Evidence for actin filament-microtubule interaction mediated by microtubule-associated proteins

We have used low shear viscometry and electron microscopy to study the interaction between pure actin filaments and microtubules. Mixtures of microtubules having microtubule-associated proteins (MAPs) with actin filament have very high viscosities compared with the viscosities of the separate components. MAPs themselves also cause a large increase in the viscosity of actin filaments. In contrast, mixtures of actin filaments with tubulin polymers lacking MAPs have low viscosities, close to the sum of the viscosities of the separate components. Our interpretation of these observations is that there is an interaction between actin filaments and microtubules which requires MAPs. This interaction is inhibited by ATP and some related compounds. Electron micrographs of thin sections through mixtures of actin and microtubules show numerous close associations between the two polymers which may be responsible for their high viscosity.     

Tubulin-myosin interaction. Some properties of binding between tubulin and myosin

This report presents evidence suggesting the direct binding between tubulin and myosin: (1) coprecipitation of tubulin with myosin occurred at a low ionic strength at which no precipitation of tubulin by itself occurred; (2) the amount of tubulin coprecipitated was unchanged when the coprecipitate was washed thoroughly; (3) about 2 mol of tubulin dimer could bind per mol of myosin at the maximum under our experimental conditions. The binding of about 1 mol of tubulin dimer was influenced by the presence of F-actin, but that of the other 1 mol of tubulin dimer was uninfluenced. In the former binding, tubulin or actin which bound first to myosin was suggested to have a priority. With regard to the priority of the binding, a similar result was obtained from the experiments of tubulin interference in actin activation of myosin Mg2+-ATPase. The tubulin-myosin binding occurred moderately even at 0 degrees C and was not affected by Ca2+ (2 mM), colchicine (200 microM), or Mg-ATP (4 mM), reflecting that the ability of tubulin to bind to myosin was different from the ability of tubulin to form microtubules and that the nature of tubulin-myosin binding was different from that of F-actin-myosin binding. Besides tubulin-myosin interaction, a possible interaction between microtubule-associated proteins (MAPs) and actomyosin was suggested from the data that MAPs activated actomyosin MG2+-ATPase activity while purified tubulin inhibited the activity.     

Preparation and purification of polymerized actin from sea urchin egg extracts

Isotonic extracts of the soluble cytoplasmic proteins of sea urchin eggs, containing sufficient EGTA to reduce the calcium concentration to low levels, form a dense gel on warming to 35-40 degrees C. Although this procedure is similar to that used to polymerize tubulin from mammalian brain, sodium dodecyl sulfate-polyacrylamide gel electrophoresis shows this gel to have actin as a major component and to contain no tubulin. If such extracts are dialyzed against dilute salt solution, they no longer respond to warming, but gelation will occur if they are supplemented with 1 mM ATP and 0.020 M KCl before heating. Gelation is not temperature reversible, but the gelled material can be dissolved in 0.6-1 M KCl and these solutions contain F- actin filaments. These filaments slowly aggregate to microscopic, birefringent fibrils when 1 mM ATP is added to the solution, and this procedure provides a simple method for preparing purified actin. the supernate remaining after actin removal contains the other two components of the gel, proteins of approximately 58,000 and 220,000 mol wt. These two proteins plus actin recombine to form the original gel material when the ionic strength is reduced. This reaction is reversible at 0 degrees C, and no heating is required.     

Isolation of microtubules and a dynein-like MgATPase from unfertilized sea urchin eggs

Taxol was used to prepare microtubules from unfertilized eggs of sea urchins Lytechinus pictus, Strongylocentrotus droebachiensis , and Strongylocentrotus purpuratus. By electron microscopy, these microtubules possessed normal morphology and were decorated with projections. The polypeptides present were tubulin plus microtubule-associated proteins (MAPs) which included various high molecular weight polypeptides, and a Mr = 80,000 polypeptide. These MAPs were extracted from the microtubules by differential centrifugation in high ionic strength buffers, yielding a pellet of microtubules which were not decorated with projections. The Mr = 80,000 and high molecular weight MAPs were separated using Bio-Gel A-1.5 m chromatography, and shown to bind taxol-stabilized microtubules assembled from purified bovine brain tubulin. A dynein-like MgATPase activity is present in sea urchin egg extracts. 10-20% of this MgATPase co-pelleted with the taxol-assembled microtubules, under conditions where greater than 90% of the tubulin pelleted. During subsequent fractionation of the microtubules, by (i) high salt extraction followed by gel filtration or sucrose density gradient fractionation or (ii) ATP extraction, the MgATpase co-purified with high Mr MAPs. The MgATPase which remained in the microtubule-depleted egg extract was partially purified by (NH4)2SO4 fractionation, followed by Bio-Gel A-5 m and hydroxylapatite chromatography. The high Mr MAP MgATPase and the hydroxylapatite MgATPase both contained a prominent polypeptide (Mr approximately 350,000), which co-migrated on sodium dodecyl sulfate gels with the major heavy chain of dynein extracted from sperm axonemes. Our data suggest that this Mr approximately 350,000 polypeptide is cytoplasmic dynein.     

