γ-Tubulin complexes in microtubule nucleation and beyond

Tremendous progress has been made in understanding the functions of γ-tubulin and, in particular, its role in microtubule nucleation since the publication of its discovery in 1989. The structure of γ-tubulin has been determined, and the components of γ-tubulin complexes have been identified. Significant progress in understanding the structure of the γ-tubulin ring complex and its components has led to a persuasive model for how these complexes nucleate microtubule assembly. At the same time, data have accumulated that γ-tubulin has important but less well understood functions that are not simply a consequence of its function in microtubule nucleation. These include roles in the regulation of plus-end microtubule dynamics, gene regulation, and mitotic and cell cycle regulation. Finally, evidence is emerging that γ-tubulin mutations or alterations of γ-tubulin expression play an important role in certain types of cancer and in other diseases.     

Mice Lacking α-Tubulin Acetyltransferase 1 Are Viable but Display α-Tubulin Acetylation Deficiency and Dentate Gyrus Distortion

α-Tubulin acetylation at Lys-40, located on the luminal side of microtubules, has been widely studied and used as a marker for stable microtubules in the cilia and other subcellular structures, but the functional consequences remain perplexing. Recent studies have shown that Mec-17 and its paralog are responsible for α-tubulin acetylation in Caenorhabditis elegans. There is one such protein known as Atat1 (α-tubulin acetyltransferase 1) per higher organism. Zebrafish Atat1 appears to govern embryo development, raising the intriguing possibility that Atat1 is also critical for development in mammals. In addition to Atat1, three other mammalian acetyltransferases, ARD1-NAT1, ELP3, and GCN5, have been shown to acetylate α-tubulin in vitro, so an important question is how these four enzymes contribute to the acetylation in vivo. We demonstrate here that Atat1 is a major α-tubulin acetyltransferase in mice. It is widely expressed in mouse embryos and tissues. Although Atat1-null animals display no overt phenotypes, α-tubulin acetylation is lost in sperm flagella and the dentate gyrus is slightly deformed. Furthermore, human ATAT1 colocalizes on bundled microtubules with doublecortin. These results thus suggest that mouse Atat1 may regulate advanced functions such as learning and memory, thereby shedding novel light on the physiological roles of α-tubulin acetylation in mammals.     

Centaurin-α2 Interacts with β-Tubulin and Stabilizes Microtubules

Centaurin-α₂ is a GTPase-activating protein for ARF (ARFGAP) showing a diffuse cytoplasmic localization capable to translocate to membrane, where it binds phosphatidylinositols. Taking into account that Centaurin-α₂ can localize in cytoplasm and that its cytoplasmatic function is not well defined, we searched for further interactors by yeast two-hybrid assay to investigate its biological function. We identified a further Centaurin-α₂ interacting protein, β-Tubulin, by yeast two-hybrid assay. The interaction, involving the C-terminal region of β-Tubulin, has been confirmed by coimmunoprecipitation experiments. After Centaurin-α₂ overexpression in HeLa cells and extraction of soluble (αβ dimers) and insoluble (microtubules) fractions of Tubulin, we observed that Centaurin-α₂ mainly interacts with the polymerized Tubulin fraction, besides colocalizing with microtubules (MTs) in cytoplasm accordingly. Even following the depolimerizing Tubulin treatments Centaurin-α₂ remains mainly associated to nocodazole- and cold-resistant MTs. We found an increase of MT stability in transfected HeLa cells, evaluating as marker of stability the level of MT acetylation. In vitro assays using purified Centaurin-α₂ and tubulin confirmed that Centaurin-α₂ promotes tubulin assembly and increases microtubule stability. The biological effect of Centaurin-α₂ overexpression, assessed through the detection of an increased number of mitotic HeLa cells with bipolar spindles and with the correct number of centrosomes in both dividing and not dividing cells, is consistent with the Centaurin-α₂ role on MT stabilization. Centaurin-α₂ interacts with β-Tubulin and it mainly associates to MTs, resistant to destabilizing agents, in vitro and in cell. We propose Centaurin-α₂ as a new microtubule-associated protein (MAP) increasing MT stability.     

