Retention of autoregulatory control of tubulin synthesis in cytoplasts: demonstration of a cytoplasmic mechanism that regulates the level of tubulin expression

Virtually all animal cells rapidly and specifically depress synthesis of new alpha- and beta-tubulin polypeptides in response to microtubule inhibitors that increase the pool of depolymerized subunits, or in response to direct elevation of the cellular tubulin subunit content through microinjection of exogenous tubulin subunits. Collectively, these previous findings have documented the presence of an apparent eucaryotic, autoregulatory control mechanism that specifies the level of expression of tubulin in cultured animal cells. Mechanistically, this regulation of tubulin synthesis is achieved through modulation of tubulin mRNA levels. To dissect further the molecular pathway that underlies this autoregulatory phenomenon, we have now investigated whether enucleated cells still retain the requisite regulatory machinery with which to alter tubulin synthetic levels in response to fluctuations in the pool size of unpolymerized tubulin subunits. Using two-dimensional gel electrophoresis to analyze the patterns of new polypeptide synthesis, we have determined that such cytoplasts can indeed respond to drug-induced microtubule depolymerization by specific repression of new beta-tubulin synthesis. Moreover, the response of cytoplasts is, if anything, greater in magnitude than that of whole cells. We conclude that autoregulatory control of beta-tubulin gene expression must derive principally, if not exclusively, from a cytoplasmic control mechanism that modulates beta-tubulin mRNA stability. For alpha-tubulin, although the response of cytoplasts after drug-induced microtubule depolymerization is quantitatively less dramatic than that of whole cells, at least part of the regulatory machinery must also be activated through a cytoplasmic regulatory event.     

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.     

Tubulin binding sites on gamma-tubulin: identification and molecular characterization

gamma-Tubulin is essential to microtubule organization in eukaryotic cells. It is believed that gamma-tubulin interacts with tubulin to accomplish its cellular functions. However, such an interaction has been difficult to demonstrate and to characterize at the molecular level. gamma-Tubulin is a poorly soluble protein, not amenable to biochemical studies in a purified form as yet. Therefore basic questions concerning the existence and properties of tubulin binding sites on gamma-tubulin have been difficult to address. Here we have performed a systematic search for tubulin binding sites on gamma-tubulin using the SPOT peptide technique. We find a specific interaction of tubulin with six distinct domains on gamma-tubulin. These domains are clustered in the central part of the gamma-tubulin primary amino acid sequence. Synthetic peptides corresponding to the tubulin binding domains of gamma-tubulin bind with nanomolar K(d)s to tubulin dimers. These peptides do not interfere measurably with microtubule assembly in vitro and associate with microtubules along the polymer length. On the tertiary structure, the gamma-tubulin peptides cluster to surface regions on both sides of the molecule. Using SPOT analysis, we also find peptides interacting with gamma-tubulin in both the alpha- and beta-tubulin subunits. The tubulin peptides cluster to surface regions on both sides of the alpha- and beta- subunits. These data establish gamma-tubulin as a tubulin ligand with unique tubulin-binding properties and suggests that gamma-tubulin and tubulin dimers associate through lateral interactions.     

Rationalization of paclitaxel insensitivity of yeast ß-tubulin and human ßIII-tubulin isotype using principal component analysis

ABSTRACT: BACKGROUND: The chemotherapeutic agent paclitaxel arrests cell division by binding to the hetero-dimeric protein tubulin. Subtle differences in tubulin sequences, across eukaryotes and among beta-tubulin isotypes, can have profound impact on paclitaxel-tubulin binding. To capture the experimentally observed paclitaxel-resistance of human betaIII tubulin isotype and yeast beta-tubulin, within a common theoretical framework, we have performed structural principal component analyses of beta-tubulin sequences across eukaryotes. RESULTS: The paclitaxel-resistance of human betaIII tubulin isotype and yeast beta-tubulin uniquely mapped on to the lowest two principal components, defining the paclitaxel-binding site residues of beta-tubulin. The molecular mechanisms behind paclitaxel-resistance, mediated through key residues, were identified from structural consequences of characteristic mutations that confer paclitaxel-resistance. Specifically, Ala277 in betaIII isotype was shown to be crucial for paclitaxel-resistance. CONCLUSIONS: The present analysis captures the origin of two apparently unrelated events, paclitaxel-insensitivity of yeast tubulin and human betaIII tubulin isotype, through two common collective sequence vectors.     

