Phosphorylation of microtubule-associated protein 2 by MAP kinase primarily involves the projection domain

Chymotryptic digestion was used to localize the sites in microtubule-associated protein 2 which are preferentially phosphorylated in vitro by MAP kinase, an insulin-stimulated serine/threonine kinase which efficiently utilizes high molecular weight MAPs as substrates. MAP kinase phosphorylates sites in the projection domain almost exclusively; less than 6% of the phosphate incorporated by MAP kinase was found in the tubulin binding domain. This site specificity is in marked contrast to that of the catalytic subunit of cAMP dependent protein kinase, and most other protein kinases phosphorylating MAP-2, which extensively phosphorylate the tubulin binding domain.     

Phosphorylation determines the binding of microtubule-associated protein 2 (MAP2) to microtubules in living cells

The influence of phosphorylation on the binding of microtubule-associated protein 2 (MAP2) to cellular microtubules was studied by microinjecting MAP2 in various phosphorylation states into rat-1 fibroblasts, which lack endogenous MAP2. Conventionally prepared brain MAP2, containing 10 mol of endogenous phosphate per mol (MAP2-P10), was completely bound to cellular microtubules within 2-3 min after injection. MAP2 prepared in the presence of phosphatase inhibitors, containing 25 mol/mol of phosphate (MAP2-P25), also bound completely. However, MAP2 whose phosphate content had been reduced to 2 mol phosphate per mol by treatment with alkaline phosphatase in vitro (MAP2-P2) did not initially bind to microtubules, suggesting that phosphorylation of certain sites in MAP2 is essential for binding to microtubules. MAP2-P10 was further phosphorylated in vitro via an endogenously bound protein kinase activity, adding 12 more phosphates, giving a total of 22 mol/mol. This preparation (MAP2-P10+12) also did not bind to microtubules. Assay of the binding of these preparations to taxol-stabilized tubulin polymers in vitro confirmed that their binding to tubulin depended on the state of phosphorylation, but the results obtained in microinjection experiments differed in some cases from in vitro binding. The results suggest that the site of phosphate incorporation rather than the amount is the critical factor in determining microtubule binding activity of MAP2. Furthermore, the interaction of MAP2 with cellular microtubules may be influenced by additional factors that are not evident in vitro.     

Comparative measurement by radioimmunoassay of the brain microtubule-associated protein MAP2

Summary The presence of the microtubule-associated protein (MAP₂) in the brain of several species has been investigated by SDS-gel electrophoresis and by radioimmunoassay. This assay had a sensitivity of approx. 10 ng and it was capable of measuring the protein either in purified microtubules or in crude brain extracts. As determined with this radioimmunoassay, MAP₂ accounted for about 10% of the porcine brain microtubule protein and 1% of the protein from a brain extract. Taking porcine MAP₂ as a reference, we have detected polypeptides with the same electrophoretic mobility in brain microtubules from cow, sheep, rat and chicken. Nevertheless, the MAP₂ from these species showed a variable degree of immunoreactivity. Bovine MAP₂ appeared closely related to the porcine protein whereas the rat antigen showed low cross-reaction and chicken MAP₂ appeared immunologically unrelated to porcine MAP₂. Our results suggest a higher variability of the MAP₂ sequences as compared to that reported by other authors for the brain microtubule protein, tubulin.     

Phosphorylation of microtubule-associated protein tau by AMPK-related kinases

Microtubule-associated protein tau is abnormally hyperphosphorylated in the intracellular filamentous inclusions seen in neurodegenerative disorders with dementia, such as Alzheimer's disease and other tauopathies. Microtubule-associated protein/microtubule-affinity regulating kinases (MARKs) have previously been identified as kinases which phosphorylate KxGS motifs in the tandem repeats of tau. They are members of the 5'-AMP-activated protein kinase (AMPK)-related kinases in the Ca(2+)/calmodulin-dependent protein kinase group. In this study, we examined the ability of AMPK-related kinases, brain-specific kinases 1 and 2, maternal embryonic leucine-zipper kinase, MARK1, and salt-inducible kinase (SIK), to phosphorylate tau. We found that they phosphorylated S262 and S356 in KxGS motifs in the repeats of tau, thus resulting in immunoreactivity with antibody 12E8. MARK1 and SIK most effectively phosphorylated tau, and their down-regulation resulted in a reduction of 12E8-labelling. BX 795, an inhibitor of MARK1 and SIK, reduced 12E8-immunolabelling of tau in rat cortical neurons. These findings reveal a significant contribution of AMPK-related kinases to the phosphorylation of tau at S262/S356.     

