Inhibition of cell-substratum attachment of cultured rat heart cells by protein synthesis inhibitors

Addition of cycloheximide to growth medium of neonatal rat heart cell cultures prevented cell-substratum attachment. Even concentrations of cycloheximide which inhibited only 50% of normal protein synthesis prevented some cells from attaching. Cells which required the longest time to attach were most dependent on protein synthesis. The kinetics of cell-substratum adhesion in the presence of various concentrations of cycloheximide supported the hypothesis that repair of damaged cell membranes was required prior to attachment. An alternate hypothesis that protein synthesis was required for substratum attachment either to synthesize new unique proteins or higher concentrations of existing proteins not damaged by enzymes was not supported by experimentally obtained data. If the second hypothesis were true, no cells would have attached when protein synthesis was completely inhibited (greater than 95%) and all cells should have been equally affected by protein synthesis inhibition; such was not the case. Inhibition of mRNA formation by actinomycin D also should have inhibited attachement completely and this was not observed. Since attachment was minimally affected by actinomycin D, protein synthesis on long-lived mRNA was apparently sufficient for cell-substratum adhesion.     

Participation of plasma membrane proteins in the formation of tight junction by cultured epithelial cells

Measurements of the transepithelial electrical resistance correlated with freeze-fracture observations have been used to study the process of tight junction formation under various experimental conditions in monolayers of the canine kidney epithelial cell line MDCK. Cells derived from previously confluent cultures and plated immediately after trypsin- EDTA dissociation develop a resistance that reaches its maximum value of several hundred ohms-cm(2) after approximately 24 h and falls to a steady-state value of 80-150 ohms- cm(2) by 48 h. The rise in resistance and the development of tight junctions can be completely and reversibly prevented by the addition of 10 μg/ml cycloheximide at the time of plating, but not when this inhibitor is added more than 10 h after planting. Thus tight junction formation consists of separable synthetic and assembly phases. These two phases can also be dissociated and the requirement for protein synthesis after plating eliminated if, following trypsinization, the cells are maintained in spinner culture for 24 h before plating. The requirement for protein synthesis is restored, however, if cells maintained in spinner culture are treated with trypsin before plating. Actinomycin D prevents development of resistance only in monolayers formed from cells derived from sparse rather than confluent cultures, but new mRNA synthesis is not required if cells obtained from sparse cultures are maintained for 24 h in spinner culture before plating. Once a steady-state resistance has been reached, its maintenance does not require either mRNA or protein synthesis; in fact, inhibition of protein synthesis causes a rise in the resistance over a 30-h period. Following treatments that disrupt the junctions in steady- state monolayers recovery of resistance also does not require protein synthesis. These observations suggest that proteins are involved in tight junction formation. Such proteins, which do not turn over rapidly under steady-state conditions, are destroyed by trypsinization and can be resynthesized in the absence of stable cell-cell or cell-substratum contact. Messenger RNA coding for proteins involved in tight junction formation is stable except when cells are sparsely plated, and can also be synthesized without intercellular contacts or cell-substratum attachment.     

Prostaglandin production by methylcholanthrene-transformed mouse BALB/3T3. Requirement for protein synthesis

Stimulation of prostaglandin synthesis in transformed mouse fibroblasts by serum, thrombin, and bradykinin was blocked by actinomycin D and cycloheximide. These RNA and protein synthesis inhibitors did not affect prostaglandin synthetase in vitro or in vivo; nor did they affect the acylation of arachidonic acid into phospholipids. Serum-stimulated release of arachidonic acid and prostaglandins from [3H]arachidonic acid-labeled cells also was inhibited by actinomycin D and cycloheximide. RNA and protein synthesis appear to be required for expression of phospholipase activity; a prerequisite for prostaglandin synthesis by these cells.     

