STUDIES ON THE MAINTENANCE OF ORAL DEVELOPMENT IN TETRAHYMENA PYRIFORMIS GL-C : II. The Relationship of Protein Synthesis to Cell Division and Oral Organelle Development

The effects of puromycin on synchronized Tetrahymena pyriformis were investigated at two different concentrations, 43 µg per ml and 430 µg per ml. The rate of incorporation of histidine-¹⁴C into hot TCA-insoluble material was reduced by 30% at the low concentration and by 80–90% at the high concentration. The rate of oxygen uptake was lowered by only 10–20% at both concentrations. Cell division was prevented at both concentrations, if the drug was added prior to a "transition point" at about 45 min after the end of the synchronizing treatment. Development of "anarchic field" oral primordia was arrested, while primordia in early stages of membranelle differentiation were resorbed. Resorption began shortly after addition of the drug, and proceeded most rapidly at the lower concentration. If the drug was added after the "transition point," cell division and oral primordium formation were completed with only slight delay at the low concentration, and with considerable delay (in some cases complete arrest) at the high concentration. The results thus indicate that protein synthesis is involved in the later as well as the earlier stages of development; what specially characterizes the earlier stages, prior to the "transition point," is a dramatic response to partial inhibition of protein synthesis. It is suggested that this response involves the activation or release of a latent intracellular degradative system which is specific for developing structures.     

Critical Phases of Oral Primordium Development in Tetrahymena pyriformis GL-C: An Analysis Employing Low Temperature Treatment

SYNOPSIS. The effects of temperatures of 12–18 C on cell division and oral primordium development were investigated in cultures of synchronized Tetrahymena pyriformis GL-C. If exposures to 12 or 15 C were initiated prior to a “transition point,” long delays of cell division were generated. After this transition point, cell division could no longer be substantially delayed by exposure to low temperature. The time of the transition point was somewhat earlier with 15 C than with 12 C treatments. At temperatures higher than 15 C long delays of cell division were not generated regardless of time of treatment. The effects of low temperature on oral morphogenesis were strongly dependent on the stage which was affected. (i) The further development of cells initially in the “anarchic field” stage (stage 1) was immediately blocked at both 12 and 15 C. (ii) Cells initially in the stages of incipient membranelle differentiation (stages 2 and 3) continued to develop at both 12 and 15 C, and formed oral primordia in which all 3 membranelles were clearly differentiated (stage 4). The subsequent progress of these stage 4 primordia depended on the temperature: at 12 C virtually all were resorbed (and cell division was blocked); at 15 C only about 1/3 were resorbed, while the remaining 2/3 completed their development (with the concomitant completion of cell division). (iii) Cells initially in intermediate stages of membranelle differentiation (early stage 4) developed to some extent at 12 C, and then underwent resorpton of oral primordia and blockage of cell division; at 15 C such cells completed their development and division normally. (iv) Cells in which the membranelles and undulating membrane were complete or nearly so (stage 5 and very late stage 4) at the time of the beginning of the cold treatment subsequently finished their development and went thru cell division, even at temperatures as low as 5 C. These results indicate that in addition to a “stabilization point” which occurs shortly before the completion of membranelle development, there is an earlier change in the primordium at the time of the onset of membranelle development, which renders development much less sensitive to direct interference by low temperature.     

Inhibitors of protein synthesis increase the agglutinability mediated by concanavalin A of the unfertilized mouse oocyte

The agglutinability mediated by concanavalin A has been studied in the zona-free mouse oocyte before and after fertilization or treatment with inhibitors of protein synthesis. At lectin concentrations of 10 μg/ml ot higher the zygote is clearly more agglutinable than the unfertilized oocyte. Treatment with 10 μg/ml of cycloheximide or puromycin, which causes parthenogenetic activation, greatly increases the agglutinability of the unfertilized oocyte; the agglutinability of the zygote and of the early blastocyst is not increased by such treatment. The possibility is discussed that the repression of cell division requires the synthesis of unstable protein molecules of the cell surface which are also involved in lectinmediated agglutinability.     

