Modification of tubulin by tyrosylation in cells and extracts and its effect on assembly in vitro

A post-translational modification of tubulin with potential regulatory significance has been revealed by the discovery of an enzyme (tubulin-tyrosine ligase) in brain extracts which can add a tyrosine residue to the alpha chain, apparently through peptide bond linkage to a C-terminal glutamate. We have investigated whether this modification also occurs in vivo, and whether it alters the extent to which tubulin can assemble in vitro. Cytoplasmic tubulin purified from bovine brain by cycles of assembly was shown to be partially tyrosylated. Carboxypeptidase A digestion of isolated alpha chains liberated about 0.3 equivalent of tyrosine. Brief digestion of native tubulin increased the proportion of alpha chains which could be tyrosylated by ligase, from 25 to 45%. The tubulin assembled to the same extent before and after carboxypeptidase treatment. When tubulin was purified after introducing labeled tyrosine with ligase, the labeled species assembled in the same proportion as unlabeled. Thus tubulin can be incorporated into microbubules in vitro with or without C-terminal tyrosine. An apparent resolution of alpha chain into two components by hydroxylapatite chromatography was shown not to be due to the presence or absence of C-terminal tyrosine. Tubulin-tyrosine ligase was found in extracts of every rat tissue examined, but was not detected in sea urchin eggs before or after fertilization, in Tetrahymena cells or cilia, or in yeast. Cultured neuroblastoma cells fixed tyrosine into tubulin alpha chains under conditions where protein synthesis was inhibited; this in vivo fixation appeared to be into an insoluble moiety of tubulin. Incidental to these studies, a new assay utilizing an enamine substrate for carboxypeptidase was investigated.     

Tubulin tyrosylation in vivo and changes accompanying differentiation of cultured neuroblastoma-glioma hybrid cells.

Changes in a posttranslational modification of tubulin, which accompany differentiation, have been studied in neuroblastoma-glioma hybrid cultured cells. The modification consists of the reversible enzymatic addition of a tyrosine to the COOH terminus of the alpha chain. Cytoplasmic tubulin purified from undifferentiated cells resembled that from adult mammalian brain in that half was in a form which can not accept tyrosine; of the remainder, which is a substrate for tubulin-tyrosine ligase, a higher proportion had COOH-terminal tyrosine. In the tubulin from differentiated cells, in which there had been extensive assembly of axonal microtubules from a preformed pool of subunits, the nonsubstrate tubulin was almost entirely replaced by the species with COOH-terminal tyrosine. In living cells, in the absence of protein synthesis, there was fixation of labeled tyrosine into cytoplasmic alpha chains which was extensive enough to be consistent with turnover, during the course of an hour, of the pre-existing COOH-terminal tyrosine. The alpha chain in the particulate fraction of the cells was comparably labeled, along with some unidentified low molecular weight components.     

Tubulin heterogeneity in the trypanosome Crithidia fasciculata.

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

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

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

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

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

Glutamylated tubulin: diversity of expression and distribution of isoforms

Glutamylation of alpha and beta tubulin isotypes is a major posttranslational modification giving rise to diversified isoforms occurring mainly in neurotubules, centrioles, and axonemes. Monoglutamylated tubulin isoforms can be differentially recognized by two mAbs, B3 and GT335, which both recognize either polyglutamylated isoforms. In the present study, immunoelectron microscopy and immunofluorescence analyses were performed with these two mAbs to determine the expression and distribution of glutamylated tubulin isoforms in selected biological models whose tubulin isotypes are characterized. In mouse spermatozoa, microtubules of the flagellum contain polyglutamylated isoforms except in the tip where only monoglutamylated isoforms are detected. In spermatids, only a subset of manchette microtubules contain monoglutamylated tubulin isoforms. Cytoplasmic microtubules of Sertoli cells are monoglutamylated. Mitotic and meiotic spindles of germ cells are monoglutamylated whereas the HeLa cell mitotic spindle is polyglutamylated. Three models of axonemes are demonstrated as a function of the degree and extent of tubulin glutamylation. In lung ciliated cells, axonemes are uniformly polyglutamylated. In sea urchin sperm and Chlamydomonas, flagellar microtubules are polyglutamylated in their proximal part and monoglutamylated in their distal part. In Paramecium, cilia are bi- or monoglutamylated only at their base. In all cells, centrioles or basal bodies are polyglutamylated. These new data emphasize the importance of glutamylation in all types of microtubules and strengthen the hypothesis of its role in the regulation of the intracellular traffic and flagellar motility.     