Sequences that confer beta-tubulin autoregulation through modulated mRNA stability reside within exon 1 of a beta-tubulin mRNA

Synthesis of alpha- and beta-tubulin is controlled in animal cells by a novel autoregulatory mechanism: the concentration of unpolymerized subunits specifies the level of tubulin mRNAs. Using transient DNA transfection, we have localized the sequences that identify a beta-tubulin RNA as a substrate for autoregulation. Insertion of as few as 106 nucleotides (57 bases of 5' untranslated region and 49 coding nucleotides) from a beta-tubulin gene into a thymidine kinase gene is sufficient to make expression of the resultant chimeric RNA regulated as if it were an authentic beta-tubulin mRNA. Furthermore, all 5' untranslated region sequences can be deleted without disrupting regulation. We conclude that this novel autoregulatory pathway is specified by cytoplasmic events that modulate mRNA stability through sequences lying within the first 16 translated codons of a beta-tubulin mRNA.     

Pig sperm tail tubulin. Its extraction and characterization

Axonemal tubulin extracted from pig sperm tails has been characterized by one- and two-dimensional electrophoresis and by one-dimensional peptide mapping. The electrophoretic mobilities of its subunits after reduction and carboxymethylation were similar to those of the major subunits of pig brain tubulin. Sperm tail tubulin subunits also had roughly the same isoelectric points as pig brain tubulin subunits, except that they appeared to have a relatively larger tailing effect. The proteolytic cleavage pattern of the pig sperm tail beta-tubulin closely resembled those of both the tunicate (Ciona intestinalis) sperm beta-tubulin and pig brain beta-tubulin. The peptide pattern of pig sperm tail alpha-tubulin, however, was more similar to that of tunicate sperm tail alpha-tubulin than to that of pig brain alpha-tubulin. This supports the hypothesis put forward in a previous investigation [1] that functionally similar tubulins from taxonomically distant species can be more related than functionally dissimilar tubulins from the same species.     

Common antigenic determinants of the tubulin binding domains of the microtubule-associated proteins MAP-2 and tau.

The structural-functional aspects of the tubulin binding domain on the microtubule-associated protein MAP-2, and its relationship with the tubulin binding domain on tau, were studied using anti-idiotypic antibodies that react specifically with the epitope(s) on MAPs involved in their interaction with tubulin in addition to other tau and MAP-2 specific antibodies. Previous studies showed that MAP-2 and tau share common binding sites on tubulin defined by the peptide sequences alpha (430-441) and beta (422-434) of tubulin subunits. Furthermore, binding experiments revealed the existence of multiple sites for the interaction of the alpha- and beta-tubulin peptides with MAP-2 and tau. Most recent studies showed that the synthetic tau peptide Val187-Gly204 (VRSKIGSTENLKHQPGGG) from the repetitive sequence on tau defines a tubulin binding site on tau. Our present immunological studies using anti-idiotypic antibodies which interact with the synthetic tau peptide and antibodies against the Val187-Gly204 tau peptide indicate that MAP-2 and tau share common antigenic determinants at the level of their respective tubulin binding domains. These antigenic determinants appear to be present in the 35 kDa tubulin binding fragment of MAP-2 and in 18-20 kDa chymotryptic fragments containing the tubulin binding site(s) on MAP-2. These findings, along with structural information on these proteins, provide strong evidence in favor of the hypothesis that tubulin binding domains on MAP-2 and tau share similar structural features.     

