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.     

Microtubule-associated proteins of HeLa cells: heat stability of the 200,000 mol wt HeLa MAPs and detection of the presence of MAP-2 in HeLa cell extracts and cycled microtubules

One of the major groups of microtubule-associated proteins (MAPs) found associated with the microtubules isolated from HeLa cells has a molecular weight of just over 200,000. Previous work has demonstrated that these heLa MAPs are similar in several properties to MAP-2, one of the major MAPs of mammalian neural microtubules, although the two types of proteins are immunologically distinct. The 200,000 mol wt HeLa MAPs have now been found to remain soluble after incubation in a boiling water bath and to retain the ability to promote tubulin polymerization after this treatment, two unusual properties also shown by neural MAP- 2. This property of heat stability has allowed the development of a simplified procedure for purification of the 200,000 HeLa MAPs and has provided a means for detection of these proteins, even in crude cell extracts. These studies have also led to the detection of a protein in crude extracts of HeLa cells and in cycled HeLa microtubules which has been identified as MAP-2 on the basis of (a) comigration with calf brain MAP-2 on SDS PAGE, (b) presence in purified microtubules, (c) heat stability, and (d) reaction with two types of antibodies prepared against neural high molecular weight-MAPs, one of these a monoclonal antibody against hog brain MAP-2, although present in HeLa cells, is at all stages of microtubule purification a relatively minor component in comparison to the 200,000 HeLa MAP's.     

Sertoli cell processes have axoplasmic features: an ordered microtubule distribution and an abundant high molecular weight microtubule- associated protein (cytoplasmic dynein)

Microtubules in the cytoplasm of rat Sertoli cell stage VI-VIII testicular seminiferous epithelium were studied morphometrically by electron microscopy. The Sertoli cell microtubules demonstrated axonal features, being largely parallel in orientation and predominantly spaced one to two microtubule diameters apart, suggesting the presence of microtubule-bound spacer molecules. Testis microtubule-associated proteins (MAPs) were isolated by a taxol, salt elution procedure. Testis MAPs promoted microtubule assembly, but to a lesser degree than brain MAPs. High molecular weight MAPs, similar in electrophoretic mobilities to brain MAP-1 and MAP-2, were prominent components of total testis MAPs, though no shared immunoreactivity was detected between testis and brain high molecular weight MAPs using both polyclonal and monoclonal antibodies. Unlike brain high molecular weight MAPs, testis high molecular weight MAPs were not heat stable. Testis MAP composition, studied on postnatal days 5, 10, 15, and 24 and in the adult, changed dramatically during ontogeny. However, the expression of the major testis high molecular weight MAP, called HMW-2, was constitutive and independent of the development of mature germ cells. The Sertoli cell origin of HMW-2 was confirmed by identifying this protein as the major MAP found in an enriched Sertoli cell preparation and in two rat models of testicular injury characterized by germ cell depletion. HMW-2 was selectively released from testis microtubules by ATP and co-purified by sucrose density gradient centrifugation with MAP-1C, a neuronal cytoplasmic dynein. The inhibition of the microtubule-activated ATPase activity of HMW-2 by vanadate and erythro-(2-hydroxy-3-nonyl)adenine and its proteolytic breakdown by vanadate-dependent UV photocleavage confirmed the dynein-like nature of HMW-2. As demonstrated by this study, the neuronal and Sertoli cell cytoskeletons share morphological, structural and functional properties.     

Separation of active tubulin and microtubule-associated proteins by ultracentrifugation and isolation of a component causing the formation of microtubule bundles

