Mean macronuclear DNA contents are variable in the ciliate Tetrahymena

Using cytophotometry the mean macronuclear DNA content of the ciliate Tetrahymena was found to be variable in two cell lines examined. While environmental changes (different culture fluids, temperature shifts) influence the mean DNA content of at least one of the two cell lines, spontaneous changes of the means are observed in both lines. The mean DNA contents of cultures maintained permanently in defined medium at various temperatures suggest the existence of a lower (7.5 pg) and an upper (13.6 pg) limit of the mean macronuclear DNA contents. Greatly differing means, either below or above those limits, were only occasionally found in cultures shifted to different temperatures for periods of less than 3 days. Eventually, the G2 mean macronuclear DNA contents of these cultures differed greatly from the doubled G1 mean value (maximum: mean G2 value equalling four times the G1 mean). Analysis of the maximum and minimum G1 DNA contents found in any culture indicates no absolute macronuclear DNA content triggering the regulation of macronuclear DNA content. There is no stringent correlation between the average cell volume and the average macronuclear DNA content. The data are discussed with reference to reported mechanisms of regulation of macronuclear DNA content.

A genetic analysis of tetrahymena that have aborted normal development

Conjugating Tetrahymena can abort the sexual cycle before the production of progeny somatic (macro-) nuclei and return to vegetative growth. We have analyzed the germinal (micronuclear) genotypes of these cells in order to determine the stage at which they aborted conjugation. Our data demonstrate that nearly all of these cells attempt meiosis, but that very few reach the successful completion of cross-fertilization. The resulting micronuclear genotypes suggest that either germinal chromosomes or entire nuclei are lost during an unsuccessful attempt at meiosis or cross-fertilization. We conclude that the decision to develop progeny macronuclei is made during meiosis and is dependent on the completion of some step necessary for successful cross-fertilization.

Tubulin synthesis during the synchronous cell cycle of Tetrahymena

The distribution of polyribosome material and the synthesis of tubulin was determined for division synchronized Tetrahymena. Cultures of Tetrahymena pyriformis GL were induced to divide synchronously by the one-heat-shock-per-generation technique. After seven heat shocks (at 34 degrees C for 30 min) spaced on generation time apart (157 min), the cells divided synchronously at 80 and 195 min after the end of the last heat shock (EH). Sucrose gradient analysis of polyribosomes demonstrates a progressive reduction in the relative amount of monosomes compared with the total amount of ribosomal material recovered during the period between EH and the first synchronous division. During the period between the first and second synchronous divisions the percentage of monosomes rises immediately after division and does not change after 120 min EH at which time it is indistinguishable from levels found in log growth cells. The specific activity of tubulin was determined throughout the first and second synchronous cell cycles. Tubulin synthesis was measured by labeling cells with L-[35S]methionine and determining the levels of radioactivity comigrating with purified tubulin. A comparison of the resulting electrophoretic patterns reveals a marked induction of tubulin synthesis during G2 of the first and second (free-running) synchronous cell cycle. At its peak, tubulin is synthesized to a point approximately 60% higher than levels observed during the initial part of S phase during the synchronous cell cycle. The results are discussed in reference to other morphological events that occur during the cell cycle and in reference to the regulation of tubulin synthesis.

Discontinuities and overlaps in patterning within single cells

Ciliates such as Tetrahymena manifest longitudinal vegetative growth and periodic equatorial subdivision. Evidence is presented suggesting that this subdivision involves the formation of discontinuities associated with the fission zone that closely resemble expressions of the segment border in multicellular organisms. Unlike latitudes, cellular longitudes can potentially maintain clonal continuity. Features of the system of longitudinal positioning of contractile vacuole pores (c.v.ps) in wild-type cells are suggestive of a circular positional system wrapped around the cell circumference, with a reference border coinciding with the axis of oral development. This border marks a discontinuity that, unlike the fission zone, can be clonally propagated. A recessive mutant, janus (jan), brings about alterations in c.v.p. positioning that suggest that a second longitudinal reference border is located about 45% of the cell circumference to the cell's right of the first. This second border, along which abnormal oral structures sporadically appear, seems to maintain a positional system oriented in a direction opposite to the primary system. When jan first comes to expression in cells previously jan+, the pattern of c.v.p. longitudes changes gradually from that characteristic of wild-type cells to the jan pattern; this change begins before abnormal oral structures first appear along the second reference border. We suggest that the two reference borders, and the positional systems that they control, might be present in wild-type as well as jan cells. The oppositely directed positional systems are likely to overlap. A simple model is proposed to illustrate how overlapping positional systems might cooperate to generate patterns such as those observed.