Incorporation of 3-nitrotyrosine into the C-terminus of alpha-tubulin is reversible and not detrimental to dividing cells.

The C-terminus of the alpha-chain of tubulin is subject to reversible incorporation of tyrosine by tubulin tyrosine ligase and removal by tubulin carboxypeptidase. Thus, microtubules rich in either tyrosinated or detyrosinated tubulin can coexist in the cell. Substitution of the terminal tyrosine by 3-nitrotyrosine has been claimed to cause microtubule dysfunction and consequent injury of epithelial lung carcinoma A549 cells. Nitrotyrosine is formed in cells by nitration of tyrosine by nitric oxide-derived species. We studied properties of tubulin modified by in vitro nitrotyrosination at the C-terminus of the alpha-subunit, and the consequences for cell functioning. Nitrotyrosinated tubulin was a good substrate of tubulin carboxypeptidase, and showed a similar capability to assemble into microtubules in vitro to that of tyrosinated tubulin. Tubulin of C6 cells cultured in F12K medium in the presence of 500 micro m nitrotyrosine became fully nitrotyrosinated. This nitrotyrosination was shown to be reversible. No changes in morphology, proliferation, or viability were observed during cycles of nitrotyrosination, denitrotyrosination, and re-nitrotyrosination. Similar results were obtained with CHO, COS-7, HeLa, NIH-3T3, NIH-3T3(TTL-), and A549 cells. C6 and A549 cells were subjected to several passages during 45 days or more in the continuous presence of 500 micro m nitrotyrosine without noticeable alteration of morphology, viability, or proliferation. The microtubular networks visualized by immunofluorescence with antibodies to nitrotyrosinated and total tubulin were identical. Furthermore, nitrotyrosination of tubulin in COS cells did not alter the association of tubulin carboxypeptidase with microtubules. Our results demonstrate that substitution of C-terminal tyrosine by 3-nitrotyrosine has no detrimental effect on dividing cells.     

CAPABILITY OF TUBULIN AND MICROTUBULES TO INCORPORATE AND TO RELEASE TYROSINE AND PHENYLALANINE AND THE EFFECT OF THE INCORPORATION OF THESE AMINO ACIDS ON TUBULIN ASSEMBLY

Abstract— Incorporation of [¹⁴C]tyrosine into the C-terminal position of α-tubulin of rat brain cytosol was 10-fold higher for non-assembled than for assembled tubulin. The incorporation into tubulin from disassembled microtubules was higher than into non-assembled tubulin; therefore, the low incorporation into microtubules was not due to a lower acceptor capacity of their tubulin constituent.
[¹⁴C]Tyrosine was released from assembled and non-assembled [¹⁴C]tyrosinated tubulin by the action of an endogenous carboxypeptidase. Release from non-assembled tubulin was shown by incubating a tubulinyl-[¹⁴C]tyrosine preparation in the presence of CaCl₂ at a concentration that abolished microtubule formation. Release from microtubules was inferred from the observation that the percentages of [¹⁴C]tyrosine released and the decrease of the specific radioactivity of the recovered microtubules were practically identical and did not change after a 10-fold dilution of the incubated microtubules.
[³H]Phenylalanine was released from a preparation of tubulinyl-[³H]phenylalanine also by an enzymatic activity.
The capacity of a tubulin preparation to incorporate tyrosine was increased 43% by pre-treatment with endogenous carboxypeptidase.
Tubulin tyrosinated in vitro was assembled to the same extent as native tubulin. After a mixture of tubulinyl-[¹⁴C]tyrosine and tubulinyl-[³H]phenylalanine was partially assembled, the ratio of ¹⁴C/³H found in the microtubules was the same as in the non-assembled tubulin fraction.     

