Dimerization of the Muscle-specific Kinase Induces Tyrosine Phosphorylation of Acetylcholine Receptors and Their Aggregation on the Surface of Myotubes*

Carsten HopfDagger and Werner Hoch§

From the Max-Planck-Institut für Entwicklungsbiologie, Abteilung Biochemie, Spemannstrasse 35, D-72076 Tübingen, Germany

    ABSTRACT
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Abstract
Introduction
Procedures
Results
Discussion
References

During development of the neuromuscular junction, neuronal splice variants of agrin initiate the aggregation of acetylcholine receptors on the myotube surface. The muscle-specific kinase is thought to be part of an agrin receptor complex, although the recombinant protein does not bind agrin with high affinity. To specify its function, we induced phosphorylation and activation of this kinase in the absence of agrin by incubating myotubes with antibodies directed against its N-terminal sequence. Antibody-induced dimerization of the muscle-specific kinase but not treatment with Fab fragments was sufficient to trigger two key events of early postsynaptic development: acetylcholine receptors accumulated into aggregates, and their beta -subunits became phosphorylated on tyrosine residues. Heparin partially inhibited receptor aggregation induced by both agrin and anti-muscle-specific kinase antibodies. In contrast, it did not affect kinase or acetylcholine receptor phosphorylation. These data indicate that agrin induces postsynaptic differentiation by dimerizing the muscle-specific kinase. They also suggest that activation of the kinase domain can account for only part of agrin's effects. Dimerization of this molecule appears to activate an additional signal, most likely by organizing a scaffold for other postsynaptic proteins.

    INTRODUCTION
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Abstract
Introduction
Procedures
Results
Discussion
References

The basal membrane protein agrin plays a central role during the early phase of synaptic differentiation at the neuromuscular junction (1-3). Neuron-specific agrin isoforms containing an eight-amino acid insertion generated by alternative splicing (4-6) are able to induce the aggregation of AChRs1 and other synaptic proteins on the surface of myotubes (7-10). Deletion of the exon sequence encoding this insert in the agrin gene by homologous recombination in mice results in malformed and misplaced AChR clusters. Agrin(-/-) mice die due to respiratory failure (11).

The mechanism of agrin-induced AChR aggregation is not completely understood. Rapsyn, a peripheral membrane protein closely associated with AChRs (12-15), is an essential component of this pathway. In rapsyn-deficient mice, agrin is not able to induce the concentration of AChRs and other synaptic components (16). Inhibitor studies suggest an important role of tyrosine phosphorylation in this pathway (17). Agrin induces the tyrosine phosphorylation of the beta -subunit of the AChR (18). It is unknown whether this modification is necessary for AChR aggregation. alpha -Dystroglycan, a component of the dystrophin-associated glycoprotein complex, has been identified as the most abundant agrin-binding protein on the myotube surface (19, 20). However, the analysis of a series of agrin fragments has revealed no correlation between their binding to alpha -dystroglycan and their capability of inducing AChR aggregation (20-22).

Genetic experiments have demonstrated an essential role in the agrin pathway for a muscle-specific receptor tyrosine kinase (MuSK), which has recently been identified in different species (23-27). In mice, deletion of this gene prevents the concentration of AChRs and other proteins at the contact site between motoneuron and muscle fiber and is therefore lethal (23). MuSK is highly expressed in rat embryonic muscle and in the C2C12 mouse muscle cell line and colocalizes with AChRs at the neuromuscular junction (25, 27). Several observations suggest an important role of MuSK in the agrin pathway (28); incubation of myotubes with agrin causes the rapid tyrosine phosphorylation of MuSK (28). This reaction, a characteristic response of receptor tyrosine kinases to binding of their ligand (29, 30), is exclusively induced by biologically active fragments and isoforms of agrin.2 In addition, agrin can be cross-linked to MuSK expressed on myotubes (28). Upon transfection into the quail cell line QT-6, MuSK is concentrated in microaggregates together with rapsyn (31). Remarkably, the extracellular domain of the MuSK molecule is required for this interaction, which therefore must be indirect. It has been suggested that a hypothetical rapsyn-associated transmembrane linker (RATL) bridges these proteins (32).

