Microtubule-associated proteins

The association of glycosomal enzymes and microtubules: a physiological phenomenon or an experimental artifact?

Subpellicular microtubules isolated from Trypanosoma brucei parasites were fractionated on a phosphocellulose column, and the trypanosomal p52 microtubule-associated protein was eluted along with two other proteins of 41 and 36 kDa. These proteins were found to be the glycosomal enzymes aldolase (41 kDa) and glyceraldehyde-3-phosphate dehydrogenase (GAPDH, 36 kDa) by enzyme activity, antibody cross-reaction, and N-terminal sequencing. These enzymes were coprecipitated with tubulin in the presence of taxol, and aldolase had the capacity to polymerize tubulin and crosslink microtubules. Immunolocalization of anti-aldolase and anti-GAPDH antibodies did not show an interaction between these enzymes and the subpellicular microtubules. The question whether the copurification of aldolase and the subpellicular microtubules could reflect a physiological phenomenon or may be an experimental artifact is discussed.

Turnover of cytoskeletal proteins in vivo

The turnover of the microtubule-associated proteins 1B and 2 (MAP1B and MAP2), tubulin, high molecular weight neurofilament protein (NF-H), and spectrin were studied by in vivo labeling. Radiolabeled [35S]methionine was injected intracranially to 10-day-old rats and the rate of turnover was measured for total and specific brain proteins. The turnover of total brain proteins was biphasic and consisted of a fast and a slow component with half lives of 6.5 +/- 0.4 and 14.2 +/- 0.7 (mean +/- S.E.M.) days, respectively. The turnover of individual cytoskeletal brain proteins was also biphasic. The fast decay rates of MAP1B, MAP2, tubulin and spectrin were 5.8 +/- 0.7, 6.9 +/- 0.3, 4.8 +/- 0.5 and 4.9 +/- 0.4 days, respectively, while the slow decay rates of these proteins were 12.0 +/- 1.3, 12.4 +/- 1.7, 15.0 +/- 0.5 and 16.0 +/- 1.2 days, respectively. In addition, the Triton X-100 insoluble fraction of MAP1B, tubulin, spectrin and NF-H showed monophasic decay rates of 29.0 +/- 2.3, 15.0 +/- 1.4, 16.0 +/- 0.9 and 18.5 +/- 1.5 days, respectively, which were similar to their slow decay rates in whole brain homogenates, suggesting that incorporation of these proteins into the cytoskeletal lattice increases their stability.

Difference in distribution of microtubule-associated proteins 5a and 5b during the development of cerebral cortex and corpus callosum in cats: dependence on phosphorylation

MAP5, a microtubule-associated protein characteristic of differentiating neurons, was studied in the developing visual cortex and corpus callosum of the cat. In juvenile cortical tissue, during the first month after birth, MAP5 is present as a protein doublet of molecular weights of 320 and 300 kDa, defined as MAP5a and MAP5b, respectively. MAP5a is the phosphorylated form. MAP5a decreases two weeks after birth and is no longer detectable at the beginning of the second postnatal month; MAP5b also decreases after the second postnatal week but more slowly and it is still present in the adult. In the corpus callosum only MAP5a is present between birth and the end of the first postnatal month. Afterwards only MAP5b is present but decreases in concentration more than 3-fold towards adulthood. Our immunocytochemical studies show MAP5 in somata, dendrites and axonal processes of cortical neurons. In adult tissue it is very prominent in pyramidal cells of layer V. In the corpus callosum MAP5 is present in axons at all ages. There is strong evidence that MAP5a is located in axons while MAP5b seems restricted to somata and dendrites until P28, but is found in callosal axons from P39 onwards. Biochemical experiments indicate that the state of phosphorylation of MAP5 influences its association with structural components. After high speed centrifugation of early postnatal brain tissue, MAP5a remains with pellet fractions while most MAP5b is soluble. In conclusion, phosphorylation of MAP5 may regulate (1) its intracellular distribution within axons and dendrites, and (2) its ability to interact with other subcellular components.

Interaction of the two structural domains of calmodulin with mature and immature rat brain microtubules

The inhibitory effect of calmodulin on the assembly of mature and immature rat brain microtubules was compared with that of the two major structural domains of this protein, the COOH-terminal fragment (amino acids 78-148) and the NH2-terminal fragment (amino acids 1-77), to determine the calmodulin structural domain responsible for the inhibitory effect on microtubule assembly. Microtubules prepared during the early stages of brain development, i.e., during intensive neurite outgrowth, are more sensitive to inhibition by the Ca2(+)-calmodulin complex than those obtained from adult brain. Significant inhibition of immature microtubule assembly was observed with both fragments in the absence of Ca2+, but the effects were more important when Ca2+ was present. With adult brain microtubules, the two fragments remained without effect on assembly in the absence of Ca2+, whereas some inhibition was seen in its presence but only with the COOH-terminal polypeptide. Under all these conditions, the COOH-terminal fragment was always more active than the NH2-terminal fragment on microtubule polymerization, albeit to a lesser extent than native calmodulin.

Transiently catecholaminergic (TC) cells in the bowel of the fetal rat: precursors of noncatecholaminergic enteric neurons

