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.     

Mechanisms of regulating tubulin synthesis in cultured mammalian cells.

Colchicine and nocadazole both depolymerize microtubules in cultured fibroblasts and lead to a rapid inhibition of tubulin synthesis. The level of translatable tubulin mRNA is greatly reduced in drug-treated cells as demonstrated by translation in a reticulocyte-derived in vitro protein synthesizing system. A model of tubulin synthesis regulation is proposed in which the elevated level of unpolymerized tubulin in drug-treated cells inhibits the formation of new tubulin mRNA and the preexisting message decays rapidly. In agreement with this model, tubulin message is found to be short-lived and has an approximately 2 hr half-life in cells treated with actinomycin D. Another prediction of the proposed model is that destabilization of microtubules without a concomitant increase in free tubulin will not inhibit tubulin synthesis. Vinblastine also disrupts microtubules but leads to the aggregation of tubulin into large paracrystals with an apparent decrease in the concentration of free tubulin. This drug does not inhibit tubulin production but rather leads to a measurable enhancement of tubulin synthesis.     

Autoregulation of tubulin expression is achieved through specific degradation of polysomal tubulin mRNAs

We have utilized protein synthesis inhibitors to investigate the autoregulatory mechanism that uses the concentration of unpolymerized tubulin subunits to specify tubulin mRNA content in animal cells. Puromycin and pactamycin, both of which remove RNAs from polysomes, completely unlink tubulin RNA content from the level of free subunits, whereas pretreatment of cells with cycloheximide, which traps mRNAs onto stalled polyribosomes, enhances the specific degradation of tubulin RNAs in response to increases in the subunit content. Moreover, in the absence of protein synthesis inhibitors, the tubulin RNAs that are lost from cells with elevated free tubulin subunit levels are those that are associated with polyribosomes. Further, beta-tubulin mRNAs encoding a truncated translation product of only 26 amino acids (and that cannot be polyribosomal) are not substrates for autoregulation. We conclude that autoregulation of tubulin synthesis is achieved by specifically altering the stability of tubulin RNAs that are bound to polyribosomes.     

THE REGENERATION OF CILIA IN PARTIALLY DECILIATED TETRAHYMENA

Partial deciliation of Tetrahymena resulted in cells losing 75% of their cilia, with the balance being paralyzed. The paralyzed cilia are resorbed in the first 20 min after partial deciliation, and regeneration of cilia begins before resorption is completed. Inhibition of protein synthesis with cycloheximide does not inhibit ciliary resorption or regeneration, whereas vinblastine sulfate inhibits regeneration but not resorption. Inhibition of regeneration occurs in completely deciliated cells when they are treated with cyclohexmimide or vinblastine sulfate. It is concluded that the resorbing cilia contribute materials which allow regeneration to occur in the absence of protein synthesis. The volume of cilia regenerated in the presence of cycloheximide in partially deciliated cells is greater than the ciliary volume which is resorbed. This suggests the Tetrahymena cells have a pool of ciliary precursors. This pool does not contribute materials for regeneration in completely deciliated cells which are treated with cycloheximide. It is concluded that resorbing cilia in partially deciliated cells contribute materials which potentiate assembly of cilia from the pool of precursors.     

Abundance of Tubulin Mrna On Poly Somes Following Deciliation and During the Synchronous Cell Cycle of Tetrahymena

The protozoan, Tetrahymena pyriformis GL, was used as a model system for studying polysomal mRNA during the cell cycle and during cilia regeneration. Our previous work has shown a substantial induction of tubulin synthesis following deciliation and during G₂ of the synchronous cell cycle. In the present study, the abundance of tubulin mRNA on polysomes was examined in order to determine whether more tubulin mRNA was being translated during the periods of peak tubulin synthesis. Polysomes isolated at sequential times following deciliation and during the synchronous cell cycle were translated in a cell-free translation system derived from wheat germ. the abundance of tubulin mRNA on polysomes was inferred from the amount of tubulin translated in vitro. Following deciliation and prior to the peak period of tubulin synthesis, the abundance of tubulin mRNA (at 140 min post-deciliation) increases to 25 times the initial value observed (at 20 min post-deciliation). Since the increase in tubulin mRNA abundance precedes the peak in tubulin synthesis, induction of tubulin synthesis appears to be mRNA-dependent. A similar analysis of tubulin mRNA abundance on polysomes during the synchronous cell cycle revealed a peak of tubulin mRNA prior to each peak of tubulin synthesis. These studies suggest that the periodic fluctuations in the synthesis of tubulin are dependent upon fluctuating levels of tubulin mRNA on polysomes.     