Agrin does not directly bind to recombinant MuSK (28) (data not shown). Therefore, a MuSK-accessory specificity component (MASC) has been postulated, mediating its activation by agrin (28). To assess the role of MuSK in the agrin signaling pathway, it is important to activate this molecule independent of agrin. In an earlier attempt, a chimeric molecule consisting of the extracellular domain of the neurotrophin receptor TrkC and the intracellular domain of MuSK has been expressed in myotubes. The TrkC ligand neurotrophin 3 added to these myotubes induces the tyrosine phosphorylation of the chimeric receptor as well as AChRs, but not AChR aggregation (33). Here we took a different approach to bypass agrin in activating MuSK. We artificially dimerized MuSK by incubating myotubes with bivalent polyclonal antibodies directed against its N terminus. We demonstrate that MuSK is sufficient to trigger responses normally evoked by neuronal agrin isoforms; antibody-induced activation of MuSK causes aggregation of AChRs and the tyrosine phosphorylation of their beta -subunit with high efficiency. We also show that AChR aggregation but not AChR-phosphorylation is inhibited by heparin, suggesting the existence of multiple pathways activated by MuSK.

    EXPERIMENTAL PROCEDURES
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Abstract
Introduction
Procedures
Results
Discussion
References

Expression Constructs and Transient Transfection-- The soluble rat agrin constructs s-agrin-(4,19) and s-agrin-(0,8) have been described previously (34). Generation of the full-length MuSK construct has been reported elsewhere,2 and an expression construct coding for the extracellular part of MuSK was assembled by the addition of sequence coding for a hexahistidine tag followed by a stop codon to the appropriate site of the MuSK cDNA.3 COS-7 cells were transiently transfected with plasmids encoding soluble agrin (30 µg of DNA/15-cm dish) according to the method of Chen and Okayama (35). The collection of serum-free agrin-conditioned media and calibration of agrin concentrations has been described (34).

Antibodies and Fab Fragments-- Polyclonal antibody (pAb) Cyt-MuSK against a bacterial fusion protein comprising the first half of the cytoplasmic domain of MuSK was affinity-purified by absorption to the antigen immobilized on Affi-Gel (Bio-Rad). pAb N-MuSK was purified from a crude antiserum against a peptide (N-peptide) corresponding to 14 amino acids of the putative N terminus of MuSK by affinity chromatography on an immobilized N-terminal bacterial fusion protein. Both pAbs specifically recognize MuSK in immunoprecipitation and Western blot experiments.2 For the antibody specificity analysis shown in Fig. 1, membrane proteins were extracted from COS cells,2 whereas a plasma membrane fraction of C2C12 cells differentiated for 5 days in fusion medium was prepared as described (36).

The phosphotyrosine antibody mAb 5E2 (37) was a kind gift from Dr. A. Ullrich (Max-Planck-Institute for Biochemistry). The phosphotyrosine antibodies mAb PY20 and mAb 4G10 were purchased from Transduction Laboratories and Upstate Biotechnology Inc., respectively. mAb 124 (rat monoclonal) directed against the beta -subunit of the AChR (38) was a kind gift from Dr. J. Lindstrom (University of Pennsylvania). Purified polyclonal antibodies against extracellular epitopes of the TGFbeta R I and M-cadherin were purchased from Santa Cruz Biotechnology. Iodinated and horseradish peroxidase-conjugated secondary antibodies were from Amersham Corp. and Jackson/Dianova.

