©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Phosphorylation of Microtubule-associated Proteins MAP2 and MAP4 by the Protein Kinase p110
PHOSPHORYLATION SITES AND REGULATION OF MICROTUBULE DYNAMICS (*)

(Received for publication, December 26, 1995)

Susanne Illenberger (§) Gerard Drewes (§) Bernhard Trinczek Jacek Biernat Helmut E. Meyer (1) Joanna B. Olmsted (2) Eva-Maria Mandelkow Eckhard Mandelkow (¶)

From the  (1)Max-Planck-Unit for Structural Molecular Biology, Notkestrasse 85, D-22603 Hamburg, Germany, the Institut für Physiologische Chemie, Ruhr-Universität, Universitätsstrasse 150, D-44780 Bochum, Germany, and the (2)Department of Biology, Rochester University, Rochester, New York 14627

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

The phosphorylation of microtubule-associated proteins (MAPs) is thought to be a key factor in the regulation of microtubule stability. We have shown recently that a novel protein kinase, termed p110 microtubule-affinity regulating kinase (``MARK''), phosphorylates microtubule-associated protein tau at the KXGS motifs in the region of internal repeats and causes the detachment of tau from microtubules (Drewes, G., Trinczek, B., Illenberger, S., Biernat, J., Schmitt-Ulms, G., Meyer, H. E., Mandelkow, E.-M., and Mandelkow, E.(1995) J. Biol. Chem. 270, 7679-7688). Here we show that p110 phosphorylates analogous KXGS sites in the microtubule binding domains of the neuronal MAP2 and the ubiquitous MAP4. Phosphorylation in vitro leads to the dissociation of MAP2 and MAP4 from microtubules and to a pronounced increase in dynamic instability. Thus the phosphorylation of the repeated motifs in the microtubule binding domains of MAPs by p110 might provide a mechanism for the regulation of microtubule dynamics in cells.


INTRODUCTION

In living cells, microtubules undergo transitions between stable and dynamic states. They are organized into stable cytoskeletal structures such as the processes of neuronal cells or the axonemes of cilia and flagella, but are also key players in dynamic events during cell morphogenesis or chromosome partitioning at mitosis. Microtubule stability is thought to be modulated by a variety of post-translational modifications of both tubulin and MAPs. (^1)Structural MAPs are filamentous proteins which bind to microtubules in a nucleotide-insensitive way, forming elongated projections from the microtubule surface (for reviews, see Olmsted(1991), Hirokawa(1994), Schoenfeld and Obar(1994), and Mandelkow and Mandelkow(1995)). MAPs can control microtubule dynamics in vitro and in vivo (Drechsel et al., 1992; Pryer et al., 1992; Umeyama et al., 1993; Gustke et al., 1994; Brandt et al., 1994; Dhamodharan and Wadsworth, 1995; Trinczek et al., 1995). Tau and MAP2 are the most studied MAPs in the vertebrate nervous system; tau is abundant in the axon, whereas MAP2 is localized predominantly in dendrites (Binder et al., 1985; Riederer and Matus, 1985). MAP4 is not limited to the nervous system and is the predominant MAP in many types of cells and tissues (Bulinski and Borisy, 1980; Parysek et al., 1984; Aizawa et al., 1990). MAP2, tau, and MAP4 are grossly similar in domain structure, having N-terminal projection domains and C-terminal microtubule binding domains (Lee et al., 1988; Lewis et al., 1988; Aizawa et al., 1991; West et al., 1991; Chapin and Bulinski, 1991). The C-terminal part of these proteins displays considerable homology in a repeated sequence motif. The sequences in the C-terminal region are rich in basic amino acids which probably interact with the acidic sequence in the C terminus of tubulin (Littauer et al., 1986).

Several lines of evidence suggest that the binding of MAPs to microtubules is regulated by phosphorylation. MAPs isolated from tissue or cells are phosphoproteins (Sloboda et al., 1975; Vallee, 1980; Burns et al., 1984; Tsuyama et al., 1986; Brugg and Matus, 1991; Watanabe et al., 1993), MAPs are good substrates for many protein kinases in vitro (Theurkauf and Vallee, 1983; Lindwall and Cole, 1984; Mori et al., 1991; Drewes et al., 1992), and phosphorylation interferes with their microtubule stabilizing capacity (Brugg and Matus, 1991; Shiina et al., 1992; Drechsel et al., 1992; Biernat et al., 1993; Brandt et al., 1994; Ookata et al., 1995; Trinczek et al., 1995). In the case of tau protein, phosphorylation has been extensively studied, because aberrantly phosphorylated tau is involved in the neurofibrillar pathology of Alzheimer's disease (reviewed by Goedert(1993), Mandelkow and Mandelkow(1993), and Trojanowski and Lee(1994)). However, it has been difficult to establish the relationship between protein kinases, phosphorylation sites, and their effect on microtubule affinity, nucleation, and dynamic instability. Recently, we have used an approach which combined site-directed mutagenesis of recombinant tau and in vitro phosphorylation by a brain tissue extract to identify sites that are crucial for microtubule binding (Gustke et al., 1992). We found that phosphorylation of tau at a single serine residue, located within the sequence KIGS)) in the first repeat of the binding domain, strongly suppresses microtubule binding (Biernat et al., 1993). The phosphorylation of sites outside the microtubule binding domain, which occurred mostly on Ser/Thr-Pro motifs, had a relatively weak effect. Subsequently, we characterized and purified from brain tissue a novel kinase of molecular mass 110 kDa, which effectively phosphorylated Ser and displayed a pronounced specificity for all four KXGS motifs in the repeat domain of tau (Drewes et al., 1995). This kinase efficiently caused the loss of tau's affinity for microtubules, resulting in high dynamic instability, and was termed p110 (microtubule affinity regulating kinase). In this paper, we show that p110phosphorylates MAP2 and MAP4 efficiently on their microtubule binding domains in vitro, and that the KXGS motifs within the conserved repeats are the major phosphorylation sites. Both MAP2 and MAP4 become detached from microtubules upon phosphorylation by the kinase, and the microtubules become unstable. The data suggest that phosphorylation of MAPs by p110 could be generally important in the MAP-mediated regulation of the dynamics and rearrangement of the microtubule network in cells.


MATERIALS AND METHODS

Proteins

A cDNA clone of the rat juvenile MAP2 isoform, MAP2c, was a gift of C. Garner (Kindler et al., 1990). Three point mutants of MAP2c were constructed: MAP2cA319, MAP2cA350, and MAP2cA319+350, in which serines at position 319 and/or 350 were mutated into alanine (corresponding to positions 1682 and 1713 in the full MAP2 numbering, Table 1). Human tau cDNA clones were a gift of M. Goedert (Goedert et al., 1989). The numbering used here refers to the rat sequence of full-length MAP2 (1830 residues) and the biggest human tau isoform (clone htau40, 441 residues). The MAP4 construct MAP4-BDC was derived from a murine MAP4 clone (West et al., 1991; Olson et al., 1995) and comprises the microtubule binding region, from residue 640 to the C terminus, and carries an N-terminal hemagglutinin tag sequence (Field et al., 1988). The numbering used here refers to the full-length murine MAP4 sequence (1125 residues). Proteins were obtained either by expressing constructs in Escherichia coli using variants of the pET expression vector (Studier et al., 1990), or by purification from tissues. Brain MAP2 was prepared from porcine brain microtubule protein by heat treatment, Mono S FPLC (Pharmacia Biotech Inc.), and gel filtration as described by Wille et al. (1992). MAP4 was prepared from a mouse heart and lung tissue extract by ammonium sulfate precipitation, heat treatment, Mono S FPLC, and hydrophobic interaction chromatography on Phenyl-Superose (modified after Aizawa et al.(1989)). Phosphocellulose-purified tubulin was prepared from porcine brain following Mandelkow et al.(1985). The protein kinase p110 was prepared from porcine brain as described recently (Drewes et al., 1995). Using 50 µM MAP2c as substrate and 1 mM ATP at 37 °C, the preparation was determined to have an activity of 33 milliunits/ml by the phosphocellulose paper assay (1 unit is defined by the transfer of 1 µmol of phosphate/min at 1 mM ATP at 37 °C).



