Studies of Membrane Formation in Tetrahymena pyriformis. VIII. On the Origin of Membranes Surrounding Food Vacuoles*†

SYNOPSIS. A procedure was devised for the isolation of purified food vacuoles from Tetrahymena pyriformis fed particles of ferric oxide. Phospholipids extracted from vacuolar membranes were more similar in composition to the lipids of microsomes than to lipids of whole cells, cilia or post-microsomal supernatant. Fractionation of cells grown in the presence of [¹⁴C]palmitic acid or [³²P]inorganic phosphate also revealed similarities in the specific radioactivities of microsomes and vacuolar membranes. The data suggested that vacuolar membranes arise from a pool of cytoplasmic membranes.     

A new principle of cell cultivation: No air-liquid interface but gas exchange across a synthetic membrane

Summary A completely liquid-filled growth chamber for axenic cultures ofTetrahymena pyriformis is described; gas exchange is ensured across a synthetic membrane. The chamber may be incorporated into a continuous flow system with inoculation and removal of cell samples under sterile conditions. Initially, the generation time of the cells was slightly prolonged, about 10%, but after some cell doublings decreased to 5%. The capacity of the cells to form food vacuoles (endocytosis) was unaltered during growth in the chamber. The synthetic membrane was highly permeable to O₂ and CO₂; however, cells grown in the chamber contained small refractive granules. The culture chamber permits the culture volume to be varied and it may be used for other protozoa, bacteria, and even tissue culture cells.     

Concanavalin A-Sepharose Chromatography of Hexosaminidase Isozymes Secreted By Tetrahymena*

Tetrahymena pyriformis strain HSM secretes 4 isozymes of hexosaminidase. Purified isozymes B₁ and B₂ are eluted from the void volume of a concanavalin A-Sepharose column, suggesting that they are not glycosylated. Purified isozymes A₁ and A₂ bind to the column and are eluted at ～0.1 M α-methylmannoside, suggesting that these isozymes are glycoproteins. In agreement with earlier deductions based on a differential kinetic assay for the A and B isozymes, the elution pattern of hexosaminidase activity from material secreted by cells grown to early and late stationary phase was consistent with these secretions containing primarily the B and the A isozymes, respectively.     

Secretion of Hexosaminidase Isozymes by Tetrahymena*

SYNOPSIS. Tetrahymena pyriformis strain HSM secrete large quantities of lysosomal acid hydrolases into the medium. The finding that 2 isozymes of β-N-acetylhexosaminidase (2-acetamido-2-deoxy-β-D-glucoside acetamidodeoxyglucohydrolase; EC 3.2.1.30) could be resolved by DEAE ion exchange chromatography and of possible differences between the secreted mixture and the intralysosomal hexosaminidase activity suggested that Tetrahymena might prove useful for studies of the control of lysosomal hydrolase isozyme secretion. In the present paper, we report a considerable purification of these isozymes and describe a number of their kinetic properties. Four isozymes were isolated into 2 major forms, A₁ and B₁, and 2 minor forms, A₂ and B₂, which were similar to the respective major forms in all kinetic properties tested. Hexosaminidase B₁ has a molecular weight of ?93,000 daltons and is inhibited by high concentrations of p-nitrophenyl-N-acetyl-β-D-glucosaminide. The inhibition is reversed by ethanol. Hexosaminidase A₁ has a molecular weight of ?170,000 and is not inhibited by high concentrations of substrate. The A forms are relatively less active against p-nitrophenyl-N-acetyl-β-D-galactosaminide than the B forms. Neither hexosaminidases A₁ or B₁ has any endo-β-N-acetylhexosaminidase activity. Comparison of the properties of the 2 major isozymes suggested that measurements of activity obtained under different assay conditions could be used to quantitate the amount of each isozyme in a mixture of the two. Log- and early stationary-phase cells secrete ?20% of isozyme A and 80% of isozyme B into the medium or into a dilute salt solution. With increasing culture age the fraction of isozyme A secreted rises to over 90%. Supplementation of the proteose-peptone growth medium with glucose causes a decrease in total hexosaminidase subsequently secreted but with no change in proportion of each isozyme. Cells suspended in a dilute salt solution containing 0.1 mM L-propranolol secrete slightly more isozyme A than do control cells suspended without L-propranolol. Phenoxy-benzamine (0.2 mM) causes a slight decrease in the proportion of isozyme A released.     