Experiments were done to study the fate of transient catecholaminergic (TC) cells that develop in the rodent gut during ontogeny. When they are first detected, at Day E11 in rats, TC cells are distributed along the vagal pathway, in advance of the descending fibers of the vagus nerves, and in the foregut. The early TC cells coexpress the immunoreactivities of several neural markers, including 150-kDa neurofilament protein, peripherin, microtubule associated protein (MAP) 5, and growth-associated protein (GAP)-43, with those of the catecholamine biosynthetic enzymes tyrosine hydroxylase (TH) and dopamine-beta-hydroxylase (DBH). All cells in the fetal rat bowel at Day E11 that express neural markers also express TH immunoreactivity. The primitive TC cells also express the immunoreactivities of neural cell adhesion molecule (N-CAM), neuropeptide Y (NPY), and nerve growth factor (NGF) receptor (and NGF receptor mRNA). By Day E12 TC cells are found along the vagal pathway and throughout the entire preumbilical bowel. At this age TC cells acquire additional characteristics, including MAP 2 and synaptophysin immunoreactivities and acetylcholinesterase activity, which indicate that they continue to mature as neurons. In addition, TC cells of the rat are immunostained at Day E12 by the NC-1 monoclonal antibody, which in rats labels multiple cell types including migrating cells of neural crest origin. Despite their neural properties, at least some TC cells divide and therefore are neural precursors and not terminally differentiated neurons. At Day E10 TH mRNA-containing cells were not detected by in situ hybridization; however, by Day E11 TH mRNA was detected in sympathetic ganglia and in scattered cells in the mesenchyme of the foregut and vagal pathway. At this age, the number of enteric and vagal cells containing TH mRNA is about 30% less than the number of cells containing TH immunoreactivity in adjacent sections. The ratio of TH mRNA-containing cells to TH-immunoreactive vagal and enteric cells is even less at Day E12, especially in more caudal regions of the preumbilical bowel. A similar decline in the ratio of TH mRNA-containing to TH-immunoreactive cells was not observed in sympathetic ganglia. After Day E12 TH mRNA cannot be detected in enteric or vagal cells by in situ hybridization; nevertheless, TH immunoreactivity continues to be present through Day E14. DBH, NPY, and NGF receptor immunoreactivities are expressed by TH-immunoreactive transitional cells in the fetal rat gut after TH mRNA is no longer detectable.(ABSTRACT TRUNCATED AT 400 WORDS)

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

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

Peptides corresponding to the second repeated sequence in MAP-2 inhibit binding of microtubule-associated proteins to microtubules

Bovine brain high molecular weight microtubule-associated proteins (MAPs) can be displaced from assembled tubules by peptides corresponding to the second of three nonidentical repeated sequences in mouse MAP-2. The octadecapeptide m2 (VTSKCGSLKNIRHRPGGG) can release MAP-1b from MAP-containing microtubules, and the extended second-sequence peptide m2' (VTSKCGSLKNIRHRPGGGRVK) displaces MAP-1a and MAP-1b as well as MAP-2a and MAP-2b. Peptides m2 and m2' stimulate tubulin polymerization in the absence of MAPs or microtubule-stabilizing agents, and m2' acts as a competitive inhibitor of radiolabeled MAP-2 binding. The dissociation constant for MAP-2 binding to taxol-stabilized tubules was 3.4 microM in the absence of m2' and 14 microM in the presence of 1.5 mM of the m2' peptide. We estimate that the inhibition constant for peptide m2' is about 0.5 mM, about 100 times lower than for the Km of MAP-2. These observations suggest that the second repeated sequence in MAP-2 may represent an important recognition site for MAP binding to microtubules and that other structural features within MAP-2 may reinforce the strength of MAP-microtubule interactions.

Activation of NMDA receptors induces rapid dephosphorylation of the cytoskeletal protein MAP2

Hippocampal slices were preincubated with 32P-orthophosphate and used to study the effect of glutamate analogs on protein phosphorylation. NMDA induced a rapid, 70% decrease in the phosphorylation of the microtubule-associated protein MAP2, with no change in the total amount of MAP2. Both competitive and noncompetitive NMDA antagonists blocked the effect of NMDA, but a glutamate antagonist acting at non-NMDA receptors did not. Kainate and quisqualate were less potent than NMDA in stimulating dephosphorylation of MAP2. Other forebrain regions (necortex, striatum, and olfactory bulb) also showed dephosphorylation of MAP2 in response to NMDA. These and other results suggest that NMDA receptor activation induces the dephosphorylation of MAP2 by stimulating a protein phosphatase, possibly the calcium/calmodulin-dependent protein phosphatase calcineurin. Moreover, they indicate that alteration in the properties of a microtubule-associated protein may account for some of the effects of glutamate on postsynaptic neurons.

Characterization and intracellular distribution of microtubule-associated protein 2 in differentiating human neuroblastoma cells

The use of a panel of monoclonal antibodies (mAbs) directed against different determinants of microtubule-associated protein 2 (MAP2) enabled us to identify two distinct high-molecular-mass MAP2 species (270 and 250 kDa) and a substantial amount of MAP2c (70 kDa) in human neuroblastoma cells. The 250-kDa MAP2 species appears to be confined to the human neuroblastoma cells and was not observed in microtubules (MTs) from bovine and rat brain, mouse neuroblastoma, or MTs from human cerebellum. A new overlay method was developed, which demonstrates binding of tubulin to human neuroblastoma high-molecular-mass MAP2 by exposing nitrocellulose-bound MT proteins under polymerization conditions to tubulin. Bound tubulin was detected with a mAb directed against beta-tubulin. The binding of tubulin to MAP2 could be abolished by a peptide homologous to positions 426-445 of the C-terminal region of beta-tubulin. Immunological cross-reactivity with several mAbs directed against bovine brain MAP2, taxol-promoted coassembly into MTs, and immunocytochemical visualization within cells were further criteria utilized to characterize these proteins as true MAPs. Indirect immunofluorescence with anti-MAP2 and anti-beta-tubulin mAbs demonstrated that there is a change in the spatial organization of MTs during induced cell differentiation, as indicated by the appearance of MT bundles and the redistribution of MAP2.

Microtubule associated protein (MAP1B) is present in cultured oligodendrocytes and co-localizes with tubulin

Differentiation of oligodendrocytes is accompanied by the extension of processes and the assembly of the myelin membrane. It is likely that the cytoskeleton plays an important role in this process in terms of changes in cell shape, transport of myelin components, and organization of the myelin membrane. Oligodendrocytes contain microtubules (MT) which associate with other components of the cytoskeleton, and microtubule associated proteins (MAPs) may mediate some of these interactions. In this study we have shown the presence of MAP1B in oligodendrocytes grown in primary glial cultures by double-label immunofluorescence using antibodies to galactocerebroside (GC) and MAP1B. The staining of the cultures showed that GC-positive oligodendrocytes were also stained with MAP1B antibodies. However, MAP1B stain was limited to cell bodies and processes, whereas GC stain was also seen in flattened membrane sheets and punctate staining in processes. MAP1B staining was also compared with that of myelin proteolipid (PLP), myelin basic protein (MBP) and beta-tubulin in secondary glial cultures that were enriched for oligodendrocytes. The results showed a typical staining of cell bodies and membranous profiles using PLP antibodies, and the staining of cell bodies and flattened regions of membranous sheets by MBP antibodies. In contrast, both polyclonal and monoclonal antibodies to MAP1B showed a uniform diffuse staining of cell bodies, major processes, and fine interconnected processes. Double-labeling of the cells showed that MAP1B was co-localized with tubulin, but was not present in glial fibrillary acidic protein (GFAP)-positive astrocytes. Western and Northern blot analyses of primary glial cultures showed that MAP1B had a molecular mass of 320 kDa and a mRNA of 10 kb. These values are identical to those previously reported for brain MAP1B (Safaei and Fischer, 1989) and demonstrate the presence of MAP1B in oligodendrocytes.