Phosphorylation Reactions

Phosphorylation reactions were carried out essentially as described (Drewes et al., 1995). Briefly, the buffer was 40 mM Hepes, pH 7.2, containing 1 mM ATP, 5 mM MgCl(2), 2 mM EGTA, 0.2 mM dithiothreitol, 0.1 mM phenylmethylsulfonyl fluoride, and 0.01% Brij-35. Reactions were terminated by brief heating to 95 °C, and phosphorylation was assayed in SDS gels (Steiner et al., 1990) or on phosphocellulose paper discs (Life Technologies, Inc.) (Casnellie, 1991).

Phosphopeptide Mapping

Following phosphorylation reactions, the kinase was removed by boiling the samples in 0.5 M NaCl, 10 mM dithiothreitol and centrifugation. The heat-stable MAPs were precipitated with 15% trichloroacetic acid, cysteine residues were modified by performic acid treatment and the protein was digested overnight with trypsin (Promega, sequencing grade) using two additions of enzyme in a ratio of 1:20 (w/w). Two-dimensional phosphopeptide mapping by thin layer electrophoresis/chromatography was performed on thin layer cellulose plates (Macherey & Nagel, Düren, Federal Republic of Germany) according to Boyle et al.(1991). For identification of spots, the digests were run along with the HPLC-purified phosphopeptides (see below). For the mapping of phosphorylation sites by sequencing, recombinant MAP4 fragment or MAP2c (200 µg) was phosphorylated with p110 and [-P]ATP (100 Ci/mol) for 2 h, the reaction terminated by a brief heat treatment, and cysteines oxidized with performic acid. After gel filtration on a Pharmacia ``Fast Desalting'' column (``Smart System'') in 10 mM ammonium bicarbonate, pH 8.5, containing 0.1 mM CaCl(2), incorporated radioactivity was measured by Cerenkov counting and the labeled protein was digested with trypsin (1:40). Separation of peptides was performed by two successive HPLC runs on a µRPC C2/C18 SC 2.1/10 column (Smart System, Pharmacia). For peptides which did not bind efficiently to this column, we employed a Vydac 218TP52 column (The Separations Group, Hesperia, CA). The digest was fractionated by HPLC using a gradient of acetonitrile in 10 mM ammonium acetate (flow rate 0.1 ml/min, 0-25% in 120 min, 25-50% in 20 min). Flow-through fractions and radioactive peaks from this gradient were further purified using a gradient of acetonitrile in trifluoroacetic acid (flow rate 0.1 ml/min, 0% acetonitrile, 0.075% trifluoroacetic acid to 66% acetonitrile, 0.05% trifluoroacetic acid in 60 min). Sequence analysis of peptides was performed using a 476A pulsed liquid phase sequencer and a 120A on-line phenylthiohydantoin-derivative analyzer (Applied Biosystems). Phosphoserines were identified as the dithiothreitol adduct of dehydroalanine by gas phase sequencing (Meyer et al., 1993).

MALDI-MS measurements were obtained using a Lasermat 2000 instrument (Finnigan).

Phosphoamino Acid Analysis

Aliquots of digestion samples were partially hydrolyzed in 6 N HCl (110 °C, 60 min) and analyzed by two-dimensional electrophoresis at pH 1.9 and pH 3.5 (Boyle et al., 1991).

Assay of Time Resolved Microtubule Length Distribution by Video Microscopy

Video microscopy of microtubules was done essentially as described (Trinczek et al., 1993). Briefly, 10 µM phosphocellulose- purified porcine brain tubulin and MAP2 (1 µM), MAP4 (1 µM), or MAP2c (2 µM) were mixed in 50 mM sodium-Pipes, pH 6.9, containing 3 mM MgCl(2), 2 mM EGTA, 1 mM GTP, and 1 mM dithiothreitol. 1.0 µl of the samples was put on a slide, covered with an 18 times 18-mm coverslip, sealed, and warmed up to 37 °C in a temperature-controlled air flow within 5 s. A constant temperature of 37 °C was maintained by the air flow. The self-nucleated microtubules were recorded at time 2.5, 5, 10, 15, 20, 25, and 30 min after the temperature shift. For each condition and time, three sequential fields of a sample were scored spaced 10 s apart. Five to 10 experiments were analyzed, and the lengths of 500-800 microtubules were measured. Only those microtubules which were clearly located within the focal plane were included in the data set. The depth of solution was 3-4 µm, and the focal depth was 1-2 µm. The microtubule number concentrations as dependent on the presence of MAP2c and its mutants (unphosphorylated or phosphorylated) were measured in the same buffer as above with 2 µM MAP and 50 µM tubulin by counting the microtubules per monitor field (117 µm times 86 µm) 2-10 min after the temperature shift.

Binding Assays

The binding of MAPs to microtubules was determined as described previously (Gustke et al., 1992, 1994). Briefly, microtubules were assembled and stabilized by taxol, MAPs were added in varying amounts, the bound and unbound fractions were separated by pelleting, and proteins were quantified by scanning of the bands in SDS gels stained with Coomassie Brilliant Blue.

Sequence Comparisons and Terminology

In order to compare the three MAPs it is useful to describe their domains with a common nomenclature (Table 1, Fig. 1). The MAPs differ in size but contain regions of homologous sequences, and they have similar gross characteristics. Each of these MAPs has an acidic N-terminal region, followed by a basic region (containing the repeats), and a short acidic or neutral tail. The interaction with microtubules lies in the basic region. One can broadly distinguish between an N-terminal ``projection'' region and a C-terminal ``assembly'' region. This distinction is based on proteolytic cleavage which leaves the assembly domain attached to the microtubule wall while the projection domain is released (Murphy and Borisy, 1975; Vallee, 1980). A finer subdivision can be derived from the sequences, as follows.


Figure 1: Bar diagram of microtubule-associated proteins tau (human tau40, longest isoform), MAP2 (rat, juvenile isoform), and a C-terminal MAP4 fragment comprising the microtubule binding domain of murine MAP4. Acidic domains are shown in white, basic domains are shaded. For domain definitions see text (``Materials and Methods''). Locations of phosphorylation sites are indicated (see Table 1).



We delimit tau into an acidic N-terminal domain (Ala, residues Met^1 to Ala, containing the two near N-terminal inserts Glu-Glu and Asp-Thr, exons 2 and 3, which may be absent due to alternative splicing, see Goedert et al. (1989) and Himmler et al.(1989)), the basic region (``B,'' ``P,'' ``R,'' residues Gly to Ser, Fig. 1), and the acidic tail (``C,'' Gly to Leu). The basic region contains the proline-rich domain (``P,'' Ile-Leu, containing a chymotryptic cleavage site Tyr which subdivides ``P'' into ``P1'' and ``P2,'' and separates the projection and assembly domains), and the repeats (see below). In the ``big tau'' isoform of peripheral nerves, there is an insert of about 254 residues between positions Gln and Ala (judging from the rat sequence, exon 4a, Couchie et al., 1992); the nature of this insert is acidic so that the size of the acidic region is expanded 3-fold (from 119 to 379 residues).

In MAP2, the acidic N-terminal region extends from Met^1 to Ala, the basic region is Arg-Ser, and the neutral C-terminal tail is from Ser to Leu. The basic region contains a proline-rich domain (Leu-Leu) and the repeats (Arg-Ser); it also contains cleavage sites for trypsin (behind Lys and Arg, Wille et al.(1992) and thrombin (behind Arg, Ainsztein and Purich(1994)) which roughly separate projection and assembly domains. In MAP2c, the region Asp-Thr (1363 residues) is spliced out. Most of the insert has acidic character, except for the last 90 residues (Arg-Thr), and thus can be regarded as a large extension of the acidic N-terminal region (from 151 residues in MAP2c to 1424 in MAP2).