Presence of Nonoxidative Enzymes of the Pentose Phosphate Shunt in Tetrahymena*

SYNOPSIS. Tetrahymena pyriformis, strain HSM, do not have glucose-6-phosphate dehydrogenase or 6-phosphogluconate dehydrogenase, but contain transaldolase, transketolase, ribose 5-phosphate isomerase, ribulose-5-phosphate 3-epimerase, and ribokinase. The nonoxidative enzymes of the pentose phosphate shunt function in metabolism as indicated by the incorporation of label from [1-¹⁴C]ribose into CO₂ and glycogen and by the increase in total glycogen content of cultures supplemented with ribose.     

The Mechanism of Food Intake in Tokophrya infusionum and Ultrastructural Changes in Food Vacuoles during Digestion*

SYNOPSIS Food intake in Tokophrya infusionum is preceded by penetration of the knob of the tentacle into the cytoplasm of the prey, Tetrahymena. Immediately thereafter, the membrane of the knob starts to invaginate into the lumen of the inner tube of the tentacle carrying with it the cytoplasm of the prey. At the proximal end of the tentacle, the invaginating membrane inflates, pinches off and forms a food vacuole. The mechanism is similar to that in amoebae during pinocytosis. The first few food vacuoles contain broken-up membranes, an indication that predigestion of prey cytoplasm takes place. This process is limited, however, to the part of cytoplasm around the knob since all food vacuoles formed later are composed of intact cytoplasmic organelles of Tetrahymena. Among them the most abundant and at the same time the most resistant to digestion are mitochondria and mucocysts. The ultrastructure of mitochondria is preserved very well during processing for electron microscopy and changes in their fine structure therefore serve conveniently as markers of the stage of digestion and of the age of food vacuoles. Digestion of mitochondria progresses over a period of several hours. They finally seem to degrade into glycogen-like particles. All components of the food vacuole reach this stage much earlier. Digestion proceeds further until the food vacuole is filled with a watery content of very low density. Digestion in such food vacuoles is completed. The complete digestion of the content of food vacuoles is of primary importance for Tokophrya, since this organism does not have a cytopyge thru which waste products could be eliminated.     

Effects of acidic conditions on the physiology of a green alga (Micractinium sp.) before and after a 5-year interaction with Tetrahymena thermophila in an experimental microcosm

The mechanisms through which algae evolve physiological characteristics related to endosymbiotic associations with heterotrophic organisms remain unclear. We previously showed that a green alga (Micractinium sp.) was able to evolve a host (ciliate)-benefiting phenotype that prolonged the longevity of Tetrahymena thermophila in the absence of bacteria during a 5-year culture period in an experimental microcosm. Comparative experiments between the ancestral alga (i.e. original) and evolved algal clones of the same lineage can be performed to analyse the mechanisms that underlie algal evolution during interactions with ciliates. Here, we investigated the effects of acidic conditions on algal physiology because the acidic conditions within the food vacuoles of Tetrahymena could potentially affect algal evolution during long-term interactions. It might be expected that algal clones isolated from T. thermophila hosts would have developed the ability to resist acidic conditions in order to establish within the host, when compared with the ancestral strain. Unexpectedly, comparative analyses demonstrated that acidic conditions with pH values ranging from 3.9 to 4.3 limited the growth of the isolated algal clones SC9-1 and SC10-2, whereas the ancestral strain could grow under these conditions. Acidic conditions were responsible for significantly lower chlorophyll a/chlorophyll b ratios in the isolated algal clones, and the isolated clone SC9-1 exhibited a high cellular content of chlorophyllide a during a short exposure to acidic conditions, suggesting that degradation of chlorophyll a occurred. Furthermore, acidic conditions increased the release of extracellular glycerol and sucrose in the SC9-1 clone. These results indicated that the ancestral strain showed phenotypic changes related to acidic conditions, which may reflect the ongoing development of an algal phenotype suited to symbiosis. Hypotheses are proposed to explain the limited growth of the isolated clones, and implications for the Micractinium–Tetrahymena association are discussed.     

