Identification and characterisation of novel tubulin-binding motifs located within the C-terminus of TRPV1

Previously, we reported that TRPV1, the vanilloid receptor, interacts with soluble alphabeta-tubulin dimers as well as microtubules via its C-terminal cytoplasmic domain. The interacting region of TRPV1, however, has not been defined. We found that the TRPV1 C-terminus preferably interacts with beta-tubulin and less with alpha-tubulin. Using a systematic deletion approach and biotinylated-peptides we identified two tubulin-binding sites present in TRPV1. These two sequence stretches are highly conserved in all known mammalian TRPV1 orthologues and partially conserved in some of the TRPV1 homologues. As these sequence stretches are not similar to any known tubulin-binding sequences, we conclude that TRPV1 interacts with tubulin and microtubule through two novel tubulin-binding motifs.     

Native tubulin-folding cofactor E purified from baculovirus-infected Sf9 cells dissociates tubulin dimers

Tubulin-folding cofactor E (TBCE) is an alpha-tubulin-binding protein involved in the formation of the tubulin dimer and in microtubule dynamics, through the regulation of tubulin heterodimer dissociation. TBCE has also been implicated in two important related human disorders, the Kenny-Caffey and Sanjad-Sakati syndromes. The expression of TBCE as a recombinant protein in bacteria results in the formation of insoluble inclusion bodies in the absence of denaturing agents. Although the active protein can be obtained from mammalian tissues, biochemical studies of TBCE present a special challenge. To express and purify native TBCE, a recombinant baculovirus expression system was used. Native wild-type TBCE purified from Sf9 extracts was sequentially purified chromatographically through cation exchange, hydrophobic interaction, and high-resolution gel-filtration columns. Mass spectrometric analysis identified 30% of the sequence of human TBCE. A stoichiometric excess of purified TBCE dissociated tubulin heterodimers. This reaction produced a highly unstable TBCE-alpha-tubulin complex, which formed aggregates. To distinguish between the aggregation of tubulin dimers induced by TBCE and tubulin dissociation, TBCE and tubulin were incubated with tubulin-folding cofactor A (TBCA). This cofactor captures the beta-tubulin released from the heterodimer with a stoichiometry of 1:1, as previously demonstrated. The beta-tubulin polypeptide was recovered as TBCA-beta-tubulin complexes, as demonstrated by non-denaturing gel electrophoresis and specific antibodies directed against beta-tubulin and TBCA.     

Structural mechanisms underlying nucleotide-dependent self-assembly of tubulin and its relatives

The alphabeta-tubulin dimer assembles into microtubules, essential polymers in all eukaryotic cells. Microtubules are highly dynamic, a property that derives from tubulin's GTPase activity. Both the bacterial homolog, FtsZ, and the recently discovered bacterial tubulins from Prosthecobacter self-assemble in a nucleotide-dependent manner into protofilaments similar to those that form the microtubule wall. A number of structural studies of alphabeta-tubulin, gamma-tubulin (the isoform involved in microtubule nucleation), FtsZ and bacterial tubulin, in a variety of nucleotide and polymerization states, have been reported in the past few years. These studies have revealed the similarities and differences between these structures and their possible functional implications. In particular, a two-state mechanism has been proposed for the recycling of alphabeta-tubulin during the microtubule disassembly-assembly cycle; this mechanism may be unique to eukaryotic dimeric tubulin and the microtubule structure.     

