New Methods for Cultivating,Harvesting, and Purifying Mass Cultures of the Hypotrich Ciliate Euplotes aediculatus1

A new method is described for mass cultivation of Euplotes aediculatus, a hypotrich ciliate containing omikron-symbionts. The ciliate cultures, continuously aerated in Erlenmeyer flasks (5000 ml) with 4500 ml medium, yield densities of 2300 cells/ml which are four to five times higher than cell densities of cultures grown in unaerated Fernbach flasks. Harvesting such cultures involves the application of 25-μm mesh sieves. Cells so concentrated can be purified by using columns or special chambers in which Euplotes migrates towards the cathodes in an electric field (field strength 7 V/cm).     

Economic Mass Cultivation of Paramecium tetraurelia on a 200-Liter Scale1

ABSTRACT. A new and inexpensive medium is described for axenic mass cultivation of Paramecium tetraurelia stock 51s and the double mutant pawn A/pawn B. Skim milk powder is the major carbon and nitrogen source in this medium. Growth characteristics (proliferation rate, final cell density, and cell size) are similar to those observed with other axenic culture media. Cultures were run in one-liter erlenmeyer flasks, a 20-liter, and a 250-liter airlift bioreactor. The yield of a large bioreactor is 750 g (wet wt.) Paramecium or 5 × 10⁹ cells. This easy, economical culture technique will greatly facilitate the use of Paramecium as a model organism for extensive biochemical studies.     

Partial Purification and Characterization of a Bacteriolytic Enzyme Secreted by Tetrahymena*

Synopsis. Tetrahymena pyriformis strain HSM secretes large quantities of acid hydrolases into the culture medium. An enzyme secreted by the ciliate and capable of degrading walls of streptococci was identified and purified to a considerable degree. The pH optimum of this enzyme was 3–4, and it was eluted after cytochrome c from Sephadex G-75 columns. Unlike lysozyme, the enzyme was thermolabile at pH 2.9, but relatively thermostable at pH 8.1. It degraded “C-labeled cell walls of streptococci releasing reducing groups. Cell walls prepared from different strains of streptococci differed in susceptibility to this enzyme, the most sensitive strain tested being of group A, type T12. It was shown in immunologic studies that this hydrolase released the group-specific carbohydrate from the walls. Secretions of Tetrahymena from early stationary-phase cultures had more bacterio-lytic activity than those from cells from late stationary-phase cultures. Further, cells from cultures grown in glucose-supplemented medium secreted less of the enzyme than ciliates of comparable age grown in unsupplemented proteose-peptone. The newly isolated bacteriolytic enzyme, presumably of lysosomal origin, may be helpful in characterizing streptococcal cell walls.     

MORPHOGENESIS OF MONOSTROMA OXYSPERMUM (KÜTZ.) DOTY (CHLOROPHYCEAE) IN AXENIC CULTURE,ESPECIALLY IN BIALGAL CULTURE1

The typical morphology of Monostroma oxyspermum (Kütz.) Doty is lost in axenic culture. In synthetic media of the ASP type, it grows as a colony-like mass composed of round cells with numerous rhizoids. Such a mass is a fragile structure which falls apart upon shaking, or slight touch, into small cell-groups and single cells or cells with a long rhizoid. Only temporary saccate or monostromatic fronds appear and reach 1–2 mm in length when grown in enriched seawater media, but disintegrate and become a colony-like mass. The typical morphology is easily restored by adding at specific intervals filtrates of bacterial cultures and supernatant medium from axenic brown and red algal cultures to the basal medium (ASP7), or by reinfecting the Monostroma with an appropriate bacterial flora. Furthermore, the typical morphology in also maintained by bialgal cultures between Monostroma and other axenic strains of various species of seaweeds except the species belonging to the Chlorophyceae. Monostroma thus appears to utilize some substances released by most species of brown and red algae for its typical growth. Active substances released by bacteria, brown and red algae have not yet been identified and purified. However, it is demonstrated that in axenic cultures many species of seaweeds produce active extracellular substances which play an important role in growth and Morphogenesis of other species of seaweeds.     