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.     

Dose- and time-dependent synthesis of 20-hydroxyecdysone modulated polypeptides in the epidermis of Tenebrio molitor

Cellular (non-cuticular) polypeptides were isolated from mid-instar larval epidermis incubated in the presence or absence of 20-hydroxyecdysone (20HE) for 14–16 h in vitro. Polypeptides synthesized during the last few hours of incubation were labelled with [³⁵S]methionine, separated in cell lysates by two-dimensional polyacrylamide gel electrophoresis and detected fluorographically. Cells incubated with hormone incorporated 28% more label into polypeptide. The synthesis of over 250 polypeptides was detected in total cell lysates. Of these, 54 showed an altered level of synthesis in response to 20HE treatment. The synthesis of most (33) was depressed. The relative synthetic rate of most “down-regulated” 20HE-sensitive polypeptides began to drop at 10⁻³ μg/ml whereas that of most “up-regulated” polypeptides increased only at concentrations above 10⁻¹ μg/ml. An early response to 20HE, involving the de novo synthesis of a 43 kDa polypeptide, was first detectable after 2 h of exposure to hormone, and peaked after 4 h. The synthesis of this 43 kDa polypeptide was selectively enhanced by the addition of 10⁻² μg/ml cycloheximide to medium containing 20HE. The long-term effect (12–16 h) of 20HE on polypeptide synthesis in subcellular fractions of the epidermis was also examined. Polypeptide synthesis found in the nuclear, mitochondrial-lysosomal, microsomal and soluble fractions changed in response to 20HE. It appears that 20HE influences epidermal behaviour predominantly through its ability to modulate the synthetic rate of many cellular polypeptides, rather than by turning off the synthesis of a few pre-existing ones and switching on that of a few new ones.     

RADIOSENSITIVITY,RNA, AND PROTEIN METABOLISM OF “LEAKY” AND ARRESTED CELLS IN SUNFLOWER ROOT MERISTEMS (HELIANTHUS ANNUUS)

Two cell populations in sunflower root meristems are described. Most cells stop in G1 after being cultured in sucrose-deficient medium, but “leaky” cells continue through DNA synthesis and stop in G2. A comparison of “leaky” and arrested cells is reported on the basis of radiosensitivity, and cytological and biochemical responses to metabolic inhibitors. “Leaky” cells are randomly distributed throughout primary meristematic tissues. They are not inhibited from initiating DNA synthesis by exposure to doses of γ-irradiation ranging from 300–7200 R; arrested cells, depending upon the dose, are inhibited partially or completely. “Leaky” cells do, however, show a dose-dependent mitotic delay in G2, which is the same as arrested cells. Treatment with puromycin and actidione does not inhibit “leaky” cells from initiating DNA synthesis but does inhibit them from mitosis. Arrested cells are inhibited from advancing to S and M by both inhibitors. Also, puromycin and actidione cause a decrease in protein and RNA synthesis, demonstrating a possible protein dependent RNA synthesis necessary for cell cycle progression. Actinomycin D (10 μg/ml) inhibits neither “leaky” nor arrested cells from entering S and M. At 30 μg/ml, however, arrested cells are partially inhibited. “Leaky” cell metabolism is unique in preparation for and initiation of DNA synthesis but similar to that of the remaining cells of the meristem in terms of requirements for progression through the rest of the mitotic cycle.     