Particle Ejection from the Cytoproct of Tetrahymena

SYNOPSIS. Egestion of carmine particle-containing food vacuoles from the cytoproct of Tetrahymena pyriformis has been analyzed by high-speed cinemicrography. The vacuole may enter into position in the cytoproct ∼ 7 sec before ejection, and forms a distinct bulge beyond the outline of the cell surface for over 2 sec prior to ejection. The ejection process itself requires 20–80 msec.     

The Role of the Contractile Vacuole in the Osmoregulation of Tetrahymena pyriformis*

The relationship of cell size and contractile vacuole efflux to osmotic stress was studied in Tetrahymena pyriformis strain W, after transfer into fresh solutions iso- or hypoosmotic to the growth medium. Microscopic measurements of the cell and contractile vacuole dimensions, made with an image-sharing ocular at 27 C, allowed the calculation of the cell size and shape and the vacuolar efflux rate which provide a measure of osmoregulation. The contractile vacuole cycles have no homeostatic oscillations. In 0.03–0.10 osmolar solutions, the cell size and shape are constant while the vacuolar efflux rate has an inverse linear dependence upon extracellular osmolarity. Regression analyses indicate that for cells with systole faster than 0.1 sec (the major part of the population), it is only the final diastolic volume of the contractile vacuole that is related to osmotic stress while the frequency of systole is independent of osmotic stress and has a constant period of 7.7 ± 0.2 sec. Therefore, osmotic stress upon Tetrahymena is regulated by a corresponding change in the filling rate of its contractile vacuole to allow an unaltered cell size and shape. Kinetic measurements of vacuoles during diastole fit the model (dV/dt = K_1-K₂A), where (dV/dt) is the vacuolar filling rate and (A) is the vacuolar surface area. This dependence of vacuolar volume upon its surface area may be ascribed either to elastic components of the vacuolar membrane or to an increasing leakiness of this membrane during diastole. Mitochondrial inhibitors were used to observe the energy requirements of vacuolar operation and of intracellular secretion of water.     

The effects of high concentrations of sodium or calcium ions on the lipid composition and properties of Tetrahymena membranes

Tetrahymena pyriformis cells have been grown in media varying in NaCl concentration from 3.7 mM (normal medium) to 0.3 M and varying in CaCl₂ from 0.2 mM (normal medium) to 0.1 M. Tetrahymena grown in 0.3 M NaCl showed relatively few alterations in phospholipid composition, with significant changes being found only in the cell surface membranes (pellicle), which increased in phosphatidylethanolamine content from 39% (low Na⁺) to 48% (high Na⁺) of the total phospholipids. The small decrease in fatty acid unsaturation and increase in shorter chain fatty acids in pellicle phospholipids were not statistically significant. No significant changes in phospholipid head group composition or fatty acid distribution were observed in high Ca²⁺-grown cells. Complementary studies of membrane fluidity, as inferred from freeze-fracture electron microscopy analysis, indicated that membranes of high Na⁺-acclimated cells were similar to those of control cells, when each was measured in its respective medium. However, the outer alveolar membrane of the pellicle and the food vacuolar membrane were considerably less fluid in high-Ca²⁺ cells. The lower fluidity in vacuolar membranes may have been responsible for alterations in the cells' capacity to form food vacuoles.     

Acid hydrolases and their Release in Food Vacuole-Less Mutants of Tetrahymena thermophila*

SYNOPSIS. Mutants (NP1 and PSJ5) of Tetrahymena thermophila strains B and D 1968 exist that are unable to construct a functional oral apparatus and form food vacuoles at 37 C but which do so normally at 30 C. Food vacuole-less cells starved in dilute salt solution released similar amounts of acid phosphatase, β-N-acetyl-glucosaminidase and ±-glucosidase activity into the medium as wildtype cells during an 8-h period. Actively growing, food vacuole-less cells had ?50% less total protein, acid phosphatase, β-N-acetyl-glucosamin-idase, and ±-glucosidase per cell than wildtype cells after 72-h growth. During this time food vacuole-less cells released significant amounts of the 3 acid hydrolases into the growth medium. For each hydrolase, the total activity released from growing, food vacuole-less cells was less, on a per cell basis, than the amount released from food vacuole formers. The proportion of the total activity secreted by the mutant and the wildtype cells was the same for acid phosphatase and β-N-acetyl-glucosaminidase and somewhat lower for ±-glucosidase. It is concluded that the release of a significant amount of acid hydrolase activity from Tetrahymena is independent of food vacuole formation and may be analogous to the secretory activity of other nonphagocytic eukaryotic cells.     