The Changes of Protein Content and Synthetic Activity in Squash Pollen During Germination

The total protein content of squash (Cucurbita moschata Duch.) pollen decreased gradually during in vitro germination. It was caused by the release of wall proteins and part of the cytoplasmic proteins. The release of the pollen wall proteins was not dependent on germination, it was a passive diffusion process. However, the cytoplasmic proteins did not release until the pollen germinated, a fraction of them was synthesized de novo during germination. The RNA and protein synthetic activities initiated soon after in vitro pollen germination. The RNA synthesis decreased during germination. As about half the activity was inhibited by α-amanitin, mRNA might be the major RNA synthesized de novo. The total protein synthesis increased during germination, almost all of this synthesis was inhibited by cycloheximide, and partially by α-amanitin, but it was not affected significantly by actinomycin D. These results indicated that both stored and de novo synthesized mRNA might play a role in the protein synthesis. The content of stored mRNA of squash pollen was about 11-3 pg/grain as measured by UV absorption after its purification from total RNA (2440 pg/grain) by oligo (dT)-cellulose affinity chromatagraphy. Both cycloheximide and α-amanitin inhibited pollen tube growth in vitro. Actinomycin D and tunicamycin inhibited pollen germination in the first hour, however, no reduction ,of the tube length was observed later. Cyclohex,nide inhibited the pollen germination and tube elongation in vivo, that fitted well with the in vitro results. According to these results, it was suggested that the de novo syntheses of mRNA and protein were neccessary for the maintenance of pollen tube growth.     

Activation and de novo synthesis of transglutaminase in cultured glioma cells

The activity of transglutaminase (TGase) was measured in cultured C6 glioma cells after their stimulation by either isoproterenol and isobutyl-methylxanthine or by a serum-containing medium. The activity fluctuated in a biphasic manner, with the peaks at 2-3 hr and 7-8 hr poststimulation. The first peak of TGase activity was affected neither by cycloheximide nor by actinomycin D, which inhibited protein synthesis. The second peak, on the other hand, was completely eliminated by cycloheximide and was reduced by actinomycin D. Immunological procedures were employed to find out whether or not the activity of TGase corresponded with the presence of the TGase antigen in the cultured cells. Indirect immunofluorescent staining and radioimmunoblot techniques suggested that unstimulated cells contained an inactive enzyme. This inactive, or cryptic, enzyme had the same molecular weight as its active counterpart. Activation of the enzyme was mediated by cell stimulation, probably by its release from the membrane. This step did not require protein synthesis, unlike the second step, which was dependent on de novo protein synthesis.     

Is protein synthesis necessary for prostaglandin production by guinea-pig endometrium?

The outputs of prostaglandin (PG) F-2 alpha, PGE-2 and 6-keto-PGF-1 alpha from Day-7 and Day-15 guinea-pig endometrium in culture were reduced by the inclusion of actinomycin D, cycloheximide and puromycin in the culture medium, with the output of PGF-2 alpha from Day-15 endometrium being particularly affected during the first 6 h of culture. The intrauterine administration of actinomycin D on Day 10 decreased the outputs of PGF-2 alpha and PGE-2, but not of 6-keto-PGF-1 alpha, from Day-15 endometrium in culture without affecting PG output from Day-15 myometrium in culture. Actinomycin D, cycloheximide and puromycin did not reduce PG output when superfused over the Day-7 and Day-15 guinea-pig uterus in vitro for 20 min, indicating that these compounds do not have a rapid inhibitory effect on endometrial PG synthesis. In fact, they tended to stimulate PG output during this 20-min period, with cycloheximide having a pronounced effect on PGE-2 output. The synthesis of secreted proteins, but not of cellular proteins, was greater by Day-15 than by Day-7 endometrium in culture. Actinomycin D, cycloheximide and puromycin inhibited the synthesis of secreted and cellular proteins by Day-7 and Day-15 endometrium in culture. Protein synthesis and PG synthesis in the endometrium were both inhibited to a greater extent by cycloheximide and puromycin than by actinomycin D. The intrauterine administration of actinomycin D on Day 10 reduced the syntheses of secreted and cellular proteins by Day-15 endometrium in culture. These findings indicate that the endometrial synthesis of PGs, particularly of PGF-2 alpha towards the end of the oestrous cycle, is dependent upon endometrial protein synthesis.     