Fab fragments of pAb N-MuSK were generated by digestion with papain conjugated to agarose beads (Sigma) for 10 h at 37 °C. Fc fragments and undigested antibodies were removed by absorption to protein A-agarose (Calbiochem). Binding of the Fab fragments and pAb N-MuSK to N-peptide as well as the recombinant extracellular domain of MuSK3 was compared by enzyme-linked immunosorbent assay. Briefly, microtiter plates were coated with N-peptide, purified recombinantly expressed extracellular domain of MuSK, or bovine serum albumin. Thereafter, the plates were incubated with several concentrations of pAb N-MuSK or Fab fragments of these antibodies for 2 h at room temperature. Unbound antibodies were removed by extensive washing, and bound antibodies were reacted with biotin-conjugated anti-rabbit-Fab-antibodies (Jackson/Dianova) followed by streptavidin-conjugated horseradish peroxidase (Amersham). As the "active concentration" of Fab fragments, the concentration of pAb N-MuSK was defined that produced the same reactivity against the N-peptide in this enzyme-linked immunosorbent assay. At this concentration, Fab fragments also showed a similar reactivity toward the extracellular domain of MuSK as the intact antibody. For staining of MuSK- or mock-transfected COS cells under native conditions, COS cells were grown on polylysine-coated slides. Medium was replaced by C2C12 fusion medium containing antibody or Fab fragments ("active concentration" 30 nM, as determined by enzyme-linked immunosorbent assay). After incubation for 1 h at 37 °C, cells were washed, fixed in 2% paraformaldehyde, and incubated with biotin-conjugated anti-rabbit-Fab-antibodies followed by Cy3 conjugated to streptavidin.

Analysis of MuSK and AChR Tyrosine Phosphorylation-- C2C12 myoblasts were propagated as described previously (7). Unless indicated otherwise, cells were allowed to differentiate in 2.5% horse serum, 2 mM glutamine in DMEM (fusion medium) for 4-5 days. They were switched to 0.25% horse serum in DMEM for 3-12 h prior to stimulation with agrin or antibodies in various concentrations.

Immunoprecipitation of MuSK with Cyt-MuSK antiserum and enrichment of AChRs by binding to biotin-alpha -bungarotoxin (Molecular Probes) followed by incubation with streptavidin-agarose beads has been described previously.2 Precipitated proteins were resolved by SDS-PAGE on 10% gels and transferred to Fluorotrans membrane (Pall Filtron). Immunoreactive bands were visualized with horseradish peroxidase-conjugated secondary antibodies and chemiluminescent SuperSignal substrate (Pierce). Antibodies were stripped from the membranes with 0.2 M glycine, pH 2.5, 150 mM NaCl, 0.1% Nonidet P-40; blocked again; and reprobed with suitable antibodies. Some experiments were performed using 125I-conjugated secondary antibodies. Bound radioactivity was quantitated by PhosphorImager analysis (Molecular Dynamics) after 5-30 days of exposure.

To assess the ability of the N-peptide or heparin to neutralize pAb N-MuSK effects, myotubes were pretreated with a 10,000-fold molar excess of N-peptide (approximately 500 µg/ml) or suitable concentrations of heparin in DMEM for 45 min prior to stimulation. Antibody was preincubated with the same excess of N-peptide for 2 h at 4 °C.

Quantitation of Antibody-induced AChR Aggregation-- C2C12 myotubes were cultured on chamber slides (Nunc). After 21/2 days in fusion medium, they were stimulated with antibody preparations or agrin for 10-16 h. AChRs were visualized with rhodamine-alpha -bungarotoxin, and the number of AChR aggregates in at least 12 microscopic fields was quantitated as described previously (34). Many small AChR clusters were observed when formation of aggregates was induced with pAb N-MuSK. These were not included in our quantitation, since only clusters >5 µm in length were counted. In experiments with heparin or N-peptide, the cells were pretreated with these agents as outlined above. All experiments were performed 2-6 times. The number of AChR aggregates is displayed as the mean of 3-5 determinations ± S.E. Statistical significance of the observed differences was verified by t test analysis (p < 0.05).