In MAP4, there is an acidic N-terminal domain (Met^1-Thr, including the acidic ``KDM'' domain Thr-Lys, a basic proline-rich domain (Asn-Arg) which can be subdivided into ``P'' (Asn-Ala, proline-rich) and ``SP'' (Thr-Arg, rich in Ser-Pro motifs), the basic repeats (Ala-Gly), and an acidic C-terminal tail (A1091-I1125). Repeats ``1a'' and ``2'' can be absent due to alternative splicing (Chapin et al., 1995).

The repeats are the most striking aspects of the three MAPs. They are typically 31-32 residues long, and are similar to one another within one MAP and between different MAPs. They can be subdivided into about approx13 residues of lower homology (sometimes referred to as the linker region or inter-repeat region), and the approx18 C-terminal residues of higher homology, the repeats proper, mostly ending with a PGGGX motif. The boundaries between the repeats can be chosen in different ways; we prefer the alignment shown in Table 1because in this case the ``second'' repeat of tau coincides exactly with one alternatively spliced exon (number 10, Val-Ser). The MAPs first cloned or sequenced contained three repeats (for tau, see Lee et al. (1988), for MAP2, Lewis et al.(1988) and Kindler et al.(1990), for MAP4, see Aizawa et al.(1989)). Later, other isoforms were found which contained four repeats (tau, Goedert et al.(1989) and Himmler et al.(1989); MAP2, Doll et al.(1993); MAP4, West et al.(1991) and Chapin and Bulinski(1991)). In addition it was realized that other stretches in the repeat domain were repeat-like, albeit with even lower homology (e.g. the 38-residue repeat following repeat ``1'' in MAP4 and the 32-residue repeat following repeat ``4'' in tau, Chapin and Bulinski(1992)). In order to unify the nomenclature we will denote the ``classical'' repeats (containing the higher degree of homology) as 1, 2, 3, and 4. One of these, 2, may be absent due to alternative mRNA splicing. The low homology repeat of MAP4 will be called 1a. The repeat following 4 will be ``4a.'' Thus Table 1shows 6 repeats, 5 of which are common to all three MAPs (1-4 and 4a), and 1a is specific for MAP4 (note that 4a of MAP4 shows less homology than the corresponding tau and MAP2 sequences). These repeats correspond to repeats 1-6 in Chapin and Bulinski(1992), and 4a was called R` in Gustke et al.(1994). The four classical repeats all contain a motif KXGS in repeats 1-4, with X = Ile, Cys, or Val (the minor exception is KCVS in repeat 2 of MAP4). In repeat 1a of MAP4 a similar motif is KAAGS. Repeat 4a contains motifs KTDH (tau), RVDH (MAP2), or AGEE (MAP4) in equivalent positions. Although formally not homologous to KXGS, they have the character of ``constitutively phosphorylated'' KXGS.


RESULTS

Phosphorylation of MAP2 and MAP4 by the Protein Kinase p110

Tau protein is phosphorylated efficiently on the KXGS motifs in its microtubule repeat region by a novel protein kinase, particularly at Ser in repeat 1 (Drewes et al., 1995). This type of phosphorylation leads to the loss of tau-microtubule interaction, and therefore we termed the kinase p110 (microtubule affinity regulating kinase). This posed the question if p110 could play a more general role, by phosphorylating other MAPs in an analogous way. As shown in Fig. 2A, brain MAP2 and its juvenile isoform, MAP2c (lanes 2-5) and heart/lung MAP4 (lanes 8 and 9), are readily phosphorylated by p110, with an efficiency comparable to the six tau isoforms (lanes 10 and 11). An E. coli expressed MAP4 fragment termed MAP4-BDC, comprising the C-terminal half which binds to microtubules (residues 640-1125), is also readily phosphorylated. As described previously for tau protein, phosphorylation of the other MAPs also leads to a small but significant shift toward higher M(r). The time course of phosphorylation of tau, MAP2c, and MAP4-BDC is also similar, leading to a saturation of the incorporation of P after 2-3 h (Fig. 2B). The final stoichiometry of phosphorylation was around 3 to 4 mol of phosphate/mol of MAP. The phosphorylation of recombinant MAP2c and tau by p110 is characterized by a similar K(m) value of around 30-50 µM, whereas the MAP4-BDC fragment is a somewhat better substrate with a K(M) of approximately 10 µM (Fig. 2C).


Figure 2: Phosphorylation of microtubule-associated proteins with p110. A, 5 µg of each MAP were phosphorylated with 0.1 microunits of p110and 1 mM [-P]ATP (100 Ci/mol) for 4 h at 37 °C. Phosphorylated proteins were analyzed by SDS-gradient PAGE (4-15%) and autoradiography. Lane 1, molecular weight markers; Lane 2, MAP2c, expressed in E. coli; Lane 3, MAP2c, phosphorylated; Lane 4, MAP2 from porcine brain; Lane 5, MAP2, phosphorylated; Lane 6, MAP4-BDC, expressed in E. coli; Lane 7, MAP4-BDC, phosphorylated; Lane 8, MAP4 from mouse; Lane 9, MAP4 from mouse, phosphorylated; Lane 10, tau, human isoforms, expressed in E. coli; Lane 11, tau, human isoforms, phosphorylated (B). Time course of phosphorylation of MAP4-BDC (triangles), MAP2c (squares), and tau (circles). C, double reciprocal plot showing initial rates of phosphorylation of MAP4-BDC (triangles), MAP2c (squares), and tau (circles) as dependent on their concentration. The inset shows the derived K and V(max) values.



As reported previously, p110 phosphorylated tau exclusively on serine residues. While phosphoamino acid analysis showed that the same is true for MAP2c, we found that MAP4 is also phosphorylated on threonine ( Table 2and Table 3).





Identification of the p110 Phosphorylation Sites on MAP2c and MAP2

For the determination of phosphorylation sites we used a strategy applied previously to tau protein in which two-dimensional phosphopeptide mapping by HV-TLE/TLC is combined with HPLC purification and sequencing of peptides. This approach gives a clear representation of the relative amount of phosphorylation at different sites, and thereby allows a distinction between major and minor sites. The specificity of p110 for sites on MAP2 was examined by tryptic digestion of P-phosphorylated MAP2 and MAP2c, the juvenile isoform, whose sequence is fully contained within the adult MAP2 isoforms. A comparison of the phosphopeptide maps obtained from recombinant MAP2c (Fig. 3A) and full-length brain MAP2 (Fig. 3B) indicates that the majority of spots, including the most prominent ones, stem from sites located within the MAP2c sequence. This was confirmed by mapping a mixture of equivalent amounts of both samples (Fig. 3D). HPLC fractionation of the digest (Fig. 3E) allowed the isolation and subsequent sequence determination of four major labeled peptides. Each purified peptide was localized within the pattern of the MAP2c digest by TLE/TLC of the peptide in combination with a small aliquot of the digest (not shown). The results are compiled in Table 2. The major phosphorylation site is Ser within the KCGS motif of repeat 3 (spot 2). A second major site is Ser within the KIGS motif of repeat 1. Minor sites are located outside the repeat region. Comparison of these data to the results obtained previously with tau shows that p110 displays a general specificity for the KXGS motifs in the microtubule binding domain. It is, however, interesting that the preference for the individual repeats of MAP2 differs from that seen with tau. While the KXGS sites in repeats 1 and 4 were the major sites in tau, the main target in MAP2 was in repeat 3, followed by that in 1. Furthermore, while we did not observe significant phosphorylation of sites within tau's projection domain, we found several such sites in MAP2c, and based on the additional unidentified spots seen in Fig. 3B there appear to be additional sites in full-length MAP2. These minor sites did not correspond to KXGS motifs.