A new method for separating microtubule-associated proteins (MAPs) and tubulin, appropriate for relatively large-scale preparations, was developed. Most of the active tubulin was separated from the MAPs by centrifugation after selective polymerization of the tubulin was induced with 1.6 M 2-(N-morpholino)ethanesulfonate (Mes) and GTP. The MAPs-enriched supernatant was concentrated and subsequently clarified by prolonged centrifugation. The supernatant (total soluble MAPs) contained almost no tubulin, most of the nucleosidediphosphate kinase activity of the microtubule protein, good activity in promoting microtubule assembly in 0.1 M Mes, and proteins with the electrophoretic mobility of MAP-1, MAP-2, and tau factor. The pellet, inactive in supporting microtubule assembly, contained denatured tubulin, most of the ATPase activity of the microtubule protein, and significant amounts of protein with the electrophoretic mobility of MAP-2. Insoluble material at this and all previous stages, including the preparation of the microtubule protein, could be heat extracted to yield soluble protein active in promoting microtubule assembly and containing MAP-2 as a major constituent. The total soluble MAPs were further purified by DEAE-cellulose chromatography into bound and unbound components, both of which induced microtubule assembly. The bound component (DEAE-MAPs) contained proteins with the electrophoretic mobility of MAP-1, MAP-2, and tau factor. The polymerization reaction induced by the unbound component (flow-through MAPs) produced very high turbidity readings. This was caused by the formation of bundles of microtubules. Although the flow-through MAPs contained significantly more ATPase, tubulin-independent GTPase, and, especially, nucleosidediphosphate kinase activity than the DEAE-MAPs, preparation of a MAPs fraction without these enzymes required heat treatment.     

Morphological integrity of single adult cardiac myocytes isolated by collagenase treatment: immunolocalization of tubulin, microtubule-associated proteins 1 and 2, plectin, vimentin, and vinculin

Single cardiac myocytes were isolated from hearts of 9 to 12-week-old rats by means of collagenase (100 U/ml). After assessment of their functional integrity they were processed for immunofluorescence microscopy of the cytoskeletal proteins tubulin, microtubule-associated proteins 1 and 2 (MAP-1 and MAP-2), plectin, vimentin, and vinculin. Antibodies to tubulin decorated a delicate filamentous network that apparently was unrelated to any sarcomeric organization. The distribution of MAP-1 and MAP-2 was strikingly different from that of tubulin, as both antigens were confined to Z-line structures. These structures were also prominently stained by affinity-purified antibodies to plectin and a monoclonal antibody to vimentin. Co-distribution of plectin and vimentin was also observed at the former intercalated disk region of the heart cell. Anti-vinculin antibodies decorated an intricate meshwork consisting of delicate filaments with predominantly irregular orientation and occasional assembly into whorls. These immunolocalization data indicate that the cell shape and cytoskeletal architecture characteristic of cardiac myocytes in tissues is maintained in single isolated cells. Furthermore, intermediate filaments rather than microtubules seem to be instrumental in the preservation of cell morphology.     

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.     

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.     

Widespread occurrence of polypeptides related to neurotubule-associated proteins (MAP-1 and MAP-2) in non-neuronal cells and tissues.

The occurrence and cellular localization of polypeptides related to hog brain microtubule-associated proteins 1 and 2 (MAP-1 and MAP-2) in non-neuronal cell lines of various species and types, and in several tissues from rat was studied. When insoluble cell fractions were prepared by incubation of isotonic cell extracts with 20 microM taxol, polypeptides co-migrating with MAP-1 and MAP-2 upon gel electrophoresis were observed in virtually all cases examined. Immunoblotting of preparations from 3T6, CHO, HeLa and N2A cells, as well as pituitary, heart, testis and liver revealed immuno-reactivity with antibodies to neuronal MAP-1 for polypeptides co-migrating with MAP-1 in all cases, except for HeLa cells and liver. With similar preparations, antibodies raised to neuronal MAP-2 were barely reactive with bands of the MAP-2 size except for N2A cells and pituitary gland. In all cases of non-neuronal cells and tissues, major cross-reactive bands, however, were of mol. wt. lower than that of MAP-2, indicating, most likely, proteolytic breakdown of MAP-2 during cell fractionation. As shown by double immunofluorescence microscopy of various cultured cell lines using affinity-purified antibodies to MAPs, and monoclonal antibodies to tubulin, MAP-1-as well as MAP-2-related antigens were generally, but not exclusively, associated with typical microtubule structures of the cytoplasm, spindle, midbody and primary cilia. Antigens related to both MAPs were also localized in frozen sections of rat trachea, testis, pituitary, kidney and cardiac and skeletal muscle.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Inhibition of microtubule assembly by poly(L-glutamic acid) and the site of its action