    RESULTS
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Abstract
Introduction
Procedures
Results
Discussion
References

MuSK Antibodies Induce Tyrosine Phosphorylation of the Kinase-- Ligand-induced dimerization is an essential step for activation of receptor tyrosine kinases and in many cases is sufficient to activate these kinases (29, 30, 39). We therefore attempted to artificially dimerize and activate MuSK in the absence of agrin using a peptide antiserum directed against the N terminus of the MuSK protein.2 Polyclonal antibodies (pAb N-MuSK) affinity-purified from this serum recognized a single band in detergent extracts from COS cells transfected with a MuSK expression construct (Fig. 1A). A band of corresponding size was recognized by these antibodies in a plasma membrane preparation of the muscle cell line C2C12 (Fig. 1B). At least a subset of these antibodies was able to react with undenatured MuSK protein, since intact antibodies as well as Fab fragments bound to MuSK-transfected unfixed COS cells but not to mock-transfected controls (Fig. 1C). MuSK was concentrated in small patches on the surface of transfected COS-cells. Similar immunoreactive patches were observed when cells were fixed by incubation with paraformaldehyde prior to exposure to antibodies or Fab fragments (data not shown). This suggests a tendency for MuSK to self-aggregate.


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Fig. 1.   Specificity of N-MuSK antibodies. A, detergent extracts were prepared from COS cells (106) either mock-transfected or transfected with a MuSK expression construct. Proteins were concentrated by precipitation (49), separated by SDS-PAGE, transferred to Fluorotrans membrane, and probed with pAb N-MuSK (30 nM). B, total protein from COS cells transfected with a MuSK-expression construct (105 cells) and a plasma membrane preparation of the muscle cell line C2C12 (5 × 106 cells) were solubilized in SDS-PAGE sample buffer and analyzed as described above. The major protein recognized by pAb N-MuSK in C2C12 cells comigrated with MuSK expressed in COS cells. A minor band migrating slightly higher most likely also represented MuSK immunoreactivity, since a similar band was recognized by antibodies directed against the cytoplasmic part of MuSK (data not shown). C, COS cells transfected with a MuSK expression construct or mock-transfected controls were incubated with pAb N-MuSK (30 nM) or Fab fragments of pAb N-MuSK (active concentration of 30 nM, as determined by enzyme-linked immunosorbent assay) for 1 h at 37 °C. After washing and fixation, bound antibodies were detected by incubation with a biotinylated anti-rabbit Fab-specific antibody and Cy3-labeled streptavidin. Bar, 10 µm.

In a first set of experiments, we assessed the ability of these antibodies to induce tyrosine phosphorylation of MuSK by incubating differentiated C2C12 myotubes for 1 h. After this stimulation, MuSK was immunoprecipitated from detergent extracts of the cells using a fusion protein antiserum directed against its intracellular domain.2 Phosphorylation of the MuSK molecule on tyrosine residues was detected by probing of Western blots with phosphotyrosine-specific antibodies. Incubation of myotubes with two concentrations of pAb N-MuSK indeed significantly induced tyrosine phosphorylation of the kinase (Fig. 2A). Several control experiments indicated that antibody-induced phosphorylation was specific: 1) phosphorylation was greatly reduced in the presence of a 10,000-fold molar excess of the N-peptide, against which the antiserum had been raised; 2) high concentrations of control antibodies directed against an intracellular region of MuSK (pAb Cyt-MuSK)2 did not cause phosphorylation of MuSK; 3) Fab fragments derived from N-MuSK antibodies had no effect, although they bound similar amounts of antigen as compared with pAb N-MuSK (Fig. 1C and data not shown). This observation indicated that bivalency of the antibodies was necessary to induce phosphorylation of MuSK, suggesting that pAb N-MuSK was able to dimerize the kinase. Reprobing the blot with MuSK-specific antibodies demonstrated that variations in the amounts of MuSK protein that had been precipitated did not account for the differences in tyrosine phosphorylation.