γ-Tubulin and microtubule organization during microsporogenesis in Ginkgo biloba

This is the first report on -tubulin and microtubule arrays during microsporogenesis in a gymnosperm. Meiosis in Ginkgo biloba is polyplastidic, as is typical of the spermatophyte clade, and microtubule arrays are organized at various sites during meiosis and cytokinesis. In early prophase, a cluster of -tubulin globules occurs in the central cytoplasm adjacent to the off-center nucleus. These globules diminish in size and spread over the surface of the nucleus. A system of microtubules focused on the -tubulin forms a reticulate pattern in the cytoplasm. As the nucleus migrates to the center of the microsporocyte, -tubulin becomes concentrated at several sites adjacent to the nuclear envelope. Microtubules organized at these foci of -tubulin give rise to a multipolar prophase spindle. By metaphase I, the spindle has matured into a distinctly bipolar structure with pointed poles. In both first and second meiosis, -tubulin becomes distributed throughout the metaphase spindles, but becomes distinctly polar again in anaphase. In telophase I, -tubulin moves from polar regions to the proximal surface of chromosome groups/nuclei where interzonal microtubules are organized. No cell wall is deposited and the interzonal microtubules embrace a plate of organelles between the two nuclear cytoplasmic domains (NCDs) of the dyad. Following second meiosis, phragmoplasts that form between sister and non-sister nuclei fuse to form a complex six-sided structure that directs simultaneous cytokinesis. -Tubulin becomes associated with nuclei after both meiotic divisions and is especially conspicuous in the distal hemisphere of each young microspore where an unusual encircling system of cortical microtubules develops.     

Nucleotide sequence and evolution of a mammalian α-Tubulin messenger RNA

Bacterial clones containing complementary DNA sequences specific for rat brain α-tubulin messenger RNA were constructed. One plasmid, pILαTl, contains >95% of the sequences found in the mRNA: the entire coding sequence as well as extensive 5′ and 3′ untranslated sequences. Comparison of the rat amino acid sequence with the known chicken α-tubulin sequence (Valenzuela et al., 1981) reveals the extraordinary evolutionary stability of α-tubulin protein. The presence of only two interspecies amino acid differences within analogous 411 amino acid sequences predicts that amino acid substitutions in this protein are fixed with a unit evolutionary period (Wilson et al., 1977) of 550 million years (i.e. the time required for a 1% difference to arise within a specific protein in two diverging evolutionary lineages). An analysis of the silent nucleotide differences, permissible because of the degeneracy of the genetic code, demonstrates that these might not occur in a random fashion. The high guanine-cytosine bias in silent codon positions within the chicken α-tubulin sequence, previously noted by Valenzuela et al. (1981), is not conserved within the rat sequence. This decrease in guanine-cytosine bias is accompanied by a selective loss of CpG dinucleotides in the rat sequence.     

Structural and Functional Characterization of the α-Tubulin Acetyltransferase MEC-17

Tubulin protomers undergo an extensive array of post-translational modifications to tailor microtubules to specific tasks. One such modification, the acetylation of lysine 40 of α-tubulin, located in the lumen of microtubules, is associated with stable, long-living microtubule structures. MEC-17 was recently identified as the acetyltransferase that mediates this event. We have determined the crystal structure of the catalytic core of human MEC-17 in complex with its cofactor acetyl-CoA at 1.7 Å resolution. The structure reveals that the MEC-17 core adopts a canonical Gcn5-related N-acetyltransferase (GNAT) fold that is decorated with extensive surface loops. An enzymatic analysis of 33 MEC-17 surface mutants identifies hot-spot residues for catalysis and substrate recognition. A large, evolutionarily conserved hydrophobic surface patch that is critical for enzymatic activity is identified, suggesting that specificity is achieved by interactions with the α-tubulin substrate that extend outside of the modified surface loop. An analysis of MEC-17 mutants in Caenorhabditis elegans shows that enzymatic activity is dispensable for touch sensitivity.     

γ-Tubulin localizes at actin-based membrane protrusions and inhibits formation of stress-fibers

γ-Tubulin serves as a template in the γ-TuRC machinery to nucleate microtubules. Curiously, γ-tubulin also interacts with Arp2/3, a complex that nucleates actin filaments, and with the Arp2/3 activator WASH. We previously reported that γ-tubulin and Arp2/3 colocalize at the centrosome, where WASH localizes. Here, we report that γ-tubulin localizes at actin-based membrane protrusions, where Arp2/3 operates. This was confirmed by the presence of tagged γ-tubulin at membrane protrusions in stimulated cells and by downregulation of γ-tubulin expression. Surprisingly, expression of tagged γ-tubulin dramatically inhibited the formation of stress-fibers, while having no effect on microtubules. This phenotype is similar to the disruption of stress-fibers by the overexpression of the WCA domain of WASH and other Wiskott–Aldrich syndrome (WAS) family members. We hypothesize that γ-tubulin regulates Arp2/3 and actin nucleation promoting factors such as WASH, explaining the similar effect of γ-tubulin expression and WCA domain expression on stress-fibers. The data presented here indicate that γ-tubulin has a profound relationship with actin filament dynamics.     