The influence of the herbicide trifluralin on flagellar regeneration in Chlamydomonas

The mode of action of trifluralin is known to include disruption of cell division in root meristems by causing an absence of spindle microtubules. It has also been shown that trifluralin binds to tubulin isolated and purified from Chlamydomonas flagella. In this paper the kinetics of in vivo flagellar regeneration was used as a model to determine the influence of trifluralin on tubulin assembly. Chlamydomonas cells were grown in synchronous culture using a 12 h light-dark cycle. At 3 h into the light cycle the cells were subjected to shear force to induce flagellar abortion. Flagellar regeneration, in the presence of varying concentrations of trifluralin, was observed by Nomarski interference microscopy. After 1.5 h, trifluralin concentrations below 0.1 μM had not affected the regeneration rate, while concentrations above 5 μM prevented the onset of regeneration. As the concentration between 0.1 and 5 μM was increased, the final length of all flagella decreased. Using combinations of cycloheximide and trifluralin it was determined that trifluralin did not influence tubulin synthesis, and removing trifluralin only restored 50% of the regeneration capacity present at the beginning of treatment. By comparing groups of cells where the tubulin pool was depleted or present, it was found that trifluralin prevented assembly rather than causing a breakdown of previously assembled flagella. The research reported here supports the theory that the mechanism of action of trifluralin is an interaction of trifluralin and tubulin in a way that prevents tubulin assembly into spindle microtubules.     

Tyrosination of microtubules and non-assembled tubulin in brain slices

Brain slices were used to examine comparatively the incorporation of [14C]tyrosine into the C terminus of alpha-tubulin of the microtubule and non-assembled tubulin pools. We found that the incorporation of [14C]tyrosine from 5 min up to 60 min of incubation was higher in microtubules than in non-assembled tubulin. The possibility that this result was due to the activity of tubulin carboxypeptidase or tubulin:tyrosine ligase during the in vitro isolation of tubulin was discarded. We also found that tubulin:tyrosine ligase was mainly associated with microtubules when brain slices were homogenized under microtubule-preserving conditions. Conversely the enzyme behaved as a soluble entity when homogenization was performed under conditions that do not preserve microtubules. In addition, soluble tubulin:tyrosine ligase did not become sedimentable when in vitro conditions were changed to induce the formation of microtubules. The results presented in this work indicate the possibility that, in vivo, microtubules and not tubulin dimers are the major substrate for tubulin:tyrosine ligase. This is in contrast with previous findings from in vitro experiments, which showed a preference of the ligase for non-assembled tubulin.     

Acetylated alpha-tubulin in Physarum: immunological characterization of the isotype and its usage in particular microtubular organelles

We have used monoclonal antibodies specific for acetylated and unacetylated alpha-tubulin to characterize the acetylated alpha-tubulin isotype of Physarum polycephalum, its expression in the life cycle, and its localization in particular microtubular organelles. We have used the monoclonal antibody 6-11B-1 (Piperno, G., and M. T. Fuller, 1985, J. Cell Biol., 101:2085-2094) as the probe for acetylated alpha-tubulin and have provided a biochemical characterization of the monoclonal antibody KMP-1 as a probe for unacetylated tubulin in Physarum. Concomitant use of these two probes has allowed us to characterize the acetylated alpha-tubulin of Physarum as the alpha 3 isotype. We have detected this acetylated alpha 3 tubulin isotype in both the flagellate and in the myxameba, but not in the plasmodium. In the flagellate, acetylated tubulin is present in both the flagellar axonemes and in an extensive array of cytoplasmic microtubules. The extensive arrangement of acetylated cytoplasmic microtubules and the flagellar axonemes are elaborated during the myxameba-flagellate transformation. In the myxameba, acetylated tubulin is not present in the cytoplasmic microtubules nor in the mitotic spindle microtubules, but is associated with the two centrioles of this cell. These findings, taken together with the apparent absence of acetylated alpha-tubulin in the ephemeral microtubules of the plasmodium suggest a natural correspondence between the presence of acetylated alpha-tubulin and microtubule organelles that are intrinsically stable or cross-linked.     