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Fig. 2.   The polyclonal antibodies N-MuSK induce tyrosine phosphorylation of MuSK and the AChR. C2C12 myotubes were treated with two concentrations (30 and 6 nM) of pAb N-MuSK with pAb N-MuSK (30 nM) in the presence of a 10,000-fold excess of N-peptide, with Fab fragments of pAb N-MuSK (active concentration 30 nM) or with pAb Cyt-MuSK (30 nM) for 60 min. A, cells were lysed and immunoprecipitated with Cyt-MuSK antiserum. Immunocomplexes were washed extensively, eluted with SDS sample buffer, and resolved by SDS-PAGE on a 10% gel. After transfer to Fluorotrans membrane, Western blot analysis (WB) was performed with a mixture of phosphotyrosine-specific monoclonal antibodies (PY) followed by horseradish peroxidase-conjugated secondary antibodies (top). Bound antibodies were removed, and the membrane was reprobed with pAb N-MuSK (bottom). Immunoreactive material below the arrow represents a proteolytic fragment of MuSK.2 B, cells were lysed and precipitated with biotin-alpha -bungarotoxin and streptavidin-agarose. Bound proteins were analyzed as described in A (top). The membrane was reblotted with mAb 124, recognizing the beta -subunit of the AChR (lower panel).

Antibodies against MuSK Trigger Tyrosine Phosphorylation of the beta -Subunit of the AChR-- Agrin induces the tyrosine phosphorylation of the beta -subunit of the AChR in chick and C2C12 myotubes cultures (18, 40). We therefore investigated whether antibody-induced dimerization of MuSK had similar effects. We isolated AChRs from detergent extracts of myotubes treated with pAb N-MuSK or from control preparations. Antibody-induced dimerization of MuSK caused a significant and dose-dependent increase in tyrosine phosphorylation of the AChR beta -subunit (Fig. 2B). We conclude that dimerization of MuSK induced not only kinase autophosphorylation but also the phosphorylation of a downstream target. Only bivalent N-MuSK-antibodies were able to induce AChR phosphorylation; Fab fragments or control antibodies had no effect. Reprobing of the blot with a monoclonal antibody directed against the beta -subunit showed that comparable amounts of AChR were precipitated from the detergent extracts in all samples.

Antibodies against MuSK Induce Aggregation of AChRs-- Next, we asked whether activation of MuSK alone is sufficient to induce not only phosphorylation but also clustering of AChRs. We incubated C2C12 myotubes with pAb N-MuSK or with soluble nerve agrin (s-agrin (4, 19)) for 12 h, visualized AChRs with rhodamine-conjugated alpha -bungarotoxin, and analyzed their distribution.

Agrin caused the redistribution of AChRs into large aggregates on the surface of myotubes (Fig. 3A). Strikingly, N-MuSK antibodies were able to trigger a similar aggregation in the absence of agrin (Fig. 3B), whereas untreated myotubes rarely bore AChR clusters (Fig. 3C). The effect of anti-MuSK antibodies was specific; antibodies against an extracellular region of M-cadherin (pAb M-cadherin), which stains the neuromuscular junction in adult mouse skeletal muscle (41), did not induce a significant number of AChR clusters (Fig. 3D). Antibodies directed against TGFbeta R I and a cytoplasmic region of MuSK also had no effect (data not shown). Typically, upon extended incubation, agrin induced long AChR patches (>5 µm in length) on C2C12 myotubes (Fig. 3A). In addition to these aggregates, pAb N-MuSK treatment often induced small AChR-rich patches that were not included in our quantitative analysis of antibody-induced AChR clustering.


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Fig. 3.   The polyclonal antibodies N-MuSK induce the aggregation of AChRs on the surface of C2C12 myotubes. C2C12 myotubes were incubated with s-agrin (4, 19) (20 pM) (A); pAb N-MuSK (15 nM) (B); DMEM (control) (C), or pAb M-cadherin (30 nM) (D) for 10 h. AChRs were visualized with rhodamine-alpha -bungarotoxin. Bar, 20 µm.

The aggregating activity of pAb N-MuSK was specific (Fig. 4A) and dose-dependent (Fig. 4B). Even higher concentrations of antibodies directed against extracellular domains of M-cadherin and TGFbeta R I, an unrelated receptor protein of the muscle surface, had no effect on the distribution of AChRs. An excess of N-peptide abolished the AChR-aggregating effects of pAb N-MuSK. As in our MuSK and AChR phosphorylation experiments, dimerization of the MuSK molecule was required for AChR clustering, Fab fragments of pAb N-MuSK did not induce AChR aggregation (Fig. 4A).