The multiple phosphorylation of the microtubule-associated protein MAP2 controls the MAP2:tubulin interaction

Pre-phosphorylation of the microtubule-associated protein MAP2 with the co-purifying cAMP-independent protein kinase (a) decrease the affinity of MAP2 for taxol-stabilised microtubules, (b) increases the dissociation rate constant for microtubule polymerisation, each of which is dependent upon the level of phosphorylation, but (c) has no effect on the association rate constant. Microtubule assembly has no effect on the kinetics of phosphorylation, whereas phosphorylation of pre-assembled microtubules causes their immediate depolymerisation at a rate which is proportional to the initial rate of phosphorylation. The results suggest that the modulated phosphorylation of MAP2 may regulate microtubule length in vivo.     

Reorganisation of the microtubular cytoskeleton by embryonic microtubule-associated protein 2 (MAP2c).

Microtubule-associated protein 2c (MAP2c) is one of a set of embryonic MAP forms that are expressed during neuronal differentiation in the developing nervous system. We have investigated its mode of action by expressing recombinant protein in non-neuronal cell lines using cell cDNA transfection techniques. At every level of expression, all the MAP2c was bound to cellular microtubules. At low MAP2c levels, the microtubules retained their normal arrangement, radiating from the centrosomal microtubule-organising centre (MTOC) but at higher levels an increasing proportion of microtubules occurred independently of the MTOC. In most cells, radially oriented microtubules still attached to the MTOC co-existed with detached microtubules, suggesting that the primary effect of MAP2 is to increase the probability that tubulin polymerisation will occur independently of the MTOC. The MTOC-independent microtubules formed bundles whose distribution depended on their length in relation to the diameter of the transfected cell. Short bundles were attached to the cell cortex at one end and followed a straight course through the cytoplasm, whereas longer bundles followed a curved path around the periphery of the cell. By comparing these patterns to those produced by two chemical agents that stabilise microtubules, taxol and dimethyl sulphoxide, we conclude that effects of MAP2c arise from two sources. It stabilises microtubules without providing assembly initiation sites and as a result produces relatively few, long microtubule bundles. These bend only when they encounter the restraining influence of the cortical cytoskeleton of the cell, indicating that MAP2c also imparts stiffness to them. By conferring these properties of stability and stiffness to neuronal microtubules MAP2c contributes to supporting the structure of developing neurites.     

Phosphorylation of microtubule-associated protein STOP by calmodulin kinase II

STOP proteins are microtubule-associated, calmodulin-regulated proteins responsible for the high degree of stabilization displayed by neuronal microtubules. STOP suppression in mice induces synaptic defects affecting both short and long term synaptic plasticity in hippocampal neurons. Interestingly, STOP has been identified as a component of synaptic structures in neurons, despite the absence of microtubules in nerve terminals, indicating the existence of mechanisms able to induce a translocation of STOP from microtubules to synaptic compartments. Here we have tested STOP phosphorylation as a candidate mechanism for STOP relocalization. We show that, both in vitro and in vivo, STOP is phosphorylated by the multifunctional enzyme calcium/calmodulin-dependent protein kinase II (CaMKII), which is a key enzyme for synaptic plasticity. This phosphorylation occurs on at least two independent sites. Phosphorylated forms of STOP do not bind microtubules in vitro and do not co-localize with microtubules in cultured differentiating neurons. Instead, phosphorylated STOP co-localizes with actin assemblies along neurites or at branching points. Correlatively, we find that STOP binds to actin in vitro. Finally, in differentiated neurons, phosphorylated STOP co-localizes with clusters of synaptic proteins, whereas unphosphorylated STOP does not. Thus, STOP phosphorylation by CaMKII may promote STOP translocation from microtubules to synaptic compartments where it may interact with actin, which could be important for STOP function in synaptic plasticity.     

Regulation of a major microtubule-associated protein by MPF and MAP kinase.

The interphase-M phase transition of microtubule dynamics is thought to be induced by phosphorylation reactions mediated by MPF and by MAP kinase functioning downstream of MPF. We have now identified and purified from Xenopus eggs a major microtubule-associated protein, p220, that may be a target protein for these two M phase-activated kinases. p220, when purified from interphase cells, potently bound to microtubules and stimulated tubulin polymerization, whereas p220 purified from M phase cells showed little or no such activities. Cell staining with a monoclonal anti-p220 antibody revealed that p220 is localized on cytoplasmic microtubule networks during interphase, while it is distributed rather diffusely throughout the cell during M phase. We have further found that p220 is phosphorylated specifically in M phase. Moreover, p220 purified from interphase cells served as a good substrate for MAP kinase and MPF in vitro, and two-dimensional phosphopeptide mapping pattern of the p220 phosphorylated in vitro was very similar to that of p220 phosphorylated at M phase in vivo. These results suggest that the drastic change in p220 activity during the transition from interphase to M phase may be induced by its phosphorylation in M phase probably catalyzed by MAP kinase and MPF.     

