CILIA REGENERATION IN TETRAHYMENA AND ITS INHIBITION BY COLCHICINE

The cilia of Tetrahymena were amputated by the use of a procedure in which the cells remained viable and regenerated cilia. Deciliated cells were nonmotile, and cilia regeneration was assessed by scoring the percentage of motile cells at intervals following deciliation. After a 30-min lag, the deciliated cells rapidly recovered motility until more than 90% of the cells were motile at 70 min after amputation. Cycloheximide inhibited both protein synthesis and cilia regeneration. This indicated that cilia formation in Tetrahymena was dependent on protein synthesis after amputation. Conversely, colchicine was found to inhibit cilia regeneration without affecting either RNA or protein synthesis. This observation suggested the action of colchicine to be an interference with the assembly of ciliary subunit proteins. The finding that colchicine binds to microtubule protein subunits isolated from cilia and flagella (13) supports this possibility. The potential of the colchicine-blocked cilia-regenerating system in Tetrahymena for studying the assembly of microtubule protein subunits during cilia formation and for isolating ciliary precursor proteins is discussed.     

A Simple Method for Determining Antitubulinic Activities of Ansamitocins and Related Compounds Using a Cilia Regeneration System with Deciliated Tetrahymena

Cilia regeneration with deciliated Tetrahymena pyriformis W was tested to determine the antitubulinic activities of ansamitocins and related compounds in a microbial system. Various factors interfered with the regeneration process, i.e. excess shearing force in deciliation procedure, high temperature (32°C or above), high or low pH (pH 9 or 5), and exogenous divalent cations, such as Zn²⁺, Mn²⁺, Cu²⁺ and Co²⁺. Under suitable conditions, cilia regeneration was completed in about 60 min of incubation, and a number of newly formed cilia were observed around the cell surface. When ansamitocins were added to the recovery solution, cilia regeneration was completely suppressed without alterations in cell shape or the surface structure of deciliated Tetrahymena. In this assay system, the inhibitory activity of ansamitocins was slightly stronger than that of maytansine.     

Cilia regeneration in Tetrahymena : A simple reproducible method for producing large numbers of regenerating cells

We have developed an improved medium in which Tetrahymena can be deciliated by gentle shearing. The cells remain viable and regenerate a new complement of cilia. Unlike previous methods for viable deciliation of Tetrahymena, this method is easily adaptable to large numbers of cells, to cells in different stages of the life cycle (growing, starved, conjugating), and to both commonly studied species, T. thermophila and T. pyriformis. Starved T. thermophila deciliated by this method regained motility by 1 h, regenerated oral apparatus by 4.0 h and restored tubulin in cilia at a linear rate of about 3 pg h⁻¹ cell⁻¹.     

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.     

Adenylate kinase in sea urchin embryonic cilia

Sea urchin embryos swim by ciliary movement. Hypertonic shock causes deciliation and loss of motility. Within 2-4 h, cilia regenerate and the embryos swim again. Regeneration of cilia occurs multiple times. The adenylate kinase (AK) activity of isolated cilia was studied. A 130-kDa Sp-AK isozyme, present in sperm flagella, is also present in embryonic cilia. AK activity is responsible for approximately 93% of nonmitochondrial ATP regeneration from ADP in embryonic cilia. This is unlike sea urchin sperm flagella, where approximately 31% of the nonmitochondrial ATP regeneration is from the 130-kDa Sp-AK isozyme and approximately 69% from the flagellar creatine kinase (Sp-CK). Embryos were deciliated 1-3 times and after a 2-h period of regeneration the major ciliary axonemal proteins such as the tubulins appeared constant in amount. However, a moderate decrease in ATPase activity, and a large decrease of total AK activity, were measured. The decrease in AK activity paralleled the decrease in embryo swimming velocity. Embryos were deciliated once and cilia regeneration followed for 4 h. ATPase activity recovered to control levels by 3 h, but AK activity and swimming velocity remained lower than in controls. Detergent solubility data and kinetic experiments indicate that, in addition to the 130-kDa Sp-AK, there is at least one additional AK isozyme in embryonic cilia. Analysis of the S. purpuratus genome indicates five AK isozymes in addition to the 130-kDa Sp-AK isozyme. Decreased swimming velocity of embryos with regenerated cilia suggests that regenerated cilia are not as functionally perfect as naturally grown cilia.     