Adaptation to cycloheximide of macromolecular synthesis in Tetrahymena

Cycloheximide (CHI) at 10 ng/ml partially inhibited protein synthesis in exponential cultures of Tetrahymena Sp. At 20 ng/ml or greater, inhibition was complete. When protein synthesis was inhibited to any extent, cell division ceased immediately. In all instances where measured, synthesis of RNA and DNA also ceased. After a period of delay, cellular functions reinitiated in the order: (i) protein synthesis, (ii) DNA synthesis and, (iii) RNA synthesis and cell division. The delay in cell division was divided into three phases of: I, zero; II, low; and, III, fully recovered rates of exponential protein synthesis. The length of the three phases increased with increasing concentration of CHI Prior growth of cells for one generation in the presence of 7.5 ng/ml CHI (facilitation) eliminated phase I and slightly decreased phases II and III following subsequent challenge with an inhibitory concentration of CHI. Facilitation for six generations further decreased phases II and III. Protein synthesis and cell division were not inhibited during facilitation In the culture, succinate dehydrogenase activity did not increase during the delay but increased normally at the onset of division. In contrast, NADPH-cytochrome c reductase activity continued to increase for an hour after inhibition of protein synthesis, was constant for a period and did not increase again until an hour after reinitiatoin of cell division and RNA synthesis Inhibition of division of all cells was immediate and reinitiation of synthesis and cell division was non-synchronous.     

An analysis of the recovery of tetrahymena from effects of cycloheximide

When cycloheximide (0.2 μg per ml) was added to synchronized cultures of Tetrahymena pyriformis GL-C, the initial rate of incorporation of ¹⁴C-leucine was reduced to about 20% of the rate observed in control cells. After one hour, the rate increased fairly abruptly to about 60% of the control rate. The cells in cycloheximide underwent synchronous division about three hours after addition of cycloheximide. A second addition of cycloheximide had little effect on either the rate of incorporation or on the time of cell division in the drug. The medium in which cells had recovered brought about full inhibition of ¹⁴C-leucine incorporation in fresh cells, indicating that recovery was not accompanied by appreciable degradation of the cycloheximide. It was therefore concluded that during recovery the cells were either adapting to the cycloheximide or excluding it. The recovery process shows some specificity, since cells which had recovered from cycloheximide, and had become insensitive to a second dose of this drug, still retained full sensitivity to another drug, colchicine. Conversely, cells recovering in colchicine became insensitive to fresh colchicine but remained sensitive to cycloheximide.     

Evidence for a cycloheximide-sensitive component in the biological clock of Acetabularia.

An 8-h exposure to cycloheximide (0.1 μg/ml) delays the phase of the photosynthesis rhythm 6–14 h in individual Acetabularia cells monitored at 25 °C, providing the drug is present during the first half of a cell's circadian cycle. Puromycin pulses (50 μg/ml) are like cycloheximide in their effect on phase, but chloramphenicol (100 μg/ml) is ineffective. These results indicate that protein synthesis on 80S ribosomes provides a necessary component for the biochemical mechanism of circadian regulation in Acetabularia.     

Synthetic Requirements of Chloroplast Development in Chlamydomonas reinhardi*†

SYNOPSIS. The synthesis of chlorophyll by chlorotic cultures of Chlamydomonas reinhardi is stimulated by a utilizable carbon source. This synthesis is almost completely inhibited by cycloheximide in concentrations as low as 0.50 μg/ml. The period of chloroplast development during which stimulation by carbon source and inhibition by cylcoheximide are most effective corresponds to a period of rapid formation of chloroplast lamellae.     

Effects of Actinomycin D on Generation Time and Morphogenesis in Paramecium*

SYNOPSIS. The sensitivity of Paramecium tetraurelia (=P. aurelia syngen 4) cells to pulse treatments with various doses of Actinomycin D (AMD) was estimated by comparing the generation times of treated and untreated sister cells. It was found that the delay of division in treated cells depended on the concentration of AMD, on their “age” at the time of the pulse treatment, and on their individual sensitivity. Sensitivity of Paramecium to AMD changes during the cell cycle in a predictable way. About 3 1/2 hr before the normally expected cell fission (total generation time ～ 5 1/2 hr) there is a decrease of sensitivity. Thereafter, the cell enters a new stage with a progressive increase of sensitivity. This 2nd phase ends at the “transition point” (～ 2 hr before cell division), when sensitivity drops abruptly. The division process itself may be altered and slowed down by high concentrations of AMD, even if the drug is applied after the transition point, but this process can never be completely annulled. The impairment of the division mechanism may lead to morphologic anomalies in the offspring. Resorption of oral anlagen in P. tetraurelia probably never occurs during the cell cycle after AMD treatment. The reason for individual variability of the cells, mechanisms controlling development, and the question of an obligate sequence of gene action in each cell cycle are discussed.     

