Site-directed antibodies to tubulin

Exposure of beta-tubulin regions defined by antibodies on an Arabidopsis thaliana microtubule protofilament model and in the cells

BACKGROUND

The function of the cortical microtubules, composed of alphabeta-tubulin heterodimers, is linked to their organizational state which is subject to spatial and temporal modulation by environmental cues. The role of tubulin posttranslational modifications in these processes is largely unknown. Although antibodies against small tubulin regions represent useful tool for studying molecular configuration of microtubules, data on the exposure of tubulin epitopes on plant microtubules are still limited.

RESULTS

Using homology modeling we have generated an Arabidopsis thaliana microtubule protofilament model that served for the prediction of surface exposure of five beta-tubulin epitopes as well as tyrosine residues. Peptide scans newly disclosed the position of epitopes detected by antibodies 18D6 (beta1-10), TUB2.1 (beta426-435) and TU-14 (beta436-445). Experimental verification of the results by immunofluorescence microscopy revealed that the exposure of epitopes depended on the mode of fixation. Moreover, homology modeling showed that only tyrosines in the C-terminal region of beta-tubulins (behind beta425) were exposed on the microtubule external side. Immunofluorescence microscopy revealed tyrosine phosphorylation of microtubules in plant cells, implying that beta-tubulins could be one of the targets for tyrosine kinases.

CONCLUSIONS

We predicted surface exposure of five beta-tubulin epitopes, as well as tyrosine residues, on the surface of A. thaliana microtubule protofilament model, and validated the obtained results by immunofluorescence microscopy on cortical microtubules in cells.The results suggest that prediction of epitope exposure on microtubules by means of homology modeling combined with site-directed antibodies can contribute to a better understanding of the interactions of plant microtubules with associated proteins.

Soluble tubulin complexes in oocytes of the common leopard frog, Rana pipiens, contain gamma-tubulin

Oocytes of the leopard frog, Rana pipiens, contain soluble tubulin which was previously shown to exist predominantly in megadalton (MDa) fractions and that fails to readily assemble in vitro. In order to further characterize these tubulin complexes, DEAE Sepharose chromatography, Sephacryl S-300 size exclusion columns and specific immunoprecipitation were used. The results revealed the presence of alpha-, beta-, and gamma-tubulin associated with several other proteins in the soluble fraction of Rana pipiens ovarian oocytes. These Rana oocyte tubulin complexes appear to be analogous to those recently reported in Xenopus ovulated eggs as gamma-tubulin ring complexes. This seems true since both size (estimates, i.e. approximately 2MDa) and protein components are similar. Furthermore, both alpha- and gamma-tubulin antibodies immunoprecipitated identical protein bands from Rana oocyte soluble fraction. These putative Rana gamma-tubulin ring proteins include 107, 97, 95, 90 and 75 kDa components which are similar in size to those found in Xenopus and other species. Rana appears to belong to a select group in which gamma-tubulin complexes contain significant alpha- and beta-tubulin (i.e., Xenopus and sheep), while other species such as Drosophila, Aspergillus, Saccharomyces, human cells and many other mammalian cells tested lack the other tubulin components. The heterogeneity in both size and protein components of Rana oocyte gamma-tubulin ring complexes may reflect different states of tubulin complex assembly. The lower vertebrate oocyte is hypothesized to act as a repository and prestaging point for the assembly of gamma-tubulin ring complexes which will become the maternal contribution to the centrosomes of the embryo. While the gamma-tubulin ring complexes of vertebrate eggs have been described previously, this is the first report biochemically characterizing soluble gamma-tubulin complexes in vertebrate ovarian oocytes.