What's new in cytoskeleton-organelle interactions? Relationship between microtubules and the Golgi-apparatus

Several biochemical processes in animal cells are confined to distinct membrane-bounded compartments. Segregation of specialized functions into different compartments necessitates intercompartment transfer of material. This transfer is mediated by carrier vesicles which, by precise sorting and transport mechanisms, are targetted to their correct destinations. Microtubules, major constituents of the cytoskeleton, are involved both in these intracellular transport processes and in the spatial organization of cytoplasmic organelles. Accumulating evidence suggests that various classes of membranous organelles interact with microtubules. The positioning of several organelles, including the Golgi apparatus and lysosomes, depends on an intact interphase microtubule network. Furthermore, it has been shown that many of these organelles, for example Golgi elements, tubules of the endoplasmic reticulum, exocytic or secretory vesicles and lysosomes move along microtubules. In this article we will discuss the role of microtubules in the movement and positioning of elements of the Golgi complex. The first part will summarize structural and functional aspects of microtubules and the Golgi apparatus and review evidence for their interaction. In the second part, the possible physiological relevance of this interaction will be discussed and correlated with other membrane-microtubule interactions. Finally, emerging questions and perspectives in this field are outlined.

A monoclonal antibody to a mitotic microtubule-associated protein blocks mitotic progression

A monoclonal antibody raised against mitotic spindles isolated from CHO cells ([CHO1], Sellitto, C., and R. Kuriyama. 1988. J. Cell Biol. 106:431-439) identifies an epitope that resides on polypeptides of 95 and 105 kD and is localized in the spindles of diverse organisms. The antigen is distributed throughout the spindle at metaphase but becomes concentrated in a progressively narrower zone on either side of the spindle midplane as anaphase progresses. Microinjection of CHO1, either as an ascites fluid or as purified IgM, results in mitotic inhibition in a stage-specific and dose-dependent manner. Parallel control injections with nonimmune IgMs do not yield significant mitotic inhibition. Immunofluorescence analysis of injected cells reveals that those which complete mitosis display normal localization of CHO1, whereas arrested cells show no specific localization of the CHO1 antigen within the spindle. Immunoelectron microscopic images of such arrested cells indicate aberrant microtubule organization. The CHO1 antigen in HeLa cell extracts copurifies with taxol-stabilized microtubules. Neither of the polypeptides bearing the antigen is extracted from microtubules by ATP or GTP, but both are approximately 60% extracted with 0.5 M NaCl. Sucrose gradient analysis reveals that the antigens sediment at approximately 11S. The CHO 1 antigen appears to be a novel mitotic MAP whose proper distribution within the spindle is required for mitosis. The properties of the antigen(s) suggest that the corresponding protein(s) are part of the mechanism that holds the antiparallel microtubules of the two interdigitating half spindles together during anaphase.

Changes in microtubule-associated protein MAP1B phosphorylation during rat brain development

Microtubule-associated protein MAP1B from neonatal rat brain was separated on sodium dodecyl sulfate-containing polyacrylamide gels into two isoforms (high and low MAP1B), both of which were recognized by a panel of monoclonal and polyclonal antibodies against MAP1B. In addition, SMI31, a monoclonal antibody directed against phosphorylated epitopes of the neurofilament proteins, showed phosphatase-sensitive reactivity against the high isoform of MAP1B. The antigenic relationship between the phosphorylated isoform of MAP1B and neurofilaments was confirmed by the reactivity of SMI31 with the immunoprecipitated MAP1B protein. After dephosphorylation of MAP1B with alkaline phosphatase, the higher-molecular-weight isoform of MAP1B was no longer detectable with phosphate-insensitive anti-MAP1B antibodies, whereas there was a significant increase in the immunoreactivity of the lower-molecular-weight MAP1B isoform. These data suggest that the structural microheterogeneity of MAP1B is due to differences in phosphorylation. The two isoforms were present in all brain regions of the young rat. During brain development, the general decrease in MAP1B levels was accompanied by changes in the relative amount of the two isoforms. In particular, the phosphorylated isoform of MAP1B decreased dramatically to almost undetectable levels in adult brain. This conclusion was further supported by immunoblotting analysis that showed the disappearance of phosphorylated epitopes of MAP1B early during brain development. In addition, dephosphorylation experiments demonstrated the phosphatase sensitivity of the phosphorylated isoform throughout development.

In vitro depolymerization dynamics of brain endogenous microtubules

A subcellular fraction containing fragments of endogenous microtubules stabilized in 50% glycerol was separated by diferential centrifugation of rat brain homogenates. The pellets were suspended in glycerol-deficient media, and microtubule depolymerization was monitored by measuring the decrease of sedimentable tubulin. Concomitantly, the number and size of microtubules in the suspensions were followed via electron microscopy. Depolymerization was accompanied by a proportional decrease in the number of microtubules, whereas the average size did not change significantly. After approximately 20 min, a subpopulation of microtubules became stable and did not suffer further depolymerization. These results indicate that upon dilution some microtubules completely depolymerize, whereas others remain stable in the glycerol-deficient medium. The degree of depolymerization depended on both the volume of the resuspension media and on the final glycerol concentration. The results suggest that the depolymerization of the remaining microtubules is prevented by stabilizing factors released from depolymerizing microtubules. Tubulin dimers are not one of these factors, since depolymerization was not altered by the addition of colchicine or by changing the concentration of free tubulin in the medium.