Figure 3: Identification of phosphorylation sites on MAP2c and MAP2. 200 µg of MAP2c or full-length MAP2 were phosphorylated with 0.5 microunits of p110 for 2 h at 37 °C. After performic acid oxidation and trypsin digestion, peptides were analyzed by TLE/TLC (A-D) and HPLC (E). A, the juvenile MAP2 isoform, MAP2c, expressed in E. coli. B, full-length MAP2 (isolated from porcine brain). C, diagram of the more prominent spots with identification of the HPLC-purified and sequenced phosphopeptides (see Table 2). Spot 2 contains Ser (KXGS in repeat 3), spot 3 Ser (KXGS in repeat 1). D, mixture of A and B showing that the major sites on MAP2 and MAP2c are identical. E, separation of the tryptic digest of phosphorylated MAP2c by reversed phase HPLC (C(18)). Radioactive fractions were purified by a second HPLC run (not shown) and sequenced. The identification of phosphorylated peptides is compiled in Table 2, e.g. spot 2 contains the CGS motif of repeat 3, spot 3 contains the IGS motif of repeat 1, spots 1 and 4 are peptides outside the repeats.



Identification of p110 Phosphorylation Sites on MAP4

For the identification of the phosphorylation sites of p110 on MAP4, an E. coli-expressed fragment, MAP4-BDC, which comprises the C-terminal microtubule binding domain of mouse MAP4 and the acidic tail (residues 640-1125), and full-length MAP4 isolated from mouse tissue were analyzed. A comparison of the phosphopeptide map obtained from the basic fragment (Fig. 4A) with that from the native MAP4 (Fig. 4B) showed that there is only minor phosphorylation of sites that lie outside this region (Fig. 4C). In light of these findings, we concentrated on isolating and sequencing the phosphopeptides from the recombinant fragment (Fig. 4E and Table 3). Major sites were identified as Ser in the KVGS motif of repeat 1 (spot 3), and Ser in the KVGS motif of repeat 4 (spot 7). This pattern is similar to what we observed with tau (Drewes et al., 1995), but different from MAP2 where repeat 3 is the main target, as described above. An additional prominent target of p110 on MAP4 is Thr (Fig. 4B, spot 4). This site is within the proline-rich region which flanks the repeats at the N-terminal side. It is noteworthy that this part of the molecule is also thought to be involved in microtubule binding (Aizawa et al., 1991; Olson et al., 1995), but there is no pronounced homology to the proline-rich regions in MAP2 or tau (Fig. 1). The extent of phosphorylation at other N-terminal sites was minor.


Figure 4: Identification of phosphorylation sites on MAP4-BDC and MAP4. 200 µg of MAP4-BDC and 20 µg of full-length MAP4 were phosphorylated with 0.5 microunits of p110 for 2 h at 37° C. After performic acid oxidation and trypsin digestion, peptides were analyzed by TLE/TLC (A-D) and HPLC (E). A, MAP4 fragment MAP4-BDC, expressed in E. coli. B, full-length MAP4 (isolated from mouse tissue). C, diagram of the more prominent spots with identification of the HPLC-purified and sequenced phosphopeptides (see Table 3). Spot 3 contains Ser (KXGS in repeat 1), spot 7, Ser (KXGS in repeat 4). D, a mixture of A and B showing that the major sites on MAP4 are localized within the MAP4-BDC construct. E, separation of the tryptic digest of phosphorylated MAP4-BDC by reversed phase HPLC (C(18)). Radioactive fractions were purified by a second HPLC run (not shown) and sequenced. The identification of phosphorylated peptides is compiled in Table 3, e.g. spot 3 contains the VGS motif in repeat 1, spot 7 contains the VGS motif of repeat 4.



Effects of MAP Phosphorylation on Dynamic Instability of Microtubules

Under certain conditions, microtubules show abrupt transitions between phases of rapid shortening (``catastrophe'') and elongation (``rescue''), and are termed ``dynamically unstable'' (Mitchison and Kirschner, 1984). MAPs are able to suppress microtubule dynamic instability by decreasing the frequency of catastrophe or increasing rescue (Pryer et al., 1992; Drechsel et al., 1992; Panda et al., 1995; Trinczek et al., 1995)). Phosphorylation of MAPs affects this stabilizing capacity by lowering microtubule affinity, and as a result the mean length of microtubules decreases. This effect can be observed in a time resolved manner by video dark field microscopy of individual microtubules.

In the experiment shown in Fig. 5the concentration of tubulin was 10 µM to ensure that microtubules did not self-assemble. However, microtubules nucleated and grew upon addition of native MAP4 prepared from brain (Fig. 5A, open circles), native MAP2 (Fig. 5B, open circles), or recombinant MAP2c (Fig. 5C, open circles). In these control experiments, p110 was added together with the MAPs but without ATP so that phosphorylation could not proceed. In a parallel experiment under otherwise identical conditions, 1 mM MgATP was added together with the kinase. The effect of the phosphorylation by p110 appeared rapidly (Fig. 5, A-C, closed circles). After about 5 min, growth is largely inhibited. Some microtubule nucleation initially took place while the MAPs were not yet phosphorylated, but polymerization after this time was suppressed due to progressive phosphorylation of the MAPs. In another type of experiment, the MAPs were phosphorylated by p110 for 30 min prior to their addition to tubulin (Fig. 5, A-C, triangles). In this case, nucleation was also abolished. However, tubulin could still form polymers, as short microtubules of about 2 µm length could be observed when axonemes were added to promote nucleation. Analysis of mutant forms of MAP2c shows that the loss of binding capacity depends on the phosphorylation of both Ser in repeat 1 and Ser in repeat 3 (Fig. 5D). If only one of these sites is mutated, microtubule growth is still induced by the phosphorylated mutants.


Figure 5: Effects of unphosphorylated and p110-phosphorylated MAP4 (A), MAP2 (B), MAP2c (C), and MAP2c point mutants (D) on the length of self-nucleated microtubules measured by dark field microscopy. For each condition 500-800 microtubules were analyzed, and the mean length were plotted against time. Tubulin concentration was 10 µM in all cases, the concentration of MAP4 and MAP2 was 1 µM, that of MAP2c, 2 µM. In control experiments, ATP was omitted (-ATP). Open circles in A-C: the MAPs were preincubated for 30 min with 2.5 milliunits/ml p110(final concentration), but without ATP. By adding 10 µM tubulin, microtubules were nucleated and the mean microtubule length increased up to about 20 µm within 30 min. If ATP was present no self-nucleation occurred, showing that the phosphorylation of the MAPs prevented microtubule formation. Short microtubules of about 2 µm length could only be observed by adding axonemes (10-100 fmol) to promote seeded nucleation (open triangles in A-C). Closed circles in A-C: tubulin and MAP were mixed at 4 °C with 2.5 milliunits/ml of p110 (final concentration) and 1 mM ATP, and the temperature was shifted immediately to 37 °C (so that initially the MAPs were unphosphorylated). Microtubule growth was promoted in all three cases, but the final mean microtubule length was only about half of that observed for the unphosphorylated MAPs (compare to open circles). D, the effect of phosphorylation site point mutations of MAP2c. All proteins were preincubated with kinase and ATP as described above. Triangles, wild type MAP2c; closed circles, MAP2cA319 (KXGS in repeat 1 mutated to KXGA); squares, MAP2cA350 (KXGS in repeat 3 mutated to KXGA); closed squares, MAP2cA319/A350 (KXGS in both repeats mutated to KXGA).



The length histograms show the distribution of microtubule lengths at 5 min (Fig. 6, A-C) and 30 min (Fig. 6, D-F) after the addition of MAP and kinase. At 5 min, where the microtubules are still in the growing phase, the length distributions, peaking around 10 µm, are comparable in the presence or absence of ATP (kinase active or inactive, Fig. 6, A-C, open and closed circles). After 30 min the distribution of the control microtubules (no ATP) has become broader (Fig. 6, D-F, closed circles). However, incubation with ATP strongly suppresses long microtubule and shifts the distribution to short lengths (open circles in Fig. 6, D-F).