Poly(L-glutamic acid) (PGA) suppresses the polymerization of porcine brain microtubule proteins and induces the depolymerization in vitro in a concentration-dependent manner. The extent of inhibition increases with increasing molecular weight of the PGA tested. A 50% inhibition of the protein polymerization was observed at a PGA (molecular weight = 60,000) to microtubule protein ratio of 0.04 (w/w), and complete inhibition was obtained at a ratio of 0.07. Such an inhibition on the polymerization by PGA is greatly decreased when Mg2+ is present at a higher concentration. The addition of PGA raises the critical concentration of microtubule proteins necessary for assembly. During incubation with PGA, microtubule proteins retain the ability to assemble, i.e., substoichiometric amounts of taxol considerably relieve the inhibition of assembly by PGA. PGA interacts with microtubule-associated proteins (MAPs) preferentially, because the amount of MAPs binding to PGA-Sepharose 4B is much larger than that of tubulin. Tau proteins were observed only in adsorbed fractions, while MAP-2 was present in both unbound and adsorbed fractions.     

Analysis of the microtubule-binding domain of MAP-2

We examined the microtubule-binding domain of the microtubule- associated protein (MAP), MAP-2, using rabbit antibodies that specifically bind to the microtubule-binding region ("stub") and the projection portion ("arm") of MAP-2. We found that (a) microtubules decorated with arm antibody look similar to those labeled with whole unfractionated MAP antibody, though microtubules are not labeled with stub antibody; (b) incubation of depolymerized microtubule protein with stub antibody prior to assembly partially inhibits the rate of microtubule elongation, presumably because MAPs that are complexed with antibody cannot bind to microtubules and stabilize elongating polymers; (c) the rate of appearance and amounts of 36- and 40-kD microtubule- binding peptides produced by digestion with chymotrypsin are distinct for MAPs associated with microtubules vs. MAPs free in solution. The enhanced stability of the 40-kD peptide when associated with microtubules suggests that this domain of the protein is closely associated with, or partially buried in, the microtubule surface; (d) MAP-2 is a slender, elongate molecule as determined by unidirectional platinum shadowing (90 +/- 30 nm), which is in approximate agreement with previous observations. Stub antibody labels MAP-2 in the terminal one-quarter of the extended protein, indicating an intrinsic asymmetry in the molecule.     

The interaction of actin filaments with microtubules and microtubule-associated proteins

Purified actin and microtubule proteins polymerized together form a gel, while mixtures of actin with tubulin polymers lacking microtubule-associated proteins (MAPs) have low viscosities close to the sum of the viscosities of the constituents. Mixtures of actin and MAPs also have high viscosities. Our interpretation of these observations was that there is interaction of actin filaments and microtubules which is mediated by MAPs (Griffith, L. M., and Pollard, T. D. (1978) J. Cell Biol. 78, 958-965). We report here further evidence for this interaction. 1) Actin filaments and microtubules can form gels at physiological ionic strength providing the anion is glutamate rather than chloride. Both glutamate and chloride inhibit actin-MAPs interaction, but this is compensated for in glutamate where the microtubules are longer than in chloride. 2) The low shear viscosity of mixtures of isolated MAPs and actin filaments is enhanced by acidic pH and inhibited by high ionic strength. 3) MAPs can be fractionated to yield four different fractions with actin cross-linking activity: a subset of high molecular weight MAPs, purified "MAP-2" and two different fractions of tau polypeptides. 4) We have reconstituted a gel from actin, purified tubulin, and whole MAPs, but have not yet been successful with actin, purified tubulin, and any single purified MAP.     

Microtubule-associated proteins (MAPs) and the organization of actin filaments in vitro

When purified muscle actin was mixed with microtubule-associated proteins (MAPs) prepared from brain microtubules assembled in vitro, actin filaments were organized into discrete bundles, 26 nm in diameter. MAP-2 was the principal protein necessary for the formation of the bundles. Analysis of MAP-actin bundle formation by sedimentation and electrophoresis revealed the bundles to be composed of approximately 20% MAP-2 and 80% actin by weight. Transverse striations were observed to occur at 28-nm intervals along negatively stained MAP- actin bundles, and short projections, approximately 12 nm long and spaced at 28-nm intervals, were resolved by high-resolution metal shadowing. The formation of MAP-actin bundles was inhibited by millimolar concentrations of ATP, AMP-PCP (beta, gamma-methylene- adenosine triphosphate), and pyrophosphate but not by AMP, ADP, or GTP. The addition of ATP to a solution containing MAP-actin bundles resulted in the dissociation of the bundles into individual actin filaments; discrete particles, presumably MAP-2, were periodically attached along the splayed filaments. These results demonstrate that MAPs can bind to actin filaments and can induce the reversible formation of actin filament bundles in vitro.     