Membrane renewal after dibucaine deciliation of Tetrahymena: Freeze-fracture technique,cilia, membrane structure

Axenic late log phase cultures of Tetrahymena pyriformis DN-B3 are deciliated by treatment with dibucaine. Deciliation occurs first at the anterior end of the cell and then progresses posteriorly. Concomitantly, all mature mucocysts are induced to discharge by the drug. The exact point of scission of each cilium is found to be a very localized region, between two specialized membrane arrays: the ciliary necklace and the ciliary patches, situated at the base of the cilium. Isolated cilia retain the patches, while the necklaces remain with the deciliated bodies. The cell membrane seals over the stubs. The new ciliary membrane then grows out above the necklace without the patches, which do not generally appear for several hours. Membrane renewal is therefore asynchronous, with bulk growth preceding the formation of specialized intramembrane particle arrays. During regrowth, the cilia also first return at the anterior end of the cell. This suggests that underlying gradients, perhaps related to Ca²⁺, are significant in the deciliation process.     

Deciliation interferes with cell-cycle progression in Tetrahymena

The impact of ciliary regeneration upon cell-cycle progression of the ciliate Tetrahymena was studied. It was found that cell division ceases during ciliary regeneration, and starts again about 4 h after deciliation. Deciliation of an asynchronously multiplying culture results in a rapid interruption of DNA synthesis, followed by resumption 1 h later. This was shown by pulse-labelling the cells with [3H]thymidine at various times after deciliation. Cytophotometric determinations of the macronuclear DNA content substantiated these observations, since the average DNA content per cell remained constant within the first hour of regeneration, confirming the labelling experiments, after which it rose. At its maximum, the average DNA content was more than doubled as compared with the beginning of the experiment. This indicates that a substantial proportion of the regenerating cells performed two rounds of DNA replication prior to cell division. The massive drop in the average DNA content during the fifth hour after deciliation indicates that the culture becomes partly synchronized for cell division by the deciliation procedure. The division synchrony results from a greater delay of the next cell division when G2 cells are deciliated than occurs in G1 cells. This was shown by deciliating cultures of Tetrahymena thermophila cells in the respective stages of the cell cycle, which had been partly synchronized by elutriator centrifugation. Thus, deciliation followed by ciliary regeneration causes a varying degree of retardation in progression through the cell cycle, being greatest for G2 cells and least for G1 cells.     

Induction of tubulin synthesis during cilia regeneration in growing Tetrahymena

Log growth Tetrahymena pyriformis GL were deciliated by means of a calcium pulse and allowed to regenerate their cilia in a non-nutrient recovery medium. Polyribosome profiles show only small amounts of polysomes up to 30 min after suspension in recovery medium. After this time the number of polysomes increases continuously as protein synthetic activity and motility are recovered. Labeling of whole cells with l-[³⁵S]methionine and comparison of the resulting electrophoretic patterns reveals a marked induction of tubulin synthesis as cilia regeneration proceeds. At its peak, tubulin accounts for 7–10% of the incorporated label but this peak occurs 35 min after the cells become greater than 90% motile and about 25 min after the cilia reach full length. These results are discussed with respect to the regulatory mechanism of tubulin induction and induction of tubulin synthesis in starved Tetrahymena.     

Synthesis and Turnover of Embryonic Sea Urchin Ciliary Proteins during Selective Inhibition of Tubulin Synthesis and Assembly

When ciliogenesis first occurs in sea urchin embryos, the major building block proteins, tubulin and dynein, exist in substantial pools, but most 9+2 architectural proteins must be synthesized de novo. Pulse-chase labeling with [³H]leucine demonstrates that these proteins are coordinately up-regulated in response to deciliation so that regeneration ensues and the tubulin and dynein pools are replenished. Protein labeling and incorporation into already-assembled cilia is high, indicating constitutive ciliary gene expression and steady-state turnover. To determine whether either the synthesis of tubulin or the size of its available pool is coupled to the synthesis or turnover of the other 9+2 proteins in some feedback manner, fully-ciliated mid- or late-gastrula stage Strongylocentrotus droebachiensis embryos were pulse labeled in the presence of colchicine or taxol at concentrations that block ciliary growth. As a consequence of tubulin autoregulation mediated by increased free tubulin, no labeling of ciliary tubulin occurred in colchicine-treated embryos. However, most other proteins were labeled and incorporated into steady-state cilia at near-control levels in the presence of colchicine or taxol. With taxol, tubulin was labeled as well. An axoneme-associated 78 kDa cognate of the molecular chaperone HSP70 correlated with length during regeneration; neither colchicine nor taxol influenced the association of this protein in steady-state cilia. These data indicate that 1) ciliary protein synthesis and turnover is independent of tubulin synthesis or tubulin pool size; 2) steady-state incorporation of labeled proteins cannot be due to formation or elongation of cilia; 3) substantial tubulin exchange takes place in fully-motile cilia; and 4) chaperone presence and association in steady-state cilia is independent of background ciliogenesis, tubulin synthesis, and tubulin assembly state.     