γ-Tubulin 2 nucleates microtubules and is downregulated in mouse early embryogenesis

γ-Tubulin is the key protein for microtubule nucleation. Duplication of the γ-tubulin gene occurred several times during evolution, and in mammals γ-tubulin genes encode proteins which share ～97% sequence identity. Previous analysis of Tubg1 and Tubg2 knock-out mice has suggested that γ-tubulins are not functionally equivalent. Tubg1 knock-out mice died at the blastocyst stage, whereas Tubg2 knock-out mice developed normally and were fertile. It was proposed that γ-tubulin 1 represents ubiquitous γ-tubulin, while γ-tubulin 2 may have some specific functions and cannot substitute for γ-tubulin 1 deficiency in blastocysts. The molecular basis of the suggested functional difference between γ-tubulins remains unknown. Here we show that exogenous γ-tubulin 2 is targeted to centrosomes and interacts with γ-tubulin complex proteins 2 and 4. Depletion of γ-tubulin 1 by RNAi in U2OS cells causes impaired microtubule nucleation and metaphase arrest. Wild-type phenotype in γ-tubulin 1-depleted cells is restored by expression of exogenous mouse or human γ-tubulin 2. Further, we show at both mRNA and protein levels using RT-qPCR and 2D-PAGE, respectively, that in contrast to Tubg1, the Tubg2 expression is dramatically reduced in mouse blastocysts. This indicates that γ-tubulin 2 cannot rescue γ-tubulin 1 deficiency in knock-out blastocysts, owing to its very low amount. The combined data suggest that γ-tubulin 2 is able to nucleate microtubules and substitute for γ-tubulin 1. We propose that mammalian γ-tubulins are functionally redundant with respect to the nucleation activity.     

Isolation and Characterization of Mutations in the β-Tubulin Gene of SACCHAROMYCES CEREVISIAE

Of 173 mutants of Saccharomyces cerevisiae resistant to the antimitotic drug benomyl (BenR), six also conferred cold-sensitivity for growth and three others conferred temperature-sensitivity for growth in the absence of benomyl. All of the benR mutations tested, including the nine conditional-lethal mutations, were shown to be in the same gene. This gene, TUB2, has previously been molecularly cloned and identified as the yeast structural gene encoding beta-tubulin. Four of the conditional-lethal alleles of TUB2 were mapped to particular restriction fragments within the gene. One of these mutations was cloned and sequenced, revealing a single amino acid change, from arginine to histidine at amino acid position 241, which is responsible for both the BenR and the cold-sensitive lethal phenotypes. The terminal arrest morphology of conditional-lethal alleles of TUB2 at their restrictive temperature showed a characteristic cell-division-cycle defect, suggesting a requirement for tubulin function primarily in mitosis during the vegetative growth cycle. The TUB2 gene was genetically mapped to the distal left arm of chromosome VI, very near the actin gene, ACT1; no CDC (cell-division-cycle) loci have been mapped previously to this location. TUB2 is thus the first cell-division-cycle gene known to encode a cytoskeletal protein that has been identified in S. cerevisiae.     

Capzb2 Interacts with β-Tubulin to Regulate Growth Cone Morphology and Neurite Outgrowth

Capping protein (CP) is a heterodimer that regulates actin assembly by binding to the barbed end of F-actin. In cultured nonneuronal cells, each CP subunit plays a critical role in the organization and dynamics of lamellipodia and filopodia. Mutations in either α or β CP subunit result in retinal degeneration in Drosophila. However, the function of CP subunits in mammalian neurons remains unclear. Here, we investigate the role of the β CP subunit expressed in the brain, Capzb2, in growth cone morphology and neurite outgrowth. We found that silencing Capzb2 in hippocampal neurons resulted in short neurites and misshapen growth cones in which microtubules overgrew into the periphery and completely overlapped with F-actin. In searching for the mechanisms underlying these cytoskeletal abnormalities, we identified β-tubulin as a novel binding partner of Capzb2 and demonstrated that Capzb2 decreases the rate and the extent of tubulin polymerization in vitro. We mapped the region of Capzb2 that was required for the subunit to interact with β-tubulin and inhibit microtubule polymerization. A mutant Capzb2 lacking this region was able to bind F-actin and form a CP heterodimer with α2-subunit. However, this mutant was unable to rescue the growth cone and neurite outgrowth phenotypes caused by Capzb2 knockdown. Together, these data suggest that Capzb2 plays an important role in growth cone formation and neurite outgrowth and that the underlying mechanism may involve direct interaction between Capzb2 and microtubules.     