Functional expression of the Candida albicans beta-tubulin gene in Saccharomyces cerevisiae

Expression of the beta-tubulin-encoding gene (TUB2) of Candida albicans has been examined in Saccharomyces cerevisiae. Overexpression of the TUB2 gene of C. albicans, as well as that of S. cerevisiae, was found to be lethal. Chromosomal integration of the C. albicans TUB2 gene into a strain in which the native TUB2 gene had been deleted led to functional complementation. The results demonstrate that correct splicing of the two introns present in the C. albicans TUB2 gene occurs in the heterologous host strain containing this gene. Such strains are supersensitive to the tubulin-binding agent benomyl, indicating that the natural resistance of C. albicans to benomyl is not related to the structure of its beta-tubulin.

Identification of a novel nucleotide-sensitive microtubule-binding protein in HeLa cells

A protein of Mr 170,000 (170K protein) has been identified in HeLa cells, using an antiserum raised against HeLa nucleotide-sensitive microtubule-binding proteins. Affinity-purified antibodies specific for this 170K polypeptide were used for its characterization. In vitro sedimentation of the 170K protein with taxol microtubules polymerized from HeLa high-speed supernatant is enhanced in the presence of an ATP depleting system, but unaffected by the non-hydrolyzable ATP analogue AMP-PNP. In addition, it can be eluted from taxol microtubules by ATP or GTP, as well as NaCl. Thus it shows microtubule-binding characteristics distinct from those of the previously described classes of nucleotide-sensitive microtubule-binding proteins, the motor proteins kinesin and cytoplasmic dynein, homologues of which are also present in HeLa cells. The 170K protein sediments on sucrose gradients at approximately 6S, separate from kinesin (9.5S) and cytoplasmic dynein (20S), further indicating that it is not associated with these motor proteins. Immunofluorescence localization of the 170K protein shows a patchy distribution in interphase HeLa cells, often organized into linear arrays that correlate with microtubules. However, not all microtubules are labeled, and there is a significant accumulation of antigen at the peripheral ends of microtubules. In mitotic cells, 170K labeling is found in the spindle, but there is also dotty labeling in the cytoplasm. After depolymerization of microtubules by nocodazole, the staining pattern is also patchy but not organized in linear arrays, suggesting that the protein may be able to associate with other intracellular structures as well as microtubules. In vinblastine-treated cells, there is strong labeling of tubulin paracrystals, and random microtubules induced in vivo by taxol are also labeled by the antibodies. These immunofluorescence labeling patterns are stable to extraction of cells with Triton X-100 before fixation, further suggesting an association of the protein with cytoplasmic structures. In vivo, therefore, the 170K protein appears to be associated with a subset of microtubules at discrete sites. Its in vitro behavior suggests that it belongs to a novel class of nucleotide-sensitive microtubule-binding proteins.

The roles of microtubule-associated proteins in brain morphogenesis: a review

Microtubule-associated proteins (MAPs) are a diverse family of cytoskeletal proteins that copurify with tubulin in vitro. Recently a number of novel approaches have been used to learn more about the functions of MAPs during brain development, including: localization of MAPs and their mRNA in the developing brain, comparisons of MAPs between species to learn potential fundamental characteristics, biochemical analysis of changes in MAPs in process-bearing cell lines, and sequence analysis of MAP cDNAs and cDNA transfection studies. Taken together, these data allow us to assign roles to MAPs which are abundant in the developing brain, and to develop models for future studies. Four MAPs are particularly abundant in the developing brain: MAP1B, the high and low-molecular weight forms of MAP2, and juvenile tau. MAP1B is the only MAP to be found consistently in extending processes in both the developing and adult brain, making it a likely regulator of neurite outgrowth. High-molecular weight MAP2 and tau crosslink microtubules in dendrites and axons, respectively. Low-molecular weight MAP2 may be able to regulate MAP2-mediated crosslinking to make processes more labile during development and in adult brain regions where synaptogenesis is active. Tau-mediated crosslinking may be regulated by temporal regulation of the expression of tau forms with different binding affinities to tubulin. High-molecular weight MAP2 is sequestered into dendrites by the selective transport of its mRNA. This allows rapid and local regulation of MAP2 synthesis.

Selective purification of microtubule-associated proteins 1 and 2 from rat brain using poly(L-aspartic acid)

A rapid and selective purification procedure for microtubule-associated protein (MAP) 1 and MAP 2 has been established. This procedure is based upon the fact that poly(L-aspartic acid) (PLAA) can specifically remove MAP 1 from microtubules polymerized by taxol (Nakamura et al., 1989, J. Biochem. 106, 93-97). MAP 1 released by PLAA was further purified by column chromatography on phosphocellulose and Bio-Gel A-15m. The purified MAP 1 contained MAPs 1A and 1 B. From microtubules devoid of MAP 1, MAP 2, consisting of MAPs 2A and 2B, could also be isolated by exposure to high ionic strength solutions in the presence of taxol without heat treatment. Both MAPs 1 and 2 cosedimented with microtubules consisting of purified tubulin.

Post-translational modification of alpha-tubulin by acetylation and detyrosination in NB2a/d1 neuroblastoma cells

Western blot analyses of total assembled microtubule fractions from NB2a/d1 neuroblastoma cells demonstrated that these cells are capable of post-translationally modifying alpha-tubulin by acetylation and detyrosination. Immunocytochemical analyses of NB2a/d1 cells differentiated with dbcAMP which had been processed under microtubule-stabilizing conditions demonstrated that all forms of alpha-tubulin were present throughout perikarya and neurites. By contrast, extraction of cells with Triton X-100 revealed a regional concentration of acetylated and detyrosinated alpha-tubulin subunits within axonal neurites, detectable in some cells after 3 days of differentiation and in nearly all cells after 7 days. Resistance of neurites to retraction following colchicine-treatment developed at a similar rate; furthermore, colchicine-resistant neurites contained intense acetylated alpha-tubulin immunoreactivity. We conclude that NB2a/d1 cells are capable of acetylating and detyrosinating alpha-tubulin subunits and that selective post-translational modification of alpha-tubulin subunits may be related to neuritic maturation.