Tubulin, actin, and tau protein interactions and the study of their macromolecular assemblies

The intracellular polymerization of cytoskeletal proteins into their supramolecular assemblies raises many questions regarding the regulatory patterns that control this process. Binding experiments using the ELISA solid phase system, together with protein assembly assays and electron microscopical studies provided clues on the protein-protein associations in the polymerization of tubulin and actin networks. In vitro reconstitution experiments of these cytoskeletal filaments using purified tau, tubulin, and actin proteins were carried out. Tau protein association with tubulin immobilized in a solid phase support system was inhibited by actin monomer, and a higher inhibition was attained in the presence of preassembled actin filaments. Conversely, tubulin and assembled microtubules strongly inhibited tau interaction with actin in the solid phase system. Actin filaments decreased the extent of in vitro tau-induced tubulin assembly. Studies on the morphological aspects of microtubules and actin filaments coexisting in vitro, revealed the association between both cytoskeletal filaments, and in some cases, the presence of fine filamentous structures bridging these polymers. Immunogold studies showed the association of tau along polymerized microtubules and actin filaments, even though a preferential localization of labeled tau with microtubules was revealed. The studies provide further evidence for the involvement of tau protein in modulating the interactions of microtubules and actin polymers in the organization of the cytsokeletal network.     

Promotion of MAP/MAP interaction by taxol

The effects of taxol on microtubule-associated proteins of high molecular weight (MAPs) were studied in vitro. After negative staining, microtubules reconstituted in the presence of taxol from preparations of partially purified tubulin and MAPs, besides being bundled, displayed prominent elongated or globular extensions without apparent regularity. These extensions, but not the tubulin polymer, were heavily decorated after immuno-gold-labeling using antibodies to MAP-1 and MAP-2. Microtubules reconsituted in the absence of taxol showed a much more regular, and apparently helical, arrangement of MAPs along their surfaces. The formation of polymeric structures was also observed when preparation of MAPs free of tubulin were incubated with taxol. In this case in addition to large network-type aggregates with little apparent substructure, more regular structures seemingly consisting of approximately 5-nm-thick filaments arrayed in parallel were observed. Taxol-induced MAP aggregation occurred rapidly and was directly proportional to the concentration of protein, as revealed by optical density measurements. It is concluded that taxol, aside from promoting the assembly of tubulin and stabilizing microtubules, promotes MAP/MAP interaction.     

Assembly properties of tubulin after carboxyl group modification

By chemically modifying carboxyl groups we have investigated the role of the highly acidic COOH-terminal domains of alpha- and beta-tubulin in regulating microtubule assembly. Using a carbodiimide-promoted amidation reaction, as many as 25 carboxyl groups were modified by the addition of 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide and an amine nucleophile, [14C] glycine ethyl ester or [3H]methylamine, to assembled microtubules. Modification occurred primarily in the carboxyl-terminal region as demonstrated by limited proteolysis of modified tubulin by trypsin, chymotrypsin, subtilisin, and carboxypeptidase Y. Modified tubulin polymerized into microtubules with a critical concentration that was 15% of that for unmodified tubulin. Assembly of modified tubulin and microtubules formed from modified tubulin were less sensitive to Ca2+ and high ionic strength. Ca2+ binding studies under low ionic strength conditions indicated that modified tubulin does not contain the high affinity Ca2+ binding site. While assembly of unmodified tubulin was stimulated by Mg2+ up to 10 mM, assembly of the modified protein was inhibited by concentrations greater than 1 mM. When 24 residues were modified, polymerization was no longer stimulated by microtubule-associated proteins (MAPs) or polylysine and incorporation of high molecular weight MAPs into the polymers was reduced by about 70% compared to unmodified tubulin. These studies demonstrate that chemical modification of carboxyl groups in tubulin, most of which are localized in the COOH-terminal region, leads to an enhanced ability to polymerize and a decrease in interaction with MAPs and other positively charged species.     

