Serotype Expression and Transformation in Tetrahymena pyriformis

SYNOPSIS. Of the 4 serotypes of Tetrahymena pyriformis, syngen 1, the H (expressed at 20–35 C) and T (expressed at 36–40 C) serotypes and their genetic bases have received the most attention. The present study describes the L and I serotypes, considers their transformations to and from the H serotype, and compares inter-locus repression with allelic repression. The L serotype occurs below 20 C. No strain differences have been found between L antigens. However, the rate of transformation between H and L varies in the families, which can be ranked according to their preference for the H or L serotype. A3 is strongly L; D1 is strongly H; the other families form a continuum between these extremes. Preference for the H or L serotype is not correlated with the H allele present. Serotype differences may be hereditary, by the “dilution” test for hereditary differences. Altho the environment largely determines which serotype will be expressed, sublines can maintain established H and L serotypes for more than 40 fissions in a common environment. Crosses between H and L cells suggest macronuclear control of serotype determination and a cytoplasmic influence on macronuclear differentiation. Evidence for the cytoplasmic influence comes from both conjugants and nonconjugants. The I serotype is induced from the H serotype at room temperature by treatment with specific H antibodies, which are also necessary for I maintenance. The I serotype consists of a series of unstable serotypes which transform among themselves. Clones go thru an initial I type one day after induction and then diversify to express secondary types. The initial type and the secondary types are characteristic of the family but are not related to the H genotype. Family C1 lacks 2 secondary types found in other families studied. The differences between inter-locus repression and allelic repression are marked. Altho inter-locus repression is labile, all efforts to reverse allelic differentiations have failed. H heterozygotes maintained for long periods of time in the I or L state showed no reversal of H allelic repression.     

Ionic Resistance in Strains of the Tetrahymena pyriformis Complex1

ABSTRACT. Strains of Tetrahymena thermophila were examined in an attempt to establish what role certain ions (Na⁺, K⁺, Li⁺, Ba⁺⁺, Ca⁺⁺, Mg⁺⁺, Mn⁺⁺, Al⁺⁺⁺, Fe⁺⁺⁺) play in influencing cell survival time in a culture medium. In short-term experiments (20–30 min), cell survival time in a 1% peptone medium is directly related to the valence of the ion employed. Long-term observations (lasting up to five days) in a 1% peptone medium containing lower ion concentrations revealed that the effects on cell-cycle time are not correlated with the valence state of the ion. Comparisons were made among the ionic resistances of strains of T. thermophila, of T. pyriformis sensu stricto, and of two subspecies of T. pigmentosa. Strains within a species are highly correlated in their patterns of ionic response, while marked differences between species occur. The most distinctive group of strains examined came from one of the subspecies (syngen 6) of T. pigmentosa.     

A cycloheximide-resistant mutant of Tetrahymena pyriformis

A mutant of Tetrahymena pyriformis, syngen 1, resistant to cycloheximide was obtained after mutagenesis (with N-methyl-N′-nitro-N-nitrosoguanidine) followed by a cross (to obtain macro-nuclear expression of the mutant phenotype). A genetic analysis has shown that cycloheximide resistance in the mutant strain is due to a dominant nuclear allele, designated chx-1. Heterozygotes (chx-1/chx⁺) are initially resistant but segregate stable, sensitive cell lines during vegetative growth, demonstrating that allelic exclusion occurs with this determinant, as with many others in syngen 1. This feature, coupled with the selective advantage conferred by the chx-1 allele in the presence of cycloheximide, makes this mutation a useful genetic tool. A strain homozygous for the chx-1 allele exhibits an exponential growth rate identical to that of the wild type in proteose peptone-yeast extract medium in the absence of cycloheximide. In 10 μg/ml of the drug, the resistant cells grow at a somewhat lower rate, after an initial lag and adaptation to the presence of the drug. This concentration causes complete inhibition of growth and eventual lysis of wild-type cells. The cellular basis for cycloheximide resistance and adaptation in the mutant is presently under investigation.     

The Preparation of Congenic Strains of Tetrahymena1

SYNOPSIS. Congenic strains of syngen 1, Tetrahymena pyriformis, were produced by backcrossing the F¹ hybrid between inbred strains C2 and D to strain D in 12 consecutive backcrosses, with selection for certain C2 genes, and then using genomic exclusion to induce homozygosity. Six congenic strains of high breeding performance are available. Five differ from strain D in single genes at 5 different loci. The 6th strain differs at all 5 loci. Assuming the size of the Drosophila gene (4 × 10⁴ nucleotide pairs), we can calculate that strains differing from D by single genes have a heterozygous segment 3 genes long while The strain which differs from D by 5 genes has 5 heterozygous segments and 15 genes contributed from strain C2. A 40-fold increase in heterozygosity would be found with a gene size of 10³ nucleotide pairs. This means that in using these strains for biochemical work we must be aware that some genetic noise still remains.     