RNA synthesis in starved deciliated Tetrahymena pyriformis.

Tetrahymena pyriformis which has been starved for 20 h by incubation in buffer, and then deciliated, can regenerate its cilia in about 90 min while still in suspension in non-nutrient medium. The process of reciliation is accompanied by protein synthesis which begins a few minutes after deciliation and by synthesis of ribosomal and messenger RNAs during a period extending from about 1 h to about 3 h after deciliation. Although net synthesis of RNA remains at a very low level until 1 h after deciliation, a qualitative change in the translatable poly(A)-containing messenger RNA content of deciliated cells, and in particular, formation of beta-tubulin mRNA can be detected almost immediately after deciliation.     

Deciliation Induces Phosphorylation of a 90-kDa Cortical Protein in Tetrahymena thermophila

ABSTRACT. We have used the anti-phosphoprotein antibody MPM-2 to examine changes in phosphorytation of cortical proteins during cilia regeneration in Tetrahymena thermophila . Although numerous cortical proteins are phosphorylated in both nondeciliated and deciliated cells, deciliation induces a dramatic increase in the phosphorylation of a 90-kDa cortical protein. The 90-kDa protein remained phosphorylated during cilia regeneration and then gradually became dephosphorylated. The 90-kDa protein was phosphorylated and dephosphorylated normally in Tetrahymena mutants that assemble short cilia, suggesting that achievement of full length is not the signal that triggers dephosphorylation of the 90-kDa protein. When initiation of cilia assembly is blocked, the 90-kDa protein becomes phosphorylated and remains phosphorylated for an extended period of time, suggesting that initiation of cilia elongation triggers eventual dephosphorylation of the 90-kDa protein, regardless of how long the cilia actually become.     

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.     

Differential protein synthesis and utilization during cilia formation in sea urchin embryos.

Pulse labeling with [¹⁴C]leucine, hypertonic deciliation, fractionation of axonemes by differential solubilization, and autoradiographic analysis of electrophoretically resolved components reveal that the onset of ciliogenesis is marked by the de novo synthesis of numerous architectural proteins of the “9 + 2” axoneme. The synthesis of most of these components continues, some at reduced rates, after full growth of cilia at hatching. Deciliation results in enhanced synthesis of these minor components, dynein, and tubulin. The A- and B-tubulin dimers, derived from the respective subfibers, have essentially identical specific activities after regeneration in the presence of isotope. Subsequent regeneration in cold leucine demonstrates substantial pools of most of the architectural proteins, but at least two such proteins (nexin and ribbon component-20) are made quantally and in limiting amounts in response to each regeneration. Such second regeneration cilia (whose pools were labeled during the first regeneration) have a decreased specific activity of B-tubulin (10–15%) and an increased specific activity of A-tubulin (30–35%), indicating a limited pool of the former but an apparent retarded synthesis, delayed activation, or initial compartmentalization of the latter. This 45% difference in specific activity of the two tubulin dimer pools offers independent evidence that chemically unique tubulin dimers form the structurally unique subfibers. During natural ciliary augmentation or after stimulation by repeated deciliation, the bulk of the initial incorporation occurs in the quantal, minor components, while newly synthesized dynein and tubulin are not maximally utilized until the succeeding generation. The limited, quantal synthesis of microtubule-associated proteins may be a control mechanism for ciliary assembly or elongation, while a delayed utilization of the major proteins of the axoneme may reflect a replenishment of pools and a requisite activation or post-translational modification of stored components.     

Selection of Nonmotile Tetrahymena with Ficoll Underlayers*,†

The mechanisms regulating the development of cilia in Tetrahymena are poorly understood but might be revealed through the study of ciliogenesis mutants. Failure to regenerate cilia after dibucaine deciliation results in continued absence of motility. Therefore, to isolate ciliogenesis mutants efficiently, methods for separating motile and nonmotile cells are essential. We examined the efficacy of Ficoll underlayers for these separations. Ciliates of T. thermophila strain mpr^-/mpr (6 mp sens IV) (6-methyl purine-sensitive; mating type IV) were mixed with Ficoll and added as underlayers to separatory funnels containing growth medium. At 27 C most of the cells remained motile and were found in the top layer; at 37 C, there was a time-dependent increase in the number of nonmotile cells and the number of cells in the Ficoll layer. After 150 min at 37 C, most of the cells became nonmotile and were found in the Ficoll layer. Other studies indicated that at 37 C, the cells remained alive and capable of regenerating cilia when deciliated. Thus, it is clear that the Ficoll underlayer effectively separates the majority of nonmotile cells from the majority of motile cells. Evidently, however, at 37 C wild-type T. thermophila exhibit temperature-sensitive phenotypic variability with regard to motility which should be minimized when selecting for mutations affecting motility and ciliogenesis.     