Cultivation of formerly noncultivable strains ofMycoplasma hyorhinis

Growth on axenic agar medium is one of several characters by which mycoplasmas are defined. In apparent contradiction of the definition, DBS 1050 and other noncultivable strains ofMycoplasma hyorhinis do not grow on axenic medium but grow in cell culture. Our results show that BHK-21 cell extracts support DBS 1050 growth in appropriate medium. An inhibition assay, based on a virus neutralization format, shows that a variety of common medium ingredients inhibit DBS 1050 growth. The most potent activity was found in yeast extract. All other noncultivable strains ofM. hyorhinis tested have a yeast extract sensitivity, while cultivable strains do not. The apparent cell dependence of DBS 1050 can be attributed to growth inhibition due to factors present in a wide variety of peptones and extracts commonly used in medium; preferential growth in cell cultures is due to the absence of effective levels of these factors. Data are not available to determine if cell cultures provide growth factors not found in standard medium. The infraspecific taxon,M. hyorhinis cultivar α, is proposed for formerly noncultivable strains ofM. hyorhinis.     

Axenic Paramecium caudatum. I. Mass Culture and Structure*

SYNOPSIS. To establish and grow Paramecium caudatum in mass axenic culture the culture medium of Soldo, Godoy & van Wagtendonk was modified by substituting phosphatidylethanolamine (PE) for TEM-4T and by a 10-fold increase in folic acid. Population densities of 4000 to 6000 cells/ml and a generation time of 20–26 h are regularly obtained. Optimal growth is obtained with PE-stigmasterol ratios between 40:1 to 400:1. Cells from 1-day-old axenic cultures have many lipid bodies aggregated in clumps (which disappear in 2 to 3 days) as well as foci of rough endoplasmic reticulum bordered by dictyosomes. The latter suggests a very active metabolism. Crystalline sheets found in both food vacuoles and lysosomes presumably play a role in digestion. Axenically grown cells also have abundant Golgi bodies (dictyosomes) and by late log phase become filled with lysosomes.     

Cohesive properties of axenically grown cells of the slime mould Dictyostelium discoideum

It has been found that Dictyostelium discoideum cells from the exponential growth phase of axenically grown cultures are cohesive, whereas those from stationary phase are not. These differences in cohesiveness are seen in phosphate buffer and in axenic medium. Stationary phase medium inhibits the aggregation of log phase cells; stationary phase cells inoculated into freshly prepared medium regain their cohesiveness. Stationary phase medium may contain an inhibitor of cell cohesion. pH differences between the two types of medium are not entirely responsible for loss of cohesiveness.     

Methods for the Large-Scale Cultivation of an Oxytricha (Ciliophora: Hypotrichida)1

ABSTRACT. Oxytricha strains used in biochemical studies have traditionally been grown in unaerated, unagitated culture tubes or Fernbach flasks. These cultures are limited in volume to about one liter and have a very nonuniform distribution of cells, with the majority of the cells at the very top or bottom of the medium. We have found conditions in which Oxytricha can be grown in 50-liter fermentation vats. The cultures grow to a uniform density of about 6000 cells/ml.     

Establishment of axenic endosymbiotic strains of Japanese Paramecium bursaria and the utilization of carbohydrate and nitrogen compounds by the isolated algae

Cells of the green paramecium, Paramecium bursaria, contain several hundred endosymbiont cells. The properties of the symbionts are considered to vary depending on the collection site of the host. Difficulties in achieving axenic cells and maintenance of axenic strains for long periods have been reported for symbiotic algae from P. bursaria isolated in Japan. To establish axenic algal strains from such Japanese P. bursaria, symbionts were isolated carefully, and isolated axenic strains were grown on an agar medium containing organic nitrogen compounds. Symbiotic algal strains were obtained from three Japanese P. bursaria strains and their axenicity was confirmed by DAPI staining, cultural tests of bacterial contamination, and DGGE-PCR. These axenic strains have been maintained for over 2 years. Utilization of carbohydrates and nitrogen compounds by symbionts was examined. Monosaccharides (glucose and fructose) increased the growth of the symbiont but disaccharides (maltose and sucrose) did not. Japanese axenic symbionts were able to use ammonia and amino acids, but not nitrate or nitrite. While potent nitrite reductase activity was stimulated by nitrate induction, nitrate reductase activity was not. Nitrate utilization of Japanese symbionts differed from that reported for European and American symbionts.     

