Cilia regeneration in starved tetrahymena: an inducible system for studying gene expression and organelle biogenesis.

Deciliated starved Tetrahymena recover motility with kinetics similar to those of growing cells and, like growing cells, require RNA and protein synthesis for regeneration. Comparisons of polysome profiles and electrophoretic analyses of newly synthesized proteins indicate, however, that the basal level of protein synthesis in starved cells is markedly lower than that in growing cells. This difference allows demonstration of changes in protein synthesis following deciliation of starved cells which cannot be detected (if they occur at all) in growing cells. Deciliation of starved cells induces a specific and orderly program of protein synthesis. The synthesis of an 80,000 dalton protein (deciliation-induced protein, DIP) begins shortly after deciliation, comprises 15% of the protein synthesized from 20-60 min, and declines around 60 min after deciliation, shortly after most cells have begun to regenerate cilia. The synthesis of a 55,000 dalton protein is also induced during regeneration and has been identified as tubulin using a well characterized antibody made to ciliary tubulin. Tubulin synthesis is undetectable during the first hour after deciliation even though 60-80% of the cells regain mobility and regenerate short but clearly visible cilia. Tubulin synthesis begins 60 min after deciliation and continues for 2 hr. At its peak, tubulin comprises 7-8% of the protein synthesized. The results of actinomycin D addition at different times after deciliation suggest that RNA required for DIP synthesis is synthesized early (0-30 min), while RNA required for tubulin is synthesized later and over a longer period (30-90 min). Thus deciliation of starved cells, an event occurring at the cell periphery, initiates a well defined and reproducible series of events culminating in cilia formation. This system should be useful in elucidating the molecular mechanisms regulating gene expression and organelle biogenesis in Tetrahymena.     

Cell cycle dependent variation of calmodulin in Tetrahymena

The level of calmodulin (CaM), a ubiquitous calcium-binding protein of eukaryotic cells was determined at different phases of the cell cycle in a synchronized Tetrahymena population. It was found that the concentration of CaM at G1 was approximately half of the concentration of S and this 2 x G1 level of CaM was maintained through the G2 and M stages of the cell cycle. To ascertain the role of CaM in the initiation of DNA synthesis, the cells were treated with trifluoperazine (TFP), a CaM antagonist, and EGTA (Ca2+-chelator) at the G1/S boundary. It was found that DNA synthesis was inhibited in these drug-treated cells. The uptake of the nucleotide precursor was not affected in TFP and EGTA treated cells, thus excluding the possibility of alteration in the membrane transport properties. Treatment with TFP failed to inhibit the synchronous mitotic division in Tetrahymena. The existence of a variable content of CaM through the cell cycle of Tetrahymena was demonstrated, suggesting the possible involvement of this Ca2+-binding protein in the nuclear DNA replication process.     

The actin gene ACT1 is required for phagocytosis, motility, and cell separation of Tetrahymena thermophila

A previously identified Tetrahymena thermophila actin gene (C. G. Cupples and R. E. Pearlman, Proc. Natl. Acad. Sci. USA 83:5160-5164, 1986), here called ACT1, was disrupted by insertion of a neo3 cassette. Cells in which all expressed copies of this gene were disrupted exhibited intermittent and extremely slow motility and severely curtailed phagocytic uptake. Transformation of these cells with inducible genetic constructs that contained a normal ACT1 gene restored motility. Use of an epitope-tagged construct permitted visualization of Act1p in the isolated axonemes of these rescued cells. In ACT1Delta mutant cells, ultrastructural abnormalities of outer doublet microtubules were present in some of the axonemes. Nonetheless, these cells were still able to assemble cilia after deciliation. The nearly paralyzed ACT1Delta cells completed cleavage furrowing normally, but the presumptive daughter cells often failed to separate from one another and later became reintegrated. Clonal analysis revealed that the cell cycle length of the ACT1Delta cells was approximately double that of wild-type controls. Clones could nonetheless be maintained for up to 15 successive fissions, suggesting that the ACT1 gene is not essential for cell viability or growth. Examination of the cell cortex with monoclonal antibodies revealed that whereas elongation of ciliary rows and formation of oral structures were normal, the ciliary rows of reintegrated daughter cells became laterally displaced and sometimes rejoined indiscriminately across the former division furrow. We conclude that Act1p is required in Tetrahymena thermophila primarily for normal ciliary motility and for phagocytosis and secondarily for the final separation of daughter cells.     