Phosphorylation of human microtubule-associated protein tau by protein kinases of the AGC subfamily

Intraneuronal inclusions made of hyperphosphorylated microtubule-associated protein tau are a defining neuropathological characteristic of Alzheimer's disease, and of several other neurodegenerative disorders. Many phosphorylation sites in tau are S/TP sites that flank the microtubule-binding repeats. Others are KXGS motifs in the repeats. One site upstream of the repeats lies in a consensus sequence for AGC kinases. This site (S214) is believed to play an important role in the events leading from normal, soluble to filamentous, insoluble tau. Here, we show that all AGC kinases tested phosphorylated S214. RSK1 and p70 S6 kinase also phosphorylated the neighbouring T212, a TP site that conforms weakly to the AGC kinase consensus sequence. MSK1 phosphorylated S214, as well as S262, a KXGS site in the first repeat, and S305 in the second repeat.     

Phosphorylation-dependent localization of microtubule-associated protein MAP2c to the actin cytoskeleton

Microtubule-associated protein 2 (MAP2) is a neuronal phosphoprotein that promotes net microtubule growth and actin cross-linking and bundling in vitro. Little is known about MAP2 regulation or its interaction with the cytoskeleton in vivo. Here we investigate the in vivo function of three specific sites of phosphorylation on MAP2. cAMP-dependent protein kinase activity disrupts the MAP2-microtubule interaction in living HeLa cells and promotes MAP2c localization to peripheral membrane ruffles enriched in actin. cAMP-dependent protein kinase phosphorylates serines within three KXGS motifs, one within each tubulin-binding repeat. These highly conserved motifs are also found in homologous proteins tau and MAP4. Phosphorylation at two of these sites was detected in brain tissue. Constitutive phosphorylation at these sites was mimicked by single, double, and triple mutations to glutamic acid. Biochemical and microscopy-based assays indicated that mutation of a single residue was adequate to disrupt the MAP2-microtubule interaction in HeLa cells. Double or triple point mutation promoted MAP2c localization to the actin cytoskeleton. Specific association between MAP2c and the actin cytoskeleton was demonstrated by retention of MAP2c-actin colocalization after detergent extraction. Specific phosphorylation states may enhance the interaction of MAP2 with the actin cytoskeleton, thereby providing a regulated mechanism for MAP2 function within distinct cytoskeletal domains.     

Phosphorylation of microtubule-associated proteins.

1. Tubulin is not an adenosine-3':5'-monophosphate-dependent (cyclic-AMP-dependent) protein kinase. Both entities have been clearly separated by sucrose gradient ultracentrifugation. With a tubulin preparation obtained by the polymerization-depolymerization technique protein kinase had a sedimentation coefficient of 8.7 S whereas tubulin sedimented with 6.4 S. After preincubation with both cyclic AMP and histone the kinase dissociated into its catalytic subunit with a sedimentation coefficient of 3.4 S. 2. Tubulin prepared by the polymerization-depolymerization technique was neither phosphorylated in vivo nor in vitro. On the contrary if this preparation was further purified by the Weisenberg's procedure (DEAE-Sephadex batch absorption) before incubation with [gamma-32 P]ATP, phosphorylation occurred. Thus, phosphorylation depended on the method used to purify tubulin i.e. was likely to an an artefact.     

A protein kinase bound to the projection portion of MAP 2 (microtubule-associated protein 2)