CONTROL OF COLONY AND UNICELL FORMATION IN A SYNCHRONIZED SCENEDESMUS12

Colony formation in a synchronized Scenedesmus could be controlled by the addition of 0.05% Na₃ citrate or 85 μM EDTA to modified Bristol's medium. No unicells were formed; only S. quadricauda-like or S. longispina-type colonies were observed in young cultures grown in that medium. A colony population could be made completely unicellular in 2 days if grown in soil-Bristol's medium and transferred daily. The pleomorphic Scenedesmus was examined in synchronized culture. When the organism was grown in a defined medium in a 15-hr light /9-hr dark cycle on a roller tube rotator at 2-6 rpm and transferred daily, synchrony of cell division and release of the products were achieved. In a synchronized culture 2 doublings/day were recorded, with most cytoplasmic cleavages and all releasing of daughter cells taking place in the dark period. In many observations with several synchronized strains of Scenedesmus, no fixed pattern of release of daughter products from mother cells or colonies was detected. Colonies or unicells had their full spine complement at the time of release. As a cell or colony aged the spines sometimes increased in thickness. Other Scenedesmus strains were examined to provide supporting data.     

Method for the Simultaneous Establishment of Many Axenic Cultures of Paramecium*†

SYNOPSIS. A method is described for the simultaneous treatment of 42 (or more) stocks of Paramecium, and their adaptation to growth in axenic culture. Samples of dense cultures of these ciliates growing with Enterobacter aerogenes are rendered bacteria-free by migration through 2 sets of tubes containing Adaptation Medium (Peters' salts solution, stigmasterol, vitamins, and autoclaved E. aerogenes). The 2nd set of tubes contains Adaptation Medium plus antibiotics. Bacteria-free samples containing ～ 100 animals are then transferred to test tubes containing Adaptation Medium without antibiotics. This medium also serves as a growth medium. It supports indefinite growth of all Paramecium stocks tested. After adaptation to this medium, the ciliates can be grown in the axenic medium developed by Soldo, Godoy & van Wagtendonk. On a single trial at least half of the stocks can be expected to produce axenic cultures within 5 to 10 days by these procedures. The method has been applied successfully to several of the species of the Paramecium aurelia complex, to all syngens of Paramecium multimicronucleatum, to several stocks of Paramecium jenningsi, and to 1 stock each of Paramecium caudatum and Paramecium calkinsi. A modification of the method also works for Didinium nasutum.     

Buoyant density of Escherichia coli is determined solely by the osmolarity of the culture medium

In previous studies, we had shown that the buoyant density ofEscherichia coli is determined by the osmolarity of the growth medium by varying the osmolarity of the medium with NaCl or sucrose. However, the buoyant density of the cells always exceeded that of the growth medium. Here we determined the effect of medium with a buoyant density greater than the expected buoyant density of cells by adding Nycodenz to Luria broth. Percoll gradients of cells were analyzed by laser light scattering. The buoyant density for 125- and 375-mOsM-grown cells was 0.002 g/ml and 0.003 g/ml more, respectively, for cells grown in the presence of Nycodenz than those grown without Nycodenz, while the buoyant density of 250-mOsM-grown cells was 0.005 g/ml less for cells grown in the presence of Nycodenz than those grown without Nycodenz. Cells grown in 500-mOsM medium with or without Nycodenz had the same buoyant density. the buoyant density of cultures grown in defined medium was the same as those grown in rich medium, with only the medium osmolarity correlating to buoyant density. We conclude from these experiments that neither buoyant density nor chemical make-up of the medium determines the buoyant density of cells grown in that medium. Only the medium osmolarity determines cell buoyant density, suggesting thatE. coli has no mechanisms to sense buoyant density.     