Cell-cycle phase-dependence of drug-induced cycle progression delay.

The effect of adriamycin on cell cycle phase progression of CHO cells synchronized into the various phases of the cell cycle by elutriation was investigated by high resolution pulse cytophotometry. Cells treated in all phases of the cell cycle showed delay in their subsequent progression. In addition to the wellknown block of cells in the G2-phase, a delay in passage of cells from G1 to S and a decreased rate of transit through the S-phase were observed. A broadening of the DNA distributions of the treated cells was observed after cell division indicating induction of chromosomal abnormalities.     

Shifts in nuclear and cytoplasmic nucleic acid content in temperature-synchronized Tetrahymena pyriformis (HSM)

Nuclei were isolated by exposing temperature synchronized Tetrahymena pyriformis (HSM) to Triton-X-100. Cell division synchrony was induced with a repetitive 12-hour temperature cycle (9.5 hours at 13°, 2.5 hours at 29°). Increase in nucleic acid content was biphasic: primarily during the last two hours of the cold period well in advance of the synchronous burst of division and secondarily in the last hour of the warm period. Nuclear RNA content rises almost two hours ahead of cytoplasmic RNA which shows a maximum 0.5 hour before the onset of the warm period. The DNA content reaches a peak 30 minutes later. On the basis of these shifts there appears to be not net synthesis of nucleic acids during cell division. The changes in RNA/DNA of the isolated macronuclei and micronuclei suggest enhanced RNA turnover, loss to the cytoplasm and enhanced ribonuclease activity prior to cell division. Cytoplasmic RNA also appears to be subject to enzymic degradation.     

The influence of epidermal growth factor and insulin on proliferation and DNA synthesis in ciliates Tetrahymena pyriformis

The influence of the epidermal growth factor (EGE) (10(-8) M), insulin (10(-6) M) and EGF (10(-8) M) in combination with insulin (10(-6) M) on proliferation and DNA synthesis in the nuclei of ciliates Tetrahymena pyriformis GL was studied. Insulin and EGF, known to stimulate growth of many types of mammalian cells revealed a mitogen influence on the unicellular eukaryotes. This effect involves stimulation of DNA synthesis, rising synchronization of cell division (upon the influence of EGF), and increase in cell number during the exponential growth. The mitogen effect may be evoked by cell progression in G1-phase under the action of growth factors and, consequently by earlier entry of cells into S-phase of the first cell cycle. Insulin repressed division of cells that entered into the generative cycle. These cells were delayed in late S-phase and G2-phase of the cycle. Part of these cells perished, while other cells could successively overcome the cell block to start their division by the 4th hours of cultivation. A collateral cytotoxic effect of insulin was found, being most prominent in early periods of Tetrahymena cultivation.     

Cytofluorimetric research on the changes in the DNA content in the nuclei of Amoeba proteus during prolonged starvation and after refeeding]

Dividing amoebae were manually selected from the culture of Amoeba proteus, and so groups of synchronously dividing (synchronized) amoebae were obtained. These synchronized amoebae were maintained without food. In spite of starvation, individual amoebae in some particular groups were seen to divide, whereas in other groups of amoebae there was no division at all. The starving amoebae died not earlier than 2 weeks after the last division. A relative DNA content in isolated nuclei has been determined cytofluorometrically for each of 6 groups of synchronized starving amoebae, unable to divide. The nuclei were isolated in different intervals after division (after the feeding was ceased): 1.0-1.5 h, 1 day and up to 13 days with 1-2 day intervals. In the all groups of amoebae DNA synthesis occurred on the first 1-2 days after division. The nuclear DNA content in amoebae of 3 groups increased more than two-fold as compared with the 1 h level, in other 3 groups the nuclear DNA content did not exceed the doubled 1 h level, but probably exceeded the doubled postmitotic level. Later on, the nuclear DNA content in starving amoebae of each group was seen to decrease by 16-20%. Amoebae of 3 of the 6 groups were given the food organisms (Tetrahymena pyriformis) 8 days after division (after cessation of feeding). 2-3 days after refeeding some of these amoebae divided, and the nuclear DNA content of the refed amoebae proved to be higher than that in amoebae that continued to starve. It is suggested that the decrease of DNA content in the nuclei of starving amoebae and the increase of DNA quantity in the nuclei of refed amoebae may result from degradation and induction of synthesis of specific extra DNA synthesized in amoeba nuclei during each cell cycle.     