Cytoskeleton-related structures in tetrahymena thermophila: microfilaments at the apical and division-furrow rings

A ring consisting of microfilaments was found in the apical region of Tetrahymena thermophila wild-type strain B and janus mutant. This ring, about 0.4 micrometer wide and 0.2 micrometer thick, is located at the bases of the anterior, non-ciliated basal bodies of the apical ciliary couplets. The apical ring is made of fine filaments showing a banded pattern, the distance between bands depending on the fixation procedure and ranging from 30–200 nm. The bands are made of small beads fastened to the filaments. The microfilaments of the apical ring are attached to the bases of the basel bodies. No connection with the cell membrane was found. In dividing cells in the incipient furrow region of filamentous band originates from the epiplasmic fibrogranular meshwork. This contractile ring is about 0.4 micrometer wide and 0.8 micrometer thick. It is formed by circumferentially aligned microfibrils. During constriction the contractile ring remains associated with the epiplasmic layer, which in turn adheres to the inner alveolar membrane. The microfilaments of both the apical and the division-furrow rings have diameters ranging from about 3.8-7.I nm.

External factors limiting the multiplication potential of Tetrahymena

By variation of nutritional and other external conditions we have determined the factors that limit the multiplication rate and the culture growth in Tetrahymena thermophila. The enriched synthetic medium of Kidder & Dewey (1951), a culture temperature of 29 degrees C, and aeration by agitation were chosen as reference conditions. The final cell density is increased by and proportional to the amount of the complete set of nutrients. Testing single nutritional factors or groups of them revealed that only nitrogen sources yield higher cell densities. But none of them or any combination is as capable of increasing the cell density as the complete medium. Therefore, the medium has to be considered as well balanced. Ammonia, cell density, O2 supply, and pH have been excluded as factors limiting the capacity for multiplication. There are no known factors promoting or inhibiting culture growth.

Age-associated changes in the micronuclear cycle of Tetrahymena thermophila A III heterokaryons. A brief note

The micronuclear cycle of Tetrahymena thermophila A III heterokaryons is shown to change with increasing clonal age. Autoradiographic and cytofluorimetric studies suggest that alteration may be due to (1) loss of late replicating sequences, or (2) (more likely) changes in the timing of micronuclear division and S with respect to cytokinesis.

Investigation into the experimental kinetic support of the two-state model of the cell cycle

Five previously published cell generation-time distribution functions have been examined in an effort to elucidate the parameters of the two-state model of the cell cycle. These parameters are the fractional number of cells that bypass the G0 state, the probability of exit from G0, and the distribution of traversal times through the active state. To explain observed beta-curve behavior of cell populations, it is necessary to define the parameters in terms of pairwise behavior of newborn sister cells. From the beta-curve, we demonstrate that at least 50% of the cells must pass through the G0 state. The alpha-curve is consistent with any positive fraction of newborn cells passing through the G0 state, and provides no further information. We explore a possible method for resolving the remaining indeterminacy regarding the number of cells bypassing the G0 state, namely, examination of the generation-time distribution functions of fast sister cells only. Such an approach, although theoretically attractive, presents formidable experimental difficulties, however. If it should turn out that indeed only 50% of the cells are apparently passing through a random-exiting phase of the cell cycle, then an alterative plausible biological mechanism for the observed variability in generation times is supplied by Prescott's hypothesis: variability is a consequence of the inequality in the metabolic content of sister cells at birth.

Temperature-sensitive periods of mutations affecting cell division in Tetrahymena thermophila

Temperature-sensitive periods were determined by application of temperature shifts and shocks to 3 temperature-sensitive cell division arrest (cda) mutants of Tetrahymena thermophila. A restrictive temperature, 36 degrees C, was found at which all 3 mutants are fully penetrant, yet other physiological effects are minimal. At this temperature, the temperature-sensitive period of cdaC2 is a unique 5-min period in mid-division, that of cdaA1 is a similarly brief period situated about 0.5 h prior to cell division, while the temperature-sensitive period of cdaH1 is 20 to 30 min long and immediately precedes cell division. These periods either coincide with (cdaC2, cdaH1) or immediately precede (cdaA1) the onset of phenotypic abnormality at the restrictive temperature. Brief exposure to 36 degrees C during the temperature-sensitive period in any of these mutants brings about irreversible arrest of division furrows in progress or preparation. Mutant cells suffering such arrest can, however, divide again at a permissive temperature by forming new furrows at different sites.