γ-Tubulin in tobacco pollen tubes: association with generative cell and vegetative microtubules

-Tubulin was localized in tobacco pollen tubes using an antibody raised against a peptide conserved in all known -tubulins. Antibody staining occurs in a primarily punctate pattern along the length of the microtubule bundles in generative cells and along cortical microtubules in the vegetative cytoplasm. During generative cell division, -tubulin is localized in the forming mitotic apparatus. By metaphase, it is present along kinetochore fibers except at their plus ends located at the kinetochores. By telophase, staining is observed in the phragmoplast, where it again avoids the plus ends of microtubules at the cell plate. -Tubulin is also present at the periphery of the sperm nuclei. A patch of intense staining on the distal side of each nucleus marks the site of assembly of a new population of sperm microtubules. No specific fluorescence is present in control pollen tubes treated with preimmune IgG. These localization patterns bear similarities to those seen in somatic cells and in addition may help explain changes in microtubule arrays between generative cells and sperm.     

Evaluation of ��-Tubulin as an Antigenic and Molecular Probe to Detect Giardia lamblia

The α/β-tubulin heterodimer is the basic subunit of microtubules in eukaryotes. Polyclonal antibodies specific to recombinant α-tubulin of Giardia lamblia were made, and found effective as a probe to specifically detect G. lamblia by immunofluorescence assays. Nucleotide sequences of α-tubulin genes were compared between G. lamblia WB and GS strains, prototypes of assemblage A and assemblage B, respectively. A set of primers was designed and used to amplify a portion of the α-tubulin gene from G. lamblia. PCR-RFLP analysis of this α-tubulin PCR product successfully differentiated G. lamblia into 2 distinct groups, assemblages A and B. The results indicate that α-tubulin can be used as a molecular probe to detect G. lamblia.     

Structural Analysis of Mutations in the Drosophila β2-Tubulin Isoform Reveals Regions in the β-Tubulin Molecule Required for General and for Tissue-Specific Microtubule Functions

We have determined the lesions in a number of mutant alleles of βTub85D, the gene that encodes the testis-specific β2-tubulin isoform in Drosophila melanogaster. Mutations responsible for different classes of functional phenotypes are distributed throughout the β2-tubulin molecule. There is a telling correlation between the degree of phylogenetic conservation of the altered residues and the number of different microtubule categories disrupted by the lesions. The majority of lesions occur at positions that are evolutionarily highly conserved in all β-tubulins; these lesions disrupt general functions common to multiple classes of microtubules. However, a single allele B2t(6) contains an amino acid substitution within an internal cluster of variable amino acids that has been identified as an isotype-defining domain in vertebrate β-tubulins. Correspondingly, B2t(6) disrupts only a subset of microtubule functions, resulting in misspecification of the morphology of the doublet microtubules of the sperm tail axoneme. We previously demonstrated that β3, a developmentally regulated Drosophila β-tubulin isoform, confers the same restricted morphological phenotype in a dominant way when it is coexpressed in the testis with wild-type β2-tubulin. We show here by complementation analysis that β3 and the B2t(6) product disrupt a common aspect of microtubule assembly. We therefore conclude that the amino acid sequence of the β2-tubulin internal variable region is required for generation of correct axoneme morphology but not for general microtubule functions. As we have previously reported, the β2-tubulin carboxy terminal isotype-defining domain is required for suprastructural organization of the axoneme. We demonstrate here that the β2 variant lacking the carboxy terminus and the B2t(6) variant complement each other for mild-to-moderate meiotic defects but do not complement for proper axonemal morphology. Our results are consistent with the hypothesis drawn from comparisons of vertebrate β-tubulins that the two isotype-defining domains interact in a three-dimensional structure in wild-type β-tubulins. We propose that the integrity of this structure in the Drosophila testis β2-tubulin isoform is required for proper axoneme assembly but not necessarily for general microtubule functions. On the basis of our observations we present a model for regulation of axoneme microtubule morphology as a function of tubulin assembly kinetics.     