Influence of Cycloheximide and Actinomycin D on Initiation and Early Development of Adventitious Roots

From leaf cuttings of the bean Phaseolus vulgaris L. adventitious roots form on the petiole. This root formation is stimulated by treatment with auxin. Simultaneous or subsequent application of cycloheximide irreversibly inhibited dedifferentiation, so that root production was completely prevented. The effects of actinomycin D application depended upon the stage of development of the root primordium. Cells in the first stage of dedifferentiation were extremely sensitive. When actinomycin D was applied later than 6 h after cutting, its inhibiting effect gradually diminished. It is concluded that an actinomycin D-sensitive process occurring early in dedifferentiation is crucial for root initiation. A second, less actinomycin D-sensitive process occurring later in dedifferentiation is required for the further development of the root primordium. During the initiation and development of the root primordium protein synthesis is required.     

Inhibition by corticosteroids of epidermal growth factor-induced recovery of cyclooxygenase after aspirin inactivation

Cultures of vascular smooth muscle cells superfused with [14C]arachidonic acid synthesized the antiplatelet substance prostacyclin as the major cyclooxygenase product. Prostacyclin synthesis was inactivated by aspirin, which irreversibly acetylates cyclooxygenase. Aspirin-treated cells recovered within 2 h by a process that was blocked by cycloheximide but not by actinomycin D, and that required a serum component identified as epidermal growth factor (EGF). EGF-induced recovery of cyclooxygenase was greatly potentiated by type beta transforming growth factor (TGF-beta). Incubation with EGF and TGF-beta in the 0.1-1.0 nanomolar range stimulated cyclooxygenase recovery up to 20-fold without increasing [35S]methionine incorporation into other cell proteins. Induction of cyclooxygenase by EGF and TGF-beta also was prevented by cycloheximide but not by actinomycin D. EGF-dependent recovery was blocked by preincubation with dexamethasone (2 microM), an effect that was duplicated by pure lipocortin (2-4 micrograms/ml). Incubation of membrane preparations from these cells with EGF selectively activated phosphorylation of a 35-kDa cellular protein that comigrated with lipocortin. The results suggest that cyclooxygenase recovery in aspirin-inactivated vascular smooth muscle cells is mediated by an EGF-dependent translational control that is inhibited by corticosteroids. The findings also provide a new mechanism whereby corticosteroids suppress inflammatory prostaglandins.     

Cell-to-cell adhesion of dissociated embryonic brain cells; the effects of metabolic inhibitors and temperature

Brain cells from 16 to 18-day-old mice embryos were dissociated by mild trypsinization and rotated for 120 min. The area and density of of the adhesive complexes formed were registered using the method described previously. The adhesiveness of dissociated embryonic brain cells (measured during the 120 min of rotation) was diminished in the presence of inhibitors of protein synthesis (puromycin, cycloheximide and inhibition of mRNA synthesis actinomycin D). The inhibition was, however, not distinct, because 1 microgram/ml of cycloheximide and actinomycin was without any significant effect, and the degree of inhibition evoked by 10 micrograms/ml and 25 micrograms/ml of puromycin bordered on significance. However, protein synthesis inhibitors in long-term aggregation experiments had a pronounced inhibitory effect and/or induced destruction of the aggregates. Metabolic inhibitors (KCN and NaN3) caused an inhibition at the lowest level of significance (p less than 0.05) 10(-3) mol/l KCN reduced the final adhesive product significantly. Cells rotated at room temperature and at +5 degrees C adhere to the same extent as in control experiments (37 degrees C). The adhesion was significantly inhibited at +60 degrees C and also after freezing at -80 degrees C with subsequent thawing. The adhesion of cells exposed for 30 min to between +80 degrees C and 100 degrees C was completely abolished. The process of embryonic brain cell adhesion requires a low energy supply, and is relatively independent of biosynthetic processes and of temperature changes between +5 degrees C and +50 degrees C.     

