EFFECTS OF DIVISION-SYNCHRONIZING HYPOXIC AND HYPERTHERMIC SHOCKS UPON TETRAHYMENA RESPIRATION AND INTRACELLULAR ATP CONCENTRATION

The division of Tetrahymena pyriformis GL cells was synchronized with either seven hypoxic or five hyperthermic (heat) shocks. Hyperthermic shocks of 34°C produced no reduction in respiration rate and only a 19% decline in intracellular ATP concentration. Hypoxic shocks of 0.15% ambient oxygen concentration depressed intracellular ATP concentration 50%. It therefore appears that hypoxic shock, but not hyperthermic shock, reverses progress of Tetrahymena toward fission by reducing ATP concentration through a reduction of the rate of oxidative phosphorylation. After the first synchronized division, whether synchronized by intermittent hypoxia or hyperthermia, total respiration rate increased exponentially at the same rate of increase as total respiration rate in an exponentially growing (log phase) Tetrahymena cell culture. Before the first synchronized division, the total respiration rate increased exponentially but more slowly than after completion of the first synchronized division. The pattern of increase of total respiration during division synchronized by either procedure was different than the pattern of increase of total respiration of synchronous cells observed by Zeuthen.     

TpMRK regulates cell division of Tetrahymena in response to oxidative stress

TpMRK was identified as a stress‐responsive mitogen activated protein kinase (MAPK)‐related kinase and has been shown to play a critical role in the stress signalling in Tetrahymena cells. Here, we found that the mRNA expression of TpMRK was correlated with cell division of Tetrahymena with decreased expression occurring in cells prior to entering synchronous cell division induced by heat treatment. Notably, cell division was delayed with a lower division index of 40% after exposure to hydrogen peroxide while 85% of cells underwent cell division synchronously at 75 min after heat treatment without the oxidative exposure. Furthermore, inactivation of TpMRK signalling by p38 MAPK inhibitor SB203580 or MEK inhibitor PD 98059 partially derepressed cell division induced by hydrogen peroxide. Our data suggest that oxidative stimuli might cause aberration of synchronous cell division of Tetrahymena through activating the TpMRK cascade. Copyright © 2009 John Wiley & Sons, Ltd.     

Microcalorimetric Study on the Toxic Effect of Pb<Superscript>2+</Superscript> to <Emphasis Type="Italic">Tetrahymena</Emphasis>

The toxic effect of Pb²⁺ has been studied in eukaryotic cells by using Tetrahymena as a target. The maximum power (P _m) and the growth rate constant (k) were determined, which showed that values of P _m and k were linked to the concentration (C) of Pb²⁺. The addition of Pb²⁺ caused a decrease of the maximum heat production and growth rate constant, indicating that Tetrahymena growth was inhibited in the presence of Pb²⁺, and Pb²⁺ took part in the metabolism of cells. From micrographs, morphological changes of Tetrahymena were observed with addition of Pb²⁺, indicating that the toxic effect of Pb²⁺ derived from destroying the membrane of surface of Tetrahymena. According to the thermogenic curves and photos of Tetrahymena under different conditions, it is clear that metabolic mechanism of Halobacterium halobium R1 growth has been changed with the addition of Pb²⁺.     

Tetrahymena pyriformis as a Model System for Membrane Studies*†

SYNOPSIS. Tetrahymena pyriformis is an exceptionally useful subject for studying metabolic interrelationships among intracellular membranes. Its advantages include the striking differences in lipid composition among the cell's various functionally distinct membrane systems, indicating a pronounced lipid specificity at the membrane sites. The magnitude of these differences permits analysis of the mechanisms underlying the specificity. Even more valuable is the unique physical isolation of ciliate surface membranes from the cytoplasm of the cell. In contrast to the almost immediate equilibration of newly made lipids with preexisting lipids found in most cells, Tetrahymena surface membranes have a lipid turnover slow enough to be conveniently analyzed. Finally, the well-studied responses of Tetrahymena to such physiological stresses as heat and starvation may be used to evaluate the effects of environmental factors on membrane formation.     

Tubulin synthesis and heat shock-induced cell synchrony in Tetrahymena

This paper offers the suggestion that heat shock inhibition of tubulin synthesis accounts for the molecular mechanism by which periodic heat shocks induce cell synchrony in Tetrahymena. Each heat shock (34 °C) represses tubulin synthesis and blocks the division cycle at the point when the oral structure, rich in microtubules, would normally begin to assemble. Recovery (at 28 °C) from each heat shock is characterized by parallel derepression of tubulin synthesis and of oral development. Changes in protein synthesis patterns are complex when the temperature is shifted up and down between 28 and 34 °C and further experimental support is required in support of the hypothesis here forwarded.     