The Methylated Purines of Tetrahymena pyriformis Transfer Ribonucleic Acid*

SYNOPSIS. By phenol extraction and DEAE cellulose column chromatography, tRNA was isolated from Tetrahymena pyriformis strain GL. Following acid hydrolysis of the tRNA, the methylated purine content was determined by Dowex 50 column chromatography and paper chromatography. The most abundant methylated guanine derivative was found to be N²-DMG. Also present were 1-MG, N²-MG, and 7-MG. The most abundant methylated adenine was found to be 1-MA; no 2-MA was detected. Small amounts of the N⁶-methyladenines were detected.     

Enrichment for Auxotrophic Mutants of Tetrahymena Using Density Gradient Centrifugation*

SYNOPSIS. A protocol based on density differences between starved and fed cells and employing density gradient centrifugation has been devised to facilitate the isolation of auxotrophic mutants of cell lines derived from Tetrahymena thermophila strain B1868. First, a mass phenotype screening procedure was established whereby true auxotrophic mutants and slow-growing wild-type cells such as strain C* could readily be distinguished. Second, simulation experiments were performed in which wild-type cells starved first in non-nutritive buffer, then suspended in a defined medium lacking a single essential amino acid became significantly denser than the same cells when starved, then suspended in a complete defined medium. Finally, using the same protocol, a reconstruction experiment was carried out which resulted in effective separation of wild-type cells from cells of a tyrosine auxotroph. The overall procedure resulted in a 9-fold increase in the relative frequency of auxotrophic cells, while the density gradient centrifugation alone provided a 400-fold enrichment.     

Effects of Calcium Ion on Growth and Behavior of Tetrahymena pyriformis

The chelator GEDTA was used to show that Ca²⁺ is required for the growth of Tetrahymena pyriformis strain W and for normal galvanotactic responses and swimming.     

Effect of starvation on insulin production and insulin binding in Tetrahymena

Tetrahymena pyriformis GL was starved for 24 h and then the immunologically demonstrable insulin content and FITC-insulin binding were measured by flow cytometry and localization was studied by confocal microscopy. The amount of endogeneous insulin as well as FITC insulin binding, was highly significantly elevated. Glucose feeding for 30 min abolished the elevation of FITC-insulin binding. In starved cells, insulin-binding sites disappeared from the surface and FITC-insulin was bound inside the cells, within large food vacuoles. Endogeneous insulin was dispersed in the cytoplasm both in the control and starved cells and food vacuoles did not contain it. The results call attention to the stimulatory effect of starvation on insulin production in Tetrahymena, in parallel with the internal storage of insulin receptors, which points to an autocrine mechanism.     

Tetrahymena australis (Protozoa,Ciliophora): A Well‐Known But “Non‐Existing” Taxon – Consideration of Its Identification,Definition and Systematic Position

A cryptic species of the Tetrahymena pyriformis complex, Tetrahymena australis, has been known for a long time but never properly diagnosed based on taxonomic methods. The species name is thus invalid according to the International Code of Zoological Nomenclature. Recently, a population isolated from a freshwater lake in Wuhan, China was investigated using live observations, silver staining methods and gene sequence data. This organism can be separated from other described species of the T. pyriformis complex by its relatively small body size, the number of somatic kineties and differences in sequences of two genes, namely the small subunit ribosomal RNA (SSU rRNA) and the mitochondrial cytochrome c oxidase subunit I (cox1). We compared the SSU rRNA gene sequences of all available Tetrahymena species to reveal the nucleotide differences within this genus. The sequence of the Wuhan population is identical to two sequences of a previously isolated strain of T. australis (ATCC #30831). Phylogenetic analyses indicate that these three sequences (X56167, M98015, KT334373) cluster with Tetrahymena shanghaiensis (EF070256) in a polytomy. However, sequence divergence of the cox1 gene between the Wuhan population and another strain of T. australis (ATCC #30271) is 1.4%, suggesting that these may represent different subspecies.     