Figure 6: Microtubule length histograms obtained at 5 min (A-C) and 30 min (D-F) derived from the experiments shown in Fig. 5(open and closed circles). Each sample shows a pronounced peak at around 10 µm after 5 min (closed circles in A-C). If Mg-ATP was absent (closed circles in D-F), the distribution became broader and shifted to greater length at 30 min. By contrast, phosphorylation of the MAPs with p110successfully decreased the mean microtubule length within 30 min of incubation (open circles in D-F). n, number of microtubules analyzed.



In summary, the results show that phosphorylation by p110 has similar dramatic effects on the function of MAP2c, MAP2, and MAP4. Microtubule stabilization is progressively impaired when the kinase and ATP are added together with the MAP to the tubulin sample. Moreover, pre-phosphorylated MAPs are not able to support microtubule growth or even nucleation. These effects are comparable to the previously reported effects of p110 phosphorylation on tau (Drewes et al., 1995).

Effects of MAP Phosphorylation on MAP-microtubule Binding

To determine whether the effects of MAP phosphorylation on dynamic instability was due to a reduced interaction with microtubules, we performed binding studies with taxol-stabilized microtubules. As we had found previously for tau protein (Gustke et al., 1994; Trinczek et al., 1995), these data demonstrate that loss of affinity (or increase in K(d) value) correlates very well with increased dynamics. As shown in Fig. 7, non-phosphorylated, recombinant MAP2c binds tightly to taxol-stabilized microtubules with an apparent K(d) around 0.25 µM (open circles). In the non-phosphorylated state, three mutants (MAP2cA319, MAP2cA350, and MAP2cA319+350, having Ser and Ser in the KXGS motifs of repeats 1 and 3 mutated to Ala individually or both) show the same behavior (data not shown). However, after phosphorylation with p110 only the binding capacity of the wild-type MAP2c is dramatically affected. It decreases to 10% of the original value, and the K(d) thereby increases at least hundredfold (closed circles). With a single mutation of either Ser or Ser to Ala, the binding becomes weakened about 30-fold (K(d) increases to about 7 µM upon phosphorylation, open and filled squares). When both phosphorylation sites are mutated, the binding characteristics after phosphorylation remain almost unchanged as compared to the non-phosphorylated protein (triangles).


Figure 7: Effect of the phosphorylation by p110 on the binding of recombinant wild type MAP2c and MAP2c point mutants to taxol stabilized microtubules (30 µM tubulin dimers). The mutations are Ser to Ala at positions 319 and/or 350 of MAP2c, corresponding to 1682 and 1713 in the full MAP2 sequence (Table 1). Open circles, non-phosphorylated wild-type MAP2c. The binding is tight (K about 0.25 µM) and saturates around 17 µM ligand (approx1 MAP2c molecule per 2 tubulin dimers). Closed circles, wild-type MAP2c, phosphorylated previously with p110 (2.5 milliunits/ml) for 2 h. Note that there is essentially no binding. Closed and open squares, MAP2cA319 and MAP2cA350, phosphorylated previously with p110 (2.5 milliunits/ml) for 2 h. The affinity to microtubules has decreased markedly (K approx 7 µM) although the stoichiometry remains similar to the wild type MAP2c. Triangles, MAP2cA319/A350, phosphorylated previously with p110 (2.5 milliunits/ml) for 2 h. The binding is similar to the unphosphorylated protein, showing that the sensitivity to phosphorylation has disappeared.




DISCUSSION

Phosphorylation Sites on MAPs

Microtubules are dynamic polymers, and their dynamic behavior is regulated by cells according to their needs. MAPs and their phosphorylation state have a pronounced effect on microtubule dynamics, and indeed changes in MAP phosphorylation patterns accompany major rearrangements of microtubules during the cell cycle or during differentiation (Vandre et al., 1991; Dinsmore and Solomon, 1991; Halpain and Greengard, 1990; Preuss et al., 1995; Ookata et al., 1995). Our previous studies have focused mainly on the kinases and phosphatases regulating the phosphorylation of the neuronal tau protein, with emphasis on the hyperphosphorylation that plays a role in the neurofibrillary pathology of Alzheimer's disease. It was intriguing to note that many ``abnormal'' phosphorylation sites were in Ser-Pro or Thr-Pro motifs and can be phosphorylated by proline-directed kinases (such as MAPK, cdk5, or GSK-3) which are important in cellular signal transduction (for review, see Mandelkow and Mandelkow(1993)). Indeed, using phosphorylation-sensitive antibodies we observed that kinases of this class phosphorylate both MAP2 and tau in cells in a cell-cycle or differentiation dependent fashion (Berling et al., 1994; Preuss et al., 1995). Similar observations were made in other laboratories (e.g. Dinsmore and Solomon(1991) and Ookata et al.(1995)). There was, however, the puzzle that proline-directed phosphorylation had only a comparatively mild effect on microtubule stability; it was dwarfed by the much larger effect of another kinase activity which phosphorylated mainly KXGS motifs in tau (Biernat et al., 1993; Trinczek et al., 1995). The search for the kinase lead to a 110-kDa protein which was termed MARK because of its regulation of the affinity of tau to microtubules (Drewes et al., 1995). Given the specificity of the enzyme it was natural to ask whether the kinase would also phosphorylate related MAPs such as MAP2 and MAP4, and whether this would have similar consequences on microtubule stability. We show here that this is indeed the case.

Our results imply that the role of MARK in regulating MAP interactions with microtubules may be more general than expected. Because tau, localized primarily to axons, and MAP2, distributed in dendrites, are both substrates, MARK or related kinases could be active in different neuronal cell compartments. An even more general role is implied by the results with MAP4, since this ubiquitous MAP has been inferred to affect microtubule stability in dividing cells (Bulinski and Borisy, 1980; Parysek et al., 1984; Chapin and Bulinski, 1994; Olson et al., 1995). Thus far it has been difficult to determine what combination of MAPs, phosphorylation sites, kinases, and other factors are responsible for the pronounced increase in microtubule dynamics during mitosis. MAP4 was considered a likely candidate, as well as other related ones (e.g. XMAP from Xenopus eggs, Faruki and Karsenti(1994)). Regarding kinases, cdc2 and MAP kinases were suggested as potential triggers of microtubule reorganization (Gotoh et al., 1991; Verde et al., 1992; Lieuvin et al., 1994; Ookata et al., 1995). However, it remains to be seen whether these kinases act directly or via other intermediate steps. The weak effect of proline-directed phosphorylation on microtubule dynamics makes us believe that other kinases, such as MARK, may be involved. In this regard it is interesting that MARK is itself activated by phosphorylation, pointing to other kinase(s) upstream in the signaling pathway. (^2)

The phosphorylation of MAPs has been studied by a number of authors, and it is pertinent to ask how the results compare with ours. In most cases it was concluded that phosphorylated MAPs bound less tightly to microtubules and supported their assembly less efficiently (although exceptions were also noted, see Brugg and Matus, 1991). However, in the majority of studies, the phosphorylation sites involved in the regulation were not known, and indirect information, such as kinase consensus motifs, are not reliable (as illustrated for tau and CaM kinase by Steiner et al.(1990), or for MAP4 and cdc2 by Ookata et al., 1995). There are, however, a few cases where phosphorylation sites have been determined directly. Examples include the sites in MAP2 altered by PKC (Ainsztein and Purich, 1994), or the sites on tau phosphorylated by several kinases (PKA, PKC, Ca/calmodulin dependent kinase II, and the proline-directed kinases MAPK, GSK-3, cdc2, and related kinases, see below). While additional parameters need to be measured for the influence of site-specific modifications on microtubule dynamics to be rigorously assessed, the observations with tau (the MAP studied most comprehensively) allows a distinction to be made between the sites within and outside the repeat domain. The sites outside the repeats examined so far have either no effect on microtubule binding and dynamics, or only a moderate effect, reducing the stabilizing power of tau from ``high'' to ``medium'' (in the classification of Trinczek et al.(1995)). This includes the many Ser-Pro or Thr-Pro sites (phosphorylated by proline-directed kinases), as well as PKA or Ca/calmodulin dependent kinase II sites (Steiner et al., 1990; Scott et al., 1993; Brandt et al., 1994). Inside the repeats there are the KXGS motifs affected by MARK. One of these (Ser in repeat 1) eliminates the stabilizing power of tau, the others have only a modulatory influence. The KXGS motifs of tau can also be phosphorylated to some extent by PKC (Ser in repeat 3, Correas et al., 1992), PKA (mostly Ser and Ser in repeats 3 and 4, Scott et al.(1993) and Drewes et al.(1995)), and GSK-3 when activated by heparin (Ser in repeat 1, Song and Yang(1995)). (^3)In vivo the phosphorylation at KXGS motifs is normally low (Seubert et al., 1995), consistent with its tight association with microtubules. This implies that the kinases affecting KXGS motifs are normally down-regulated.