Distinct localization and cell cycle dependence of COOH terminally tyrosinolated alpha-tubulin in the microtubules of Trypanosoma brucei brucei

alpha-Tubulin can be posttranslationally modified in that its COOH-terminal amino acid residue, tyrosine, can be selectively removed and replaced again. This reaction cycle involves two enzymes, tubulin carboxypeptidase and tubulin tyrosine ligase. The functional significance of this unusual modification is unclear. The present study demonstrates that posttranslational tyrosinolation of alpha-tubulin does occur in the parasitic hemoflagellate Trypanosoma brucei brucei and that posttranslational tyrosinolation can be detected in both alpha-tubulin isoforms found in this organism. Trypanosomes contain a number of microtubular structures: the flagellar axoneme; the subpellicular layer of singlet microtubules which are closely associated with the cell membrane; the basal bodies; and a cytoplasmic pool of soluble tubulin. Tyrosinolated alpha-tubulin is present in all these populations. However, immunofluorescence studies demonstrate a distinct localization of tyrosinolated alpha-tubulin within individual microtubules and organelles. This localization is subject to a temporal modulation that correlates strongly with progress of a cell through the cell cycle. Our results indicate that the presence of tyrosinolated alpha-tubulin is a marker for newly formed microtubules.     

Monoclonal antibodies specific for an acetylated form of alpha-tubulin recognize the antigen in cilia and flagella from a variety of organisms

Seven monoclonal antibodies raised against tubulin from the axonemes of sea urchin sperm flagella recognize an acetylated form of alpha-tubulin present in the axoneme of a variety of organisms. The antigen was not detected among soluble, cytoplasmic alpha-tubulin isoforms from a variety of cells. The specificity of the antibodies was determined by in vitro acetylation of sea urchin and Chlamydomonas cytoplasmic tubulins in crude extracts. Of all the acetylated polypeptides in the extracts, only alpha-tubulin became antigenic. Among Chlamydomonas tubulin isoforms, the antibodies recognize only the axonemal alpha-tubulin isoform acetylated in vivo on the epsilon-amino group of lysine(s) (L'Hernault, S.W., and J.L. Rosenbaum, 1985, Biochemistry, 24:473-478). The antibodies do not recognize unmodified axonemal alpha-tubulin, unassembled alpha-tubulin present in a flagellar matrix-plus-membrane fraction, or soluble, cytoplasmic alpha-tubulin from Chlamydomonas cell bodies. The antigen was found in protein fractions that contained axonemal microtubules from a variety of sources, including cilia from sea urchin blastulae and Tetrahymena, sperm and testis from Drosophila, and human sperm. In contrast, the antigen was not detected in preparations of soluble, cytoplasmic tubulin, which would not have contained tubulin from stable microtubule arrays such as centrioles, from unfertilized sea urchin eggs, Drosophila embryos, and HeLa cells. Although the acetylated alpha-tubulin recognized by the antibodies is present in axonemes from a variety of sources and may be necessary for axoneme formation, it is not found exclusively in any one subset of morphologically distinct axonemal microtubules. The antigen was found in similar proportions in fractions from sea urchin sperm axonemes enriched for central pair or outer doublet B or outer doublet A microtubules. Therefore the acetylation of alpha-tubulin does not provide the mechanism that specifies the structure of any one class of axonemal microtubules. Preliminary evidence indicates that acetylated alpha-tubulin is not restricted to the axoneme. The antibodies described in this report may allow us to deduce the role of tubulin acetylation in the structure and function of microtubules in vivo.     