Spindle Dynamics and the Role of γ-Tubulin in Early Caenorhabditis elegans Embryos

gamma-Tubulin is a ubiquitous and highly conserved component of centrosomes in eukaryotic cells. Genetic and biochemical studies have demonstrated that gamma-tubulin functions as part of a complex to nucleate microtubule polymerization from centrosomes. We show that, as in other organisms, Caenorhabditis elegans gamma-tubulin is concentrated in centrosomes. To study centrosome dynamics in embryos, we generated transgenic worms that express GFP::gamma-tubulin or GFP::beta-tubulin in the maternal germ line and early embryos. Multiphoton microscopy of embryos produced by these worms revealed the time course of daughter centrosome appearance and growth and the differential behavior of centrosomes destined for germ line and somatic blastomeres. To study the role of gamma-tubulin in nucleation and organization of spindle microtubules, we used RNA interference (RNAi) to deplete C. elegans embryos of gamma-tubulin. gamma-Tubulin (RNAi) embryos failed in chromosome segregation, but surprisingly, they contained extensive microtubule arrays. Moderately affected embryos contained bipolar spindles with dense and long astral microtubule arrays but with poorly organized kinetochore and interpolar microtubules. Severely affected embryos contained collapsed spindles with numerous long astral microtubules. Our results suggest that gamma-tubulin is not absolutely required for microtubule nucleation in C. elegans but is required for the normal organization and function of kinetochore and interpolar microtubules.     

Roles of β-Tubulin Residues Ala428 and Thr429 in Microtubule Formation in Vivo

The C termini of β-tubulin isotypes are regions of high sequence variability that bind to microtubule-associated proteins and motors and undergo various post-translational modifications such as polyglutamylation and polyglycylation. Crystallographic analyses have been unsuccessful in resolving tubulin C termini. Here, we used a stepwise approach to study the role of this region in microtubule assembly. We generated a series of truncation mutants of human βI and βIII tubulin. Transient transfection of HeLa cells with the mutants shows that mutants with deletions of up to 22 residues from βIII and 16 from βI can assemble normally. Interestingly, removal of the next residue (Ala⁴²⁸) results in a complete loss of microtubule formation without affecting dimer formation. C-terminal tail switching of human βI and βIII tubulin suggests that C-terminal tails are functionally equivalent. In short, residues outside of 1–429 of human β-tubulins make no contribution to microtubule assembly. Ala⁴²⁸, in the C-terminal sequence motif N-QQYQDA⁴²⁸, lies at the end of helix H12 of β-tubulin. We hypothesize that this residue is important for maintaining helix H12 structure. Deletion of Ala⁴²⁸ may lead to unwinding of helix H12, resulting in tubulin dimers incapable of assembly. Thr⁴²⁹ plays a more complex role. In the βI isotype of tubulin, Thr⁴²⁹ is not at all necessary for assembly; however, in the βIII isotype, its presence strongly favors assembly. This result is consistent with a likely more complex function of βIII as well as with the observation that evolutionary conservation is total for Ala⁴²⁸ and frequent for Thr⁴²⁹.Microtubules are involved in a great variety of cellular functions. Their constituent protein tubulin is an αβ heterodimer, both α- and β-tubulin existing as multiple isotypes, encoded by different genes and differing in amino acid sequence (1). The differences among the isotypes are highly conserved in evolution. In mammals, the β isotypes are βIa, βIb, βII, βIII, βIVa, βIVb, βV, and βVI. There is evidence that the isotype differences have functional significance. For instance, the βIV isotype is found in all axonemes (2).Structurally, both α- and β-tubulin consist of a globular region of 427 amino acids followed by a C-terminal region of 17–24 amino acids (3–5). The C-terminal region is highly negatively charged, being especially rich in glutamate residues and lacking in basic residues, and is likely to project outward from the rest of the molecule, because of its high negative charge and the electrostatic repulsion among the glutamate residues (3). The three-dimensional structure of the globular domain has been determined by electron and x-ray crystallography (4, 5). However, the C-terminal region has never been localized in the three-dimensional reconstructions except by computer modeling. The probable reasons for this are 1) that, if the C-terminal region projects out from the rest of molecule, it is likely to be very flexible with respect to the rest of the molecule and 2) the C-terminal region undergoes post-translational modification. Both of these can lead to structural heterogeneity and cause the C terminus to be invisible to crystallographic techniques.In this work, we examine the role of the C termini of human β-tubulins to determine the minimal sequence requirement for microtubule incorporation through structure/function analyses. The human βI and βIII tubulin isotypes were utilized based on their high degree of sequence variability clustered at the C terminus (Fig. 1) and the fact that βI is broadly distributed among normal tissues, whereas βIII has a very narrow tissue distribution. These two isotypes share 92% sequence identity, with differences among these isotypes occurring in both the globular domain and the C-terminal region (1).Open in a separate windowFIGURE 1.Sequence alignment of human βIa and βIII tubulin isotypes. Human βIa and βIII tubulin isotypes were aligned with ClustalX 1.83 and processed with BioEdit. Hyphens denote identical residues between sequences.

