cells can grow to macrocolonies, in state B the cells have suffered potentially lethal damage and can grow to macrocolonies only if they are allowed to repair the damage and in state C the cells are lethally damaged. A method of deriving the values of the parameters of the model from the experimental data is given. The dependence of the reaction rate constant of the repair of potentially lethal damage on the dose D is used to derive a possible mechanism for the production of the shoulder in the dose effect curve. Finally this model is compared with other models of radiation action on living cells.     

Effect of hyperthermia on protein biosynthesis in L5178Y murine leukemic lymphoblasts

The effects of elevated temperatures upon protein biosynthesis were determined in L5178Y murine leukemic lymphoblasts. The rate of protein synthesis was inhibited proportionately to the increase in temperature. Efforts were made to determine the mechanism of heat inactivation of protein synthesis by studying the requirements for recovery of activity after the cells were returned to 37°C. The ability of actinomycin to block the recovery process suggests that elevated temperatures destroy or inactivate a species of RNA required for protein synthesis. Loss of RNA during heating of the cells is apparently at least partially dependent on protein synthesis, since the presence of cycloheximide during heat shock, is capable of ameliorating the effects of short duration heat treatment.     

DNA replicatiion and cell-cycle progresssion of cultured mouse FM3A cells after treatment with 8-methoxypsoralen plus near-UV radiation

To investigate the response of cells to one type of DNA damage — namely DNA crosslinks — cell-cycle progression and macromolecular synthesis were studied with cultured mouse FM3A cells. Treatment of the cells with low doses of 8-methoxypsoralen (8-MOP) plus near-UV radiation (0.1 μg/ml plus 5 kJ/m² or 1.0 μg/ml plus 1–2.5 kJ/m²)_halted the progression of cells through the cell cycle temporarily for the first several hours. Then the cells resumed progression through the cell cycle, and most of the cells reached, and were finally arrested at, the G2 phase of the cycle. There was a rapid decrease of incorporation of [³H]thymidine into cellular DNA immediately after the treatment. Then, after 8 h of incubation, the incorporation of [³H]thymidine recovered to some extent depending on the dose of 8-MOP plus near-UV radiation. Thus the decrease and recovery of the incorporation of [³]Hthymidine were correlated with the halt and resumption in the cell-cycle process.Synthesis of RNA and protein was measured by determination of the amounts in the cells or by the incorporation of radioactive precursors after treatment. RNA and protein synthesis were stimulated by low doses of 8-MOP plus near-UV radiation, but inhibited severely by high doses.     

In vitro replication of mouse hepatitis virus strain A59.

An in vitro replication system for mouse hepatitis virus (MHV) strain A59 was developed using lysolecithin to produce cell extracts. In extracts of MHV-infected cells, radiolabeled UMP was incorporated at a linear rate for up to 1 h into RNA, which hybridized to MHV-specific cDNA probes and migrated in denaturing formaldehyde-agarose gels to the same position as MHV genomic RNA. The incorporation of [32P]UMP into genome-sized RNA in vitro correlated with the observed increase of [3H]uridine incorporation in MHV-infected cells labeled in vivo. Incorporation of [32P]UMP into genome-sized RNA was inhibited when extracts were incubated with puromycin. The addition to the assay of antiserum to the MHV-A59 nucleocapsid protein N inhibited synthesis of genome-sized RNA by 90% compared with the addition of preimmune serum. In contrast, antiserum to the E1 or E2 glycoproteins did not significantly inhibit RNA replication. In vitro-synthesized RNA banded in cesium chloride gradients as a ribonucleoprotein complex with the characteristic density of MHV nucleocapsids isolated from virions. These experiments suggest that ongoing protein synthesis is necessary for replication of MHV genomic RNA and indicate that the N protein plays an important role in MHV replication.     

Protein Synthesis and Breakdown during Heat Shock of Cultured Pear (Pyrus communis L.) Cells

Cultured pear (Pyrus communis L. cv Passe Crassane) cells were subjected to temperatures of 39, 42, and 45[deg]C. Heat-shock protein (hsp) synthesis was greater at 30[deg]C than at temperatures above 40[deg]C and continued for up to 8 h. Both cellular uptake of radiolabeled methionine and total protein synthesis were progressively lower as the temperature was increased. Polysome levels decreased immediately when cells were placed at 39 or 42[deg]C, although at 39[deg]C the levels began to recover after 1 h. In cells from both temperatures, reassembly occurred after transfer of cells to 25[deg]C Four heat-shock-related mRNAs[mdash]hsp17, hsp70, and those of two ubiquitin genes[mdash]all showed greatest abundance at 39[deg]C and decreased at higher temperatures. Protein degradation increased with time at 42 and 45[deg]C, but at 39[deg]C it increased for the first 2 h and then decreased. In the presence of cycloheximide, which prevented hsp synthesis, protein degradation at 39[deg]C was as great as that at 45[deg]C in the absence of cycloheximide. The data suggest that hsps may have a role in protecting proteins from degradation at the permissive temperature of 39[deg]C. At temperatures high enough to inhibit hsp synthesis, protein degradation was enhanced. Although ubiquitin may play a role in specific protein degradation, it does not appear to be involved in increased protein degradation occurring above 40[deg]C.     

Protein metabolism in senescing wheat leaves : determination of synthesis and degradation rates and their effects on protein loss

Wheat leaves (Triticum aestivum L.) at the moment of their maximum expansion were detached and put in darkness. Their protein, RNA and DNA contents, as well as their rates of protein synthesis and degradation, were measured at different times from 0 to 5 days after detachment. Rates of protein synthesis were measured by incorporation into proteins of large amounts of [³H]leucine. Fractional rates of protein degradation were estimated either from the difference between the rates of synthesis and the net protein change or by the disappearance of radioactivity from proteins previously labeled with [³H]leucine or [¹⁴C]proline.

Protein loss reached a value of 20% during the first 48 hours of the process. RNA loss paralleled that of protein, whereas DNA content proved to be almost constant during the first 3 days and decreased dramatically thereafter.

Measurements of protein synthesis and degradation indicate that, in spite of a slowdown in rate of protein synthesis, an increased rate of protein breakdown is mainly responsible for the observed rapid protein loss.

     

Isolation of relaxed-control mutants of Escherichia coli K-12 which are sensitive to glucose starvation

Mutants of $\text{Escherichia coli}$ K-12 which are sensitive to glucose starvation were isolated by an enrichment procedure using thymine starvation to select for nongrowing cells. Eleven independent isolates were obtained by this method. The mutants are also sensitive to glycerol starvation and to a lesser extent to nitrogen or amino acid starvation. The mutants are more sensitive than the parental strain to inhibitors of protein synthesis but not inhibitors of RNA or DNA synthesis. [³H]-leucine incorporation experiments indicate that protein synthesis is blocked in the mutants during recovery from glucose starvation or chloramphenicol inhibition. Incorporation of [³H]uridine in amino acid-starved cells demonstrates that the mutants are partially relaxed for control of RNA synthesis. Physiological and genetic experiments indicate that these mutants are different from previously isolated relaxed-control mutants.