A taxol-dependent procedure for the isolation of microtubules and microtubule-associated proteins (MAPs)

The effect of the antimitotic drug taxol on the association of MAPs (microtubule-associated proteins) with microtubules was investigated. Extensive microtubule assembly occurred in the presence of Taxol at 37 degrees C. at 0 degrees C, and at 37 degrees C in the presence of 0.35 M NaCl, overcoming the inhibition of assembly normally observed under the latter two conditions. At 37 degrees C and at 0 degrees C, complete assembly of both tubulin and the MAPs was observed in the presence of Taxol. However, at elevated ionic strength, only tubulin assembled, forming microtubules devoid of MAPs. The MAPs could also be released from the surface of preformed microtubules by exposure to elevated ionic strength. These properties provided the basis for a rapid new procedure for isolating microtubules and MAPs of high purity from small amounts of biological material. The MAPs could be recovered by exposure of the microtubules to elevated ionic strength and subjected to further analysis. Microtubules and MAPs were prepared from bovine cerebral cortex (gray matter) and from HeLa cells. MAP 1, MAP2, and the tau MAPs, as well as species of Mr = 28,000 and 30,000 (LMW, or low molecular weight, MAPs) and a species of Mr = 70,000 were isolated from gray matter. Species identified as the 210,000 and 125,000 mol wt HeLa MAPs were isolated from HeLa cells. Microtubules were also prepared for the first time from white matter. All of the MAPs identified in gray matter preparations were identified in white matter, but the amounts of individual MAP species differed. The most striking difference in the two preparations was a fivefold lower level of MAP 2 relative to tubulin in white matter than in gray. The high molecular weigh MAP, MAP1, was present in equal ratio to tubulin in white and gray matter. These results indicate that MAP 1 and MAP2, as well as other MAP species, may have a different cellular or subcellular distribution.     

Promotion of Microtubule Assembly by Neurofilament-Associated Microtubule-Associated Proteins

Abstract: Intact neurofilaments (NF) purified from mammalian brain and spinal cord promote the assembly of microtubules in solutions of pure phosphocellulose (PC)-purified tubulin. This assembly is temperature-dependent and is inhibited by mitotic spindle inhibitors. The ability of NF to induce microtubule formation is 20% of that of purified microtubule-associated proteins (MAPs), whereas MAPs comprise less than 5% of the protein in the NF preparations. The inducing activity of NF is rapidly lost on boiling. When intact NF are incubated with PC-tubulin and then centrifuged, tubulin is sedimented together with the filaments. This association is inhibited by colchicine and podophyllotoxin and is cold-sensitive. NF purified to homogeneity under denaturing conditions and then reassembled completely lack the ability to promote the assembly of PC-tubulin or to bind tubulin on a centrifugation assay. No MAPs are present in these preparations, though these filaments have the ability to bind exogenous MAPs. While these experiments do not rule out an intrinsic microtubule-assembly-promoting activity, they suggest that this activity is due to nontriplet proteins in the preparation, most likely filament-associated MAPs.     

Biochemical and electron microscopy analysis of the endotoxin binding to microtubulesin vitro

The mechanisms involved in cellular activation and damage by bacterial endotoxins are not completely defined. In particular, there is little information about possible intracellular targets of endotoxins. Recently, the participation of a microtubule associated protein in endotoxin actions on macrophages has been suggested. In the present work, we have studied the effect ofE. coli lipopolysaccharide on the polymerization of microtubular proteinin vitro. Electrophoretic analysis of the polymerization mixtures showed that the endotoxin inhibited the polymerization when present at high concentrations. At lower concentrations, LPS selectively displaced the microtubule associated protein MAP-2 from the polymerized microtubules. Electron microscopy showed that LPS binds to microtubules of tubulin+MAPs and to microtubules of purified tubulin (without MAPs) polymerized with taxol. Gel filtration experiments confirmed the binding of LPS to tubulin, and by ligand blot assays an interaction LPS — MAP-2 was detected. The ability of LPS to interact with microtubular proteins suggests a possible participation of microtubules on the cellular effects of endotoxins.     