The effect of lutropin on specific protein synthesis in tumour Leydig cells and in Leydig cells from immature rats

The amount of (35)S incorporated into the various proteins after separation by electrophoresis on sodium dodecyl sulphate/polyacrylamide gels was used as an estimate of their synthesis in the Leydig cells. Increased synthesis of proteins with apparent mol.wts. 27000 and 29000 was observed 3h after addition of lutropin to tumour Leydig cells. Incubation of Leydig cells from immature rats with lutropin (100ng/ml) for 2h or longer resulted in increased synthesis of proteins with apparent mol.wts. 11000, 21000, 27000 and 29000. At higher concentrations (>/=100ng/ml) of lutropin there was a decrease in the synthesis of a protein with apparent mol.wt. 13000. The amount of lutropin required for the stimulation of protein synthesis in both types of Leydig cells was similar to that needed for stimulation of steroidogenesis. Lutropin-stimulated specific protein synthesis was not due to increased concentrations of testosterone, however, because (1) addition of testosterone to the cells had no effect on the synthesis of the proteins, and (2) inhibition of steroidogenesis with elipten phosphate (an inhibitor of the cholesterol side-chain-cleavage enzyme complex) did not abolish the effect of lutropin. The stimulation of specific protein synthesis was also not due to contaminating follitropin in the lutropin preparation. Addition of actinomycin D to the cells at the start of the incubation prevented the effect of lutropin on specific protein synthesis, indicating that mRNA synthesis may be needed for this effect of lutropin. Incubation of the cells with cycloheximide for 30min after labelling of the proteins did not result in a detectable decrease in the amounts of the lutropin-induced proteins, indicating that their half-life is longer than 30min.     

Corticosteroids suppress cyclooxygenase messenger RNA levels and prostanoid synthesis in cultured vascular cells

Prostacyclin synthesis by cultured vascular smooth muscle cells was inactivated by aspirin. Recovery required serum factors replaceable by EGF plus TGF-beta and was blocked by cycloheximide but not by actinomycin D. Recovery of cyclooxygenase activity was prevented by preincubation with dexamethasone (0.1 to 2 microM), which also suppressed basal enzyme activity by up to 70%. A full length 2.8 Kb cDNA hybridization probe for human cyclooxygenase identified a cyclooxygenase messenger RNA of approximately 2.8 Kb in these cells. Cyclooxygenase mRNA levels were enhanced by EGF/TGF-beta, but suppressed completely by corticosteroids. It is concluded that inhibition of prostanoid synthesis by corticosteroids is mediated by suppressing cyclooxygenase messenger RNA. These observations provide a new molecular mechanism for the anti-inflammatory activity of the corticosteroids.     

Synthesis of protein and mRNA is necessary for transition of suspension-cultured Catharanthus roseus cells from the G1 to the S phase of the cell cycle

The effects of inhibition of the synthesis of protein, mRNA or rRNA on the progression of the cell cycle have been analyzed in cultures of Catharanthus roseus in which cells were induced to divide in synchrony by the double phosphate starvation method. The partial inhibition of protein synthesis at the G₁ phase by anisoniycio or cycloheximide caused the arrest of cells in the G₁ phase or delayed the entry of cells into the S phase. When protein synthesis was partially inhibited at the S phase, cell division occurred to about the same extent as in the control. When asynchronously dividing cells were treated with cycloheximide, cells accumulated in the G₁ phase, as shown by flow-cytometric analysis. The partial inhibition of mRNA synthesis by α-amanitin at the G₁ phase caused the arrest of cells in the G₁ phase, although partial inhibition of mRNA synthesis at the S phase had little effect on cell division. In the case of inhibition of synthesis of rRNA by actinomycin D at the G₁ phase, initiation of DNA synthesis was observed, but no subsequent DNA synthesis or the division of cells occurred. However, the addition of actinomycin D during the S phase had no effect on cell division. These results suggest that specific protein(s), required for the progression of the cell cycle, are synthesized in the G₁ phase, and that the mRNA(s) that encode these proteins are also synthesized at the G₁ phase.     