Genetic code limit organisms — do they exist?

Summary The concept of genetic code limit organisms is introduced. Its DNA composition suggestsTetrahymena pyriformis syngen 1 to be a low G + C coding limit organism. One of the predictions ofTetrahymena's being a coding limit organism—i.e. a particular striking dissimilarity in the composition of the two strands of its DNA duplexes—has been tested experimentally and confirmed.     

Temperature Effects on Maturity Periods in Tetrahymena pyriformis Syngen 1*

Cells of Tetrahymena pyriformis syngen 1 grown at 30 C after conjugation achieve sexual maturity more quickly than do cells grown at 19 C, whether time is measured in numbers of cell divisions or in terms of absolute time. This result is achieved regardless of the temperature at which conjugation and nuclear reorganization occur. These observations differ from those of other workers investigating Paramecium, and suggest that the long term “chronometer” is more tightly coupled to cell division in Paramecium multimicronucleatum and Paramecium caudatum than in Tetrahymena pyriformis.     

Effect of salinity on seed germination,seedling growth,and physiological characteristics of Perilla frutescens

Abstract

Salt stress is one of the major environmental factors limiting crop growth and yield. To understand the effect of salt stress on plant growth, we investigated the response of three perilla varieties (Suyin 1, Ziye 7, and Ziye 10) to NaC1 exposure at concentrations of 0, 50, 100, 150, 200, and 250 mM in terms of seed germination, seedling growth, root activity, contents of soluble sugar, proline, and malondialdehyde (MDA), and peroxidase (POD) enzyme activity. Germination characteristics, such as the percentage of seed germination, tended to decrease with increasing NaC1 concentrations. After three weeks of salt stress, the three varieties exhibited different salt tolerance in terms of seed germination, seedling growth, and physiological changes: seedling growth was inhibited to various degrees, seedling vigor and root activities decreased, and MDA, proline, and soluble sugar contents increased with increasing NaCl concentrations. POD enzyme activity, a protective mechanism against salt stress, increased at low NaC1 concentrations in Suyin1 (0–150 mM) and Ziye 7 (0–100 mM), and then decreased at higher NaCl concentrations. In Ziye 10, on the other hand, POD activity dropped significantly with increasing NaCl concentrations. These results suggest that among the three varieties Suyin 1 is more salt tolerant than Ziye 7 and Ziye 10, and that Ziye 10 is the most sensitive to salt stress.     

Influence of monovalent cations on the activity of T4 DNA ligase in the presence of polyethylene glycol.

Monovalent cations such as Na+ and K+ inhibit the activity of T4 DNA ligase. However, the extent of inhibition varies with the terminal sequence of the duplex DNA used as substrate; in many cases, ligation of DNA is completely inhibited at 200 mM. The activity of the ligase is stimulated by raising the concentration of polyethylene glycol 6000 from 0 to 15% (w/v) when NaC1 and KC1 were both absent. Ligation was reduced as the concentration of NaC1 or KC1 was raised in a mixture containing 5 or 15% PEG 6000. With 10% PEG 6000, both cohesive- and blunt-end ligation of this ligase increased at high concentrations of salt (150-200 mM NaC1, or 200-250 mM KC1). Further, with 10% PEG 6000, inter- and intramolecular ligation occurred at low salt concentrations (0-100 mM NaC1, or 0-150 mM KC1); only linear oligomers were formed by intermolecular ligation at the high concentrations.     

Three New “Biological” Species of Tetrahymena (T. hegewischi n. sp., T. sonneborni n. sp., T. nipissingi n. sp.) and Temperature Tolerance of Members of the “pyriformis” Complex1

Stocks of the Tetrahymena pyriformis complex have been collected in North America and their mating reactivity has been studied. In addition to stocks mating with Tetrahymena americanis, T. borealis, T. pigmentosa, T. hyperangularis, and T. australis, stocks belonging to old syngen 5 and three new mating groups, numbers 13, 14, and 15, were discovered. Syngen 5 and groups 13 and 14 are distinct “biological” species, based on their reproductive isolation from other groups and on the ability of withingroup crosses to produce immature progeny. These species have been named T. hegewischi n. sp., T. sonneborni n. sp., and T. nipissingi n. sp., respectively. The cross between the two group 15 stocks did not produce immature progeny, and there is not sufficient evidence to conclude that this pair of stocks represents a separate species. Temperature tolerance measurements have been made on stocks representing all known micronucleate members of “pyriformis” complex. Within each species, the range of temperature tolerances is narrow; the average within-species standard deviation is 0.63°C. The species averages range from 32.7 to 40.7°C. Using syngen numbers, the order from lowest to highest temperature tolerance is 9, 8, 10, 7, 6, 4, 13, 14, 12, 11, 5, 3, 2, 1. The large differences among species make temperature tolerance a useful aid in identification, but the origins of the differences among species are unknown.     