Microtubule-associated proteins connect microtubules and neurofilaments in vitro

Neuronal intermediate filaments (neurofilaments) prepared from brain form a viscous sedimentable complex with microtubules under suitable conditions [Runge, M.S., Laue, T.M., Yphantis, D.A., Lifsics, M.R., Saito, A., Altin, M., Reinke, K., & Williams, R.C., Jr. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 1431-1435]. Under the same conditions, neurofilaments prepared from spinal cord did not form such a complex. Brain neurofilaments were shown to differ from spinal cord neurofilaments in part by having proteins that resemble microtubule-associated proteins (MAPs) attached to them. MAPs became bound to spinal cord neurofilaments when the two structures were incubated together. The resulting MAP-decorated neurofilaments formed a viscous complex with microtubules, showing that some component of the MAPs mediated the association between the two filamentous organelles. By means of gel filtration, the MAPs were separated into two major fractions. The large Stokes radius fraction was active in producing neurofilament-microtubule mixtures of high viscosity, while the small Stokes radius fraction was not. The dependence of the viscosity of neurofilament-microtubule mixtures upon the concentration of MAPs was found to possess a maximum. This result suggests that the MAPs serve as cross-bridges between the two structures. Neurofilaments, with and without bound MAPs, were allowed to adhere to electron microscope grids. The grids were then exposed to microtubules, fixed, and stained. The grids prepared with MAP-decorated neurofilaments bound numerous microtubules, each in apparent contact with one or more neurofilaments. The grids prepared with untreated neurofilaments lacked microtubules. These results show that one or more of the MAPs mediates association between microtubules and neurofilaments.     

Polyglutamylation of atlantic cod tubulin: immunochemical localization and possible role in pigment granule transport

In higher organisms, there is a large variety of tubulin isoforms, due to multiple tubulin genes and extensive post-translational modification. The properties of microtubules may be modulated by their tubulin isoform composition. Polyglutamylation is a post-translational modification that is thought to influence binding of both structural microtubule associated proteins (MAPs) and mechano-chemical motors to tubulin. The present study investigates the role of tubulin polyglutamylation in a vesicle transporting system, cod (Gadus morhua) melanophores. We did this by microinjecting an antibody against polyglutamylated tubulin into these cells. To put our results into perspective, and to be able to judge their universal application, we characterized cod tubulin polyglutamylation by Western blotting technique, and compared it to what is known from mammals. We found high levels of polyglutamylation in tissues and cell types whose functions are highly dependent on interactions between microtubules and motor proteins. Microinjection of the anti-polyglutamylation antibody GT335 into cultured melanophores interfered with pigment granule dispersion, while dynein-dependent aggregation was unaffected. Additional experiments showed that GT335-injected cells were able to aggregate pigment even when actin filaments were depolymerized, indicating that the maintained ability of pigment aggregation in these cells was indeed microtubule-based and did not depend upon actin filaments. The results indicate that dynein and the kinesin-like dispersing motor protein in cod melanophores bind to tubulin on slightly different sites, and perhaps depend differentially on polyglutamylation for their interaction with microtubules. The binding site of the dispersing motor may bind directly to the polyglutamate chain, or more closely than dynein.     

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.     

Interactions between neurofilaments and microtubule-associated proteins: a possible mechanism for intraorganellar bridging

Mammalian neurofilaments prepared from brain and spinal cord by either of two methods partially inhibit the in vitro assembly of microtubules. This inhibition is shown to be due to the association of a complex of high molecular weight microtubule-associated proteins (MAP1 and MAP2) and tubulin with the neurofilament. Further analysis of the association reveals a saturable binding of purified brain MAPs to purified neurofilaments with a Kd of 10(-7) M. Purified astroglial filaments neither inhibit microtubule assembly nor show significant binding of MAPs. It is proposed that the MAPs might function as one element in a network of intraorganellar links in the cytoplasm.     