The results on the other MAPs echo those of tau. Phosphorylation sites outside the repeats may reduce the interaction with microtubules, but they do not eliminate it. For MAP4, this includes the sites Ser and Ser in the proline-rich domain (our numbering, see Table 1) which are potential targets of cdc2 (Ookata et al., 1995). Sites inside the repeats include the KGXS motifs which cooperate to eliminate the interaction with microtubules (see Fig. 7). They also include reported PKC sites in MAP2 at serines 1705, 1713, and 1730 (our numbering, Fig. 1; see Ainsztein and Purich, 1994). The second of these is in the KXGS motif of repeat 3. The example illustrates how PKC could exert a modulatory effect by phosphorylating one KXGS motif, while MARK would eliminate microtubule interactions by phosphorylating two motifs (in 1 and 3). In the case of MAP4, point mutants of KXGS motifs are not available, but in analogy with MAP2 and tau we expect that the full inhibition of microtubule binding by MARK resides in repeats 1, 4, or both. Other phosphorylation sites of MAP4 have not been determined thus far.

Most studies on MAPs emphasize their role as microtubule stabilizers, but it is worth noting that they have at least two additional functions. One is their role as ``spacers'' between microtubules and other cellular components (Chen et al., 1992). This is achieved mainly by the acidic N-terminal domain which may be short (as in MAP2c or tau) or long (as in MAP2 or MAP4). A third function is that of a docking site for cellular enzymes, including kinases and phosphatases or their cofactors (PKA, cdc2, PKC-, MAP kinase, PP-1, see Obar et al.(1989), Mandelkow et al.(1992), Baumann et al.(1993), Ookata et al.(1995), Lehrich and Forrest(1994), Reszka et al.(1995), and Sontag et al.(1995)). It is intriguing to speculate that the docked kinases may be activated by some signaling cascade and then phosphorylate their host protein or others nearby, thus modulating their association with the microtubule cytoskeleton.

Structural Implications

We conclude by commenting on possible structural implications of the phosphorylation by MARK. The main sites affecting microtubule binding and dynamics are in the repeat domain although this domain, taken by itself, interacts only rather weakly with microtubules (Ennulat et al., 1989; Joly and Purich, 1990; Butner and Kirschner, 1991; Gustke et al., 1994). On the other hand, the domains flanking the repeats, particularly the basic and proline-rich domains, cause strong binding to microtubules (Aizawa et al., 1991; Lee and Rook, 1992; Olson et al., 1995; Ookata et al., 1995); however, their phosphorylation has only a limited effect on microtubule interactions. We view the flanking domains as ``targeting'' domains which place the MAPs on the microtubule surface which then allows the ``catalytic'' repeat domains to affect microtubule stability, presumably by providing extra bonds between subunits and protofilaments (Gustke et al., 1994). This view would overcome the apparent discrepancy between the weak binding of the repeat domain to microtubules and the strong effect of phosphorylation in the repeats.

It still needs to be explained why certain sites in the KXGS motifs can have a major effect (e.g. in repeat 1 of tau, or in 1 and 3 of MAP2), independently of whether other KXGS motifs are phosphorylated as well. This conceptual difficulty could be overcome if one abandons the traditional models of MAP-microtubule interactions. These models have assumed that the repetitive elements in the MAP sequence correspond to the repetitive nature of the microtubule lattice, i.e. each repeat was thought to interact with a different tubulin subunit, but in an equivalent manner. In this picture one would expect that the phosphorylation of one repeat might release it from its subunit but leave the other repeats in place, and consequently one would expect that several phosphorylation sites would have to be combined before the MAP detaches from the microtubule.

There is, however, an alternative view: the repeats could be folded into a coherent structure, or ``buttoned up,'' such that they could link tubulin subunits in adjacent protofilaments on the microtubule surface. This interaction could be disrupted if the folding of the repeat domain were destroyed. Imagine a folded structure formed by several repeats of the MAPs in which the ``button'' was formed by several unphosphorylated KXGS motifs which could be ``unbuttoned'' by phosphorylation. Within this model, the positions of the most critical residues might be variable and depend on details of the surrounding sequence. This might explain the predominant role of the phosphorylation in repeat 1 of tau, compared with the cooperation between 1 and 3 in MAP2 or between 1 and 4 in MAP4. There is increasing evidence for a folded structure in the repeats: the two cysteines in repeats 2 and 3 of tau are in close proximity (Schweers et al., 1995), and the reaction of certain antibodies can only be explained by discontinuous epitopes involving a folded repeat domain (Lichtenberg-Kraag et al., 1992). Interestingly, the accessibility of the core of Alzheimer PHFs to proteases is also explained if one assumes that the repeats of tau are folded up; the result is that the resistant core is formed by peptides roughly equivalent to three repeats, but in different combinations (end of 1 plus 3, 4, 4a, or end of 1 plus 2, 3, 4, Jakes et al. (1991)). The details of this structure are not yet known, but it will be crucial for an understanding of the MAP-microtubule interaction in molecular terms.


FOOTNOTES

*
This work was supported by grants from the Deutsche Forschungsgemeinschaft and the Ministry of Science and Technology. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
The first two authors contributed equally to this work.

To whom correspondence should be addressed. Tel.: 49-40-89982810; Fax: 49-40-891314; mand{at}mpasmb.desy.de.

(^1)
The abbreviations used are: MAPs, microtubule-associated proteins; PKA, protein kinase A; PKC, protein kinase C; MAPK, mitogen-activated protein kinase; mark, MAP/microtubule affinity regulating kinase; HV-TLE, high voltage-thin layer electrophoresis; HPLC, high performance liquid chromatography; Pipes, 1,4-piperazinediethanesulfonic acid.

(^2)
G. Drewes, H. E. Meyer, E.-M. Mandelkow, and E. Mandelkow, unpublished data.

(^3)
R. Godemann, G. Schmitt-Ulms, S. Illenberger, J. Biernat, E.-M. Mandelkow, and E. Mandelkow, unpublished observations.


ACKNOWLEDGEMENTS

We thank Nicole Burmester and Heike Niebuhr for excellent technical assistance, and Dr. Craig Garner (University of Alabama) for providing the cDNA clone of MAP2c.