Use of Genomic Exclusion to Isolate Heat-Sensitive Mutants in Tetrahymena

We have used the abnormal form of conjugation known as "genomic exclusion" to isolate a collection of heat-sensitive mutants of Tetrahymena pyriformis, syngen 1. Growth at room temperature in bacterized medium and no growth at 40 degrees C in the same medium was the criterion used for the isolation. The mutant strains were tested for growth in pure (axenic) culture in proteose peptone medium; of the 31 strains which grew normally at room temperature and not at 40 degrees C in that medium, 21 also failed to grow at 37 degrees C. Preliminary results of complementation tests suggest that most, if not all, the mutations are recessive and that a variety of genes was affected. A detailed genetic analysis was performed on one mutant (H9). The results are all consistent with the idea that the heat-sensitive phenotype of this mutant is determined by a single recessive mutation, designated ts-2. Heterozygotes ts-2/+ yield heat-sensitive segregants during vegetative growth; we interpret this finding as another example of allelic exclusion, a phenomenon universally encountered among heterozygotes in syngen 1 of T. pyriformis. Our results are discussed in the context of some questions of current interest in Tetrahymena genetics.     

Induction of Competence for Mating in Tetrahymena by Cell-Free Fluids

SYNOPSIS. Cell-free fluid from sexually reactive cultures of Tetrahymena pyriformis, syngen 7 can induce mating in otherwise unreactive mixtures of cells of 2 mating types. Rare individual cells may initiate the production of this substance, but once it is produced, the entire culture becomes sexually reactive.     

Modification of culture conditions for production of the anti-tubercular hirsutellones by the insect pathogenic fungus Hirsutella nivea BCC 2594

Aims:  This work aimed to improve the production of anti-tubercular hirsutellones by the insect pathogenic fungus Hirsutella nivea BCC 2594.
Methods and Results:  The fungus was cultivated under different carbon/nitrogen sources and aerations (shake vs static flasks) to improve the production of the anti-tubercular alkaloids, hirsutellones A–D. Under the basal conditions, static cultivation at 25°C in minimum salt medium, only hirsutellone B and C were detected with maximum concentrations of 139·00 and 18·27 mg l⁻¹. Substitution of fructose for glucose and peptone for yeast extract increased the titres of hirsutellones A, B and C about two- to threefold. However, hirsutellone D was not detected in this medium. Culture agitation induced the production of hirsutellone D. As a result, the significant amounts of hirsutellones A–D were obtained with the concentration of 29·93, 169·63, 22·65 and 15·71 mg l⁻¹ within 15 days.
Conclusions:  Improved titres of hirsutellones in H. nivea BCC 2549 were achieved with an agitated (200 rev min⁻¹) fructose–peptone medium at 25°C.
Significance and Impact of the Study:  Improved yields of hirsutellones B–D will enable medicinal chemistry modifications leading to a development of a potential candidate for tuberculosis therapy.     

The extremely high Al resistance of Penicillium janthineleum F-13 is not caused by internal or external sequestration of Al

Penicillium janthinellum F-13 has been isolated in previous work as a fungus tolerating the presence of high concentrations of Al (as high as 100 mM AlCl₃). Here its growth rate and yield in three acidic (pH 3.0) media of different composition with varying concentrations of Al are reported. The presence of Al did not affect these parameters, except that the growth yield was somewhat lower in GM (a glucose/peptone/yeast extract-containing medium) with the highest concentration tested (100 mM AlCl₃). The amount of Al found in the mycelium was so low that it cannot lead to a significant decrease in the medium for the higher Al concentrations applied. Although citric acid was excreted at growth on GM, and the presence of Al even promoted this, the concentration of this was far too low to diminish (by chelation) the high Al concentrations in the medium to a non-toxic level, i.e. the level (of approx. 1 mM) that is tolerated by low-resistance fungi. At growth on SLBM (a peptone/yeast extract/soil extract-containing medium), a rise in pH occurred. The same was found for SM (a glucose/mineral salts-containing medium), although in this case the picture was more complicated because the initial rise in pH was followed by a lowering due to the excretion of oxalic acid. Although both phenomena can diminish Al toxicity (by decreasing the external concentration of monomeric Al, regarded to be the toxic species), again the decrease is far too low to attain a non-toxic level when high Al concentrations are applied. Therefore, although in principal the metabolic phenomena observed for P. janthinellum F-13 at growth on different media can diminish Al toxicity, the tolerance of this organism for high external Al concentrations must be caused by another mechanism.     