Characterization of Deciliation-Regeneration Process of Tetrahymena Pyriformis for Cellular Robot Fabrication

Artificial magnetotactic Tetrahymena pyriformis GL (T. pyriformis) cells were created by the internalization of iron oxide nano particles and became controllable with a time-varying external magnetic field. Thus, T. pyriformis can be utilized as a cellular robot to conduct micro-scale tasks such as transportation and manipulation. To complete these tasks, loading inorganic or organic materials onto the cell body is essential, but functionalization of the cell membrane is obstructed by their motile organelles, cilia. Dibucaine HCl, a local anesthetic, removes the cilia from the cell body, and the functional group would be absorbed more efficiently during cilia regeneration. In this paper, we characterize the recovery of artificial magnetotactic T. pyriformis after the deciliation process to optimize a cellular robot fabrication process. After sufficient time to recover, the motility rate and the average velocity of the deciliated cells were six and ten percent lower than that of non-deciliated cells, respectively. We showed that the motile cells after recovery can still be controlled using magnetotaxis, making T. pyriformis a good candidate to be used as a cellular robot.     

Electron microscopic analysis of the effect of progesterone upon the hormone-sensitive solitary cilia and centriolar complexes in the luminal epithelial cells of the uterus of the ovariectomized-adrenalectomized rat

The time course of the hormonally controlled deciliation cycles of the centriolar complexes in the cells of the luminal epithelium of the uterus of the ovariectomized and adrenalectomized rat was analyzed at ultrastructural levels. The results were expressed quantitatively. The half-life of the solitary cilia after progesterone administration in the cell population was 14.6 hr, longer approximately by 1 hr than that previously reported for the estrogen-induced deciliation of the same cells. The time course of the progesterone-induced loss of solitary cilia strongly suggested that the phenomenon is biphasic. After the initial loss of 50%, the process progressed slowly. Twenty-four hours after the injection of the hormone, 35% of the cilia remained; after 60 hours, 4% were still present. This is in striking contrast to the effect of estrogen, which causes almost complete deciliation within 24 hr after the injection of the hormone. Prolonged exposure of the deciliated luminal epithelial cells to progesterone leads to disarrangement of the diplosome relationship. The phenomenon might be causally correlated with the block of estrogen-induced mitoses by this hormone; this view, however, needs further experimental corroboration.     

Cilia-Mediated Oriented Chemokinesis in Tetrahymena thermophila

The role of the cilia in the locomotion (“gliding”) of Tetrahymena thermophila in a semi-solid medium has been studied when cells were migrating in gradients of attractant. Video recordings and computer-aided motion analysis of migrating cells and their ciliary activity show that Tetrahymena thermophila migrate by swimming forward in semi-solid methyl cellulose, using their cilia. Ciliary reversals occur at certain intervals and cause a termination (“stop”) of cellular migration. Cells with reversed cilia resume forward migration when normal ciliary beating resumes. In gradients of attractants, cells migrating towards the attractant suppress ciliary reversals, which leads to longer runs between stops than in control cells. Cells migrating away from the attractant have a higher frequency of ciliary reversals than the control cells resulting in shorter runs. Stimulated cells adapt to a particular ambient concentration of attractant several times during migration in the gradient. Adaptation is followed by de-adaptation, which occurs during the “stop”. In the presence of cycloheximide, a strong inhibitor of chemoattraction, the attractant-induced suppression of ciliary reversal is abolished (cells become desensitized to the attractant). It is concluded that Tetrahymena has a short-term memory during adaptation. This is important for the efficiency of migration towards an attractant.     

Local Degeneration of Cilia and Nuclear Activation during Sexual Reproduction in Paramecium caudatum

The correlation between local degeneration of cilia and nuclear activation during chemically induced autogamy in Paramecium caudatum was studied by experimental interruption of autogamy. When the induction of autogamy was interrupted 60 min after the onset of chemical induction, nuclear activation did not occur and ciliary regeneration took place at the deciliated surface. On the contrary, when it was interrupted 3 hr after the onset of induction, nuclear activation was not stopped and no reciliation was observed. At this critical stage, the deciliated zone was seen to extend to the right wall of the gullet. These findings suggest that there is a transition point in activation processes. It is conceivable that in autogamous cells that have gone beyond this transition point all processes of nuclear activation proceed, and that the ability to regenerate cilia is lost by the end of autogamy, even if the stimulus for autogamy is removed.