Determinations of Volumes and Minimal Surface Areas of Individual Compressed Live Tetrahymena1

ABSTRACT. A method to determine the volume of individual live Tetrahymena with improved precision has been developed. Cells are compressed between a microslide and coverslip and their volume calculated from their thickness and area determined by interference microscopy and from a photomicrograph, respectively. A formula has been derived to correct for the “edge error” which arises because the rounded edges of the cells are projected on the film as if they were rectangular. The minimal surface area of compressed cells, i.e. that necessary to surround the cells smoothly, can also be calculated. Cells may be recovered after measurements. The method may also be applied to other cells.     

THE TETRAHYMENA HOMOLOG OF BACTERIAL AND MAMMALIAN 4-HYDROXYPHENYLPYRUVATE DIOXYGENASES LOCALIZES TO MEMBRANES OF THE ENDOPLASMIC RETICULUM

The expression and intracellular localization of the Tetrahymena homolog of 4-hydroxyphenylpyruvate dioxygenase (HPPD) were investigated in wild-type Tetrahymena thermophila strain B1868 VII and the mutant strains IIG8, defective in food vacuole formation, MS-1, blocked in secretion of lysosomal enzymes, and SB 281, defective in mucocyst maturation. Immunoelectron microscopy and confocal laser scanning microscopy demonstrated that Tetrahymena HPPD primarily localized to membranes of the endoplasmic reticulum. In addition, Tetrahymena HPPD was detected in association with membranes of the Golgi apparatus, and transport vesicles in exponentially growing wild-type and mutant strains. In starved cells, Tetrahymena HPPD localized exclusively to membranes of small vesicles. Since no de novo synthesis ofTetrahymena HPPD takes place in cells starved for more than 30min, these results suggest that there is a flow ofTetrahymena HPPD from the endoplasmic reticulum to small vesicles, possibly via the Golgi apparatus, and thatTetrahymena HPPD contains a signal for vesicle membrane retrieval or retention.     

HISTONE F1 OF TETRAHYMENA MACRONUCLEI : Unique Electrophoretic Properties and Phosphorylation of F1 in an Amitotic Nucleus

Histone fraction F1 has been isolated and purified from macronuclei of the ciliated protozoan, Tetrahymena pyriformis. In many respects, Tetrahymena F1 is similar to that of other organisms. It is the only Tetrahymena histone soluble in 5% perchloric acid or 5% trichloroacetic acid, has a higher molecular weight than any other Tetrahymena histone, is the histone most easily dissociated from Tetrahymena chromatin, and is susceptible to specific proteolytic cleavage. However, unlike F1 in all other organisms, Tetrahymena F1 is not the slowest-migrating histone fraction when analyzed by polyacrylamide gel electrophoresis at low pH. Tetrahymena F1 also exhibits unusual behavior in sodium dodecyl sulfate-containing polyacrylamide gels, migrating faster than calf thymus F1 at pH 10, and slower than calf thymus F1 at pH 7.6. Tetrahymena F1 was found to be highly phosphorylated in rapidly growing cells, suggesting that the relationship between cell replication and F1 phosphorylation previously observed in mammalian cells may extend to all eukaryotes. The observation that extensive F1 phosphorylation occurs in macronuclei, which divide amitotically, argues against a unique role for F1 phosphorylation in the process of chromosome condensation at mitosis.     

Is cyclin Zeuthen's “division protein”?

Biochemical evidence is presented for the presence of cyclin in Tetrahymena. Zeuthen previously postulated the existence of a heat-labile “division protein” to explain heat-shock-induced division synchrony in Tetrahymena [(1964) Synchrony in Cell Division and Growth (Zeuthen, E., Ed.), pp. 99–158, Interscience, New York]. We show that cyclin is heat-labile in Tetrahymena and suggest that cyclin may be Zeuthen's division protein. Cyclin and cell cycle control is of interest in Tetrahymena because the division mechanism drives macronuclear amitosis, closed and acentric micronuclear mitosis, and cortical differentiation in this cell type.     

THE RELATIONSHIP BETWEEN DEOXYRIBONUCLEIC ACID REPLICATION AND CELL DIVISION IN HEAT-SYNCHRONIZED TETRAHYMENA

The effect of supraoptimal temperature on macronuclear DNA synthesis in Tetrahymena was studied by radioautography during prolonged heat and heat-shock synchronization treatments. Prolonged heat treatments (34°C) delayed the initiation of S, but did not appreciably delay DNA synthesis in progress. Return to optimal temperature (28°C) 50 or 100 min later resulted in initiation of S, in delayed cells, at a rate greater than in controls. During the synchronization treatment, most cells were unable to enter S during a heat shock, but initiated S with a slight delay during the following intershock period. These cells were not appreciably delayed in completion of S by subsequent heat shocks. Supraoptimal temperature appears to affect the DNA synthetic cycle near the G₁ to S transition. Cells subjected to the heat-shock treatment in early G₁ all participated in one S period, and many underwent a succession of two S periods. DNA synthesis occurred in about 50% of the cells between EST and the first synchronous division, with the likelihood of DNA synthesis becoming greater the longer the interval between these two events. In some cells no detectable DNA synthesis occurred between EST and the second synchronous division. It was concluded that a precise temporal alternation of DNA replication and cell division is not obligatory in Tetrahymena.     