The Effect of Methyl Glyoxal on Growth and Cell Division of Chlamydomonas reinhardii

Methyl glyoxal, at concentrations of 1.0–2.0 mM, inhibits growth of the green alga, Chlamydomonas reinhardii. The photosynthetic assimilation of carbon dioxide is also inhibited by the glyoxal. At the lower concentrations (less than 1.0–1.5 mM) protein synthesis Is inhibited, whereas polysaccharide synthesis and assimilation of carbon dioxide into the alcohol–soluble fraction is stimulated; at higher concentrations fl.5–2.5 mM) these latter two processes are also inhibited. Cell division in synchonized cultures of the alga is more sensitive to methyl glyoxal when it is added at the start of the growth cycle than when added late in the growth cycle. However, when added late in the growth cycle, methyl glyoxal delays the onset of cell division by 2 hours. No such delay occurs when cycloheximide is added 4–6 hours before division.     

Continuous protein synthesis is required to maintain the probability of entry into S phase

“Normal fibroblast” lines such as 3T3 cells arrest in the G0/G1 compartment of the cell cycle when starved of serum. Following readdition of serum and after a lag of 14 hr, the cells enter S phase with first-order kinetics. Cell cycle progress after stimulation is thus consistent with the existence of a single, rate-limiting random event (or transition) in G1 as proposed by Smith and Martin (1973). The addition of low concentrations of cycloheximide (33–100 ng/ml) at any time after the end of the lag phase brings about a rapid reduction (within 1–2 hr) of the rate constant for entry into S phase by an amount that is proportional to the inhibition of leucine incorporation. This suggests that the transition probability depends upon the continuous synthesis of a protein with a short half-life, or on some other unstable substance whose concentration is geared to the rate of translation. More importantly at present, the results indicate that the rate-limiting transition occurs within 2 hr of the start of DNA synthesis.When the same low concentrations of cycloheximide are added at the time of serum stimulation, they also lead to a marked elongation of the lag phase which again is related to the inhibitor concentration. This result is surprising since the lag is independent of serum concentration which itself influences the rate of protein synthesis.     

Problems in the estimation of mutation rates and in the detection of induced mutations in man

The contribution of nuclear-directed protein synthesis in the repair of lethal and mitochondrial genetic damage after UV-irradiation of exponential and stiationary phase haploid yeast cells was examined. This was carried out using cycloheximide (CH), a specific inhibitor of nuclear protein synthesis. It appears that nuclear protein synthesis required for the increase in survival seen after the liquid holding of cells at both stages, as well as for the “petite” recovery seen after the liquid holding of exponential phase cells. The characteristic negative liquid holding effect observed for the UV induction of “petites” in stationary phase cells (increase of the frequency of “petites” during storage) remained following all the treatments which inhibited nuclear protein synthesis. However, the application of photoreactivating light following dark holding with cycloheximide indicates that some steps of the repair of both nuclear and mitochondrial damage are performed in the absence of a synthesis of proteins.     

Cycloheximide effect on DNA degradation and delta-crystallin synthesis in terminally differentiating lens cells

Low concentrations of a protein synthesis inhibitor, cycloheximide, were added throughout the process of in vitro differentiation of 11-day old embryonic chick lens cells. We found with low concentrations of cycloheximide (0.01 to 0.03 microgram/ml, 3 days of culture), that there was an almost complete delay of DNA degradation as observed on alkaline sucrose gradient. Identical concentrations and exposure time had no blocking effect on increased delta-crystallin synthesis as detected by immunoprecipitation and electrophoresis. Higher concentrations of cycloheximide (0.1 to 1 microgram/ml) showed a marked effect on DNA size and a net inhibition on delta-crystallin synthesis. Thus a selective effect of low doses of cycloheximide was observed on terminal differentiation suggesting that there was not a relationship between DNA degradation and delta-crystallin synthesis in these short term experiments. The investigations of minor proteins could be of interest as they may have a crucial role in intact nuclei cataracts.     