Regeneration of cilia in starved Tetrahymena thermophila involves induced synthesis of ciliary proteins but not synthesis of membrane lipids.

The synthesis of ciliary-membrane phospholipids and ciliary proteins was studied after deciliation in starving Tetrahymena thermophila cells. Deciliated cells regenerated the new ciliary membrane without any induced phospholipid synthesis. The constant cell volume found during the regrowth of the cilia suggests that renewal of ciliary membranes takes place by insertion of intracellular membrane material into the cell surface. In contrast with the absence of induced phospholipid synthesis during ciliary regeneration, the synthesis of ciliary proteins was found to be induced. This enhanced synthetic activity was made possible by an increased rate of intracellular protein degradation in regenerating cells. It was found that the extent of the induced synthesis strongly depends upon the growth conditions of the cells before starvation. Furthermore, it was shown that the degree of induced protein synthesis is greater for higher-molecular-weight ciliary proteins than for lower-molecular-weight species.     

Reappraisal of G1-phase arrest and synchronization by lovastatin

It has been proposed that lovastatin arrests cells in the G1-phase of the division cycle, and that release from lovastatin inhibition produces a synchronized culture. A new method of methocel time-lapse-videography has been used to analyse cell division patterns following lovastatin treatment. Release of L1210 cells from lovastatin inhibition failed to produce synchronized divisions. Moreover, contrary to earlier proposals, lovastatin did not arrest cells with a G1-phase amount of DNA. Analysis of previous reports of 'synchronization' and growth-arrest support these findings. It is concluded that lovastatin neither synchronizes cells, nor arrests cells in the G1-phase of the division cycle.     

Cell division induced by mechanical stimulation in starved Tetrahymena thermophila: cell cycle without synthesis of macronuclear DNA

Starved Tetrahymena thermophila cells underwent synchronous cell division 2 h after a mechanical stimulation. The macronucleus showed no obvious increase in DNA content before the cell division in the starvation medium, and the DNA content was decreased after the cell division. On the other hand, when the starved cells were given nutrient-supplied medium immediately after the mechanical stimulation, cell division was delayed for 3 h. This period was almost the same as that for G1 cells in the stationary culture to first division after transfer to fresh nutrient medium. These results suggest that the mechanical stimulation induces an early division of starved cells, skipping the macronuclear S-phase with the starved cells probably becoming trapped in G1. Starved cells that had finished division soon formed mating pairs with cells of the opposite type. These observations lead us to propose that cell division in starvation conditions may be necessary to reduce macronuclear DNA content prior to the mating of T. thermophila.     

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.     

Studies of Messenger RNA during the Cell Cycle in Synchronized Mass Cultures of Tetrahymena pyriformis GL by Hybridization

SYNOPSIS RNA isolated from free ribosomes, from cell structures and from soluble cell phase after indole lysis of synchronized Tetrahymena cells showed different abilities to hybridize with DNA. The supraoptimal temperature (34 C) caused a decrease in the ability to hybridize in all 3 RNA fractions. The same effect was noted at the time of cell division. Synthesized messenger RNA as a proportion of the total quantity of RNA was roughly constant during the whole cell cycle. However, in contrast to synchronized mammalian cells the messenger RNA synthesis did not proceed at a constant rate thruout the cell cycle.     