Phospholipid Synthesis in Sindbis Virus-Infected Cells

We investigated the metabolic requirements for the decrease in phospholipid synthesis previously observed by Pfefferkorn and Hunter in primary cultures of chick embryo fibroblasts infected with Sindbis virus. The incorporation of (32)PO(4) into all classes of phospholipids was found to decline at the same rate and to the same extent; thus, incorporation of (14)C-choline into acid-precipitable form provided a convenient measure of phospholipid synthesis that was used in subsequent experiments. Experiments with temperature-sensitive mutants suggested that some viral ribonucleic acid (RNA) synthesis was essential for the inhibition of choline incorporation, but that functional viral structural proteins were not required. The reduction in phospholipid synthesis was probably a secondary effect of infection resulting from viral inhibition of the cellular RNA and protein synthesis. All three inhibitory effects required about the same amount of viral RNA synthesis; the inhibition of host RNA and protein synthesis began sooner than the decline in phospholipid synthesis; and both actinomycin D and cycloheximide inhibited (14)C-choline incorporation in uninfected cells. In contrast, incorporation of (14)C-choline into BHK-21 cells was not decreased by 10 hr of exposure to actinomycin D and declined only slowly after cycloheximide treatment. Growth of Sindbis virus in BHK cells did not cause the marked stimulation of phospholipid synthesis seen in picornavirus infections of other mammalian cells; however, inhibition was seen only late in infection.     

Macromolecular synthesis, differentiation and cell division in Tetrahymena pyriformis, mating type I variety 1

In Tetrahymena pyriformis, mating type I, variety 1, cycloheximide rapidly and completely inhibited incorporation of ¹⁴C-L-leucine into protein. Actinomycin D (25 μg per ml) inhibited incorporation of ¹⁴C-uracil into cold-TCA-insoluble material, after a 5–10 minute lag. Frequently a subsequent decline in the amount of radioactivity was observed. Protein synthesis continued in actinomycintreated cultures for a variable time after cessation of RNA synthesis. Oral development was affected by cycloheximide virtually immediately, and by actinomycin D after a 10–15 minute lag. Cells affected by either drug before the onset of oral membranelle formation were permanently arrested in the stomatogenic field phase. Cells affected in the early and middle stages of membranelle formation completed development of membranelles, but did not invariably complete cell division. Cycloheximide, when added at the beginning of membranelle formation, brought about arrest or resorption of membranelles after they were completed. Actinomycin did not elicit resorption, but sometimes brought about blockage during cell division. Cells affected by either drug after membranelles were fully formed (and cell division was just beginning) completed oral development, nuclear divisions, and cell division. These results suggest that concurrent RNA and protein synthesis are essential for the initiation but not for the completion of membranelle differentiation. The results also suggest that a specific messenger RNA(s) with a very short half-life is required for the synthesis of proteins involved in the initiation of membranelle differentiation.     

Rapid turnover of endogenous endonuclease activity in thymocytes: effects of inhibitors of macromolecular synthesis

Previous work has shown that inhibitors of protein or mRNA synthesis block endonuclease activation in thymocytes undergoing programmed cell death. In the present study we used isolated nuclei to investigate the effects of cycloheximide and actinomycin D, inhibitors of protein and mRNA synthesis, respectively, on endogenous endonuclease activity in thymocytes. We observed a rapid loss of Ca2(+)-dependent endonuclease activity in nuclei isolated from thymocytes treated with these inhibitors. In contrast, pretreatment of cells with antipain and leupeptin, inhibitors of proteases, prevented the depletion of endonuclease activity in the nuclei, suggesting that proteolysis was involved. The effects of cycloheximide and actinomycin D were mimicked by incubating thymocytes with treatments known to exert their effects via activation of protein kinase C. Our results suggest that endonuclease activity in thymocyte nuclei undergoes rapid, spontaneous turnover. Agents interfering with macromolecular synthesis may therefore block DNA fragmentation in thymocytes by depleting nuclei of endogenous endonuclease activity.