The role of microtubules in platelet secretory release

The role of microtubules in platelet aggregation and secretion has been analyzed using platelets permeabilized with digitonin and monoclonal antibodies to alpha (DM1A) and beta (DM1B) subunits of tubulin. Permeabilized platelets were able to undergo aggregation and secretory release. However, threshold doses of agonists capable of eliciting a second wave of aggregation and the platelet release reaction were higher than in control platelets exposed to dimethyl sulfoxide, the solvent for digitonin. Both antibodies to alpha and beta tubulin caused a further increase in the threshold concentration of agonists and inhibited the secretory release of permeabilized platelets, but were ineffective using intact platelets. Neither monoclonal antibody inhibited polymerization or depolymerization of platelet tubulin in vitro. Antibodies to platelet actin and myosin also exhibited an inhibitory activity on platelet aggregation albeit less severe than that observed with the antibodies to alpha and beta tubulin. There was evidence of an interaction between DM1A and DM1B and the antibodies to actin and myosin. The interaction of platelet tubulin and myosin was investigated by two different methods. (1) Coprecipitation of the proteins at low ionic strength at which tubulin by itself did not precipitate and (2) affinity chromatography on columns of immobilized myosin. Tubulin freed of its associated proteins (MAPs) by phosphocellulose chromatography bound to myosin in a molar ratio which approached 2. Platelet actin competed with tubulin for 1 binding site on the myosin molecule. MAPs also reduced the binding stoichiometry of tubulin/myosin. Treatment of microtubule protein with p-chloromercuribenzoate or colchicine did not influence its binding to myosin. DM1A and DM1B inhibited the interaction of tubulin and myosin. This effect could also be demonstrated by reaction of electrophoretic transblots of extracted platelet tubulin with the respective proteins. We interpret these results as evidence for an interference of the two monoclonal antibodies to the tubulin subunits (DM1A and DM1B) with the translocation of microtubule protein from its submembranous site to a more central one during the activation process.     

Isolation of microtubule-associated proteins from carrot cytoskeletons: a 120 kDa map decorates all four microtubule arrays and the nucleus

A method for biochemically isolating microtubule-associated proteins (MAPs) from the detergent-extracted cytoskeletons of carrot suspension cells has been devised. The advantage of cytoskeletons is that filamentous proteins are enriched and separated from vacuolar contents. Depolymerization of cytoskeletal microtubules with calcium at 4°C releases MAPs which are then isolated by association with taxol stabilized neurotubules. Stripped from microtubules (MTs) by salt, then dialysed, the resulting fraction contains a limited number of high molecular weight proteins. Turbidimetric assays demonstrate that this MAP fraction stimulates polymerization of tubulin at concentrations at which it does not self-assemble. By adding it to rhodamine-conjugated tubulin, the fraction can be seen to form radiating arrays of long filaments, unlike MTs induced by taxol. In the electron microscope, these arrays are seen to be composed of mainly single microtubules. Blot-affinity purified antibodies confirm that two of the proteins decorate cellular microtubules and fulfil the criteria for MAPs. Antibodies to an antigenically related triplet of proteins about 60–68 kDa (MAP 65) stain interphase, preprophase band, spindle and phragmoplast microtubules. Antibodies to the 120 kDa MAP also stain all of the MT arrays but labelling of the cortical MTs is more punctate and, unlike anti-MAP 65, the nuclear periphery is also stained. Both the anti-65 kDa and the anti-120 kDa antibodies stain cortical MTs in detergent-extracted, substrate-attached plasma membrane disks ('footprints'). Since the 120 kDa protein is detected at two surfaces (nucleus and plasma membrane) known to support MT growth in plants, it is hypothesized that it may function there in the attachment or nucleation of MTs.     

Dependency of microtubule-associated proteins (MAPS) for tubulin stability and assembly; use of estramustine phosphate in the study of microtubules

Summary Microtubule-associated proteins (MAPS) were separated from tubulin with several different methods. The ability of the isolated MAPs to reinduce assembly of phosphocellulose purified tubulin differed markedly between the different methods. MAPs isolated by addition of 0.35 M NaCl to taxol-stabilized microtubules stimulated tubulin assembly most effectively, while addition of 0.6M NaCl produced MAPs with a substantially lower ability to stimulate tubulin assembly. The second best preparation was achieved with phosphocellulose chromatographic separation of MAPs with 0.6 M NaCl elution.The addition of estramustine phosphate to microtubules reconstituted of MAPS prepared by 0.35 M NaCl or phosphocellulose chromatography, induced less disassembly than for microtubules assembled from unseparated proteins, and was almost without effect on microtubules reconstituted from MAPs prepared by taxol and 0.6 M NaCl. Estramustine phosphate binds to the tubulin binding part of the MAPs, and the results do therefore indicate that the MAPs are altered by the separation methods. Since the MAPs are regarded as highly stable molecules, one probable alteration could be aggregation of the MAPs, as also indicated by the results. The purified tubulin itself seemed not to be affected by the phosphocellulose purification, since the microtubule proteins were unchanged by the low buffer strenght used during the cromatography. However, the assembly competence after a prolonged incubation of the microtubule proteins at 4° C was dependent on intact bindings between the tubulin and MAPs.Abbreviations Pipes 1,4-Piperazinediethanesulfonic acid - EDTA Ethylenedinitrilo Tetraacetic Acid - MAPs Microtubule-Associated Proteins - SDS-PAGE SDS-Polyacrylamide Gel Electrophoresis     