The relationship between the excess-delay phenomenon and temperature-sensitive periods in Tetrahymena thermophila

Although temperatures of 37.5 and 39 degrees C allow continuous and rapid exponential growth of wild type Tetrahymena thermophila, sudden shifts up to these temperatures can bring about long excess-delays of cell division with accompanying resorption of developing oral primordia. A characteristic parameter of this delay-phenomenon is the physiological transition point, before which delays are maximal and after which they are negligible. When measured at a restrictive temperature that does not induce excess delays (36 degrees C), the end of the temperature-sensitive period of the cell division arrest of mutant cdaA1 precedes the physiological transition point, that of cdaH1 roughly coincides with it, while the entire temperature-sensitive period of cdaC2 comes after the physiological transition point. When cdaA1 cells are exposed to 37.5 degrees C or above, the manifestations of temperature sensitivity are drastically affected: the estimate of the end of the temperature-sensitive period (the execution point) becomes spuriously late, and the characteristic division arrest following heat shocks is not manifested. The differential effects of the higher restrictive temperatures on cdaH1 are most subtle, whereas those on cdaC2 are negligible. We conclude that the excess-delay phenomenon involves a set-back of genemediated processes occurring at specific stages of the cell cycle.

The regulation of amounts and proportions of genetic elements in the macronuclei of Tetrahymena thermophila strains of diverse karyotype

Measurements of the micronuclear DNA content of clones with assumed different degrees of micronuclear ploidy confirmed the triploid nature of one clone. The micronuclear DNA content of a presumptive haploid clone was found to be slightly higher than expected, whereas one of two aneuploid clones had an unexpectedly low micronuclear DNA content. The macronuclear DNA content of cells with macronuclei which had developed from triploid, diploid and probably haploid and aneuploid macronuclear-Anlagen is very similar. Specifically, the smallest individual macronuclear DNA contents are consistently found within the same size class in all clones tested. Cell volumes, RNA and protein contents are alike in all clones tested. Only the growth rate and maximal density reached of one out of two aneuploid clones is reduced in comparison with the very similar other clones. The results are discussed with reference to the regulation of macronuclear DNA content, and to the compensation of gene-dosage.

Increase in macromolecular amounts during the cell cycle of Tetrahymena: a contribution to cell cycle control

Increases in RNA, protein and cell size were determined cytophotometrically during the cell division cycle of Tetrahymena. For these parameters different patterns were found. RNA accumulates slowly during G1 period and faster during macronuclear S. This agrees with the changing uridine incorporation rate which is at least partly related to the varying macronuclear DNA amount. Increases in protein content and cell size occur mainly during G1 and G2. This pattern was confirmed by determining the RNA: protein ratio in individual cells. It is minimal at the end of the G1 period. These findings and evidence from the literature suggest that initiation of DNA replication is under negative control by the relative RNA content of the cell.

Use of 8-hydroxyquinoline to enrich for temperature-sensitive mutants of Tetrahymena

The effects of the chelating agent 8-hydroxyquinoline (Hq) on Tetrahymena thermophila were examined. Cell division was completely inhibited by 5 micrograms of Hq per ml. At this concentration deoxyribonucleic acid, ribonucleic acid, and protein syntheses were also completely and nonselectively inhibited. The inhibition was reversible after 6 h of Hq treatment. At concentrations above 20 micrograms/ml a 10,000-fold decrease in survival as seen after 2 h in the drug. The sensitivity of Tetrahymena to Hq was found to be dependent upon cell concentration, wild-type strain, medium, and length of time the culture is at 38 degrees C before Hq is added. Mutants of Tetrahymena that are unable to divide at the restrictive temperature, but which continue macromolecular synthesis, were found to be resistant to Hq treatment. Conditions were obtained in which more than a 1,000-fold difference in survival was seen between this class of mutant and the wild type. The effect of Hq on three other classes of temperature-sensitive mutants was examined, and the results are discussed.

Life cycle variation and regulation of macronuclear DNA content in Tetrahymena thermophila

The mean DNA content of G2 macronuclei varies during the life cycle of the ciliate Tetrahymena thermophila. Early in the life cycle the mean is about 130 C; later it is about 94 C. In hybrids between strains A and B the decrease from 130 C to 94 C usually began after 60 fissions after conjugation. In B X B clones the decrease was complete by 50 fissions. The data suggest that there may be a genetic difference between strains A and B with respect to the onset of the decrease in DNA content. The downward regulation of the mean DNA content appears to be related to the mechanism which removes the variance in macronuclear DNA content which is added to macronuclei by unequal macronuclear division. Unequal macronuclear division regularly occurs at all stages of the life cycle, with larger macronuclei tending to divide more unequally. In the absence of regulation, unequal macronuclear division would constantly add variance to G1 macronuclei and their range would continue to increase. Analysis of the variances of G1 and G2 macronuclei suggests that at all stages of the life cycle the added variance is removed by acting upon nuclei which become too small or too large. According to this model, macronuclei with smaller amounts of DNA are regulated upward by an extra macronuclear S phase, while larger amounts are regulated downward by chromatin extrusion and the skipping of macronuclear S. The mean DNA content appears to change during the life cycle because the thresholds at which macronuclei become too small or too large are readjusted. It is postulated that these thresholds are a function of gene dosage.