SECRETION OF ACID HYDROLASES AND ITS INTRACELLULAR SOURCE IN TETRAHYMENA PYRIFORMIS

Axenic Tetrahymena pyriformis, syngen 1, mating type II cells were grown in Cox's defined medium. When washed and transferred into nonnutrient dilute salt solution or resuspended in the defined medium, the intact cells secrete acid hydrolases into the medium. Cells starving in the salt solution release in 5 hr about two-thirds of their β-glucosidase, β-N-acetylglucosaminidase, α-glucosidase, and amylase activities, about one-third of their deoxyribonuclease and phosphatase activities, smaller amounts of ribonuclease, and only a negligible fraction of their proteinase activity and protein content. During this period there is practically no change in the enzyme activities (except for a sudden increase of ribonuclease activity) and protein content of cells and medium together. Cells resuspended in the nutrient medium secrete enzymes as do the starved cells, but replace this loss, so that there is a continuous increase of the activities in the total system. According to isopycnic centrifugation experiments performed in sucrose gradients, the source of the hydrolases is a special population of lysosomes which disappear from the cells during starvation. This population equilibrates in the high density region of the gradients and contains the various acid hydrolases in about the proportion in which these enzymes appear in the medium.     

Changes in calcium and magnesium levels during heat-shock synchronized cell division in Tetrahymena

Calcium and magnesium contents were measured in cells of Tetrahymena pyriformis induced to divide synchronously by a multi-heat-shock procedure. During free-running synchronized cell division in complex proteose peptone medium, significant peaks of both calcium and magnesium were observed at points in the cell cycle just prior to division. No such peaks were detected in cells dividing asynchronously in proteose peptone. When synchronized cell division was followed after transfer to an inorganic medium, cell calcium and magnesium levels were observed to decrease in relation to the corresponding cell number increase, indicating that in concentration terms, calcium and magnesium remain fairly constant. This latter result suggests that neither calcium nor magnesium influxes act as triggers for cell division in Tetrahymena and that the fluctuations of these metals seen during the synchronized division cycle in complex medium represent an effect rather than a cause.     

The divalent cation requirement of Dead Sea halobacteria

Pleomorphic Halobacterium strains isolated from the Dead Sea (H. volcanii, H. marismortui) require high concentrations of divalent cations (75 mM Mg²⁺) for growth. When suspended in medium containing less than 50 mM Mg²⁺ cells lose their native shape within minutes and become spherical. This occurs even at elevated sodium chloride concentrations. Concomitant with the morphological changes, a high mlecular weight component which is positive in Coomassie Brilliant Blue and in periodate Schiff stain is released into the surrounding medium. At divalent cation concentrations lower than 100 mM magnesium cells were shown to lose their viability and their ability to incorporate amino acids. The potency of different divalent cations or their combinations to enable growth and stabilize morphology and viability was studied. It is suggested that different mechanisms underlie the divalent cation requirement of the different functions.     

Structural and functional characterization of AtPTR3, a stress-induced peptide transporter of Arabidopsis

A T-DNA tagged mutant line of Arabidopsis thaliana, produced with a promoter trap vector carrying a promoterless gus (uidA) as a reporter gene, showed GUS induction in response to mechanical wounding. Cloning of the chromosomal DNA flanking the T-DNA revealed that the insert had caused a knockout mutation in a PTR-type peptide transporter gene named At5g46050 in GenBank, here renamed AtPTR3. The gene and the deduced protein were characterized by molecular modelling and bioinformatics. Molecular modelling of the protein with fold recognition identified 12 transmembrane spanning regions and a large loop between the sixth and seventh helices. The structure of AtPTR3 resembled the other PTR-type transporters of plants and transporters in the major facilitator superfamily. Computer analysis of the AtPTR3 promoter suggested its expression in roots, leaves and seeds, complex hormonal regulation and induction by abiotic and biotic stresses. The computer-based hypotheses were tested experimentally by exposing the mutant plants to amino acids and several stress treatments. The AtPTR3 gene was induced by the amino acids histidine, leucine and phenylalanine in cotyledons and lower leaves, whereas a strong induction was obtained in the whole plant upon exposure to salt. Furthermore, the germination frequency of the mutant line was reduced on salt-containing media, suggesting that the AtPTR3 protein is involved in stress tolerance in seeds during germination.Figure a Induction of AtPTR3 gene by amino acids. GUS staining of line 9 plants eight hours after induction with amino acids. Control indicates plant treated with water. His, Leu and Phe indicate plants treated with 10 mM amino acids histidine, leucine or phenylalanine, respectively. b Induction of AtPTR3 gene by salt. GUS staining of line 9 plants grown on MS medium on different salt concentrations: Control indicates plant grown on MS medium and 100 mM, 120 mM and 140 mM indicate plants grown on MS medium supplemented with the indicated NaCl concentrations. Size of the plants grown on salt medium has been magnified. c Germination frequency of Atptr3 knockout mutant line is reduced on salt medium. Atptr3 knockout mutant (9) and wild type C24 (WT) sown on MS medium (Control) and MS medium supplemented with salt (140 mM NaCl).      