Role of histone deacetylation in developmentally programmed DNA rearrangements in Tetrahymena thermophila

In Tetrahymena, as in other ciliates, development of the somatic macronucleus during conjugation involves extensive and reproducible rearrangements of the germ line genome, including chromosome fragmentation and excision of internal eliminated sequences (IESs). The molecular mechanisms controlling these events are poorly understood. To investigate the role that histone acetylation may play in the regulation of these processes, we treated Tetrahymena cells during conjugation with the histone deacetylase inhibitor trichostatin A (TSA). We show that TSA treatment induces developmental arrests in the early stages of conjugation but does not significantly affect the progression of conjugation once the mitotic divisions of the zygotic nucleus have occurred. Progeny produced from TSA-treated cells were examined for effects on IES excision and chromosome breakage. We found that TSA treatment caused partial inhibition of excision of five out of the six IESs analyzed but did not affect chromosome breakage at four different sites. TSA treatment greatly delayed in some cells and inhibited in most the excision events in the developing macronucleus. It also led to loss of the specialized subnuclear localization of the chromodomain protein Pdd1p that is normally associated with DNA elimination. We propose a model in which underacetylated nucleosomes mark germ line-limited sequences for excision.     

Effects of inhibitors of RNA and protein synthesis on activation of glyconeogenesis in Tetrahymena

The effects of actinomycin D, puromycin, and p-fluorophenylalanine on the activation of glyconeogenesis in Tetrahymena were studied. The extent of activation of glyconeogenesis in cultures containing inhibitor was as great as or greater than in the controls, as was the uptake of tracer levels of acetate into glycogen. These increases occurred despite a partial or complete inhibition of synthesis of isocitrate lyase, a glyconeogenic enzyme in Tetrahymena. Washed cells from these cultures could convert tracer or substrate levels of acetate to glycogen at enhanced rates. When glyconeogenesis was activated in starved cells in the presence of inhibitor, there was a negligible increase in the amount of isocitrate lyase, but a significant increase in the rate of glyconeogenesis. The data indicate that glyconeogenesis in Tetrahymena can be activated in the absence of enzyme synthesis.     

Effect of endocytosis upon acid phosphatase activity ofTetrahymena pyriformis

Summary Increased endocytosis inTetrahymena pyriformis, produced by presenting starved cells with either peptone-yeast extract medium or killed yeast cell suspension, results in increased cellular acid phosphatase activity.Tetrahymena, grown in peptone-yeast extract medium, showed increased acid phosphatase activity after phagocytosis of yeast cells. This increase was not apparent until about one hour after presentation and was maximal at about 2.5 hours.Tetrahymena, grown on yeast suspension, showed little increase in acid phosphatase activity on presentation with peptone-yeast extract medium. These results may indicate that endocytosis, of either particles or solutes, produces an adaptive increase in acid phosphatase activity (presumably lysosomal in nature) which is related to feeding.Histochemical examination failed to localise the increase in acid phosphatase activity cellularly, but small particles, of about 1 diameter, which showed acid phosphatase activity and were presumably lysosomes were noted. Closely orientated yeast cells showed varying intensities of lead deposition, from absence to intense staining. This suggests that newly ingested yeast cells may be ingested initially in a single phagosome and that thereafter one or more lysosomes may fuse with them.     

THE REGENERATION OF CILIA IN PARTIALLY DECILIATED TETRAHYMENA

Partial deciliation of Tetrahymena resulted in cells losing 75% of their cilia, with the balance being paralyzed. The paralyzed cilia are resorbed in the first 20 min after partial deciliation, and regeneration of cilia begins before resorption is completed. Inhibition of protein synthesis with cycloheximide does not inhibit ciliary resorption or regeneration, whereas vinblastine sulfate inhibits regeneration but not resorption. Inhibition of regeneration occurs in completely deciliated cells when they are treated with cyclohexmimide or vinblastine sulfate. It is concluded that the resorbing cilia contribute materials which allow regeneration to occur in the absence of protein synthesis. The volume of cilia regenerated in the presence of cycloheximide in partially deciliated cells is greater than the ciliary volume which is resorbed. This suggests the Tetrahymena cells have a pool of ciliary precursors. This pool does not contribute materials for regeneration in completely deciliated cells which are treated with cycloheximide. It is concluded that resorbing cilia in partially deciliated cells contribute materials which potentiate assembly of cilia from the pool of precursors.     

