Tetrahymena Tubulins and In Vitro Translation of Tetrahymena RNA*

SYNOPSIS. Tetrahymena outer doublet tubulin was compared with neurotubulin and Chlamydomonas flagellar tubulin on SDS-polyacrylamide gels. Tetrahymenaα tubulin did not comigrate with either brain or flagellar α tubulins, although brain, flagellar, and ciliary β tubulins all comigrated. Axonemal tubulin from Tetrahymena strain ST was compared with this tubulin from strains W. S. HSM, and E, and all were found to have the same mobilities. Poly-A containing RNA was separated from whole cell Tetrahymena RNA by oligo-dT cellulose chromatography. Poly-A+ RNA from 24-h cultures (early exponential growth) stimulated greater incorporation of amino acids into polypeptides in the wheat germ cell-free translation system than did poly-A+ RNA from 36-h and 49-h cultures. When separated on SDS-polyacrylamide gels, the translation products of the 24-h poly-A + RNA had 2 prominent protein bands which comigrated with α and β tubulin isolated from Tetrahymena cilia. These bands were not found in the translation products of poly-A+ RNA isolated from 49-h cultures or in the translation products ofpoly-A- RNA.     

Translation in vitro of Tetrahymena pyriformis polyadenylated mRNA. Identification of tubulin amongst the translated products and demonstration of its heterogeneity.

The capacity of poly(A)-containing RNA of the protozoan ciliate Tetrahymena pyriformis to direct the synthesis of proteins in vitro has been tested using two cell-free systems: a wheat germ extract and a rabbit reticulocyte lysate. The results obtained with these two systems are compared and the identification of alpha and beta tubulins among the products of protein synthesis in vitro, after separation by one-dimensional and two-dimensional electrophoresis, is described. By isoelectric focusing in polyacrylamide gels, each species of tubulin is resolved into several bands, suggesting that the main subunits are more heterogeneous than has been generally described. Poly(A)-containing RNA has also been fractionated on a 70% formamide/sucrose gradient and it is shown that alpha and beta tubulins are coded by separate mRNAs.     

Cell type-dependent expression of tubulins in Physarum

Three alpha-tubulins and two beta-tubulins have been resolved by two-dimensional gel electrophoresis of whole cell lysates of Physarum myxamoebae or plasmodia. Criteria used to identify the tubulins included migration on two-dimensional gels with myxamoebal tubulins purified by self-assembly into microtubules in vitro, peptide mapping with Staphylococcus V8 protease and with chymotrypsin, immunoprecipitation with a monoclonal antibody specific for beta-tubulin, and, finally, hybrid selection of specific mRNA by cloned tubulin DNA sequences, followed by translation in vitro. Differential expression of the Physarum tubulins was observed. The alpha 1- and beta 1-tubulins were detected in both myxamoebae and plasmodia; alpha 2 and beta 2 were detected only in plasmodia, alpha 3 was detected only in the myxamoebal phase, and may be specific to the flagellate. Observation of more tubulin species in plasmodia than in myxamoebae was remarkable; the only microtubules detected in plasmodia are those of the mitotoic spindle, whereas myxamoebae display cytoplasmic, centriolar, flagellar, and mitotic-spindle microtubules. In vitro translation of myxamoebal and plasmodial RNAs indicated that there are distinct mRNAs, and therefore probably separate genes, for the alpha 1-, alpha 2-, beta 1-, and beta 2-tubulins. Thus, the different patterns of tubulin expression in myxamoebae and plasmodia reflect differential expression of tubulin genes.     

Heterogeneity of the alpha subunit of tubulin and the variability of tubulin within a single organism

When tubulins obtained from particular microtubules of the sea urchin (ciliary doublet A tubules, flagellar doublet microtubules, and mitotic microtubules) are analyzed by electrophoresis in a polyacrylamide gel system containing sodium dodecyl sulfate and urea, heterogeneity of the alpha subunit, and differences between the tubulins are revealed. The alpha subunit of tubulin from mitotic apparatus and from A microtubules of ciliary doublets is resolved into two bands, while the alpha subunit of flagellar doublet tubulin gives a single band. The mitotic and ciliary tubulins differ in the mobilities of their two alpha species, or in the relative amounts present, or both. The existence of differences between the tubulins has been confirmed by a preliminary analysis of their cyanogen bromide peptides.     