Accumulation of Extracellular Amino Acids by Euglena gracilis

SYNOPSIS. Normal Euglena gracilis , strain z, growing in the light in defined medium (initial nitrogen concentration 140 μ/ml) depletes the medium of all ninhydrin-positive N by the time a cell density of 2 million per ml is reached. A further 2- to 3-fold increase in the cell number takes place in the absence of exogenous N. The N content of an early log phase cell is about 100 picograms but decreases very rapidly as the culture continues to grow, reaching 22 picograms in the stationary phase. When grown in the dark, normal cells take up N somewhat more slowly but the supernatant fluid from saturation cultures is again devoid of N.
At modest cell densities, the permanently bleached strains examined contain less N per cell than do normal strains. The cultures of the bleached strains achieve a maximum density of about 1 to 2 million per ml rather than the 4 to 5 million reached by the normal strain. As a result, supernates from stationary phase cultures of bleached cells still contain a large proportion of the total N supplied.
Paper chromatographic analysis of these supernates reveals several ninhydrin-positive compounds. Most of these have been identified as common amino acids. Some of the properties of two unidentified, ninhydrin-positive compounds are described.     

Automatic Cell Counting in Continuous Flow Cultures of Tetrahymena pyriformis*

This report describes an electronic cell counter constructed for determining cell number in cultures of the ciliate, Tetrahymena pyriformis. The culture chamber has been equipped with a device which determines the number of cells per unit volume and records the number automatically. As cell multiplication is unaffected by the counting procedure the cells are returned to the culture. Furthermore, keeping the culture volume constant we have arranged a continuous flow of fresh nutrient medium through the culture chamber and thus established conditions under which cell multiplication has continued for months while determinations of cell concentrations have been recorded every 10 min. Since the culture volume has been small, ～25 ml, growth studies utilizing this method require less than one liter of fresh medium per week in spite of the fast multiplication (9 generations per 24 hr) occurring in cultures of Tetrahymena pyriformis under optimal conditions.     

AXENIC CULTIVATION OF THE HETEROTROPHIC DINOFLAGELLATE PFIESTERIA SHUMWAYAE AND OBSERVATIONS ON FEEDING BEHAVIOR1

Pfiesteria shumwayae Glasgow et J. M. Burkh. [=Pseudopfiesteria shumwayae (Glasgow et J. M. Burkh.) Litaker, Steid., P. L. Mason, Shields et P. A. Tester] is a heterotrophic dinoflagellate commonly found in temperate, estuarine waters. P. shumwayae can feed on other protists, fish, and invertebrates, but research on the biochemical requirements of this species has been restricted by the lack of axenic cultures. An undefined, biphasic culture medium was formulated that supported the axenic growth of two of three strains of P. shumwayae. The medium contained chicken egg yolk as a major component. Successful growth depended on the method used to sterilize the medium, and maximum cell yields (10⁴ · mL^?1) were similar to those attained in previous research when P. shumwayae was cultured with living fish or microalgae. Additionally, P. shumwayae flagellate cells ingested particles present in the biphasic medium, allowing detailed observations of feeding behavior. This research is an initial step toward a chemically defined axenic culture medium and determination of P. shumwayae metabolic requirements.     

Myxococcal predation of the cyanobacterium Phormidium luridum in aqueous environments

Two strains of Myxococcus xanthus, and a strain of Myxococcus fulvus were compared with respect to their ability to entrap and lyse trichomes of the cyanobacterium Phormidium luridum var. olivaceae. All of these isolates form colonial aggregates and spherules in either axenic culture with a tryptone-salts medium or in a mixed culture with viable cyanobacterial cells as the sole source of nutrients. Light microscopy showed evidence of swarming activity on the surface of all three myxococci with the accompanying formation of fruiting structures. Extended incubation of mixed cultures showed the myxococci to be capable of long-term control of the cyanobacterial population with predator-prey population cycling occurring on average every 9 days. Serial transfer of mixed cultures into either fresh autotrophic medium or cyanobacterial cultures of 10⁷ per ml showed the persistence of predatory activity. Myxococcal densities were shown to return repeatedly to initial virulent levels. Predator inoculum levels could be reduced to 50 cells per 100 ml in a cyanobacterial culture of 10⁷ per ml. These in vitro data enhance the potential of the myxococcus predatory colony as a biological control agent for in situ cyanobacteria.     