TABLE 1

The C-terminal amino acid sequences of the human β-tubulin isotypes

Specific α- and β-Tubulin Isotypes Optimize the Functions of Sensory Cilia in Caenorhabditis elegans

Primary cilia have essential roles in transducing signals in eukaryotes. At their core is the ciliary axoneme, a microtubule-based structure that defines cilium morphology and provides a substrate for intraflagellar transport. However, the extent to which axonemal microtubules are specialized for sensory cilium function is unknown. In the nematode Caenorhabditis elegans, primary cilia are present at the dendritic ends of most sensory neurons, where they provide a specialized environment for the transduction of particular stimuli. Here, we find that three tubulin isotypes—the α-tubulins TBA-6 and TBA-9 and the β-tubulin TBB-4—are specifically expressed in overlapping sets of C. elegans sensory neurons and localize to the sensory cilia of these cells. Although cilia still form in mutants lacking tba-6, tba-9, and tbb-4, ciliary function is often compromised: these mutants exhibit a variety of sensory deficits as well as the mislocalization of signaling components. In at least one case, that of the CEM cephalic sensory neurons, cilium architecture is disrupted in mutants lacking specific ciliary tubulins. While there is likely to be some functional redundancy among C. elegans tubulin genes, our results indicate that specific tubulins optimize the functional properties of C. elegans sensory cilia.THE fitness of all organisms depends on an ability to appropriately sense and respond to the environment. At the cellular level, many specific architectures have evolved to optimize these sensory functions. Prominent among these is the sensory cilium, a tubulin-based cytoplasmic extension that interrogates the extracellular environment in many biological contexts (Davenport and Yoder 2005; Berbari et al. 2009). Cilia are important for the transduction of a broad range of visual, auditory, mechanical, thermal, and chemical stimuli. They also function during development to receive a variety of signals, both chemical and mechanical, that regulate proliferation and differentiation (Goetz and Anderson 2010). Indeed, the disruption of cilium assembly and function can give rise to a spectrum of human diseases collectively known as ciliopathies (Berbari et al. 2009; Lancaster and Gleeson 2009). These disorders, which include autosomal dominant polycystic kidney disease (ADPKD) and autosomal recessive polycystic kidney disease (ARPKD), Bardet–Biedl syndrome, Meckel–Gruber syndrome, and Joubert syndrome, are associated with a variety of pathogenic conditions including polycystic kidneys and neurological impairments.At the core of all cilia and flagella is the microtubule axoneme. This characteristic structural element comprises nine doublet outer microtubules that may surround a central pair, the presence of which often indicates a motile cilium/flagellum. Like all microtubule-based structures, ciliary axonemes are built of heterodimers of α- and β-tubulins, highly conserved small GTP-binding proteins. The recruitment of other cilium components, including signal transduction machinery, requires a conserved assembly and maintenance process called intraflagellar transport (IFT) (Blacque et al. 2008; Pedersen and Rosenbaum 2008). IFT employs two major complexes that transport ciliary cargo bidirectionally by traveling along the axonemal microtubules. Loss of individual IFT components can cause a broad spectrum of defects in the assembly, maintenance, and function of cilia.Important insights into cilium structure and function have come from studies of genetically tractable organisms, particularly the green alga Chlamydomonas and the nematode Caenorhabditis elegans (Bae and Barr 2008; Pedersen and Rosenbaum 2008). In C. elegans, sensory cilia are found exclusively at the dendritic ends of sensory neurons. These cilia constitute a highly specialized sensory environment characterized by localized sensory receptors and specific signaling components. Cilium morphology is quite distinctive in many of these cells and likely contributes to their functional specialization (Ward et al. 1975). Recent progress has shed light on the mechanisms that confer this specialization onto more general pan-ciliary pathways (Evans et al. 2006; Mukhopadhyay et al. 2007; Jauregui et al. 