The C terminus of tubulin, a versatile partner for cationic molecules: binding of Tau, polyamines, and calcium

The C-terminal region of tubulin is involved in multiple aspects of the regulation of microtubule assembly. To elucidate the molecular mechanisms of this regulation, we study here, using different approaches, the interaction of Tau, spermine, and calcium, three representative partners of the tubulin C-terminal region, with a peptide composed of the last 42 residues of α1a-tubulin. The results show that their binding involves overlapping amino acid stretches in the C-terminal tubulin region: amino acid residues 421-441 for Tau, 430-432 and 444-451 for spermine, and 421-443 for calcium. Isothermal titration calorimetry, NMR, and cosedimentation experiments show that Tau and spermine have similar micromolar binding affinities, whereas their binding stoichiometry differs (C-terminal tubulin peptide/spermine stoichiometry 1:2, and C-terminal tubulin peptide/Tau stoichiometry 8:1). Interestingly, calcium, known as a negative regulator of microtubule assembly, can compete with the binding of Tau and spermine with the C-terminal domain of tubulin and with the positive effect of these two partners on microtubule assembly in vitro. This observation opens up the possibility that calcium may participate in the regulation of microtubule assembly in vivo through direct (still unknown) or indirect mechanism (displacement of microtubule partners). The functional importance of this part of tubulin was also underlined by the observation that an α-tubulin mutant deleted from the last 23 amino acid residues does not incorporate properly into the microtubule network of HeLa cells. Together, these results provide a structural basis for a better understanding of the complex interactions and putative competition of tubulin cationic partners with the C-terminal region of tubulin.     

Direct interaction of Bcl-2 proteins with tubulin

A direct interaction between tubulin and several pro-apoptotic and anti-apoptotic members of the Bcl-2 family has been demonstrated by effects on the assembly of microtubules from pure rat brain tubulin. Bcl-2, Bid, and Bad inhibit assembly sub-stoichiometrically, whereas peptides from Bak and Bax promote tubulin polymerization at near stoichiometric concentrations. These opposite effects on microtubule assembly are mutually antagonistic. The BH3 homology domains, common to all members of the family, are involved in the interaction with tubulin but do not themselves affect polymerization. Pelleting experiments with paclitaxel-stabilized microtubules show that Bak is associated with the microtubule pellet, whereas Bid remains primarily with the unpolymerized fraction. These interactions require the presence of the anionic C-termini of alpha- and beta-tubulin as they do not occur with tubulin S in which the C-termini have been removed. While in no way ruling out other pathways, such direct associations are the simplest potential regulatory mechanism for apoptosis resulting from disturbances in microtubule or tubulin function.     

Review: postchaperonin tubulin folding cofactors and their role in microtubule dynamics

The microtubule cytoskeleton consists of a highly organized network of microtubule polymers bound to their accessory proteins: microtubule-associated proteins, molecular motors, and microtubule-organizing proteins. The microtubule subunits are heterodimers composed of one alpha-tubulin polypeptide and one beta-tubulin polypeptide that should undergo a complex folding processing before they achieve a quaternary structure that will allow their incorporation into the polymer. Due to the extremely high protein concentration that exists at the cell cytoplasm, there are alpha- and beta-tubulin interacting proteins that prevent the unwanted interaction of these polypeptides with the surrounding protein pool during folding, thus allowing microtubule dynamics. Several years ago, the development of a nondenaturing electrophoretic technique made it possible to identify different tubulin intermediate complexes during tubulin biogenesis in vitro. By these means, the cytosolic chaperonin containing TCP-1 (CCT or TriC) and prefoldin have been demonstrated to intervene through tubulin and actin folding. Various other cofactors also identified along the alpha- and beta-tubulin postchaperonin folding route are now known to have additional roles in tubulin biogenesis such as participating in the synthesis, transport, and storage of alpha- and beta-tubulin. The future characterization of the tubulin-binding sites to these proteins, and perhaps other still unknown proteins, will help in the development of chemicals that could interfere with tubulin folding and thus modulating microtubule dynamics. In this paper, current knowledge of the above postchaperonin folding cofactors, which are in fact chaperones involved in tubulin heterodimer quaternary structure achievement, will be reviewed.     

Gamma-tubulin: the microtubule organizer?