Characterization and in vitro polymerization of Tetrahymena tubulin

Tetrahymena tubulin was purified from the cell extract using DEAE-Sephadex A-50 ion-exchanger and ammonium sulfate precipitation. About 2.2% of the total protein in the 20,000 X g supernatant was recovered as DEAE-Sephadex-purified tubulin fraction. Applying the temperature-dependent polymerization-depolymerization method to this fraction in the presence of Tetrahymena outer fibers as a seed, almost pure tubulin was obtained. Tetrahymena tubulin dimer showed different behavior on SDS-polyacrylamide gels from porcine brain tubulin, and showed very low affinity for colchicine, amounting to about one-twentieth of the binding to porcine brain tubulin. The tubulin fraction failed to polymerize into microtubules by itself. Addition of a small amount of the ciliary outer fiber fragment induced polymerization as demonstrated by viscometric measurements, but the reconstituted microtubules were very unstable in the absence of glycerol. Microtubule-depolymerizing agents such as Ca2+ ions, low temperature, or colchicine all inhibited in vitro polymerization. Although Tetrahymena tubulin purified by the polymerization-depolymerization method could copolymerize with porcine brain microtubules, the DEAE-Sephadex-purified tubulin fraction suppressed the initial rate of porcine brain microtubule assembly in vitro. There seemed to be no differences between cytoplasmic tubulin and outer fiber tubulin in colchicine binding activity or SDS-gel electrophoretic behavior, or between the fine structure of both reconstituted microtubules observed by electron microscopy.     

Tubulin heterogeneity in the trypanosome Crithidia fasciculata.

The interphase cell of Crithidia fasciculata has three discrete tubulin populations: the subpellicular microtubules, the axonemal microtubules, and the nonpolymerized cytoplasmic pool protein. These three tubulin populations were independently and selectively purified, yielding, in each case, microtubule protein capable of self-assembly. All three preparations polymerized to form ribbons and sheets rather than the more usual microtubular structures. Analyses of the tubulin by two-dimensional polyacrylamide gel electrophoresis, isoelectric focusing, and peptide mapping indicated that the beta-tubulin complex remained constant regardless of source but that some heterogeneity was present in the alpha subunit. Cytoplasmic pool alpha tubulins (alpha 1/alpha 2) were the only alpha isotypes in the cytoplasm and also formed most of the alpha tubulin species in the pellicular fraction. Flagellar alpha tubulin (alpha 3) was the sole alpha isotype in the flagella; it appeared in small amounts in the pellicular fraction but was completely absent from the cytoplasm. In vitro translation products from polyadenylated RNA from C. fasciculata were also examined by two-dimensional polyacrylamide gel electrophoresis and possessed a protein corresponding to alpha 1/alpha 2 tubulin but lacked any alpha 3 tubulin. The alpha 3 polypeptide arose from a post-translational modification of a precursor polypeptide not identifiable by two-dimensional polyacrylamide gel electrophoresis as alpha 3. Peptide mapping data indicated that cytoplasmic alpha tubulin is the most likely precursor. These results demonstrate alpha-tubulin heterogeneity in this organism and also how close the relationship between flagellar and cytoskeletal tubulins can be among lower eucaryotes.     

Flagellar regeneration of the trypanosome Crithidia fasciculata involves post-translational modification of cytoplasmic alpha tubulin.

Deflagellation of Crithidia fasciculata stimulated formation of new flagella and maximized production of alpha 3 tubulin. Continuous labeling during reflagellation revealed that alpha 1, 2, and 3 tubulins were formed, whereas the polyadenylated RNA translation products lacked alpha 3 isoform. Pulse-chase labeling experiments demonstrated that alpha 3 was a post-translational modification of cytoplasmic alpha tubulin.     

Fractionation of Tetrahymena ciliary membranes with triton X-114 and the identification of a ciliary membrane ATPase

Cilia were isolated from Tetrahymena thermophila, extracted with Triton X-114, and the detergent-soluble membrane + matrix proteins separated into Triton X-114 aqueous and detergent phases. The aqueous phase polypeptides include a high molecular mass polypeptide previously identified as a membrane dynein, detergent-soluble alpha and beta tubulins, and numerous polypeptides distinct from those found in axonemes. Integral membrane proteins partition into the detergent phase and include two major polypeptides of 58 and 50 kD, a 49-kD polypeptide, and 5 polypeptides in relatively minor amounts. The major detergent phase polypeptides are PAS-positive and are phosphorylated in vivo. A membrane-associated ATPase, distinct from the dynein-like protein, partitions into the Triton X-114 detergent phase and contains nearly 20% of the total ciliary ATPase activity. The ATPase requires Mg++ or Ca++ and is not inhibited by ouabain or vanadate. This procedure provides a gentle and rapid technique to separate integral membrane proteins from those that may be peripherally associated with the matrix or membrane.     