2008; Mukhopadhyay et al. 2008; Silverman and Leroux 2009).The genomes of many eukaryotes harbor multiple α- and β-tubulin genes. Two hypotheses, which are not mutually exclusive, have been proposed to account for these paralogs (Cleveland 1987; Wade 2007). At one extreme, different tubulin isotypes might be functionally redundant, such that their minor coding differences are largely irrelevant. According to this model, multiple genes allow the maintenance of a stable pool of available monomers and dimers. The small amount of sequence variation within the α- and β-tubulin families supports this idea, as do studies of functionally redundant mitotic tubulins in C. elegans (Ellis et al. 2004; Lu et al. 2004; Phillips et al. 2004; Lu and Mains 2005). The alternative hypothesis proposes that specific structures, e.g., ciliary axonemes or axonal microtubules, rely on tubulins optimized for specific roles. Support for this idea has come from studies of cultured mammalian neurons (Joshi and Cleveland 1989), Drosophila (Hutchens et al. 1997; Raff et al. 1997), and human tubulins (Vent et al. 2005; Jaglin et al. 2009). In Drosophila, studies of motile sperm flagella have revealed that the sperm-specific β2 tubulin isoform builds not only the specialized motile axoneme but also all other tubulin-based structures (Kemphues et al. 1982). However, sequences both within and outside the axoneme motif in the C-terminal tail of this tubulin isoform are required for the flagellar axoneme, and other closely related β-tubulins cannot support this role (Fuller et al. 1987; Raff et al. 1997; Popodi et al. 2008). Genetic interactions have provided evidence that β2 tubulin heterodimerizes with the α-tubulin 84B (Hays et al. 1989), which also possesses specific functional properties not provided by structurally similar α-tubulins (Hutchens et al. 1997). In C. elegans, a specific role for tubulin isoforms has been described in the six touch receptor neurons. These nonciliated cells harbor unusual 15-filament microtubules composed of dimers of the α-tubulin MEC-12 and the β-tubulin MEC-7. The loss of mec-7 or mec-12, the expression of which is largely restricted to these cells, results in the conversion of 15-filament microtubules to the standard 11-microfilament variety and a commensurate loss of light-touch response (Savage et al. 1989; Fukushige et al. 1999; Bounoutas et al. 2009). Thus experimental support exists for both of these opposing views, and it seems likely that the role of specific tubulin isoforms in regulating microtubule structure and function differs according to cell and organelle type.The C. elegans genome encodes nine α- and six β-tubulin genes (Gogonea et al. 1999). Some of these genes, particularly tba-1, tba-2, tbb-1, and tbb-2, are expressed broadly during embryogenesis and function redundantly in spindle assembly and positioning (Ellis et al. 2004; Lu et al. 2004; Phillips et al. 2004; Lu and Mains 2005). tba-1 and tbb-2 have also been recently shown to be important for axon outgrowth and synaptogenesis (Baran et al. 2010). Several others, including mec-7, mec-12, and the β-tubulin ben-1, have been identified through genetic screens for particular phenotypes, such as touch insensitivity or benzimidazole resistance (Driscoll et al. 1989; Savage et al. 1989; Fukushige et al. 1999). However, the extent to which specific tubulin isoforms are required for structural and functional diversity in the C. elegans nervous system remains unknown. Here, taking advantage of several existing genome-wide data sets, we identify the α-tubulins TBA-6 and TBA-9 and the β-tubulin TBB-4 as strong candidates for tubulins that have roles in sensory cilia. We find that each of these genes are expressed in characteristic, partially overlapping, sets of sensory neurons, where their products localize to ciliary axonemes. While the loss of any one (or all three) of these genes does not abolish ciliogenesis, tubulin mutants exhibit significant defects in the localization of cilium proteins and in some cilium-dependent behavioral responses. Together, our results indicate that specific α- and β-tubulin isoforms are important, although not essential, for the efficient assembly and function of specific classes of C. elegans sensory cilia. Sensory cilia throughout the animal kingdom may therefore employ specific tubulin isoforms to optimize their function.     