Differential effect of cycloheximide on penicillin and cephalosporin biosynthesis by Cephalosporium acremonium

In resting cells of Cephalosporium acremonium CW19, protein synthesis was inhibited completely by 100 μg cycloheximide per ml. Furthermore, ongoing protein synthesis halted abruptly when cycloheximide was added after 20 min of incubation. Although cycloheximide did not affect the specific rate of penicillin N production, it markedly inhibited the specific rate of cephalosporin C production. The effect of cycloheximide was not influenced by the carbon source used to prepare the cells for the resting cell system.     

Parthenogenetic development of bovine oocytes matured in vitro for 24 hr and activated by ethanol and cycloheximide

This research was undertaken to improve development of parthenogenetic embryos following various combined treatments of ethanol and cycloheximide. In Experiment 1 in vitro matured oocytes (IVM, 24 hr) were treated with 7% ethanol for 5 min followed by incubation in 10 μg/ml cycloheximide in Medium 199 for 0 (control), 5, 10, and 20 hr. Development to 2–8 cells following culture for 3 days was similar among treated groups (32–41%; P > 0.05), which was higher than that of controls (6%; P < 0.05). Experiment 2 compared pre-ethanol exposures for 0, 1, 2.5, and 5 min, followed by 5 hr cycloheximide treatment on activation development. One- to 5-min groups resulted in 42–44% cleavage contrasted to 1–12% for controls (P < 0.05). Experiment 3 examined the effect on oocyte development of ethanol and different concentrations of cycloheximide (0, 1, 5, and 10 μg/ml). Cleavage to 2–8 cells was similar among the 5 and 10 μg/ml cycloheximide groups (36% and 42%, P > 0.05) but lower (P < 0.05) for the 1 μg/ml group (24%) and the controls (2–13%). When 5 μg/ml cycloheximide was used (Experiment 4), pre-exposure to ethanol (1, 2.5, and 5 min) resulted in more oocytes cleaved (38–41%) than in the cycloheximide alone group (0%) or the control (0%, P < 0.05). Experiment 5 tested blastocyst development of the activated oocytes with or without cytochalasin B treatment. Oocytes developed to blastocyts were 0%, 14%, 3%, and 3% (P < 0.05), respectively, for control, treatment with ethanol and cycloheximide in the presence, or absence of cytochalasin B, or electrical pulse plus cycloheximide. In conclusion, the combined ethanol and cycloheximide treatment supported high rates of parthenogenetic development using 24 hr IVM bovine oocytes. Blastocyst rate was significantly higher when cytochalasin B was added to the combined activation regimen. © 1994 Wiley-Liss, Inc.     

Morphology and Development of Mirror-Image Doublets of Stylonychia mytilus

This paper describes the cortical anatomy and development of mirror-image doublets of Stylonychia mytilus, analyzed using the protargol technique. The reversed, or “left-handed” (LH) component of these doublets is a mirror image of the normal or “right handed” (RH) component with regard to the arrangement of cortical structures. The mirror-image patterning is imperfect, however, as the individual ciliary structures of the LH component all are of normal internal asymmetry, and the orientation of membranelles is inverted. Certain structures that would be expected to form near the line of symmetry are absent. During cell division and cortical reorganization, ciliary primordia arise and become arranged in a mirror-image pattern that is more perfect than that exhibited by the mature structures. Deviations from a mirror-image pattern appear at late stages when organelle sets differentiate within ciliary primordia: for example, the membranelle set differentiates within the oral primordium of the LH component in a sequence that is an inversion rather than a mirror image of the corresponding sequence of the RH component. This mixed control of oral development by different cortical “informational systems” accounts for some of the characteristic abnormalities of the mature oral structures of the LH component.