Synthesis, axonal transport, and turnover of the high molecular weight microtubule-associated protein MAP 1A in mouse retinal ganglion cells: tubulin and MAP 1A display distinct transport kinetics

Microtubule-associated proteins (MAPs) in neurons establish functional associations with microtubules, sometimes at considerable distances from their site of synthesis. In this study we identified MAP 1A in mouse retinal ganglion cells and characterized for the first time its in vivo dynamics in relation to axonally transported tubulin. A soluble 340-kD polypeptide was strongly radiolabeled in ganglion cells after intravitreal injection of [35S]methionine or [3H]proline. This polypeptide was identified as MAP 1A on the basis of its co-migration on SDS gels with MAP 1A from brain microtubules; its co-assembly with microtubules in the presence of taxol or during cycles of assembly-disassembly; and its cross-reaction with well-characterized antibodies against MAP 1A in immunoblotting and immunoprecipitation assays. Glial cells of the optic nerve synthesized considerably less MAP 1A than neurons. The axoplasmic transport of MAP 1A differed from that of tubulin. Using two separate methods, we observed that MAP 1A advanced along optic axons at a rate of 1.0-1.2 mm/d, a rate typical of the Group IV (SCb) phase of transport, while tubulin moved 0.1-0.2 mm/d, a group V (SCa) transport rate. At least 13% of the newly synthesized MAP 1A entering optic axons was incorporated uniformly along axons into stationary axonal structures. The half-residence time of stationary MAP 1A in axons (55-60 d) was 4.6 times longer than that of MAP 1A moving in Group IV, indicating that at least 44% of the total MAP 1A in axons is stationary. These results demonstrate that cytoskeletal proteins that become functionally associated with each other in axons may be delivered to these sites at different transport rates. Stable associations between axonal constituents moving at different velocities could develop when these elements leave the transport vector and incorporate into the stationary cytoskeleton.

Chromosome instability mutants of Saccharomyces cerevisiae that are defective in microtubule-mediated processes

By using a multiply marked supernumerary chromosome III as an indicator, we isolated mutants of Saccharomyces cerevisiae that display increased rates of chromosome loss. In addition to mutations in the tubulin-encoding TUB genes, we found mutations in the CIN1, CIN2, and CIN4 genes. These genes have been defined independently by mutations causing benomyl supersensitivity and are distinct from other known yeast genes that affect chromosome segregation. Detailed phenotypic characterization of cin mutants revealed several other phenotypes similar to those of tub mutants. Null alleles of these genes caused cold sensitivity for viability. At 11 degrees C, cin mutants arrest at the mitosis stage of their cell cycle because of loss of most microtubule structure. cin1, cin2, and cin4 mutations also cause defects in two other microtubule-mediated processes, nuclear migration and nuclear fusion (karyogamy). Overproduction of the CIN1 gene product was found to cause the same phenotype as loss of function, supersensitivity to benomyl. Our findings suggest that the CIN1, CIN2, and CIN4 proteins contribute to microtubule stability either by regulating the activity of a yeast microtubule component or as structural components of microtubules.

Polypeptides from the myxomycete Physarum polycephalum interacting in vitro with microtubules

Microtubule-interacting proteins have been studied in the lower eukaryote Physarum polycephalum. We show for the first time 1) the presence in Physarum amoebal crude extracts of at least six polypeptides that bind specifically to amoebal microtubules, 2) the binding between these proteins and mammalian microtubules, 3) the heat stability of two of these polypeptides (125 and 235 kDa), 4) the functional properties of a fraction containing a heat-soluble 125 kDa polypeptide, and 5) the phosphorylation of the 125 kDa polypeptide during two distinct periods of the cell cycle in Physarum synchronous plasmodia, first at late S/early G2 phase and second at late G2/prophase.

Microtubule-associated proteins from Antarctic fishes

Microtubules and presumptive microtubule-associated proteins (MAPs) were isolated from the brain tissues of four Antarctic fishes (Notothenia gibberifrons, N. coriiceps neglecta, Chaenocephalus aceratus, and a Chionodraco sp.) by means of a taxol-dependent, microtubule-affinity procedure (cf. Vallee: Journal of Cell Biology 92:435-442, 1982). MAPs from these fishes were similar to each other in electrophoretic pattern. Prominent in each preparation were proteins in the molecular weight ranges 410,000-430,000, 220,000-280,000, 140,000-155,000, 85,000-95,000, 40,000-45,000, and 32,000-34,000. The surfaces of MAP-rich microtubules were decorated by numerous filamentous projections. Exposure to elevated ionic strength released the MAPs from the microtubules and also removed the filamentous projections. Addition of fish MAPs to subcritical concentrations of fish tubulins at 0-5 degrees C induced the assembly of microtubules. Both the rate and the extent of this assembly increased with increasing concentrations of the MAPs. Sedimentation revealed that approximately six proteins, with apparent molecular weights between 60,000 and 300,000, became incorporated into the microtubule polymer. Bovine MAPs promoted microtubule formation by fish tubulin at 2-5 degrees C, and proteins corresponding to MAPs 1 and 2 co-sedimented with the polymer. MAPs from C. aceratus also enhanced the polymerization of bovine tubulin at 33 degrees C, but the microtubules depolymerized at 0 degrees C. We conclude that MAPs are part of the microtubules of Antarctic fishes, that these proteins promote microtubule assembly in much the same way as mammalian MAPs, and that they do not possess special capacities to promote microtubule assembly at low temperatures or to prevent cold-induced microtubule depolymerization.

Chromosome instability mutants of Saccharomyces cerevisiae that are defective in microtubule-mediated processes

By using a multiply marked supernumerary chromosome III as an indicator, we isolated mutants of Saccharomyces cerevisiae that display increased rates of chromosome loss. In addition to mutations in the tubulin-encoding TUB genes, we found mutations in the CIN1, CIN2, and CIN4 genes. These genes have been defined independently by mutations causing benomyl supersensitivity and are distinct from other known yeast genes that affect chromosome segregation. Detailed phenotypic characterization of cin mutants revealed several other phenotypes similar to those of tub mutants. Null alleles of these genes caused cold sensitivity for viability. At 11 degrees C, cin mutants arrest at the mitosis stage of their cell cycle because of loss of most microtubule structure. cin1, cin2, and cin4 mutations also cause defects in two other microtubule-mediated processes, nuclear migration and nuclear fusion (karyogamy). Overproduction of the CIN1 gene product was found to cause the same phenotype as loss of function, supersensitivity to benomyl. Our findings suggest that the CIN1, CIN2, and CIN4 proteins contribute to microtubule stability either by regulating the activity of a yeast microtubule component or as structural components of microtubules.