A peptide from Tetrahymena disrupts subunit organization of E. coli RNA polymerase.

Incubation of the E. coli RNA polymerase with a polypeptide factor from the protozoan Tetrahymena reduces the affinity of the holoenzyme for DNA. SDS-polyacrylamide gel electrophoresis of the peptide-treated RNA polymerase showed that the band pattern of the polymerase subunits was strongly altered. The three large subunits, beta', beta and sigma, disappear and a high number of rapidly migrating bands appeared. However, a brief heat treatment of the samples almost restored the original RNA polymerase subunit composition, and in addition a high molecular weight protein band approximately 240 kDa appeared. It is suggested that the Tetrahymena peptide specifically binds to the RNA polymerase and changes the structures of the large subunits.     

Programmed appearance of translatable flagellar tubulin mRNA during cell differentiation in Naegleria.

The programmed de novo synthesis of flagellar tubulin during the hour-long differentiation of Naegleria gruberi from amoebae to flagellates is our paradigm for the study of gene expression during cell differentiation. This paper reports the efficient translation of flagellar tubulin mRNA in the wheat germ cell-free system directed by total or polyadenylated RNA extracted from differentiating cells. The tubulin in the in vitro product has a subunit molecular weight of 55,000, separates into alpha and beta subunits under suitable conditions of polyacrylamide gel electrophoreis and co-polymerizes with calf brain tubulin. At least half of the tubulin synthesized in vitro is precipitated by antibodies specific to flagellar tubulin, and the immunoprecipitated tubulin subunits yield peptide maps similar to those of outer doublet tublin. Flagellar tubulin is the predominant protein synthesized in the cell-free system, and amounts to about 5% of the polypeptides whose synthesis is directed by total RNA from differentiating cells. In contrast, little or no flagellar tubulin is synthesized when the cell-free system is directed by RNA extracted from amoebae prior to differentiation. Translation assays show that at least 92% of the flagellar tubulin mRNA appears during differentiation. The time course of appearance of this mRNA was measured by quantitative immunoprecipitation of the cell-free products. Under conditions where cells from flagella 60 min after initiation of differentiation, translatable flagellar tubulin mRNA was first detected at 20 min, reached a maximum at about 60 min and then declined. An excellent correlation was observed between the amount of translatable flagellar tubulin mRNA and the previously measured rates of flagellar tubulin synthesis in vivo. These results indicate that synthesis of flagellar tubulin is a direct reflection of the abundance of its mRNA, and provide the molecular techniques for dissection of the factors that regulate the rapid appearance of this structural protein during differentiation.     

Increased levels of mRNAs for tubulin and other flagellar proteins after amputation or shortening of Chlamydomonas Flagella

A dramatic stimulation of synthesis of flagellar proteins occurs in Chlamydomonas following flagellar removal or experimentally induced resorption of the flagella into the cell. In this report we show that this stimulation involves an increase in the levels of mRNAs for tubulin and many other flagellar proteins. Total RNA and poly(A) RNA were isolated from cells after deflagellation or flagellar resorption, and were then translated in the reticulocyte lysate system. Two-dimensional gel analysis of the translation products demonstrates that the RNA-directed in vitro synthesis of α and β tubulins, and a number of other flagellar proteins, increases after deflagellation or flagellar resorption. Surprisingly, the α-tubulin synthesized in vitro does not co-migrate on two-dimensional gels with mature flagellar α-tubulin. Moreover, in vivo labeling experiments show that the major α-tubulin synthesized in the cell after deflagellation co-migrates with the major α-tubulin made in vitro, not with the major α-tubulin present in the flagella. These results suggest that flagellar α-tubulin is synthesized as a precursor, and undergoes post-translational modification before assembly into the flagella. In addition, we report that the synthesis of tubulin and other flagellar proteins can be specifically inhibited, as well as stimulated. Treatment of cells with IBMX, which induces flagellar resorption, causes a marked decrease in the levels of translatable mRNAs for tubulin and other flagellar proteins, without affecting levels of mRNAs for nonflagellar proteins.     