In previous work we have demonstrated that the microtubule-associated protein 2 (MAP 2) molecule consists of two structural parts. One part of the molecule, referred to as the assembly-promoting domain, binds to the microtubule surface and is responsible for promoting microtubule assembly; the other represents a filamentous projection observed on the microtubule surface that may be involved in the interaction of microtubules with other cellular structures. MAP 2 is known to be specifically phosphorylated as the result of a protein kinase activity that is present in microtubule preparations. We have now found that the activity copurifies with the projection portion of MAP 2 itself. Kinase activity coeluted with MAP 2 when microtubule protein was subjected to either gel- filtration chromatography on bio-gel A-15m or ion-exchange chromatography on DEAE- Sephadex. The activity was released from microtubules by mild digestion with chymotrypsin in parallel with the removal by the protease of the MAP 2 projections from the microtubule surface. The association of the activity with the projection was demonstrated directly by gel filtration chromatography of the projections on bio-gel A-15m. Three protein species (M(r) = 39,000, 55,000, and 70,000) cofractionated with MAP 2, and two of these (M(r) = 39,000 and 55,000) may represent the subunits of an associated cyclic AMP- dependent protein kinase. The projection-associated activity was stimulated 10-fold by cyclic AMP and was inhibited more than 95 percent by the cyclic AMP-dependent protein kinase inhibitor from rabbit skeletal muscle. It appeared to represent the only significant activity associated with microtubules, almost no activity being found with tubulin, other MAPs, or the assembly-promoting domain of MAP 2, and was estimated to account for 7-22 percent of the total brain cytosolic protein kinase activity. The location of the kinase on the projection is consistent with a role in regulating the function of the projection, though other roles for the enzyme are also possible.     

Domain structure and antiparallel dimers of microtubule-associated protein 2 (MAP2).

We have studied the microtubule-associated protein MAP2 from porcine brain and its subfragments by limited proteolysis, antibody labeling, and electron microscopy. Two major chymotryptic fragments start at lys 1528 and arg 1664, generating microtubule-binding fragments of Mr 36 kDa (303 residues, analogous to the "assembly domain" of Vallee, 1980) and 18 kDa (167 residues). These fragments can be labeled with the antibody 2-4 which recognizes the last internal repeat of MAP2 (Dingus et al., 1991). The epitope of another monoclonal antibody, AP18 (Binder et al., 1986), was mapped to the first 151 residues of MAP2. The interaction with AP18 is phosphorylation dependent; dephosphorylated MAP2 is not recognized. Intact MAP2 forms rod-like particles of 97 nm mean length, similar to Gottlieb and Murphy's (1985) observations. Both antibodies bind near an end of the rod, suggesting that the sequence and the structure are approximately colinear. There is a pronounced tendency for MAP2 to form dimers whose components are nearly in register but of opposite polarity. MAP2 can also fold in a hairpin-like fashion, generating 50-nm rods, and it can self-associate into oligomers and fibers. The 36-kDa microtubule-binding fragment also has a rod-like shape; its mean length is 49 nm, half of the intact molecule, even though the fragment contains only one-sixth of the mass. The antibody 2-4 decorates one end of the rod, similar to the intact protein. The fragment also forms antiparallel dimers, but its tendency for higher self-assembly forms is much lower than with intact MAP2.     

Purification of brain microtubule-associated protein MAP1A

Brain microtubule-associated protein MAP1A has been purified until homogeneity by using a novel procedure involving copolymerization with microtubules, treatment with poly-l-aspartic acid and FPLC. The purified protein retains its capacity to facilitate microtubule assembly.     

Specific binding of dehydroepiandrosterone to the N terminus of the microtubule-associated protein MAP2

The effect of neurosteroids is mediated through their membrane or nuclear receptors. However, no dehydroepiandrosterone (DHEA)-specific receptors have been evidenced so far in the brain. In this paper, we showed by isothermal titration calorimetry that the DHEA specifically binds to the dendritic brain microtubule-associated protein MAP2C with an association constant of 2.7 x 10(7) m-1 and at a molar ratio of 1:1. By partial tryptic digestions and mass spectrometry analysis, we found that the binding involved the N-terminal region of MAP2C. Interestingly, MAP2C displays homologies with 17 beta-hydroxysteroid dehydrogenase 1, an enzyme required for estrogen synthesis. Based on these sequence homologies and on the x-ray structure of the DHEA-binding pocket of 17 beta-hydroxysteroid dehydrogenase 1, we modeled the complex of DHEA with MAP2C. The binding of DHEA to MAP2C involved specific hydrogen bonds that orient the steroid into the pocket. This work suggests that DHEA can directly influence brain plasticity via MAP2C binding. It opens interesting ways for understanding the role of DHEA in the brain.     

Bovine platelets contain a 280 kDa microtubule-associated protein antigenically related to brain MAP 2.