Structural diversity and dynamics of microtubules and polymorphic tubulin assemblies

Tubulin, the main protein of microtubules (MTs), has the potency of forming a variety of other assembly products in vitro: rings, ring-crystals, C- and S-shaped ribbons, 10 nm fibres, hoops, sheets, heaped sheets, MT doublets, MT triplets, double-wall MTs, microtubules, curled ribbons, and paracrystals. The supramolecular subunits of all of them are the protofilaments which might be arranged either parallel to the axis (e.g., in MTs, ribbons) or curved (e.g., in hoops, microtubules). There is strong evidence that in the second case the protofilaments have an inside-out orientation compared to MTs. All assembly products mentioned are described structurally and their relevance to the in vivo situation is considered. Moreover, MTs and the other assemblies undergo permanent changes. These dynamics occurring in both individual assemblies and assembly populations are discussed from the structural point of view.

Behavior of C-shaped microtubule endings in the cell

The association of incomplete microtubule assemblies with either another incomplete structure or complete microtubules was studied in two organisms, the phytoflagellate Polytoma papillatum and the phorid fly Megaselia scalaris, using transmission electron microscopy. In the alga, hook-shaped appendages on cytoplasmic and spindle microtubules were detected. These resulted from the lateral association of a curved ribbon of protofilaments with the surface of a complete microtubular wall. In the fly, an S-shaped protofilament sheet was found embedded in the kinetochore plate of a prometaphase I spermatocyte. Tracing of the S-shaped element towards the spindle pole revealed that it was formed by the lateral junction of two curved protofilament sheets. In all cases, the C-shaped protofilament sheets represented the endings of complete microtubules. Incomplete microtubules are generally considered as representing intermediates of microtubule assembly and disassembly. Since high molecular weight proteins are believed to be responsible for maintaining microtubule-microtubule spacing, it is hypothesized that the endings of growing and shrinking microtubules are sparsely studded with these proteins; their depletion allows lateral microtubule contacts. In addition, the microtubule-microtubule contacts may be rendered possible by the flexibility of the slender elongated microtubule-associated molecules. Relatively long C-shaped protofilament appendages (0.6-1.4 microns) were detected in this study. Therefore, it is plausible to assume that the protofilament sheets are stabilized by contact with one another or with an intact tubule wall.

A discrete repeated sequence defines a tubulin binding domain on microtubule-associated protein tau

The protein domain responsible for the interaction of tau with tubulin has been identified. Biophysical studies indicated that the synthetic peptide Val187-Gly204 (VRSKIG-STENLKHQPGGG) from the repetitive sequence on tau binds to two sites on the tubulin heterodimer and to one site on each of the microtubule-associated protein-interacting C-terminal tubulin peptides alpha(430-441) and beta(422-434). The binding data showed a relatively stronger interaction of Val187-Gly204 with beta(422-434) as compared to that with alpha(430-441). The interaction of this tau peptide with either alpha or beta tubulin peptides appears to be associated with conformational changes in both the tau and the tubulin peptides. The beta tubulin peptide also appears to induce a structural change of tau fragment Val218-Gly235. Interestingly, tau peptides Val187-Gly204 and Val218-Gly235 induced tubulin self-assembly in a cold-reversible fashion, and incorporated into the assembled polymers. The specificity of the interaction of the tau peptide was supported by the competition of tau protein for the interaction with the tubulin polymer. In addition, the tau peptide appears to contain the principal antigenic determinant(s) recognized by anti-idiotypic antibodies that react with the tubulin binding domains on microtubule-associated proteins. The present findings together with the demonstration of the presence of multiple sites for the binding of the alpha(430-441) and beta(422-434) tubulin fragments to tau, and the existence of repetitive sequences on tau, strongly support the hypothesis that the region of tau defined by the repetitive sequences is involved in its interaction with tubulin.

Organization of microtubules in dendrites and axons is determined by a short hydrophobic zipper in microtubule-associated proteins MAP2 and tau

Here we report that the microtubule-associated proteins MAP2 and tau share two separable functional domains. One is the microtubule-binding site which serves to nucleate microtubule assembly; the second is a short C-terminal alpha-helical sequence which can crosslink microtubules by means of a hydrophobic zipper interaction into dense stable parallel arrays characteristic of axons or dendrites. Thus, interactions between molecules of a single type are capable of drastically reorganizing microtubules and completely suppressing their dynamic properties.

Assembly properties of altered beta-tubulin polypeptides containing disrupted autoregulatory domains

beta-Tubulin synthesis in eucaryotic cells is subject to control by an autoregulatory posttranscriptional mechanism in which the first four amino acids of the beta-tubulin polypeptide act either directly or indirectly to control the stability of beta-tubulin mRNA. To investigate the contribution of this amino-terminal domain to microtubule assembly and dynamics, we introduced a series of deletions encompassing amino acids 2 to 5 of a single mammalian beta-tubulin isotype, M beta 1. Constructs carrying such deletions were inserted into an expression vector, and the ability of the altered polypeptide to coassemble into microtubules was tested by using an anti-M beta 1-specific antibody. We show that the M beta 1 beta-tubulin polypeptide was competent for coassembly into microtubules in transient transfection experiments and in stably transfected cell lines when it lacked either amino acid 2 or amino acids 2 and 3. The capacity of these mutant beta-tubulins to coassemble into polymerized microtubules was only slightly diminished relative to that of unaltered beta-tubulin, and their expression did not influence the viability or growth properties of cell lines carrying these deletions. However, more extensive amino-terminal deletions either severely compromised or abolished the capacity for coassembly. In analogous experiments in which alterations were introduced into the amino-terminal domain of a mammalian alpha-tubulin isotype, M alpha 4, deletion of amino acid 2 did not affect the ability of the altered polypeptide to coassemble, although removal of additional amino-terminal residues essentially abolished the capacity for competent coassembly. The stability of the altered assembly-competent alpha- and beta-tubulin polypeptides was measured in pulse-chase experiments and found to be indistinguishable from the stability of the corresponding unaltered polypeptides. An assembly-competent M alpha 4 polypeptide carrying a deletion encompassing the 12 carboxy-terminal amino acids also had a half-life indistinguishable from that of the wild-type alpha-tubulin molecule. These data suggest that the universally conserved amino terminus of beta-tubulin acts largely in a regulatory role and that the carboxy-terminal domain of alpha-tubulin is not essential for coassembly in mammalian cells in vivo.