Cotranslational protein integration into the ER membrane is mediated by the binding of nascent chains to translocon proteins

During cotranslational protein integration into the ER membrane, each transmembrane (TM) segment moves laterally through the translocon to reach the lipid bilayer. Photocrosslinking studies reveal that a particular surface of each nascent chain TM alpha helix and signal-anchor sequence always faces Sec61alpha in the translocon. This nonrandom and TM sequence-dependent positioning reveals that each TM segment makes specific contacts with Sec61alpha and is retained at a fixed location within the translocon, observations that are best explained by the binding of each TM sequence to a translocon protein(s). Since TM sequence hydrophobicity does not correlate with its rate of release from the translocon, nascent chain movement through the translocon appears to be mediated primarily by protein-protein interactions rather than hydrophobic nascent chain-phospholipid interactions.     

Cyclostreptin binds covalently to microtubule pores and lumenal taxoid binding sites

Cyclostreptin (1), a natural product from Streptomyces sp. 9885, irreversibly stabilizes cellular microtubules, causes cell cycle arrest, evades drug resistance mediated by P-glycoprotein in a tumor cell line and potently inhibits paclitaxel binding to microtubules, yet it only weakly induces tubulin assembly. In trying to understand this paradox, we observed irreversible binding of synthetic cyclostreptin to tubulin. This results from formation of covalent crosslinks to beta-tubulin in cellular microtubules and microtubules formed from purified tubulin in a 1:1 total stoichiometry distributed between Thr220 (at the outer surface of a pore in the microtubule wall) and Asn228 (at the lumenal paclitaxel site). Unpolymerized tubulin was only labeled at Thr220. Thus, the pore region of beta-tubulin is an undescribed binding site that (i) elucidates the mechanism by which taxoid-site compounds reach the kinetically unfavorable lumenal site and (ii) explains how taxoid-site drugs induce microtubule formation from dimeric and oligomeric tubulin.     

A dual effect on protein synthesis and degradation modulates the tubulin level in rice cells treated with oryzalin

The effect of the anti-microtubular drug oryzalin on growth and morphology of cultured rice (Oryza sativa L., cv. Roncarolo) cells was evaluated with specific reference to mechanisms that control intracellular tubulin levels. The addition of oryzalin caused a great reduction in the level of both alpha- and beta-tubulin polypeptides, as detected by Western blot analysis. However, no appreciable decrease was observed in the population of total or isotype-specific alpha- and beta-tubulin mRNAs. Only within the first 24 h of the oryzalin treatment, when the level of both alpha- and beta-tubulin polypeptides was still undiminished, was a consistent reduction in the amount of total beta-tubulin mRNA observed. Pulse-chase experiments performed on rice cells grown in the presence of 1 microM oryzalin revealed the presence of two distinct mechanisms that negatively control alpha- and beta-tubulin polypeptide levels. (i) There was an immediate effect on protein synthesis, which resulted in a reduction in the level of newly synthesized tubulin. (ii) There was a delayed response characterized by a substantial degradation of both alpha- and beta-tubulin monomers; this degradation occurred after 24 h of herbicide treatment. The possible involvement of Ca2+ in the degradation of the unincorporated tubulin monomers is also documented and discussed.     

The amino terminus of opsin translocates "posttranslationally" as efficiently as cotranslationally

Opsin, a member of the G-protein-coupled receptor family, is a polytopic membrane protein that does not encode a cleaved amino-terminal signal sequence. The amino terminus of opsin precedes the first known targeting information, suggesting that it translocates across the endoplasmic reticulum (ER) membrane after synthesis, uncoupled from translation. However, translocation across the mammalian ER is believed to be coupled to protein synthesis. In this study we show that opsin, within a range of nascent peptide lengths, targets and translocates equally efficiently co- and posttranslationally. Longer nascent opsin peptides have a lower efficiency of cotranslational translocation but an even lower efficiency of posttranslational translocation. We also show that SRP is required for both co- and posttranslational targeting.