Sea urchin deciliation induces thermoresistance and activates the p38 mitogen-activated protein kinase pathway

In this study, we demonstrate by a variety of approaches (ie, morphological analysis, Western blots, immunolocalization, and the use of specific antibodies) that hyperosmotic deciliation stress of sea urchin embryos induces a thermotolerant response. Deciliation is also able to activate a phosphorylation signaling cascade the effector of which might be the p38 stress-activated protein kinase because we found that the administration of the p38 inhibitor SB203580 to sea urchin deciliated gastrula embryos makes the hyperosmotic deciliation stress lethal.     

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.     

Microtubule formation from maternal tubulins during sea urchin embryogenesis: measurement of soluble and insoluble tubulin pools

The mass of tubulin protein in developing embryos of the sea urchin Lytechinus pictus was measured using a radiodilution immunoassay based on densitometric analysis of immunoprecipitated tubulins resolved electrophoretically. The tubulins constitute an average of 360 +/- 35 pg per egg, or 0.66% of the total protein, and there is no significant change in their concentration during embryogenesis. The masses of soluble and polymerized tubulin were measured for extracts prepared under conditions that stabilize microtubules. In eggs, a maximum of 14% of the tubulin is insoluble, and this increases throughout embryogenesis to 67% at pluteus stage (72 hr). The concentration of tubulin in eggs is at least 500 micrograms/ml, well above the critical concentration for tubulin assembly in vitro, yet microtubules have not been observed in eggs. The mass of newly synthesized tubulin, estimated from the mass of tubulin mRNA per embryo, accounts for a small fraction of the total tubulin by the end of gastrulation but for over half of the tubulin by the 72-hr pluteus stage. These observations are consistent with a model in which the declining level of unpolymerized tubulin controls the stability of tubulin mRNa, providing an autogenous regulation of the ontogenetic pattern of tubulin synthesis during sea urchin embryogenesis (Gong and Brandhorst, Development 102: 31-43).     

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.     

Microtubule assembly in cultivated Greene melanoma cells is stimulated by dibutyryl adenosine 3'':5''-cyclic monophosphate or cholera toxin

Both dibutyryl cyclic AMP (DBcAMP) and cholera toxin promote the formation and elongation of processes of cultivated Greene hamster melanoma cells. The formation and maintenance of these processes, which contain many microtubules, are sensitive to colcemid and vinblastine. Tubulin was measured by [3H]colchicine binding and by acrylamide gel electrophoresis. We found that DBcAMP or cholera toxin increases the ratio of polymerized to unpolymerized tubulin but not the total amount of tubulin per cell. The sum of the lengths of microtubules per unit area was significantly greater in cells treated with DBcAMP than in control cells. Our findings support the hypothesis that cyclic AMP promotes the elongation of cell processes by stimulating the assembly of microtubules from existing tubulin.     

The abundance of alpha-tubulin mRNA increases during ciliary regeneration in Tetrahymena, and this occurs independently of the soluble tubulin content

Control mechanisms of tubulin synthesis are analyzed during ciliary regeneration of the ciliate Tetrahymena. Titration of the alpha-tubulin mRNA concentrations during the regeneration period reveal that enhancement of tubulin synthesis is preceded and accompanied by increased concentrations of tubulin mRNA molecules. Stimulation of tubulin synthesis is independent of the pool size of soluble tubulin molecules, as suggested by at least two independent lines of evidence: First, like cells of normal phenotype a temperature sensitive size mutant enhances tubulin synthesis as well as tubulin mRNA concentration during ciliary regeneration, although these large mutant cells have a much higher concentration and amount of soluble tubulin molecules in the cytoplasm. Second, slowly regenerating cells of normal phenotype shift-up their concentration of tubulin mRNA molecules already before a time, when ciliary outgrowth might cause a significant depletion of the pool of soluble tubulin molecules. Thus, neither an induction of tubulin synthesis nor an increase in tubulin mRNA molecules is mediated via changes in the pool size of soluble tubulin molecules.     

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.