Microtubules are composed predominantly of two related proteins: alpha- and beta-tubulin. These proteins form the tubulin heterodimer, which is the basic building block of microtubules. Surprisingly, recent molecular genetic studies have revealed the existence of gamma-tubulin, a new member of the tubulin family. Like alpha- and beta-tubulin, gamma-tubulin is essential for microtubule function but, unlike alpha- and beta-tubulin, it is not a component of microtubules. Rather, it is located at microtubule-organizing centres and may function in the nucleation of microtubule assembly and establishment of microtubule polarity.     

N-terminal stathmin-like peptides bind tubulin and impede microtubule assembly

Microtubules are major cytoskeletal components involved in numerous cellular functions such as mitosis, cell motility, or intracellular traffic. These cylindrical polymers of alphabeta-tubulin assemble in a closely regulated dynamic manner. We have shown that the stathmin family proteins sequester tubulin in a nonpolymerizable ternary complex, through their stathmin-like domains (SLD) and thus contribute to the regulation of microtubule dynamics. We demonstrate here that short peptides derived from the N-terminal part of SLDs impede tubulin polymerization with various efficiencies and that phosphorylation of the most potent of these peptides reduces its efficiency as in full-length stathmin. To understand the mechanism of action of these peptides, we undertook a NMR-based structural analysis of the peptide-tubulin interaction with the most efficient peptide (I19L). Our results show that, while disordered when free in solution, I19L folds into a beta-hairpin upon binding to tubulin. We further identified, by means of saturation transfer difference NMR, hydrophobic residues located on the beta2-strand of I19L that are involved in its tubulin binding. These structural data were used together with tubulin atomic coordinates from the tubulin/RB3-SLD crystal structure to model the I19L/tubulin interaction. The model agrees with I19L acting through an autonomous tubulin capping capability to impede tubulin polymerization and provides information to help understand the variation of efficiency against tubulin polymerization among the peptides tested. Altogether these results enlighten the mechanism of tubulin sequestration by SLDs, while they pave the way for the development of protein-based compounds aimed at interfering with tubulin polymerization.     

Tubulin subunit sorting: Analysis of the mechanisms involved in the segregation of unique tubulin isotypes within microtubule copolymers

Summary Vertebrate cells contain biochemical and genetic isotypes of tubulin which are expressed in unique combinations in different tissues and cell types. To determine if mixtures of tubulin isotypes assemblein vitro to form different classes of microtubules, we analyzed the composition of microtubule copolymers assembled from mixtures of chicken brain and erythrocyte tubulin. During microtubule elongation brain tubulin assembled onto the ends of microtubules faster than erythrocyte tubulin, resulting in copolymers with continually changing ratios of isotypes along their lengths. Unlike examples of microtubule assembly where the rate of polymerization depends on the association rate constant (k⁺) and the subunit concentration, the rate and extent of sorting in copolymers appear to depend on the dissociation rate constant (k^–), which governs the rate at which subunits are released from tubulin oligomers and microtubules and thereby made available for reassembly into copolymers. The type of microtubule seed used to initiate elongation was also found to influence the composition of copolymers, indicating that polymerization favors association of subunits of the same isotype.     

New insights into microtubule structure and function from the atomic model of tubulin

The structure of tubulin has recently been solved by electron crystallography of zinc-induced tubulin sheets. Because tubulin was studied in a polymerized state, the model contains information on the interactions between monomers that give rise to the αβ dimer as well as contacts between adjacent dimers that result in the structure of the protofilament. The model includes the binding site of taxol, an anti-cancer agent that acts by stabilizing microtubules. The present tubulin model gives the first structural framework for understanding microtubule polymerization and its regulation by nucleotides and anti-mitotic drugs at the molecular level. Received: 15 December 1997 / Revised version: 25 January 1998 / Accepted: 2 February 1998     