Characterization of putative cytoskeletal proteins from a trypanosomatid and their comparative binding to microtubules and soluble tubulin

The corset of microtubules which encloses the cell body of Crithidia fasiculata displays cross-links joining tubules to each other and to plasma membrane. Two proteins, designated COP-33 and COP-61 on the basis of their subunit Mr values, have been considered putative components of this apparatus because of their abundance in isolated cytoskeleton and their ability to cross-link brain microtubules in vitro. The oligomeric structures of the native proteins have now been characterized, and they have been shown to be basic, rather symmetrical, and to require detergent for solubilization. Using monospecific antibodies, enzyme-linked immunoassays of subcellular fractions have shown that each is 5-fold enriched in the microtubule plasma membrane fraction and absent from flagellar and some internal membranes. The binding of each to soluble tubulin and to microtubules has been systematically studied and compared with that of two noncytoskeletal protein ligands (glycolytic enzymes). The observed positive cooperatively was unexpected for binding of these large ligands to microtubules. In each case the maximum number of mol of ligand bound per mol of tubulin (0.5-1.0) was identical whether the latter was dissociated or assembled and so were the dissociation constants (1.3-6.0 x 10(-7) M) for three of the ligand proteins.     

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

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

Tubulin, but not microtubules, is the substrate for tubulin:tyrosine ligase in mature avian erythrocytes

Chicken erythrocytes, which contain a marginal band of microtubules, were used to study the influence of the aggregation state of tubulin on the post-translational incorporation of tyrosine into the alpha-tubulin subunit. We found that the incorporation of [14C]tyrosine occurs almost exclusively into the nonassembled tubulin pool. The marginal band was practically not labeled. The low incorporation into microtubules was not due to the lack of tubulin with acceptor capacity since after cold-induced disassembly, an additional amount of [14C]tyrosine could be incorporated. 14C-Tyrosinated tubulin of the nonassembled pool could not be incorporated into microtubules of the marginal band after prolonged incubation at 37 degrees C or when the marginal band was regenerated after cold-induced depolymerization. In erythrocytes, tubulin:tyrosine ligase behaved as a soluble entity when the cells were lysed under microtubule-preserving conditions.     

Reassembly of flagellar B (alpha beta) tubulin into singlet microtubules: consequences for cytoplasmic microtubule structure and assembly

B(alpha beta) tubulin was obtained from a homogeneous class of microtubules, the incomplete B subfiber of sea urchin sperm flagellar doublet microtubules, by thermal fractionation. The thermally derived soluble B tubulin fraction (100, 000 g-h) repolymerizes in vitro, yielding microtubule-like structures. The microtubule-associated protein (MAP) composition and certain assembly parameters of thermally derived B tubulin are different from those reported for sonication- derived flageller tubulin and purified vertebrate tubulin. The "microtubules" reassembled from thermally prepared B tubulin are composed of 12-15 protofilaments (73% possess 14 protofilaments). A certain number possess a single "adlumenal component" applied to their inside walls, regardless of the number of protofilaments. Following the first cycle of polymerization, 81% of the B tubulin and essentially 100% of the MAPs remain cold insoluble. Evidence suggests that B tubulin assembles faithfully into a B lattice, creating a j seam between two protofilaments that are laterally bonded in a A-lattice configuration. The significance of these seams is discussed in relation to the mechanism of microtubule assembly, the stability of observed ribbons of protofilaments, and the three-dimensional organization of microtubule-associated components.     