Resting bovine platelets contain a microtubule coil which reorganizes into linear arrays upon thrombin activation. Microtubule arrays in both resting and activated platelets are extensively cross-linked. In an effort to determine the proteins responsible for this cross-linking, we have developed a method to isolate taxol-stabilized microtubule coils directly from platelet-rich plasma. Negatively stained coils are still cross-linked, and fine filamentous projections are seen between adjacent microtubules. Critical-point-dried rotary shadowed replicas of these coils most clearly demonstrate the projections radiating from individual microtubules as well as along the microtubule coil. Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) analysis of isolated coils shows many microtubule-associated proteins (MAPs) present in addition to tubulin. One of these proteins, a 280 kDa MAP, cross-reacts with an antibody to bovine brain MAP 2 by immunoblot analysis. Immunofluorescence localization of this protein with both monoclonal and polyclonal antibodies demonstrates that it is associated with the microtubule coil in resting platelets and with the linear microtubule array present after thrombin activation. Immunoelectron microscopic localization demonstrates that projections from individual microtubules are labeled by the antibodies. We suggest that this MAP, along with several other potential MAPs, is responsible for the cross-linking and stability of bovine platelet microtubules.     

Phosphorylation of microtubule-associated protein tau by Ca2+/calmodulin-dependent protein kinase II in its tubulin binding sites

The paired helical filaments (PHF) found in Alzheimer's disease (AD) brain are composed mainly of the hyperphosphorylated form of microtubule-associated protein tau (PHF-tau). It is well known that tau is a good in vitro substrate for Ca(2+)/calmodulin-dependent protein kinase II (CaM kinase II). To establish the phosphorylation sites, the longest human tau (hTau40) was bacterially expressed and phosphorylated by CaM kinase II, followed by digestion with lysyl endoprotease. The digests were subjected to liquid chromatography/mass spectrometry. We found that 5 of 22 identified peptides were phosphorylated. From the tandem mass spectrometry, two phosphorylation sites (serines 262 and 356) were identified in the tubulin binding sites. When tau was phosphorylated by CaM kinase II, the binding of tau to taxol-stabilized microtubules was remarkably impaired. As both serines 262 and 356 are reportedly phosphorylated in PHF-tau, CaM kinase II may be involved in hyperphosphorylation of tau in AD brain.     

Regulated association of microtubule-associated protein 2 (MAP2) with Src and Grb2: evidence for MAP2 as a scaffolding protein

Microtubule-associated protein 2 (MAP2) and tau, which is involved in Alzheimer's disease, are major cytoskeletal proteins in neurons. These proteins are involved in microtubule assembly and stability. To further characterize MAP2, we took a strategy of identifying potential MAP2 binding partners. The low molecular weight MAP2c protein has 11 PXXP motifs that are conserved across species, and these PXXP motifs could be potential ligands for Src homology 3 (SH3) domains. We tested for MAP2 interaction with SH3 domain-containing proteins. All neuronal MAP2 isoforms bound specifically to the SH3 domains of c-Src and Grb2 in an in vitro glutathione S-transferase-SH3 pull-down assay. Interactions between endogenous proteins were confirmed by co-immunoprecipitation using brain lysate. All three proteins were also found co-expressed in neuronal cell bodies and dendrites. Surprisingly, the SH3 domain-binding site was mapped to the microtubule-binding domain that contains no PXXP motif. Src bound primarily the soluble, non-microtubule-associated MAP2c in vitro. This specific MAP2/SH3 domain interaction was inhibited by phosphorylation of MAP2c by the mitogen-activated protein kinase extracellular signal-regulated kinase 2 but not by protein kinase A. This phosphorylation-regulated association of MAP2 with proteins of intracellular signal transduction pathways suggests a possible link between cellular signaling and neuronal cytoskeleton, with MAP2 perhaps acting as a molecular scaffold upon which cytoskeleton-modifying proteins assemble and dissociate in response to neuronal activity.     

MAP3: characterization of a novel microtubule-associated protein

Using monoclonal antibodies we have characterized a brain protein that copurifies with microtubules. We identify it as a microtubule-associated protein (MAP) by the following criteria: it copolymerizes with tubulin through repeated cycles of microtubule assembly in vitro; it is not associated with any brain subcellular fraction other than microtubules; in double-label immunofluorescence experiments antibodies against this protein stain the same fibrous elements in cultured cells as are stained by antitubulin; and this fibrous staining pattern is dispersed when cytoplasmic microtubules are disrupted by colchicine. Because it is distinct from previously described MAPs we designate this novel species MAP3. The MAP3 protein consists of a closely spaced pair of polypeptides on SDS gels, Mr 180,000, which are present in both glial (glioma C6) and neuronal (neuroblastoma B104) cell lines. In brain the MAP3 antigen is present in both neurons and glia. In nerve cells its distribution is strikingly restricted: anti-MAP3 staining is detectable only in neurofilament-rich axons. It is not, however, a component of isolated brain intermediate filaments.