Differential distribution of microtubule-associated proteins MAP-1 and MAP-2 in neurons of rat brain and association of MAP-1 with microtubules of neuroblastoma cells (clone N2A).

To study the individual location of the microtubule proteins MAP-1 and MAP-2 in neuronal tissues and cells, antisera to electrophoretically purified MAP-1 and MAP-2 components were raised in rabbits. When frozen sections through rat brain were examined by immunofluorescence microscopy the antibodies to MAP-1 strongly stained a variety of nerve cells including dendrites and myelinated axons in the cerebrum and cerebellum. Antibodies to MAP-2 showed similar staining patterns, except that myelinated axons were unstained. These results were confirmed by immunoelectron microscopy of frozen sections through cerebellum using the peroxidase technique. Thereby, the association of MAP-1 with microtubules was also clearly demonstrated. When cultured mouse neuroblastoma N2A cells were examined by immunofluorescence microscopy the antiserum to MAP-1 brightly stained filamentous structures resembling microtubules, whereas relatively weak and diffuse staining of the cytoplasm was observed with the antiserum to MAP-2. In agreement with the immunolocalization, MAP-1, but not MAP-2, was found as a prominent component of microtubules proteins polymerized in vitro by taxol from soluble N2A cell extracts. Together these results indicate that neuronal microtubules are preferentially associated with distinct high mol. wt. polypeptides. Therefore, they support the concept that different complements of associated proteins determine distinct functions of microtubules.     

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.     

A microtubule-associated protein in Drosophila melanogaster: identification, characterization, and isolation of coding sequences

Microtubules and microtubule-associated proteins (MAPs) have been isolated from cultured cells of Drosophila melanogaster by a taxol-dependent polymerization procedure. The principal MAPs are a group of four polypeptides with similar electrophoretic mobilities corresponding to approximately Mr 205,000 (the 205K MAP). These proteins are resistant to precipitation by boiling. One mouse monoclonal antibody and one polyclonal rabbit antiserum specific for the Mr 205,000 MAP were produced and characterized by immunoblotting and indirect immunofluorescence. Both antibody preparations stain the Mr 205,000 molecules and an Mr 255,000 molecule in immunoblots of Drosophila cell homogenates; the rabbit antiserum also stains an Mr 150,000 triplet. Both preparations stain the microtubules of the mitotic spindle, and the rabbit antiserum stains the cytoplasmic microtubules as well. Experiments using affinity-purified rabbit antiserum demonstrate that it is the Mr 205,000 species that is located in the mitotic apparatus and on cytoplasmic microtubules. A random shear genomic library was produced in the expressing vector lambda gt11 and screened with the rabbit antiserum to isolate the DNA sequences encoding these polypeptides. Several cross-hybridizing clones were recovered, shown to encode antigenic determinants in the Mr 205,000 MAP, and characterized by hybridization to Northern blots of mRNA and Southern blots of genomic DNA. Analysis by in situ hybridization reveals that the gene encoding the 205K MAP is located in polytene region 100EF.     

Phosphorylation of Microtubule Proteins in Rat Brain at Different Developmental Stages: Comparison with That Found in Neuronal Cultures