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Fig. 4.   Antibody-induced AChR clustering is specific and dose-dependent. AChR aggregates induced by pAb N-MuSK and control antibodies were quantified. A, C2C12 myotubes were treated with pAb N-MuSK (30 nM) alone or in the presence of a 10,000-fold molar excess of N-peptide, with pAbs against M-cadherin and against TGFbeta R I (both 60 nM), with Fab fragments (active concentration 30 nM) derived from pAb N-MuSK, or with DMEM (control) for 16 h. After staining with rhodamine-alpha -bungarotoxin, AChR clusters in at least 12 microscopic fields were counted. One representative experiment performed in triplicate is shown (mean ± S.E.). B, concentration dependence of antibody-induced aggregation of AChR. C2C12 myotubes were treated with different concentrations of pAb N-MuSK. Mean numbers of aggregates ± S.E. from five culture chambers are shown. The number of AChR aggregates induced by all concentrations of MuSK antibodies used in these experiments was significantly different from the number of spontaneous clusters observed in the absence of effector (t test; p < 0.01)

MuSK Antibodies Induced MuSK Phosphorylation with Higher Efficiency than AChR Phosphorylation and Aggregation-- The experiments described above demonstrated that MuSK activation alone mimics effects normally triggered by agrin. However, they could not exclude the possibility that interactions of agrin with components of the myotube surface not connected to MuSK (e.g. alpha -dystroglycan) play a synergistic role in initiating AChR aggregation. To set a limit for the potential effects of such MuSK-independent effects of agrin, it was important to compare the ability of agrin and anti-MuSK antibodies to induce different effects more quantitatively. C2C12 myotubes were stimulated with various concentrations of pAb N-MuSK and s-agrin (4, 19) or with DMEM (control). From one aliquot of the cell lysates, MuSK was immunoprecipitated; from another, AChRs were affinity-purified. In both preparations, tyrosine phosphorylation evoked by the two effectors was measured by quantitative Western blot analysis. In the concentration range used in this experiment, pAb N-MuSK induced a higher degree of MuSK phosphorylation than agrin, whereas AChR phosphorylation was triggered with reversed efficiencies (Fig. 5). For example, 40 pM agrin induced a comparable level of MuSK phosphorylation as 24 nM pAb N-MuSK, but 3-fold higher antibody concentrations were required to match the ability of 40 pM agrin to cause AChR phosphorylation. Similarly, 3-fold higher concentrations of antibody were required to induce AChR aggregation in comparison with MuSK phosphorylation (data not shown). Thus, a potential activation of MuSK-independent receptors by agrin can at best play a small synergistic role in the agrin signaling pathway.


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Fig. 5.   Comparison of antibody- and agrin-induced tyrosine phosphorylation of MuSK and the AChR. C2C12 myotubes were stimulated with different concentrations of s-agrin-(4,19) or pAb N-MuSK or with DMEM (control). The cell lysate was split into two aliquots; MuSK and AChRs, respectively, were enriched as outlined in the legend to Fig. 2. Proteins were resolved by SDS-PAGE, and Western blots were probed with phosphotyrosine antibodies and radioiodinated secondary antibodies. Blot membranes were exposed to a PhosphorImager screen for 4 days (top). The intensity of the immunoreactive band representing MuSK or the AChR beta -subunit was quantified and plotted (bottom) as relative phosphorylation (100%; effect of 1000 pM agrin).

Antibody-induced AChR Aggregation, but Not Tyrosine Phosphorylation of MuSK or AChRs Is Inhibited by Heparin-- The possibility of activating AChR aggregation in the absence of agrin allowed us to further delineate a target for the action of heparin, a well known inhibitor of nerve- as well as agrin-induced clustering of AChRs (42, 43). This inhibitor could prove useful in studies aiming at an understanding of the mechanisms by which MuSK activation triggers AChR aggregation. While heparin directly binds to a subset of agrin isoforms (21, 22, 44), this direct binding to agrin only accounts for part of its inhibitory effects. Recently, we showed that heparin acts as an inhibitor at an additional step in the agrin pathway (34), which has not been identified.