The role of protein metabolism in glucocorticoid-lnduced prolongation of G1 phase in human NHIK 3025 cells

It has previously been found that human NHIK 3025 cells have a glucocortiocoid-sensitive restriction point in mid-G1 phase of the cell cycle. When these cells were synchronized by mitotic selection and exposed to dexamethasone before the restriction point, G1 phase was prolonged whereas the rest of the cell cycle was unperturbed by the hormone. These observations were confirmed by flowcytometric mesurements of synchronized cells in the present study. Cells that received dexamethasone (10^?6 M) just after mitotic selection had a 4 hour prolongation of both G1 and the total cell cycle. However, the general rates of both protein synthesis and protein degradation were found not to be altered by the hormone, i.e., the rate of protein accumulation in dexamethasone exposed cells was equal to that of control cells. Dexamethasone exposed NHIK 3025 cells were found to be larger than control cells at the time of cell division. This is a direct consequence of a prolonged cell cycle duration with no change in general protein metabolism. It thus appears that the dexamethasone-induced prolongation of G1 phase is the result of a steroid-regulated G1 specific process(es) leading toward DNA replication, a process that does not alter general protein accumulation.     

Synchronization of Leishmania tarentolae by Hydroxyurea

SYNOPSIS Leishmania tarentolae cells in brain-heart infusion medium were partially synchronized in terms of DNA synthesis and cell division by a 10 hour period of inhibition in 200 μg/ml hydroxyurea at 27 C. Nuclear and kinetoplast DNA synthesis commenced immediately upon removal of hydroxyurea, and kinetoplast and nuclear division occurred after about 5 hr. The Index of Synchronization (3) varied from 33-41%.
A moderate decay of the synchronicity was noted by the 2nd cell cycle. Hydroxyurea was selectively lethal to S-phase cells.     

Synchronization of carrot cell culture by starvation and cold treatment

When a suspension culture of carrot cells in the early stationary phase was allowed to stand at 4 °C for 72 h, the cell population was partially synchronized in relation to their division cycle. Judging from a pattern of increase of cell number, two steps in the cell cycle are thought to be sensitive to these treatments. When an additional cold treatment was applied to the culture, degree of synchronization was markedly increased. Protein content in a synchronized culture increased in a stepwise fashion as well as DNA while RNA increased continuously.     

Influence of deciliation and ciliary regeneration on hormonal imprinting in Tetrahymena. Observations on the 'localization' of imprinting

Imprinting induced in Tetrahymena with insulin is not abolished by deciliation. No imprinting occurred in deciliated cells exposed to insulin at 1 or 2 h of regeneration. However, imprinting did occur if Tetrahymena was exposed to insulin after 3 h of regeneration. It appears that while presence of cilia is a prerequisite of imprinting, the pertinent information is not, or not exclusively stored in the cilia.     

Effect of cell population density on G2 arrest in Tetrahymena

The ciliated protozoan, Tetrahymena pyriformis strain GL-C, has been used to study the effect of cell population density during starvation on the synchrony obtained after refeeding and on the number of cells arrested in G2 phase of the cell cycle. At high cell densities two peaks of division indices were observed after refeeding while only one was observed at low cell densities. Cell division began earlier in cultures starved at high cell densities. Most importantly, the proportion of cells in G2 was considerably higher in populations starved at high cell densities. When tritiated thymidine was present during the refeeding period, radioautographs of cell samples at different times showed that the first cells to exhibit division furrows contained unlabeled nuclei. The first peak in the division index after refeeding was observed only at higher cell densities and is attributed to the cells arrested in G2. These results suggest that Tetrahymena is an excellent organism to study the concept of resting stages in the cell cycle and their control.     

Sizes of G1 and G2 populations in starved Tetrahymena

Feulgen cytophotometry and autoradiography were used to study DNA content and DNA synthesis in starved and starved-refed Tetrahymena pyriformis GL-C. It was found that (1) the cell population shows a limited increase in cell number during starvation and this increase is restricted to the first 7 h of starvation; (2) at the end of starvation, there is a portion of the cell population whose DNA content is similar to that for standard G2 cells; (3) a significant portion of the dividing cells at the first division following refeeding in the presence of [³H]TdR are unlabeled; (4) these unlabeled cells are among the first to divide and, upon division, generally enter into a cell cycle either lacking a G1 phase or with a shortened G1 phase.