REFERENCES

  1. Ainsztein, A., and Purich, D. (1994) J. Biol. Chem. 269, 28465-28471 [Abstract/Free Full Text]
  2. Aizawa, H., Kawasaki, H., Murofushi, H., Kotani, S., Suzuki, K., and Sakai, H. (1989) J. Biol. Chem. 264, 5885-5890 [Abstract/Free Full Text]
  3. Aizawa, H., Emori, Y., Murofushi, H., Kawasaki, H., Sakai, H., and Suzuki, K. (1990) J. Biol. Chem. 265, 13849-13855 [Abstract/Free Full Text]
  4. Aizawa, H., Emori, Y., Mori, A., Murofushi, H., Sakai, H., and Suzuki, K. (1991) J. Biol. Chem. 266, 9841-9846 [Abstract/Free Full Text]
  5. Baumann, K., Mandelkow, E.-M., Biernat, J., Piwnica-Worms, H., and Mandelkow, E. (1993) FEBS Lett. 336, 417-424 [CrossRef][Medline] [Order article via Infotrieve]
  6. Berling, B., Wille, H., Röll, B., Mandelkow, E.-M., Garner, C., and Mandelkow, E. (1994) Eur. J. Cell Biol. 64, 120-130 [Medline] [Order article via Infotrieve]
  7. Biernat, J., Gustke, N., Drewes, G., Mandelkow, E.-M., and Mandelkow, E. (1993) Neuron 11, 153-163 [Medline] [Order article via Infotrieve]
  8. Binder, L. I., Frankfurter, A., and Rebhun, L. (1985) J. Cell Biol. 101, 1371-1378 [Abstract]
  9. Boyle, W. J., van der Geer, P., and Hunter, T. (1991) Methods Enzymol. 201, 110-149 [Medline] [Order article via Infotrieve]
  10. Brandt, R., Lee, G., Teplow, D. B., Shalloway, D., and Abdel-Ghany, M. (1994) J. Biol. Chem. 269, 11776-11782 [Abstract/Free Full Text]
  11. Brugg, B., and Matus, A. (1991) J. Cell Biol. 114, 735-743 [Abstract]
  12. Bulinski, J. C., and Borisy, G. G. (1980) J. Cell Biol. 87, 802-808 [Abstract]
  13. Burns, R. G., Islam, K., and Chapman, R. (1984) Eur. J. Biochem. 141, 609-615 [Abstract]
  14. Butner, K. A., and Kirschner, M. W. (1991) J. Cell Biol. 115, 717-730 [Abstract]
  15. Casnellie, J. E. (1991) Methods Enzymol. 200, 115-120 [Medline] [Order article via Infotrieve]
  16. Chapin, S. J., and Bulinski, J. C. (1991) J. Cell Sci. 98, 27-36 [Abstract]
  17. Chapin, S. J., and Bulinski, J. C. (1992) Cell Mot. Cytoskel. 23, 236-243 [Medline] [Order article via Infotrieve]
  18. Chapin, S. J., and Bulinski, J. C. (1994) Cell Motil. Cytoskel. 27, 133-149 [Medline] [Order article via Infotrieve]
  19. Chapin, S. J., Lue, C. M., Yu, M. T., and Bulinski, J. C. (1995) Biochemistry 34, 2289-2301 [Medline] [Order article via Infotrieve]
  20. Chen, J., Kanai, Y., Cowan, N., and Hirokawa, N. (1992) Nature 360, 674-677 [CrossRef][Medline] [Order article via Infotrieve]
  21. Correas, I., Diaz-Nido, J., and Avila, J. (1992) J. Biol. Chem. 267, 15721-15728 [Abstract/Free Full Text]
  22. Couchie, D., Mavilia, C., Georgieff, I., Liem, R., Shelanski, M., and Nunez, J. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 4378-4381 [Abstract]
  23. Dhamodharan, R., and Wadsworth, P. (1995) J. Cell Sci. 108, 1679-1689 [Abstract/Free Full Text]
  24. Dinsmore, J., and Solomon, F. (1991) Cell 64, 817-826 [Medline] [Order article via Infotrieve]
  25. Doll, T., Meichsner, M., Riederer, B. M., Honegger, P., and Matus, A. (1993) J. Cell Sci. 106, 633-640 [Abstract/Free Full Text]
  26. Drechsel, D. N., Hyman, A. A., Cobb, M. H., and Kirschner, M. W. (1992) Mol. Biol. Cell 3, 1141-1154 [Abstract]
  27. Drewes, G., Lichtenberg-Kraag, B., Döring, F., Mandelkow, E.-M., Biernat, J., Goris, J., Doree, M., and Mandelkow, E. (1992) EMBO J. 11, 2131-2138 [Abstract]
  28. Drewes, G., Trinczek, B., Illenberger, S., Biernat, J., Schmitt-Ulms, G., Meyer, H. E., Mandelkow, E.-M., and Mandelkow, E. (1995) J. Biol. Chem. 270, 7679-7688 [Abstract/Free Full Text]
  29. Ennulat, D. J., Liem, R. K. H., Hashim, G. A., and Shelanski, M. L. (1989) J. Biol. Chem. 264, 5327-5330 [Abstract/Free Full Text]
  30. Faruki, S., and Karsenti, E. (1994) Cell Motil. Cytoskel. 28, 108-118 [Medline] [Order article via Infotrieve]
  31. Field, J., Nikawa, J.-I., Broek, D., MacDonald, B., Rodgers, L., Wilson, I. A., Lerner, R. A., and Wigler, M. (1988) Mol. Cell. Biol. 8, 2159-2165 [Medline] [Order article via Infotrieve]
  32. Goedert, M. (1993) Trends Neurosci. 16, 460-465 [CrossRef][Medline] [Order article via Infotrieve]
  33. Goedert, M., Spillantini, M., Jakes, R., Rutherford, D., and Crowther, R. A. (1989) Neuron 3, 519-526 [Medline] [Order article via Infotrieve]
  34. Gotoh, Y., Nishida, E., Matsuda, S., Shiina, N., Kosako, H., Shiokawa, K., Akiyama, T., Ohta, K., and Sakai, H. (1991) Nature 349, 251-254 [CrossRef][Medline] [Order article via Infotrieve]
  35. Gustke, N., Steiner, B., Mandelkow, E.-M., Biernat, J., Meyer, H. E., Goedert, M., and Mandelkow, E. (1992) FEBS Lett. 307, 199-205 [CrossRef][Medline] [Order article via Infotrieve]
  36. Gustke, N., Trinczek, B., Biernat, J., Mandelkow, E.-M., and Mandelkow, E. (1994) Biochemistry 33, 9511-9522 [Medline] [Order article via Infotrieve]
  37. Halpain, S., and Greengard, P. (1990) Neuron 5, 237-246 [Medline] [Order article via Infotrieve]
  38. Himmler, A., Drechsel, D., Kirschner, M., and Martin, D. (1989) Mol. Cell Biol. 9, 1381-1388 [Medline] [Order article via Infotrieve]
  39. Hirokawa, N. (1994) Curr. Opin. Cell Biol. 6, 74-81 [Medline] [Order article via Infotrieve]
  40. Jakes, R., Novak, M., Davison, M., and Wischik, C. M. (1991) EMBO J. 10, 2725-2729 [Abstract]
  41. Joly, J. C., and Purich, D. L. (1990) Biochemistry 29, 8916-8920 [Medline] [Order article via Infotrieve]
  42. Kindler, S., Schulz, B., Goedert, M., and Garner, C. C. (1990) J. Biol. Chem. 265, 19679-19684 [Abstract/Free Full Text]
  43. Lee, G., and Rook, S. (1992) J. Cell Sci. 102, 227-237 [Abstract]
  44. Lee, G., Cowan, N., and Kirschner, M. (1988) Science 239, 285-288 [Medline] [Order article via Infotrieve]
  45. Lehrich, R. W., and Forrest, J. N., Jr. (1994) J. Biol. Chem. 269, 32446-32450 [Abstract/Free Full Text]
  46. Lewis, S. A., Wang, D., and Cowan, N. J. (1988) Science 242, 936-939 [Medline] [Order article via Infotrieve]
  47. Lichtenberg-Kraag, B., Mandelkow, E.-M., Biernat, J., Steiner, B., Schröter, C., Gustke, N., Meyer, H. E., and Mandelkow, E. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 5384-5388 [Abstract]