Plasma membrane isolated from Giardia lamblia: identification of membrane proteins

Two methods are introduced for preparing plasma membranes from Giardia lamblia trophozoites. Isolated membranes were purified by centrifugation on either a sucrose step-gradient or a self-generated Percoll gradient, where they band at a density of approximately 1.04 g ml-1. In pure fractions, membranes formed vesicles or extensive sheets. Electron microscope profiles show that they are asymmetric with a thin filamentous coat on one side. Membrane proteins were resolved by SDS/PAGE. They included a major component of apparent Mr 75,000 (75 kDa), and additional bands detectable by gel staining at 58 kDa, 54 kDa, 32 to 38 kDa (5 bands), 22 kDa, and 15 to 20 kDa. To probe the surface location of proteins, gels were also prepared from Giardia cells that were surface radio-iodinated using the immobilised catalyst IODOGEN. The 75 kDa membrane protein was strongly labelled in the corresponding autoradiograph, also the bands at 58 kDa and 54 kDa, the 22 kDa polypeptide, and some faint bands not resolved in the isolated membrane preparations. The set of close-running bands at 32 to 38 kDa were not iodinated. The labelled 58 kDa and 54 kDa proteins comigrated with alpha and beta-tubulins. Controls showed that cytoskeleton and flagellar tubulins were not iodinated in this experiment, indicating that the labelled tubulin is surface-derived. The principal approximately 75 kDa surface protein identified in isolated membranes probably corresponds to an iodinatable and antibody-precipitated "82 kDa" antigen reported previously.     

Partial purification of the alpha-tubulin and beta-tubulin messenger RNAs from rat brain

Poly(A)-containing RNA from frozen adult rat brain were fractionated by centrifugation in a formamide/sucrose gradient. Individual fractions were used to program protein synthesis in vitro in a reticulocyte lysate. The cell-free translation products were analyzed by two-dimensional electrophoresis in polyacrylamide slab gels. We observed a heterodispersion of the mRNA translation activity coding for the beta-tubulin subunit which contrasts with a relatively homogeneous distribution of the alpha-tubulin subunit mRNA. These last mRNA species are present in a peak which sediments near the 18-S region of the gradient whereas the beta-tubulin mRNA activity is predominant in the fractions corresponding to the heaviest mRNA species. When these heaviest RNAs were separated again by centrifugation in a second formamide/sucrose gradient, a poly(A)-rich RNA population was obtained that was enriched in RNA for programming the beta-tubulin subunit. Analysis of the products whose synthesis in vitro was directed by this mRNA population revealed that beta tubulin was the main protein formed, the ratio beta/alpha being more than tenfold greater than in the products translated in vitro using total poly(A)-rich RNA.     

Equimolar heterodimers in microtubules

Two equimolar beta chains can be resolved from sea urchin sperm flagellar and scallop gill ciliary tubulins, and from certain brain tubulins as well, using the Triton X-100-acid-urea polyacrylamide gel system commonly used for histone analysis. The beta chains are identified as such from their mobility on urea-free SDS PAGE, from amino acid composition, and from tryptic peptide distribution. Scallop beta chains have almost identical amino acid profiles but they differ by one tryptic peptide. Optimal conditions for beta chain resolution are very species-dependent, with some closely related species showing either maximal or no beta chain separation. In addition, beef brain tubulin on Triton X-100-acid-urea electrophoresis and scallop gill ciliary tubulin upon isoelectric focusing in the presence of SDS show two approximately equimolar alpha chains. These data, indicating equimolar amounts of two potentially different tubulin heterodimers from a variety of microtubule types, support a model for microtubule structure wherein protofilaments consist of alternating heterodimers of two kinds, generating a 16-nm (2-dimer) axial repeat.     