A Direct Interaction between Leucine-rich Repeat Kinase 2 and Specific β-Tubulin Isoforms Regulates Tubulin Acetylation

Mutations in LRRK2, encoding the multifunctional protein leucine-rich repeat kinase 2 (LRRK2), are a common cause of Parkinson disease. LRRK2 has been suggested to influence the cytoskeleton as LRRK2 mutants reduce neurite outgrowth and cause an accumulation of hyperphosphorylated Tau. This might cause alterations in the dynamic instability of microtubules suggested to contribute to the pathogenesis of Parkinson disease. Here, we describe a direct interaction between LRRK2 and β-tubulin. This interaction is conferred by the LRRK2 Roc domain and is disrupted by the familial R1441G mutation and artificial Roc domain mutations that mimic autophosphorylation. LRRK2 selectively interacts with three β-tubulin isoforms: TUBB, TUBB4, and TUBB6, one of which (TUBB4) is mutated in the movement disorder dystonia type 4 (DYT4). Binding specificity is determined by lysine 362 and alanine 364 of β-tubulin. Molecular modeling was used to map the interaction surface to the luminal face of microtubule protofibrils in close proximity to the lysine 40 acetylation site in α-tubulin. This location is predicted to be poorly accessible within mature stabilized microtubules, but exposed in dynamic microtubule populations. Consistent with this finding, endogenous LRRK2 displays a preferential localization to dynamic microtubules within growth cones, rather than adjacent axonal microtubule bundles. This interaction is functionally relevant to microtubule dynamics, as mouse embryonic fibroblasts derived from LRRK2 knock-out mice display increased microtubule acetylation. Taken together, our data shed light on the nature of the LRRK2-tubulin interaction, and indicate that alterations in microtubule stability caused by changes in LRRK2 might contribute to the pathogenesis of Parkinson disease.     

Genetic Variability of the β-Tubulin Genes in Benzimidazole-Susceptible and -Resistant Strains of Haemonchus Contortus

Benzimidazole anthelmintics are the most common chemotherapeutic agents used to remove intestinal helminths from farm animals. The development of drug resistance within helminth populations is wide-spread and can render these drugs essentially useless. The mechanism of benzimidazole resistance appears to be common to many species ranging from fungi to nematodes and involves alterations in the genes encoding β-tubulin. During the selection process resulting in resistance, there must be quantitative changes in the population gene pool. Knowledge of these changes would indicate the mechanisms underlying the spread of resistance in the population, which in turn could be used to design more effective drug administration strategies. To this end we have identified allelic variation at two β-tubulin genes in Haemonchus contortus using restriction map analysis of individual adults. Extremely high levels of variation were identified at both loci within a susceptible strain. In two independently derived benzimidazole resistant strains, allele frequencies at both loci were significantly different from the susceptible strain but not from each other. The same alleles at both loci, in both resistant strains, were favored by selection with benzimidazoles, suggesting that both loci are involved in determining benzimidazole resistance. These data confirm that changes in allele frequency, rather than novel genetic rearrangements induced by exposure to the drug, explain the changes associated with benzimidazole resistance. These results also show that any DNA based test for the development of benzimidazole resistance must take into account the frequency of alleles present in the population and not simply test for the presence or absence of specific allelic types.     

Cell Cycle Activity and β-Tubulin Accumulation During Dormancy Breaking of Acer platanoides L. seeds

Cell cycle events in embryo axes of Norway maple (Acer platanoides L.) seeds were studied during dormancy breaking by flow cytometric analyses of the nuclear DNA content and by immunodetection of β-tubulin. Most embryonic nuclei of dry, fully matured seeds were arrested in the G₂ phase of the cell cycle. In addition, the lowest content of β-tubulin was detected in dry, mature seeds. Imbibition in water and cold stratification resulted in a decrease in the number of nuclei in G₂, and a simultaneous increase in β-tubulin content. In germinated seeds the content of β-tubulin was the highest and the number of cells in G₂ was the lowest. Both cell cycle events preceded cell expansion and division and subsequent growth of the radicle through the seed coat. The anatomical investigation has proved that the main reason for decrease in the number of nuclei in G₂ is mitosis, started with seeds germination (radicle protrusion). The activation of the cell cycle and the β-tubulin accumulation were associated with embryo dormancy breaking. This revised version was published online in July 2006 with corrections to the Cover Date.