  48. Lieuvin, A., Labbe, J.-C., Doree, M., and Job, D. (1994) J. Cell Biol. 124, 985-996 [Abstract]
  49. Lindwall, G., and Cole, R. D. (1984) J. Biol. Chem. 259, 5301-5305 [Abstract/Free Full Text]
  50. Littauer, U. Z., Giveon, D., Thierauf, M., Ginzburg, I., and Ponstingl, H. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 7162-7166 [Abstract]
  51. Mandelkow, E.-M., and Mandelkow, E. (1993) Trends Biochem. Sci. 18, 480-483 [Medline] [Order article via Infotrieve]
  52. Mandelkow, E.-M., and Mandelkow, E. (1995) Curr. Opin. Cell Biol. 7, 72-81 [CrossRef][Medline] [Order article via Infotrieve]
  53. Mandelkow, E.-M., Herrmann, M., and Rühl, U. (1985) J. Mol. Biol. 185, 311-327 [Medline] [Order article via Infotrieve]
  54. Mandelkow, E.-M., Drewes, G., Biernat, J., Gustke, N., Van Lint, J., Vandenheede, J. R., and Mandelkow, E. (1992) FEBS Lett. 314, 315-321 [CrossRef][Medline] [Order article via Infotrieve]
  55. Meyer, H. E., Eisermann, B., Heber, M., Hoffmann-Posorske, E., Korte, H., Weigt, C., Wegner, A., Hutton, T., Donella-Deana, A., and Perich, J. W. (1993) FASEB J. 7, 776-782 [Abstract/Free Full Text]
  56. Mitchison, T., and Kirschner, M. (1984) Nature 312, 237-242 [Medline] [Order article via Infotrieve]
  57. Mori, A., Aizawa, H., Saido, T. C., Kawasaki, H., Mizuno, K., Murofushi, H., Suzuki, K., and Sakai, H. (1991) Biochemistry 30, 9341-9346 [Medline] [Order article via Infotrieve]
  58. Murphy, D. B., and Borisy, G. G. (1975) Proc. Natl. Acad. Sci. U. S. A. 72, 2696-2700 [Abstract]
  59. Obar, R. A., Dingus, J., Bayley, H., and Vallee, R. B. (1989) Neuron 3, 639-645 [Medline] [Order article via Infotrieve]
  60. Olmsted, J. B. (1991) Curr. Opin. Cell Biol. 3, 52-58 [Medline] [Order article via Infotrieve]
  61. Olson, K. R., McIntosh, J. R., and Olmstedt, J. B. (1995) J. Cell Biol. 130, 639-650 [Abstract]
  62. Ookata, K., Hisanaga, S., Bulinski, J. C., Murofushi, H., Aizawa, H., Itoh, T. J., Hotani, H., Okumura, E., Tachibana, K., and Kishimoto, T. (1995) J. Cell Biol. 128, 849-862 [Abstract]
  63. Panda, D., Goode, B. L., Feinstein, S. C., and Wilson, L. (1995) Biochemistry 34, 11117-11127 [Medline] [Order article via Infotrieve]
  64. Parysek, L. M., Asnes, C. F., and Olmsted, J. B. (1984) J. Cell Biol. 99, 1309-1315 [Abstract]
  65. Preuss, U., Döring, F., Illenberger, S., and Mandelkow, E.-M. (1995) Mol. Biol. Cell 6, 1397-1410 [Abstract]
  66. Pryer, N., Walker, R., Skeen, V., Bourns, B., Soboeiro, M., and Salmon, E. D. (1992) J. Cell Sci. 103, 965-976 [Abstract/Free Full Text]
  67. Reszka, A. A., Seger, R., Diltz, C. D., Krebs, E. G., and Fischer, E. H. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 8881-8885 [Abstract]
  68. Riederer, B., and Matus, A. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 6006-6009 [Abstract]
  69. Schoenfeld, T. A., and Obar, R. A. (1994) Int. Rev. Cytol. 151, 67-137 [Medline] [Order article via Infotrieve]
  70. Schweers, O., Mandelkow, E.-M., Biernat, J., and Mandelkow, E. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 8463-8467 [Abstract]
  71. Scott, C., Spreen, R., Herman, J., Chow, F., Davison, M., Young, J., and Caputo, C. (1993) J. Biol. Chem. 268, 1166-1173 [Abstract/Free Full Text]
  72. Seubert, P., Mawal-Dewan, M., Barbour, R., Jakes, R., Goedert, M., Johnson, G. V. W., Litersky, J. M., Schenk, D., Lieberburg, I., Trojanowski, J. Q., and Lee, V. M. Y. (1995) J. Biol. Chem. 270, 18917-18922 [Abstract/Free Full Text]
  73. Shiina, N., Moriguchi, T., Ohta, K., Gotoh, Y., and Nishida, E. (1992) EMBO J. 11, 3977-3984 [Abstract]
  74. Sloboda, R. D., Rudolph, S. A., Rosenbaum, J. L., and Greengard, P. (1975) Proc. Natl. Acad. Sci. U. S. A. 72, 177-181 [Abstract]
  75. Song, J. S., and Yang, S. D. (1995) J. Protein Chem. 14, 95-105 [Medline] [Order article via Infotrieve]
  76. Sontag, E., Nunbhakdicraig, V., Bloom, G. S., and Mumby, M. C. (1995) J. Cell Biol. 128, 1131-1144 [Abstract]
  77. Steiner, B., Mandelkow, E.-M., Biernat, J., Gustke, N., Meyer, H. E., Schmidt, B., Mieskes, G., Söling, H. D., Drechsel, D., Kirschner, M. W., Goedert, M., and Mandelkow, E. (1990) EMBO J. 9, 3539-3544 [Abstract]
  78. Studier, W. F., Rosenberg, A. H., Dunn, J. J., and Dubendorff, J. W. (1990) Methods Enzymol. 185, 60-89 [Medline] [Order article via Infotrieve]
  79. Theurkauf, W. E., and Vallee, R. B. (1983) J. Biol. Chem. 258, 7883-7886 [Abstract/Free Full Text]
  80. Trinczek, B., Marx, A., Mandelkow, E.-M., Murphy, D. B., and Mandelkow, E. (1993) Mol. Biol. Cell 4, 323-335 [Abstract]
  81. Trinczek, B., Biernat, J., Baumann, K., Mandelkow, E.-M., and Mandelkow, E. (1995) Mol. Biol. Cell 6, 1887-1902 [Abstract]
  82. Trojanowski, J. Q., and Lee, V. M. Y. (1994) Am. J. Pathol. 144, 449-453 [Medline] [Order article via Infotrieve]
  83. Tsuyama, S., Bramblett, G., Huang, K.-P., and Flavin, M. (1986) J. Biol. Chem. 261, 4110-4116 [Abstract/Free Full Text]
  84. Umeyama, T., Okabe, S., Kanai, Y., and Hirokawa, N. (1993) J. Cell Biol. 120, 451-465 [Abstract]
  85. Vallee, R. B. (1980) Proc. Natl. Acad. Sci. U. S. A. 77, 3206-3210 [Abstract]
  86. Vandre, D., Centonze, V., Peloquin, J., Tombes, R., and Borisy, G. G. (1991) J. Cell Sci. 98, 577-588 [Abstract]
  87. Verde, F., Dogterom, M., Stelzer, E., Karsenti, E., and Leibler, S. (1992) J. Cell Biol. 118, 1097-1108 [Abstract]
  88. Watanabe, A., Hasegawa, M., Suzuki, M., Takio, K., Morishima-Kawashima, M., Titani, K., Arai, T., Kosik, K. S., and Ihara, Y. (1993) J. Biol. Chem. 268, 25712-25717 [Abstract/Free Full Text]
  89. West, R. R., Tenbarge, K. M., and Olmsted, J. B. (1991) J. Biol. Chem. 266, 21886-21896 [Abstract/Free Full Text]
  90. Wille, H., Mandelkow, E.-M., Dingus, J., Vallee, R., Binder, L., and Mandelkow, E. (1992) J. Struct. Biol. 108, 49-61 [Medline] [Order article via Infotrieve]

©1996 by The American Society for Biochemistry and Molecular Biology, Inc.