Tubulin expression in trypanosomes

Microtubules in trypanosomes are the main component of the flagellar axoneme and of the subpellicular microtubule corset, whose relative positions determine the morphology of each cell stage of the life cycle of these parasites. Microtubules are polymers of tubulin, a protein dimer of two 55-kDa subunits, alpha- and beta-tubulin; in Trypanosoma brucei, the tubulin-coding sequences are clustered in a 40-kb fragment of tandemly repeated alpha- and beta-tubulin genes separated by a 170-bp intergenic zone. This cluster is transcribed in a unique RNA which is rapidly processed into mature mRNAs carrying the 5' 35-nucleotide leader sequence found in all trypanosome mRNAs. Although no heterogeneity has been found at the gene level, tubulin can be post-translationally modified in 2 ways: the C-terminal tyrosine of alpha-tubulin can be selectively cleaved and added again with 2 enzymes, tubulin carboxypeptidase and tubulin-tyrosine ligase; alpha-tubulin can also be acetylated on a lysine residue. Some molecular domains of tubulin are restricted to subpopulations of microtubules; for instance, the beta-tubulin form defined by the monoclonal antibody 1B41 is sequestered into a part of the subpellicular cytoskeleton limited to the flagellar adhesion zone, which might correspond to the group of 4 microtubules associated with a cisterna of the endoplasmic reticulum, forming the so-called "subpellicular microtubule quartet" (SFMQ). The early assembly of this zone in each daughter cell during the cell division of T. brucei, together with the alterations undergone by the domain defined by the monoclonal antitubulin 24E3 during the differentiation of Trypanosoma cruzi, suggest that specific tubulin forms are responsible for dynamic properties of SFMQ possibly involved in trypanosome morphogenesis.     

An Apparent Paradox in the Occurrence, and the In Vivo Turnover, of C-Terminal Tyrosine in Membrane-Bound Tubulin of Brain

: Tubulin tyrosine ligase catalyzes the reversible addition of tyrosine to the C-terminus of tubulin α chains. By using ligase and carboxypeptidase A in conjunction, we have previously shown that brain cytoplasmic tubulin exists in three forms: 15–40% already has C-terminal tyrosine, another 10-30% can accept additional tyrosine, and about one-half is an uncharacterized species which is not a ligase substrate. A membrane-bound fraction of brain tubulin, purified by vinblastine precipitation from a detergent extract, has been found to differ by the complete absence of preexisting tyrosine. The membrane fraction from which tubulin was extracted also contained masked forms of both ligase and a distinct detyrosylating enzyme, which can be released by detergent extraction. The turnover of α-chain C-terminal tyrosine in vivo was studied by incubating brain mince with labeled tyrosine, or injecting it intracerebrally, under conditions where protein synthesis was inhibited. Tyrosine appeared to turn over to about the same extent in membrane-bound, as in soluble, tubulin. This apparently paradoxical result was not due to ATPase in the membrane fraction, which might have allowed ligase-catalyzed exchange between free and fixed tyrosine. Authentic [¹⁴C]tyrosylated tubulin added to the brain membrane fraction was not detyrosylated or subject to endoprotease digestion during subsequent procedures to isolate tubulin. The unexpected finding that tubulin tyrosylated at the C-terminal in vivo appears to be in the “non-substrate” fraction points toward a possible resolution of the paradox.     

Localization of a highly divergent mammalian testicular alpha tubulin that is not detectable in brain.

Sequence analysis of a mouse testicular alpha-tubulin partial cDNA, pRD alpha TT1, reveals an isotype that differs from both the somatic and the predominant testicular alpha tubulins at approximately 30% of the 212 amino acid residues determined. Although this mouse testicular cDNA retains the highly conserved sequence, Glu-Gly-Glu-Glu, found in the carboxyl termini of many alpha tubulins, the protein extends substantially beyond this sequence and does not terminate with a C-terminal tyrosine. Using rabbit antiserum prepared to a novel synthetic peptide predicted from this mouse testis alpha-tubulin cDNA, we have have detected by immunoblot and indirect immunofluorescence an antigenic epitope present in testicular alpha tubulin that is not detectable in brain alpha tubulins. We find that the antiserum specifically binds to the manchettes and meiotic spindles of the mouse testis but not with neural fibers or tubulin extracts of the adult mouse brain. These results demonstrate that at least one of the multiple alpha-tubulin isotypes of the mammalian testis is expressed and used in male germ cells but not in the brain.