Monoamine Oxidase and Catechol-O-Methyl Transferase Activity in Tetrahymena*

SYNOPSIS Tetrahymena pyriformis strain HSM was found to have monoamine oxidase (MAO) and a catechol-O-methyl transferase-like (COMT) activity. As in mammalian tissues, the MAO activity is predominantly localized in the mitochondrial pellet and COMT in the cytosol. The COMT-like activity was present in amounts comparable to several mouse tissues and was inhibited by tropolone. MAO activity was much lower than in any of the mouse tissues tested, and its activity varied greatly from preparation to preparation. The substrate preference of Tetrahymena MAO was tryptamine > serotonin > dopamine, and activity increased with increasing pH from pH 6.5 to pH 7.8, as does that of mouse liver MAO. The K_m of Tetrahymena MAO for tryptamine was 4 μM, an order of magnitude lower than that of mouse liver MAO. Sensitivity to inhibition by MAO inhibitors was variable. In some preparations, no inhibition was observed. In others clear inhibition was obtained, harmine and clorgyline being among the most potent inhibitors.     

Dual Capacity for Nutrient Uptake in Tetrahymena. II. Role of the Two Systems in Vitamin Uptake

SYNOPSIS Previously, we found that a mutant strain of Tetrahymena pyriformis without food vacuoles failed to grow unless the nutrient media were richly supplemented with vitamins and trace metals. Here we show that calcium folinate alone can replace the extra vitamin supplementation. The mutant requires ∼ 90-fold higher concentrations of folinate than the wild-type cells to give similar growth responses in a chemically defined medium. We infer that the food vacuole is an important route of uptake for this vitamin in the wild-type cells. We found no difference between mutant and wild-type cells in their requirements for nicotinic acid, pantothenic acid, riboflavin-monophosphate, and pyridoxal. We infer that an extravacuolar route contributes importantly to uptake of these 4 compounds.     

Transformation in Tetrahymena pyriformis: Description of an Inducible Phenotype*†

SYNOPSIS. Transformation of Tetrahymena pyriformis to a rapid-swimming (presumably dispersal) form can be induced by washing cells and suspending them in distilled H₂O, Dryl's solution or 10 mm Tris. Transformation is possible with high efficiency in mass cultures of axenically grown cells within ～ 5 h at 30 C. The radically different phenotype produced during transformation is characterized by a more elongate body form, increased numbers of somatic basal bodies and cilia, a long caudal cilium and oral membranelles positioned beneath the cell surface. DNA quantities characteristic of G1, S, and G2 cells are found in these transformed ciliates, suggesting that achievement of a particular stage in the DNA-division cycle is not a prerequisite for transformation. Preliminary observations on cells belonging to syngens 2–12 indicate that they also have a capacity to form a caudal cilium, but that the amicronucleate strain GL-C does not. Possible relevance of the transformed phenotype for taxonomy of Tetrahymena is discussed.     

Effect of Chlorpromazine on Active Transport of Amino Acids in Tetrahymena*

SYNOPSIS. Low concentrations of chlorpromazine (～0.01 mM) inhibit growth and nucleic acid synthesis in the ciliate Tetrahymena pyriformis. Brief exposure of the cells to, e.g. 0.018 mM chlorpromazine, had very little effect on ¹⁴CO₂ production or on label incorporation into glycogen from [1-¹⁴C]glucetate, [6–14C]glucose, or [1-¹⁴C]leucine, but 17-h exposure of stationary phase cultures to this drug caused marked alterations in metabolism, including an almost complete loss of ability to decarboxylate L-[1-¹⁴C]leucine and L-[1-¹⁴C]tyrosine. It was shown that loss of ability to decarboxylate these amino acids results from loss of ability to transport them.