High-resolution model of the microtubule

A high-resolution model of the microtubule has been obtained by docking the crystal structure of tubulin into a 20 A map of the microtubule. The excellent fit indicates the similarity of the tubulin conformation in both polymers and defines the orientation of the tubulin structure within the microtubule. Long C-terminal helices form the crest on the outside of the protofilament, while long loops define the microtubule lumen. The exchangeable nucleotide in beta-tubulin is exposed at the plus end of the microtubule, while the proposed catalytic residue in alpha-tubulin is exposed at the minus end. Extensive longitudinal interfaces between monomers have polar and hydrophobic components. At the lateral contacts, a nucleotide-sensitive helix interacts with a loop that contributes to the binding site of taxol in beta-tubulin.

Structure of the alpha beta tubulin dimer by electron crystallography

The alphabeta tubulin heterodimer is the structural subunit of microtubules, which are cytoskeletal elements that are essential for intracellular transport and cell division in all eukaryotes. Each tubulin monomer binds a guanine nucleotide, which is nonexchangeable when it is bound in the alpha subunit, or N site, and exchangeable when bound in the beta subunit, or E site. The alpha- and beta-tubulins share 40% amino-acid sequence identity, both exist in several isotype forms, and both undergo a variety of posttranslational modifications. Limited sequence homology has been found with the proteins FtsZ and Misato, which are involved in cell division in bacteria and Drosophila, respectively. Here we present an atomic model of the alphabeta tubulin dimer fitted to a 3.7-A density map obtained by electron crystallography of zinc-induced tubulin sheets. The structures of alpha- and beta-tubulin are basically identical: each monomer is formed by a core of two beta-sheets surrounded by alpha-helices. The monomer structure is very compact, but can be divided into three functional domains: the amino-terminal domain containing the nucleotide-binding region, an intermediate domain containing the Taxol-binding site, and the carboxy-terminal domain, which probably constitutes the binding surface for motor proteins.

Expression of tubulin isoforms during the differentiation of mammalian spermatozoa

Using the GT 335 mAb we have previously demonstrated a differential expression of glutamylated tubulin isoforms during spermatogenesis and in spermatooza of the mouse and human. Moreover, the proximodistal decrease of the immunolabeling and its predominance in doublets 1-5-6, corresponding to the plane of the flagellar wave, suggested that the glutamylated tubulin could be involved in a functional heterogeneity of microtubules in peripheral doublets of the sperm flagellum. In order to characterize further the importance of glutamylated tubulin in the sperm model, we analyzed tubulin isoforms by immunoblotting and quantitative immunogold, using antibodies to the C-terminal domain of both subunits including non-glutamylated and glutamylated epitopes. The unique differential immunolabeling of the glutamylated tubulin was confirmed with three mAbs 406-3, 392-2 and B3, in addition to GT 335. This differential labeling was interpreted as a differential accessibility of tubulin epitopes since it was greatly reduced in human spermatozoa lacking dynein arms and after motility inhibition of normal spermatozoa by azide pretreatment. We suggest that the glutamylated tubulin interacts with other axonemal and/or periaxonemal proteins which could be involved in flagellar beating and its regulation.

A putative beta-tubulin phosphate-binding motif is involved in lateral microtubule protofilament interactions

We have investigated the role of a putative GTP-binding beta-tubulin motif in microtubule polymerization. A peptide containing residues 126-142 of the beta-tubulin subunit (peptide G) was synthesised and an antibody against it raised. Peptide G prevents the binding of GTP to tubulin and also microtubule polymerization but not the formation of vinblastine-induced tubulin spirals, suggesting that it may prevent lateral but not longitudinal tubulin-tubulin interactions. The antibody to peptide G shows little reaction with the interphase microtubule network, mitotic spindles or midbody of cultured cells, whereas it clearly reacts with vinblastine-induced paracrystals. These results suggest that this putative phosphate-binding site present in beta-tubulin could be involved in the lateral tubulin-tubulin interactions along the microtubule structure.