Identification of Ncd tail domain-binding sites on the tubulin dimer

The Drosophila non-claret disjunctional (Ncd) kinesin-like protein is required for spindle assembly in oocytes and spindle maintenance in early embryos. Through the action of ATP-dependent microtubule (MT)-binding sites in the head and ATP-independent MT-binding sites in the tail, Ncd may bundle and, perhaps, slide MTs relative to each other. Our previous work on the MT-binding site of the Ncd tail domain demonstrated that this site, like the MT-binding sites of tau, contains basic residues flanked by proline residues and can promote MT assembly and stability. Here, we characterize the interactions of a monomeric Ncd tail protein with subtilisin-digested MTs in order to identify sites on the tubulin dimer that interact with the Ncd tail. The results provide evidence for four such binding sites per tubulin dimer and support the hypothesis that each binding site consists of a cluster of acidic residues in the C-terminal regions of alpha- and beta-tubulin.     

Structural rearrangements in tubulin following microtubule formation

Microtubules are essential cytoskeletal structures that mediate several dynamic processes in a cell. To shed light on the structural processes relating to microtubule formation and dynamic instability, we investigated microtubules composed of 15 protofilaments using cryo-electron microscopy, helical image reconstruction and computational modelling. Analysis of the configuration of the alpha beta-tubulin heterodimer shows distinct structural differences in both subunits, and illustrates that the tubulin subunits have different roles in the microtubule lattice. Our modelling data suggest that after GTP hydrolysis microtubules, adopt a conformational state somewhere between a straight protofilament conformation--as found in zinc-induced tubulin sheets--and an outward curved conformation--as found in tubulin-stathmin complexes. The tendency towards a curved conformation seems to be mediated mostly by beta-tubulin, whereas alpha-tubulin resembles a state more related to the straight structure. Our data suggest a possible explanation of dynamic instability of microtubules, and for nucleotide-sensitive microtubule-binding properties of microtubule-associated proteins and molecular motors.     

RGS2 promotes formation of neurites by stimulating microtubule polymerization

Regulator of G-protein signaling (RGS) proteins interact with subunits of heterotrimeric G-proteins via the RGS domain and attenuate their activity by accelerating GTPase activity. RGS2, a member of the RGS family, regulates synaptic development via hereto unknown mechanism. In this study, we found that RGS2 directly interacted with tubulin via a short region at the N-terminus: amino acids 41–60. RGS2 enhanced microtubule polymerization in vitro, and the tubulin binding region was necessary and sufficient for this activity. In Vero cells, polymerization of microtubule was stimulated when peptides containing the tubulin binding region were microinjected. Immunocytochemical analysis showed that endogenous RGS2 was localized at the termini of neurites in differentiated PC12 cells. Over-expression of RGS2 enhanced the nerve growth factor-induced neurite outgrowth in PC12 cells, while specific knock-down of endogenous RGS2 suppressed the neurite outgrowth. These findings demonstrate that RGS2 contributes to the neuronal cell differentiation via regulation of microtubule dynamics.     

Measuring nanometer scale gradients in spindle microtubule dynamics using model convolution microscopy

A computational model for the budding yeast mitotic spindle predicts a spatial gradient in tubulin turnover that is produced by kinetochore-attached microtubule (kMT) plus-end polymerization and depolymerization dynamics. However, kMTs in yeast are often much shorter than the resolution limit of the light microscope, making visualization of this gradient difficult. To overcome this limitation, we combined digital imaging of fluorescence redistribution after photobleaching (FRAP) with model convolution methods to compare computer simulations at nanometer scale resolution to microscopic data. We measured a gradient in microtubule dynamics in yeast spindles at approximately 65-nm spatial intervals. Tubulin turnover is greatest near kinetochores and lowest near the spindle poles. A beta-tubulin mutant with decreased plus-end dynamics preserves the spatial gradient in tubulin turnover at a slower time scale, increases average kinetochore microtubule length approximately 14%, and decreases tension at kinetochores. The beta-tubulin mutant cells have an increased frequency of chromosome loss, suggesting that the accuracy of chromosome segregation is linked to robust kMT plus-end dynamics.     