Induction of microtubule protein synthesis in Chlamydomonas reinhardi during flagellar regeneration

Flagellar regeneration in gametes of Chlamydomonas reinhardi is initiated within 15–20 min after flagellar amputation and proceeds at a rapid but decelerating rate until by 90 min flagellar outgrowth is 80–85% complete. Sufficient flagellar protein reserves exist in the cytoplasm to allow regeneration of flagella $\text{1}\text{3}\text{–}\text{1}\text{2}$ normal length. Nevertheless, in vivo labeling with ¹⁴C-amino acids shows that microtubule protein and other flagellar proteins are synthesized de novo during flagellar regeneration. To determine whether tubulin is synthesized continuously by gametic cells or whether its synthesis is induced as a consequence of deflagellation, we have isolated polyribosomes from deflagellated and control cells, and analyzed the proteins produced by these polyribosomes during in vitro translation. Two proteins of 53,000 and 56,000 molecular weight which co-migrate with flagellar and chick brain tubulin on SDS-polyacrylamide gels and which selectively co-assemble with chick brain tubulin during in vitro microtubule assembly are synthesized by polyribosomes (or polyadenylated mRNA) from deflagellated cells. No microtubule proteins can be detected in the translation products synthesized by polyribosomes (or mRNA) from control cells, clearly indicating that deflagellation results in the induction of tubulin synthesis.Kinetics of tubulin synthesis demonstrate that induction takes place immediately after deflagellation; polyribosomes bearing tubulin mRNA can be detected in the cytoplasm in as little as 15 min after removal of flagella. Maximal rates of tubulin synthesis occur between 45 and 90 min after deflagellation when approximately 14% of the protein being synthesized by the cell is tubulin. This estimate of tubulin synthesis based on in vitro translation data agrees well with in vivo measurements of flagellar tubulin synthesis. While high levels of tubulin production extend well beyond the period of rapid flagellar assembly, synthesis begins to decline after 90 min, and by 180 min after deflagellation only low levels of tubulin mRNA are detectable in polyribosomes.     

Cold-stable microtubules from Antarctic fishes contain unique alpha tubulins

The cytoplasmic microtubules of Antarctic fishes assemble from their tubulin subunits at physiological body temperatures in the range -2 to +2 degrees C. Our objective is to determine the structural features that enhance the assembly of Antarctic fish tubulins at low temperatures. Here we compare the structures of tubulin subunits from three Antarctic fishes (Notothenia gibberifrons, Notothenia coriiceps neglecta, and Chaenocephalus aceratus), from three temperate fishes (the dogfish shark Mustelus canis, the channel catfish Ictalurus punctatus, and the goosefish Lophius americanus), and from a mammal (the cow Bos taurus). When reduced, carboxymethylated, and examined by polyacrylamide gel electrophoresis, multiple alpha chains were observed in tubulins from the Antarctic fishes, the catfish, and the goosefish; dogfish and bovine alpha tubulins migrated as single components on this gel system. Prominent in the Antarctic fish tubulins was an alpha variant that migrated more rapidly than the bovine alpha chain; smaller amounts of a rapidly migrating alpha chain were also present in catfish and goosefish tubulins. The beta tubulins of the fishes, with the exception of the goosefish, resolved into major and minor variants with mobilities similar to those of beta 1 and beta 2 tubulins from bovine brain. Peptide mapping demonstrated that the alpha tubulins of Antarctic fishes were similar in structure, yet differed from the alpha chains of the dogfish and the cow (which, in turn, were similar to each other). In contrast, the beta tubulins from these organisms gave peptide patterns of near identity. Finally, the alpha chains of native tubulins from N. coriiceps neglecta and the cow differed in the sensitivity of their C-terminal domains to digestion by subtilisin. These results demonstrate that the alpha tubulins of Antarctic fishes (but not their beta chains) differ structurally from those of temperate fishes and a mammal.     

Subpellicular and flagellar microtubules of Trypanosoma brucei brucei contain the same alpha-tubulin isoforms

The cytoskeleton of the parasitic hemoflagellate Trypanosoma brucei brucei essentially consists of two microtubule-based structures: a subpellicular layer of singlet microtubules, which are in close contact with the cell membrane, and the flagellar axoneme. In addition, the cells contain a small pool of soluble tubulin. Two-dimensional gel electrophoretic analysis of the tubulins present in these subcellular compartments revealed two distinct electrophoretic isoforms of alpha-tubulin, termed alpha 1 and alpha 3. alpha 1-Tubulin most likely represents the primary translation product, while alpha 3-tubulin is a posttranslationally acetylated derivative of alpha 1-tubulin. In the pool of soluble cytoplasmic tubulin, alpha 1 is the predominant species, while the very stable flagellar microtubules contain almost exclusively the alpha 3-tubulin isoform. The subpellicular microtubules contain both isoforms. Neither of the two alpha-tubulin isoforms is organelle specific, but the alpha 3 isoform is predominantly located in stable microtubules.