A novel heat-stable 205 kDa microtubule-associated protein is involved in the neural development of the rat brain

A novel microtubule associated protein (MAP) was identified with a monoclonal antibody (mAb) among rat brain microtubule (MT) proteins. This MAP, which is found in a heat-stable MAP fraction, is co-polymerized with tubulin from rat brain homogenates both in cycled and in taxol-driven assembly purifications. When the heat-stable fraction of MT proteins and purified tubulin are assembled in vitro without taxol, 205 kDa MAP is identified in the MT pellet. Immunofluorescent studies using the mAb against this MAP on sections of a rat spinal cord, hippocampus, retina and cerebellar cortex, showed that 205 kDa MAP was localized in not only neural cell bodies, dendrites, and axons, but also in glial cells. This 205 kDa MAP is clearly distinct from previously reported MAPs as to molecular mass, heat stability, immunoreactivity, distribution among tissues or within a neuron, and the developmental aspect of the postnatal cerebellar cortex. As for development, the 205 kDa MAP has already been seen to appear at postnatal day 3. Throughout the postnatal development of the cerebellar cortex, 205 kDa MAP is expressed in developing Purkinje cells, with the staining reaction being particularly intense in the more superficially positioned parallel fiber profiles. This points out the possible important functions of 205 kDa MAP in the morphogenesis of parallel fiber axons.

Generation of a stable, posttranslationally modified microtubule array is an early event in myogenic differentiation

Microtubules (MTs) have been implicated to function in the change of cell shape and intracellular organization that occurs during myogenesis. However, the mechanism by which MTs are involved in these morphogenetic events is unclear. As a first step in elucidating the role of MTs in myogenesis, we have examined the accumulation and subcellular distribution of posttranslationally modified forms of tubulin in differentiating rat L6 muscle cells, using antibodies specific for tyrosinated (Tyr), detyrosinated (Glu), and acetylated (Ac) tubulin. Both Glu and Ac tubulin are components of stable MTs, whereas Tyr tubulin is the predominant constituent of dynamic MTs. In proliferating L6 myoblasts, as in other types of proliferating cells, the level of Glu tubulin was very low when compared with the level of Tyr tubulin. However, when we shifted proliferating L6 cells to differentiation media, we observed a rapid accumulation of Glu tubulin in cellular MTs. By immunofluorescence, the increase in Glu tubulin was first detected in MTs of prefusion myoblasts and was specifically localized to MTs that were associated with elongating portions of the cell. MTs in the multinucleated myotubes observed at later stages of differentiation maintained the elevated level of Glu tubulin that was observed in the prefusion myoblasts. When cells at early stages of differentiation (less than 1 d after switching the culture medium) were immunostained for Glu tubulin and the muscle-specific marker, muscle myosin, we found that the increase in Glu tubulin preceded the accumulation of muscle myosin. Thus, the elaboration of Glu MTs is one of the very early events in myogenesis. Ac tubulin also increased during L6 myogenesis; however, the increase in acetylation occurred later in myogenesis, after fusion had already occurred. Because detyrosination was temporally correlated with early events of myogenesis, we examined the mechanism responsible for the accumulation of Glu tubulin in the MTs of prefusion myoblasts. We found that an increase in the stability of L6 cell MTs occurred at the onset of differentiation, suggesting that the early increase in detyrosination that we observed is a manifestation of a decrease in MT dynamics in elongating myoblasts. We conclude that the establishment of an oriented array of microtubules heightened in its stability and its level of posttranslationally modified subunits may be involved in the subcellular remodeling that occurs during myogenesis.

The microtubule-binding fragment of microtubule-associated protein-2: location of the protease-accessible site and identification of an assembly-promoting peptide

Thrombin cleavage of bovine brain microtubule-associated protein (MAP-2) yields two stable limit polypeptide fragments (28,000 and 240,000 Mr). The smaller cleavage product contains the microtubule-binding domain and is derived from the carboxyl terminus of MAP-2 while the 240,000 Mr fragment is derived from the amino terminus. The amino terminal sequence of the smaller cleavage product is homologous with the microtubule-binding fragment of tau in sequence and in a similar location relative to three imperfect octadecapeptide repeats implicated in microtubule binding. Peptides corresponding to the cleavage site and the three repeats of MAP-2 were synthesized. Only the second octadecapeptide repeat (VTSKCGSLKNIRHRPGGG) was capable of stimulating microtubule nucleation and elongation. Microtubules formed in the presence of this peptide displayed normal morphology and retained the inhibition properties of calcium ion, podophyllotoxin, and colchicine. Our result indicates that a region comprising only approximately 1% of the MAP-2 sequence can promote microtubule assembly.

The appearance of acetylated alpha-tubulin during early development and cellular differentiation in Xenopus

Early development in Xenopus is characterized by dramatic changes in the organization of the microtubule cytoskeleton. We have used whole-mount immunocytochemistry to follow the expression of the acetylated form of alpha-tubulin during early Xenopus development. In the egg and early embryo, the monoclonal anti-acetylated tubulin antibody 6-11B-1 stained meiotic and mitotic spindles, midbody microtubules, and what appears to be the central region of the sperm aster; the antibody did not stain the sperm aster itself or the cortical microtubule system associated with the rotation of the fertilized egg. Following gastrulation, acetylated tubulin disappeared from all but mitotic midbody microtubules. During the course of neurulation high levels of acetylated tubulin reappeared in the precursors of the ciliated epidermal cells (stage 15), transiently in neural folds (stage 16/17), in neuronal processes (stage 18/19), and in somas (stage 21). The changing pattern of anti-acetylated tubulin staining during Xenopus development raises intriguing questions as to the physiological significance of tubulin acetylation.