Collapsin response mediator protein-2 regulates neurite formation by modulating tubulin GTPase activity

Collapsin response mediator protein-2 (CRMP-2) plays a key role in axonal development by regulating microtubule dynamics. However, the molecular mechanisms underlying this function have not been clearly elucidated. In this study, we demonstrated that hCRMP-2, specifically amino acid residues 480–509, is essential for stimulating tubulin GTPase activity. We also found that the GTPase-activating protein (GAP) activity of hCRMP-2 was important for microtubule assembly and neurite formation in differentiated PC12 pheochromocytoma cell lines. Mutant hCRMP-2, lacking arginine residues responsible for GAP activity, inhibited microtubule assembly and neurite formation. Interestingly, we found that the N-terminal region (amino acids150–299) of hCRMP-2 had an inhibitory role on GAP activity via a direct interaction with the C-terminal region (amino acids 480–509). Our results suggest that CRMP-2 as a tubulin direct binder may be a GAP of tubulin in neurite formation and that its GAP activity may be regulated by an intramolecular interaction with an N-terminal inhibitory region.     

A novel step in beta-tubulin folding is important for heterodimer formation in Saccharomyces cerevisiae

Undimerized beta-tubulin is toxic in the yeast S. cerevisiae. It can arise if levels of beta-tubulin and alpha-tubulin are unbalanced or if the tubulin heterodimer dissociates. We are using the toxicity of beta-tubulin to understand early steps in microtubule morphogenesis. We find that deletion of PLP1 suppresses toxic beta-tubulin formed by disparate levels of alpha- and beta-tubulin. That suppression occurs either when alpha-tubulin is modestly underexpressed relative to beta-tubulin or when beta-tubulin is inducibly and strongly overexpressed. Plp1p does not affect tubulin expression. Instead, a significant proportion of the undimerized beta-tubulin in plp1Delta cells is less toxic than that in wild-type cells. It is also less able to combine with alpha-tubulin to form a heterodimer. As a result, plp1Delta cells have lower levels of heterodimer. Importantly, plp1Delta cells that also lack Pac10, a component of the GimC/PFD complex, are even less affected by free beta-tubulin. Our results suggest that Plp1p defines a novel early step in beta-tubulin folding.     

Translation of beta-tubulin mRNA in vitro generates multiple molecular forms

We describe the in vitro expression and characterization of the isolated beta-tubulin subunit in rabbit reticulocyte lysates and compare its assembly and chromatographic properties with that of the isolated alpha-subunit and the tubulin heterodimer. The beta-tubulin polypeptides, derived from a single chicken beta-tubulin cDNA, were found in three distinct molecular forms: a multimeric or lysate-associated form, beta I (Mr approximately 180,000); the free beta-subunit beta II (Mr approximately 55,000); and the hybrid heterodimer alpha(rabbit) beta(chick), beta III (Mr approximately 80,000-100,000). The hybrid heterodimers were 100% assembly competent, whereas beta-tubulin in the "associated" beta I and the monomeric beta II forms displayed only approximately 70 +/- 15 and 25 +/- 10% competence, respectively, in coassembly assays with bovine brain tubulin. This reduced functionality was not a consequence of diminished beta-subunit stability or protein denaturation. By comparing the elution positions of the three beta forms, the monomeric alpha-subunit, and tubulin dimer purified from bovine brain, we demonstrate that anion-exchange columns (Mono-Q) interact preferentially with the alpha-subunit and chromatograph tubulin dimer on the basis of alpha-subunit isotype. The rate of exchange of the free beta-subunit into bovine tubulin dimer was followed chromatographically. The exchange was slow at 4 degrees C and rapid at 37 degrees C where it is essentially complete in 40 min in the presence of 2.5 mg/ml bovine microtubule protein. Exogenous GTP, a potent effector of microtubule assembly, binds exchangeably to beta II and enhances the recovery of this form from the Mono-Q column, suggesting that GTP binding may occur at identical sites in the isolated beta-subunit and in the tubulin heterodimer.     

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.