The phosphorylation of rat brain microtubule protein on intracranial injection of labeled phosphate has been analyzed. The major microtubule protein components phosphorylated in vivo in rat brain are the high-molecular-weight microtubule-associated proteins (MAPs) MAP-1A, MAP-1B, and MAP-2. A slight phospholabeling of beta-tubulin, which corresponds to the phosphorylation of a minor neuronal beta-tubulin isotype, is also observed. Whereas MAP-1B, MAP-2, and beta-tubulin are phosphorylated in the brain of 5-day-old rat pups, when most neurons of the CNS are extending processes, MAP-1A phosphorylation is observed only after neuronal maturation takes place. The phosphorylation of MAP-1A, MAP-1B, and beta-tubulin may be due mainly to casein kinase II or a related enzyme, whereas MAP-2 appears to be modified by other enzymes such as the cyclic AMP-dependent protein kinase (protein kinase A) and the calcium/phospholipid-dependent protein kinase (protein kinase C). Microtubule protein phosphorylation has also been studied in neuronal cultures. In differentiated neuroblastoma cells, only MAP-1B and beta-tubulin are phosphorylated in a manner coupled to neurite outgrowth. In primary cultures of fetal rat brain neurons, the pattern of microtubule protein phosphorylation resembles that found in vivo in rat pup brain. As phosphorylated MAP-1A and MAP-1B are present mainly on assembled microtubules, whereas the phosphorylation of MAP-2 decreases its interaction with microtubules, a role can be suggested for the phosphorylation of these proteins in the regulation of microtubule assembly and disassembly during neuronal development.     

A 205 kDa protein from non-neuronal cells in culture contains tubulin binding epitopes

Microtubule-associated proteins (MAPs) interact with tubulinin vitro andin vivo. Despite that there is a large amount of information on the roles of these proteins in neurons, the data on non-neuronal MAPs or MAPs-related proteins is scarce. There is an increasing number of microtubule-interacting proteins that have been identified in different cultured cell lines, and some of them share common functional epitopes with the most well-known MAPs, MAP-2 and tau. In a search for tubulin-interacting proteins in non-neuronal cells we identified a 205 kDa protein in the monkey kidney Vero cells in culture, on the basis of immunological studies and affinity chromatography. This protein interacts with the C-terminal moiety of -tubulin and cosediments with taxol assembled microtubules, but it was not recovered after successive cycles of assembly and disassembly. The presence of neuronal MAPs such as MAP-1, MAP-2 and tau was not detected in these cells. Interestingly, the studies showed that the 205 kDa protein contained a tubulin binding motif which was recognized by site-directed antibodies that also tag tubulin binding epitopes on MAP-2 and tau. This characteristic led us to designate this protein as MBD-205, a component that shares binding domains with these MAPs, rather than as a marker of the MAPs family. On the other hand, immunofluorescence experiments using site-specific antibodies, i.e. MAP-reacting monoclonal anti-idiotypic reagent MTB6.22 and a polyclonal antibody to the second tau repeat, revealed a MBD-205 co-localization with membrane structures and microtubule-organizing centers in Vero cells. Microinjection studies along with studies on the cell distribution suggest that MBD-205 appears to play a structural role at the level of the microtubule interactions in these cells.     

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.     

Unusual properties of a cold-labile fraction of Atlantic cod (Gadus morhua) brain microtubules

A cold-labile fraction of microtubules with unusual properties was isolated from the brain of the Atlantic cod (Gadus morhua). The yield was low, approximately six times lower than that for bovine brain microtubules. This was mainly caused by the presence of a large amount of cold-stable microtubules, which were not broken down during the disassembly step in the temperature-dependent assembly-disassembly isolation procedure and were therefore lost. The isolated cold-labile cod microtubules contained usually only a low amount of microtubule-associated proteins (MAPs). Three high molecular mass proteins were found, of which one was recognized as MAP2. Cod MAP2 differed from mammalian brain MAP2; it was not heat stable and had a slightly higher molecular mass. In contrast to mammalian MAPs, MAP1 was not found in the cold-labile fraction of microtubules. A new heat-labile MAP of higher molecular mass (400 kilodaltons) was however present, as well as a heat-stable protein of slightly lower molecular mass than MAP2. These MAPs showed similar tubulin-binding characteristics as bovine brain MAPs, since they coassembled with taxol-assembled bovine brain microtubules consisting of pure bovine tubulin. In spite of the fact that Ca2+ bound equally to cod and porcine tubulins, it did not inhibit cod microtubule assembly even at high concentrations (greater than 1 mM). In contrast, rings, spirals, and macrotubules were formed. The results show that there are major differences between this fraction of cod microtubules and microtubules from mammalian brain.