The Exchange of RNA and Protein During Conjugation in Tetrahymena*

SYNOPSIS. Exchange of cytoplasm in Tetrahymena pyriformis, syngen 1, has been demonstrated by growing cells of 1 mating type in medium supplemented with H³-uridine or H³-histidine, washing, mixing with cells of an unlabeled, starved mating type, sampling conjugants at different times, and preparing autoradiographs. It was found that cytoplasmic interchange begins soon after the mates unite, and has become extensive before the end of the 1st prezygotic prophase (micronuclear crescent stage). When the RNA in one mating type had been labeled with H³-uridine, the activity was distributed almost evenly between the mates by late stages of conjugation. These results are consistent with electron micrographs of this syngen showing small pores in the attachment region of the mates, and many free ribosomes in the cytoplasm (8,11). By contrast, when protein in one mating type had been labeled with H³-histidine, these cells at late conjugation remained about twice as active as their originally unlabeled mates, presumably because of the physical characteristics of some structures which incorporated the amino acid (for example, cilia and membranes of the cell surface; cytoplasmic bodies, such as mitochondria, larger than the pores). That the radioactivity in the originally unlabeled cells came from their mates and not from the environment is indicated by the continued presence of inactive non-conjugants after 1 and 2 days in the mating type mixtures. Other cells which did acquire small amounts of active cytoplasm probably had engaged in abortive conjugation, separating from labeled mates before forming and exchanging pronuclei.     

Factors influencing the pattern of dopamine secretion in Tetrahymena pyriformis

Dopamine production and secretion by the unicellular eukaryote Tetrahymena pyriformis were examined through the use of high performance liquid chromatography (HPLC) with electrochemical detection and through labeling studies with radioactive precursors. Growing cultures maintained a steady state intracellular level of 1.6 ± 0.3 pmol dopamine/10⁶ cells while secreting dopamine into the medium at a rate of 0.2–0.3 pmol/10⁶ cells per min. Incorporation of [¹⁴C]tyrosine and l-[³H]dihydroxyphenylalanine (DOPA) into dopamine was most successful in a basal medium (1.3 mM Tris-HCl, 1 mM citric acid, and 1 mM Ca(OH)₂, (pH 6.5)). A rapid conversion of added l-[³H]DOPA into dopamine confirmed the dynamic pattern of dopamine synthesis and secretion first indicated by the quantitative chromatographic analyses. The intracellular concentration of dopamine dropped sharply after cells were resuspended in the basal medium at 10⁶ cells/ml, so that by approx. 1 h after resuspension, dopamine dropped below the level detectable by HPLC (0.15 pmol/10⁶ cells). Under these conditions, dopamine secretion continued at a high rate for some time, finally leading to a maximal extracellular concentration of 8.71 ± 1.73 pmol/ml by 1 h. At this concentration, the rate of secretion appears to match that of degradation. Pulse chase experiments confirmed the rapid 3urnover of intracellular dopamine. Approx. 90% of [³H]dopamine and l-[³H]DOPA disappeared from l-[³H]DOPA-prelabeled cells during a 5 min chase, with approx. 50% of this being recovered as [³H]dopamine in the cells' medium. Dopamine secretion could be increased by nearly 100-fold by adding high levels (15 nmol/ml) of l-DOPA to the medium. In contrast, NSD-1015, a potent inhibitor of dopamine synthesis, completely blocked dopamine production. 0.15 mM dibucaine and 0.02 mM reserpine reduced dopamine secretion by approx. 65% over a 25-min incubation, but 5 mM EGTA had no noticeable effect.