Tubulin and Neurofilament Proteins Are Transported Differently in Axons of Chicken Motoneurons

SUMMARY 1. We previously showed that actin is transported in an unassembled form with its associated proteins actin depolymerizing factor, cofilin, and profilin. Here we examine the specific activities of radioactively labeled tubulin and neurofilament proteins in subcellular fractions of the chicken sciatic nerve following injection of L-[³⁵S]methionine into the lumbar spinal cord.2. At intervals of 12 and 20 days after injection, nerves were cut into 1-cm segments and separated into Triton X-100-soluble and particulate fractions. Analysis of the fractions by high-resolution two-dimensional gel electrophoresis, immunoblotting, fluorography, and computer densitometry showed that tubulin was transported as a unimodal wave at a slower average rate (2–2.5 mm/day) than actin (4–5 mm/day). Moreover, the specific activity of soluble tubulin was five times that of its particulate form, indicating that tubulin is transported in a dimeric or small oligomeric form and is assembled into stationary microtubules.3. Neurofilament triplet proteins were detected only in the particulate fractions and transported at a slower average rate (1 mm/day) than either actin or tubulin.4. Our results indicate that the tubulin was transported in an unpolymerized form and that the neurofilament proteins were transported in an insoluble, presumably polymerized form.     

Subpopulations of tau interact with microtubules and actin filaments in various cell types

It has been demonstrated that microtubule-associated proteins (MAPs) interact with tubulin in vitro and in vivo. However, there is no clear evidence on the possible roles of the interactions of MAPs in vivo with other cytoskeletal components in maintaining the integrity of the cell architecture. To address this question we extracted the neuronal cytoskeleton from brain cells and studied the selective dissociation of specific molecular isospecies of tau protein under various experimental conditions. Tau, and in some cases MPA-2, were analysed by the use of anti-idiotypic antibodies that recognize epitopes on their tubulin binding sites. Fractions of microtubule-bound tau isoforms were extracted with 0.35 M NaCl or after the addition of nocodazole to allow microtubule depolymerization. Protein eluted with this inhibitor contained most of the assembled tubulin dimer pool and part of the remaining tau and MAP-2. When the remaining cytoskeletal pellet was treated with cytochalasin D to allow depolymerization of actin filaments, only tau isoforms were extracted. Immunoprecipitation studies along with immunolocalization experiments in cell lines containing tau-like components supported the findings on the roles of tau isospecies as linkers between tubulin in the microtubular structure with actin filaments. Interestingly, in certain types of cells, antibody-reactive tau isospecies were detected by immunofluorescence with a discrete distribution pattern along actin filaments, which was affected by cytochalasin disruption of the actin filament network. These results suggest the possible in vivo roles of subsets of tau protein in modulating the interactions between microtubules and actin filaments.     

Molecular Interaction of S-100 Proteins with Microtubule Proteins In Vitro

Several procedures were employed to examine the in vitro interaction between S-100 proteins and microtubule proteins. Binding of S-100 to tau factors was observed under all experimental conditions. S-100 binding to microtubule-associated protein 2 (MAP2) was best detected by exposing nitrocellulose-immobilized MAP2 or MAPs to either 125I-labeled S-100 or biotinylated S-100. S-100 binding to tubulin was detected when the two protein fractions were first incubated with each other followed by exposure to the bifunctional cross-linker disuccinimidylsuberate, and then separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and transfered onto nitrocellulose paper. By this procedure, complex formation between S-100 and tubulin, as well as between S-100 and a relatively low-molecular-weight MAP, was evidenced by immunoblotting using an anti-S-100 antiserum. Alternatively, complex formation between biotinylated S-100 and either tubulin or MAPs was visualized by means of avidin-peroxidase, after SDS-PAGE of the complex mixtures and transfer of the separated proteins onto nitrocellulose. The interaction between S-100 and tubulin was strictly Ca2+ dependent, and resistant to high concentrations of KCl, colchicine, or vinblastine.