Neurotrophic molecules

Neurotrophic molecules have a profound influence on developmental events such as naturally occurring cell death, differentiation, and process outgrowth. Despite their striking effects on developing neurons, a role for these molecules in the pathogenesis or therapy of neurological disease has not yet been defined. However, a variety of recent advances promise to provide the techniques necessary to assess the potential relevance of neurotrophic molecules to clinical neurology. In this article we review recent investigations into the biological effects, regulation of production, and mechanisms of action of the best characterized trophic molecule, nerve growth factor. In addition we review studies characterizing brain-derived neurotrophic factor and other putative neurotrophic molecules. Finally, we discuss how pharmacological effects of these molecules may be relevant to the therapy of disease states as well as neural regeneration.

The expression of acetylated microtubules during axonal and dendritic growth in cerebellar macroneurons which develop in vitro

The distribution of acetylated microtubules in cerebellar macroneurons which develop in culture was studied with 6-11B-1, a monoclonal antibody specific for acetylated alpha-tubulin. In these neurons 6-11B-1 helps to define a subset of stable, colchicine-resistant, microtubules that during early neuronal development are exclusively localized in the neuron's axon. On the other hand, in mature neurons acetylated microtubules display a widespread distribution being localized in the axon and thick dendritic trunks, a phenomenon correlated with an increase in the levels of acetylated alpha-tubulin and colchicine-resistant microtubules. Taken collectively, these observations suggest that the acetylation of alpha-tubulin is important for differentiating microtubules during neurite growth: in young neurons this post-translational modification may contribute to determine a selective stabilization of microtubules accompanying axonal differentiation.

Properties of a microtubule-associated cofactor-independent protein kinase from pig brain

A protein kinase activity was identified in pig brain that co-purified with microtubules through repeated cycles of temperature-dependent assembly and disassembly. The microtubule-associated protein kinase (MTAK) phosphorylated histone H1; this activity was not stimulated by cyclic nucleotides. Ca2+ plus calmodulin, phospholipids or polyamines. MTAK did not phosphorylate synthetic peptides which are substrates for cyclic AMP-dependent protein kinase, cyclic GMP-dependent protein kinase. Ca2+/calmodulin-dependent protein kinase II, protein kinase C or casein kinase II. MTAK activity was inhibited by trifluoperazine [IC50 (median inhibitory concn.) = 600 microM] in a Ca2+-independent fashion. Ca2+ alone was inhibitory [IC50 = 4 mM). MTAK was not inhibited by heparin, a potent inhibitor of casein kinase II, nor a synthetic peptide inhibitor of cyclic AMP-dependent protein kinase. MTAK demonstrated a broad pH maximum (7.5-8.5) and an apparent Km for ATP of 45 microM. Mg2+ was required for enzyme activity and could not be replaced by Mn2+. MTAK phosphorylated serine and threonine residues on histone H1. MTAK is a unique cofactor-independent protein kinase that binds to microtubule structures.

Microtubule formation and neurite growth in cerebellar macroneurons which develop in vitro: evidence for the involvement of the microtubule-associated proteins, MAP-1a, HMW-MAP2 and Tau

The relationship between the expression of microtubule-associated proteins (MAPs) and microtubule formation was studied in embryonic cerebellar macroneurons maintained in culture. The results obtained suggest that in these neurons high molecular weight-MAP2 (HMW-MAP2) acts as a promoter of tubulin assembly since its induction and pattern of distribution are highly correlated with the increase in microtubule mass which parallels axonal and dendritic growth; MAP-1a may have a similar role but restricted to the assembly of dendritic microtubules. On the other hand, Tau expression and accumulation follows a time course identical to that of the induction of stable microtubules; besides, at all stages of neurite differentiation and growth this protein seems to be preferentially associated with this subset of microtubules as opposed to the other MAPs, observations which suggest an important role for this protein in determining microtubule stability during axonal and dendritic elongation. Finally, the present results show that environmental stimuli are capable of regulating the expression of these MAPs; the induction of each of them varies as a function of the type of signal. Thus, while diffusable substances are able to dramatically induce HMW-MAP2, MAP-1a and Tau inductions depend on cell substrate attachment and/or cell-cell interactions.

Hypothesis: microtubules, a key to Alzheimer disease

Alzheimer disease (AD) is a clinicopathologic syndrome of unknown etiology with numerous abnormalities in neuronal and nonneuronal cells. A review of the literature suggests that a common basic intracellular defect may underlie many of the reported abnormalities. We hypothesize impairment of the microtubule (MT) system as one explanation for the pathogenesis of AD. Evidence in support of the hypothesis includes the following: MTs are ubiquitous and vital cell components, unequally distributed, with the highest concentration in the brain; various abnormalities, including the key neuropathologic lesions, can be explained by impairments of the MT system; and experiments utilizing pharmacologic agents known to disrupt MTs have reproduced certain abnormalities observed in AD. The hypothesis provides a framework for systematic investigations of MTs at the cellular and molecular levels as well as the basis for in vivo diagnostic tests for AD.

Proteolysis of tau by calpain

The calpain-induced proteolysis of tau associated with twice-cycled microtubules or from a total brain heat-stable fraction was studied. Twice-cycled microtubule tau was rapidly hydrolyzed by calpain. In contrast, tau purified from the total brain heat-stable fraction was very resistant to degradation by calpain. These results clearly demonstrate that there are at least 2 populations of tau in the brain based on calpain-sensitivity, a calpain-sensitive form that is associated with microtubules and a calpain-resistant form that may represent another population of tau in the brain.

Expression of multiple tau isoforms and microtubule bundle formation in fibroblasts transfected with a single tau cDNA

Tau proteins are a class of low molecular mass microtubule-associated proteins that are specifically expressed in the nervous system. A cDNA clone of adult rat tau was isolated and sequenced. To analyze functions of tau proteins in vivo, we carried out transfection experiments. A fibroblast cell line, which was transfected with the cDNA, expressed three bands of tau, while six bands were expressed in rat brain. After dephosphorylation, one of the three bands disappeared, demonstrating directly that phosphorylation was involved in the multiplicity of tau. Morphologically, we observed a thick bundle formation of microtubules in the transiently and stably tau-gene-transfected cells. In addition, we found that the production of tubulin was prominently enhanced in the stably transfected cells. Thus, we suppose that tau proteins promote polymerization of tubulin, form bundles of microtubules in vivo, and play important roles in growing and maintaining nerve cell processes.