Survival of Tetrahymena thermophila at Low Initial Cell Densities. Effects of Lipids and Long-Chain Alcohols

ABSTRACT. Cells of the ciliate Tetrahymena thermophila failed to establish cultures in lipid-free standard synthetic nutrient medium if the initial population density was 250 cells per ml or less. These cells died within 10 h, but were saved and formed dense cultures if their medium was supplemented with 10 μg per ml of either certain phospholipids, 1,2-di-, 1-monoglycerides, fatty acids, long-chain alcohols, or sterols. Cell multiplication was followed in cultures in which the standard synthetic medium was supplemented with a selection of the compounds listed above. It was observed that the cells in the supplemented cultures in their exponential phases of growth had about the same average doubling times as control cells starting multiplication at 10-fold higher initial cell densities in lipid-free medium. These cells have been grown for decades in lipid-free synthetic nutrient media at short (ca. two-three h) doubling times. Therefore lipids have been considered nutritionally non-essential for growth and multiplication of these cells. We propose that those compounds that rescue the cells at low cell densities act as "proliferation signals," sensu lato . This effect of lipids and long-chain alcohols has so far remained unnoticed.     

Nutritional stress in Tetrahymena relieved by addition of hemin or phospholipids

Summary The ciliate Tetrahymena thermophila was grown in a synthetic nutrient medium at various amino acid concentrations. Before the beginning of the experiments the cells were starved for 4 h in a pH buffer. They were inoculated at an initial density of only 250 cells per ml. Under these conditions the cells grew and multiplied at only the two highest amino acid concentrations used. Hemin or phospholipids were found to stimulate cell growth at the lower amino acid concentrations. The mechanism behind this stimulatory effect is unknown, but may be connected with the maintenance of an adequate energy flow under adverse conditions. These additions represent an improvement of the synthetic medium for Tetrahymena.Abbreviations PPYS proteose peptone, yeast extract, and salts medium     

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.     

CELL DEATH,SURVIVAL AND PROLIFERATION IN TETRAHYMENA THERMOPHILA. EFFECTS OF INSULIN,SODIUM NITROPRUSSIDE, 8-BROMO CYCLIC GMP,NG-METHYL-L-ARGININE AND METHYLENE BLUE

Cells of the ciliate Tetrahymena thermophila produce compounds that act as autocrine (paracrine) survival and/or growth factors. 8-Bromo cyclic GMP, sodium nitroprusside, hemin, protoporphyrin IX, human recombinant and bovine insulin were tested for their ability to substitute for the cell-produced factors and stimulate cell survival and proliferation. The cells were inoculated into conical flasks in a nutritionally complete, chemically defined medium at known cell densities from 5 to 5000cells/ml. In unsupplemented medium cells at 5 to 500cells/ml (‘low initial cell density cultures’) died within 8h, whereas cells at 1000 and 5000cells/ml (‘high initial cell density cultures’) proliferated with lag phases lasting for up to 4h. In the presence of insulin compounds, hemin, protoporphyrin IX, or 8-bromo cyclic GMP, cells also proliferated at all low initial cell densities. Sodium nitroprusside was effective over two separate concentration ranges: at the nanomolar levels as well at low pico- to femtomolar levels. At initial population densities of up to 50cells/ml the cells at both concentrations of sodium nitroprusside survived about 4-fold longer than the controls. At 500 initial cells/ml, cells at thehigh concentrations of sodium nitroprusside survived about 4-fold longer than those of the control cultures; they proliferated in the low concentrations of sodium nitroprusside. Concentrations of hemin, too low to have any effects on their own, had synergistic effects with sodium nitroprusside. N^G-methyl-L-arginine inhibited proliferation at high initial cell densities. This inhibitory action was reduced by high concentrations of L-arginine, protoporphyrin IX, sodium nitroprusside, or 8-bromo cGMP, but not by insulin. Methylene blue inhibited cell proliferation at high initial cell densities. This inhibition was circumvented by addition of 8-bromo cGMP. The findings that insulin-related material may be released from Tetrahymena and that insulin and sodium nitroprusside increase intracellular cGMP in these cells are discussed in relation to the presented results. Together these observations suggest that cGMP is responsible for supporting cell survival in Tetrahymena and switching the cells into their proliferative mode, and that cell-produced signal molecules and insulin stimulate an NO-dependent guanylate cyclase into producing cGMP.