Post-translational modifications and multiple tubulin isoforms in Nicotiana tabacum L. cells

Distribution of post-translationally modified tubulins in cells of Nicotiana tabacum L. was analysed using a panel of specific antibodies. Polyglutamylated, tyrosinated, nontyrosinated, acetylated and delta 2-tubulin variants were detected on alpha-tubulin subunits; polyglutamylation was also found on beta-tubulin subunits. Modified tubulins were detected by immunofluorescence microscopy in interphase microtubules, preprophase bands, mitotic spindles as well as in phragmoplasts. They were, however, located differently in the various microtubule structures. The antibodies against tyrosinated, acetylated and polyglutamylated tubulins gave uniform staining along all microtubules, while antibodies against nontyrosinated and delta 2-tubulin provided dot-like staining of interphase microtubules. Additionally, immunoreactivity of antibodies against acetylated and delta 2-tubulins was strong in the pole regions of mitotic spindles. High-resolution isoelectric focusing revealed 22 tubulin charge variants in N. tabacum suspension cells. Immunoblotting with antibodies TU-01 and TU-06 against conserved antigenic determinants of alpha- and beta-tubulin molecules, respectively, revealed that 11 isoforms belonged to the alpha-subunit and 11 isoforms to the beta-subunit. Whereas antibodies against polyglutamylated, tyrosinated and acetylated tubulins reacted with several alpha-tubulin isoforms, antibodies against nontyrosinated and delta 2-tubulin reacted with only one. The combined data demonstrate that plant tubulin is extensively post-translationally modified and that these modifications participate in the generation of plant tubulin polymorphism.

Mapping surface sequences of the tubulin dimer and taxol-induced microtubules with limited proteolysis

Native tubulin alpha beta dimers and microtubules have been subjected to limited proteolysis with trypsin, chymotrypsin, elastase, clostripain, proteinase lysine-C, thermolysin, protease V8, papain, subtilisin, proteinase K, proteinase aspartic-N, and bromelain. Eighty nicking points have been mapped onto the alpha- and beta-tubulin sequences with the aid of site-directed antibodies, of which 18 sites have been exactly determined by N-terminal sequencing, and the probable position of 6 others deduced from protease specificities. Proteolytic sites cluster into five characteristic zones, including the C termini of both chains. Residues accessible to proteases in the tubulin dimer include alpha-tubulin Lys40-Thr41-Ile42, Glu168-Phe169-Ser170, Ser178-Thr179-Ala180-Val181, Lys280-Ala281, Glu290-Ile291, Ala294-Cys295, Arg339-Ser340 (plus probably Lys60-His61 and Glu183-Pro184) and beta-tubulin Gly93-Gln94, Lys174-Val175, Gly277-Ser278, Tyr281-Arg282-Ala283, Cys354-Asp355 (plus probably Arg121-Lys122, Phe167-Ser168, Tyr183-Asn184, and Glu426-Asp427 or Ala430-Asp431). While the majority of these sites remain accessible at the outer surface of taxol-induced microtubules, alpha-tubulin Lys280-Ala281, Arg339-Ser340 and beta-tubulin Tyr281-Arg282-Ala283 (and probably Arg121-Lys122) become protected from limited proteolysis, suggesting that they are close to or at intermolecular contacts in the assembled structure. The protease nicking points constitute sets of surface constraints for any three-dimensional model structures of tubulin and microtubules. The dimer tryptic site at alpha-tubulin 339-340 jumps approximately 12-22 residues upstream (probably to Lys326-Asp327 or Lys311-Tyr312) in taxol microtubules, suggesting a tertiary structural change. The cleavage of the approximately 10 C-terminal residues of alpha-tubulin by protease V8, papain, and subtilisin is inhibited in taxol microtubules compared to tubulin dimers, while the approximately 20 C-terminal residues of beta-tubulin are similarly accessible to protease V8, subtilisin, proteinase K, proteinase AspN, and bromelain and show enhanced papain cleavage. This is consistent with models in which the alpha-tubulin C-terminal zone is near the interdimer contact zone along the protofilaments, whereas the C terminus of beta is near the interface between both subunits.