Epinigericin toxicity towards Tetrahymena pyriformis GL; changes in cell volume and intracellular pH

A study of the toxicity of epinigericin, an antibiotic ionophor, towards the ciliate Tetrahymena pyriformis showed that this molecule stopped cell division, increased cell volume and led to a more basic intracellular pH. The action of epinigericin was probably linked to its function as an ionophor. The ionic selectivity of this molecule is still not known. The raising of the intracellular pH of ciliates by this antibiotic may be linked to its toxic action and its ion-transport mechanism in Tetrahymena. *** DIRECT SUPPORT *** AG903066 00009     

Expression of Surface Coat Glycoconjugates by Bacteria-Fed Tetrahymena1

ABSTRACT. We have shown that bacteria-fed Tetrahymena express at their surface and excrete into the medium a glycoconjugate absent in axenically grown cells. A preliminary analysis of the purified molecule is given. Immunolabeling of blotted surface extracts and fixed cells shows that bacteria-fed Tetrahymena build up a surface coat whose material originates totally or in part in the mucocysts. The glycoconjugate is located externally on the coat and mediates cell immobilization and immunolabeling by the serum. The results also indicate that axenic cells are probably devoid of surface coat.     

An electrophoretic comparison of the histones of various strains of Tetrahymena pyriformis

Histones were extracted from isolated macronuclei of several strains of the ciliated protozoan Tetrahymena pyriformis and compared by electrophoresis on both urea-acrylamide and sodium dodecyl sulfate-acrylamide gels. High resolution urea-acrylamide-gel electrophoresis resolves Tetrahymena histones into five main classes. The lysine-rich histone H1 exhibits microheterogeneity within each strain, mostly due to phosphorylation, and varies extensively in electrophoretic mobility and apparent molecular weight among the strains. Both H3 and H4 are constant among Tetrahymena strains and consist of several secondarily modified subspecies. However, while the electrophoretic constancy of H4, observed in higher organisms, extends to this lower eukaryote, H3 of each Tetrahymena strain migrates faster than calf thymus H3 in both gel systems. This suggests that H3 is not as rigidly conserved as H4. Fraction HX has no electrophoretic counterpart in calf thymus histone. It consists of five subfractions, each of which displays a remarkably constant electrophoretic mobility among the various strains. H2B is electrophoretically variable among Tetrahymena strains. The intersyngen and interphenoset diversity of Tetrahymena histone is shown to be comparable to that found among vertebrate classes.     

The Absence of a Direct Relationship between the Ability of Yeasts to Grow at Elevated Temperatures and Their Survival after Lethal Heat Shock

The study of the growth of the yeasts Rhodotorula rubra, Saccharomyces cerevisiae, and Debaryomyces vanriji at elevated temperatures and their survival after transient lethal heat shock showed that the ability of these yeasts to grow at supraoptimal temperatures (i.e., their thermoresistance) and their ability to tolerate lethal heat shocks (i.e., their thermotolerance) are determined by different mechanisms. It is suggested that the thermotolerance of the yeasts is mainly determined by the division rate of cells before their exposure to heat shock.     

Uptake of Ferritin-labeled Antibodies by Tetrahymena1

Experiments with Tetrahymena thermophila using ferritin probes revealed that these cells take up ferritin conjugated to antibodies (not directed against Tetrahymena) much more readily than they do ferritin or cationized ferritin. The massive and rapid uptake of antibody-ferritin offers certain advantages for studies of endocytosis and membrane flow in cells of this type, and the method may be applicable to other types of protozoa as well.     

Phospholipase D in Tetrahymena: activity and significance

We detected phospholipase D in three species of ciliates: Tetrahymena: T. thermophila, T. pyriformis and T. setosa in nutrient medium supplemented with ethanol in in vivo systems, by the appearance of phosphatidylethanol. The calcium ionophore A23187 increased the synthesis of phosphatidylethanol, as compared with untreated controls. We suggest that Tetrahymena possess a calcium sensitive phospholipase D. Propranolol caused the cells in dense cultures to increase their average generation times or die, dependent on the drug concentration. This inhibition could be overcome by the addition of phospholipids or ethanol. Pure phosphatidylethanol had no effect on growth rates or generation times in cultures at high cell density, but postponed cell death in cultures at low cell density by a factor of 10. We suggest that an important role of phospholipase D in Tetrahymena is to supply the cell with diacylglycerol without which it can not enter the mode of proliferation from the lag phase of the culture.