Interaction of kinesin motor domains with alpha- and beta-tubulin subunits at a tau-independent binding site. Regulation by polyglutamylation

Interaction of rat kinesin and Drosophila nonclaret disjunctional motor domains with tubulin was studied by a blot overlay assay. Either plus-end or minus-end-directed motor domain binds at the same extent to both alpha- and beta-tubulin subunits, suggesting that kinesin binding is an intrinsic property of each tubulin subunit and that motor directionality cannot be related to a preferential interaction with a given tubulin subunit. Binding features of dimeric versus monomeric rat kinesin heads suggest that dimerization could drive conformational changes to enhance binding to tubulin. Competition experiments have indicated that kinesin interacts with tubulin at a Tau-independent binding site. Complementary experiments have shown that kinesin does not interact with the same efficiency with the different tubulin isoforms. Masking the polyglutamyl chains with a specific monoclonal antibody leads to a complete inhibition of kinesin binding. These results are consistent with a model in which polyglutamylation of tubulin regulates kinesin binding through progressive conformational changes of the whole carboxyl-terminal domain of tubulin as a function of the polyglutamyl chain length, thus modulating the affinity of tubulin for kinesin and Tau as well. These results indicate that microtubules, through tubulin polymorphism, do have the ability to control microtubule-associated protein binding.

Comparative immunogold analysis of tubulin isoforms in the mouse sperm flagellum: unique distribution of glutamylated tubulin

The distribution of different tubulin isoforms in the mouse sperm flagellum was studied using four site-directed antibodies to tubulin: DM1A and DM1B general anti alpha and beta-tubulin, 6-11B-1 anti-acetylated alpha-tubulin, and GT335 anti-glutamylated alpha and beta-tubulin. Quantitative immunogold analyses were performed on five regions of the flagellum: the middle piece, three successive regions of the principal piece, and the terminal piece. A uniform labeling was observed with DM1A and DM1B along the entire flagellum both for peripheral doublets and the central pair. Similar results were obtained with 6-11B-1 directed to acetylated alpha-tubulin, an N-terminal-modified tubulin isoform. In contrast, the labeling for glutamylated alpha and beta-tubulin, C-terminal modified isoforms, was not uniform. The highest intensity was found in the middle piece and the terminal piece. The labeling which decreased significantly both for peripheral doublets and central pair along the principal piece was considered as a loss of glutamylated tubulin accessibility. From the middle piece to the end of the principal piece, this labeling was predominant in doublets 1-5-6, corresponding to the plane of the flagellar wave. However, the labeling for doublets 2-3-4-7-8-9 was heterogeneous, showing an increasing asymmetry. These results suggest that in the mammalian sperm cell model, the glutamylated tubulin might be involved in a functional heterogeneity among peripheral doublets of the flagellum.

Differential effects of vincristine and phenytoin on the proliferation, migration, and invasion of human glioma cell lines

The aim of this study was to investigate the antimigratory and antiinvasive potential of vincristine sulfate (VCR) on human glioma cells and to analyze whether phenytoin (5,5-diphenylhydantoin; DPH) might act synergistically with VCR. Vincristine affects the cytoplasmic microtubules; DPH has been reported to enhance VCR cytotoxicity in murine cells. In two human glioma cell lines, GaMG and D-37MG, we found VCR to reduce monolayer growth and colony formation in a dose-dependent fashion at concentrations of 10 ng/ml and above. Phenytoin increased the cytotoxic and cytostatic effects of VCR in monolayer cells but not in spheroids. Multicellular spheroids were used to investigate directional migration. A coculture system of GaMG and D-37MG spheroids with fetal rat brain aggregates was used to analyze and quantify tumor cell invasion. A dose-dependent inhibition of migration and invasion by VCR was observed in both cell lines without further enhancement by DPH. Immunofluorescence microscopy with antibodies against alpha-tubulin revealed dose-dependent morphological alterations in the microtubules when the cells were exposed to VCR but not after incubation with DPH. Based on the combination of standardized in vitro model systems currently in use and the present data, the authors strongly suggest that VCR inhibits migration and invasion of human glioma cells. This is not altered by DPH, which inhibits cell proliferation in combination with VCR.