To narrow down this second target of heparin, we investigated whether heparin differentially affects AChR aggregation induced by agrin or anti-MuSK antibodies. High concentrations of heparin reduce the amount of AChR aggregates induced by a non-heparin-binding agrin isoform by 55-75% (34). Upon inducing AChR aggregation by incubation of myotubes with anti-MuSK antibodies, we observed an ~80% reduction in the number of AChR clusters (Fig. 6A), demonstrating that the target mediating this heparin inhibition is not localized up-stream of MuSK.


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Fig. 6.   Heparin partially inhibits AChR aggregation but not tyrosine phosphorylation of MuSK or the AChR. A, partial inhibition of antibody-induced aggregation of AChR by high concentrations of heparin. C2C12 myotubes were incubated with 30 nM pAb N-MuSK in the absence or presence of 300 µg/ml heparin for 16 h and analyzed as described in the legend to Fig. 3. Mean numbers of AChR aggregates ± S.E. (n = 5) are presented. B, heparin does not affect antibody- or agrin-induced tyrosine phosphorylation of either MuSK or AChR. Myotubes (after 2 days of differentiation in fusion medium) were preincubated with 0, 5, 30, or 200 µg/ml heparin for 45 min. They were then either left untreated or stimulated with an agrin isoform that does not bind heparin (s-agrin-(0, 8); 1 nM) or with pAb N-MuSK (200 nM) in the presence of identical heparin concentrations. Cell lysates were processed, and tyrosine phosphorylation was analyzed as described in Fig. 5. One representative of four experiments with similar results is shown.

Next, we assessed whether heparin blocks phosphorylation of MuSK and AChRs to a similar extent as it inhibits AChR aggregation. We incubated C2C12 myotubes with a non-heparin-binding agrin isoform or MuSK antibodies in the presence of different concentrations of heparin. Then we precipitated MuSK by incubation with our fusion protein antiserum and AChRs by absorption to biotin-alpha -bungarotoxin and analyzed their phosphotyrosine content (Fig. 6B). Surprisingly, neither MuSK nor AChR phosphorylation was significantly affected by the presence of heparin. Similar results were obtained with lower concentrations of agrin and pAb N-MuSK (data not shown).

These experiments provided additional evidence that heparin acts downstream from MuSK. In addition, they identify heparin as the first agent that selectively affects AChR aggregation but not its phosphorylation.

    DISCUSSION
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Abstract
Introduction
Procedures
Results
Discussion
References

The goal of our study was to specify the role of MuSK in the assembly of the postsynaptic apparatus induced by agrin. We have shown that incubation of myotubes with antibodies against MuSK triggers the tyrosine phosphorylation of MuSK. More importantly, we have demonstrated that this antibody-induced cross-linking is sufficient to induce similar effects as treatment of myotubes with agrin; AChRs started to aggregate, and their beta -subunits became phosphorylated on tyrosine residues.

Fab fragments of pAb N-MuSK did not trigger similar effects, although they bound to MuSK to a similar extent as bivalent antibodies in several control experiments. We found no evidence for binding of our antibodies to other cell surface proteins besides MuSK. Furthermore, the small size of the N-peptide (14 amino acids) against which N-MuSK antibodies are directed makes it very unlikely that more than one antibody at a time bound to MuSK's N terminus. Based on these considerations, we conclude that the observed AChR aggregation is caused by a selective dimerization of MuSK and cannot be attributed to extensive cross-linking of this molecule.

In comparison with agrin, anti-MuSK antibodies displayed slightly different efficiencies of MuSK phosphorylation versus AChR phosphorylation and aggregation. These differences could indicate the synergistic participation of a hypothetical MuSK-independent signal, which is triggered by agrin but not by the antibodies. However, in a detailed study of the ligand specificity of agrin-induced effects, no evidence was found for the existence of such a signal.2 Alternatively, the reduced level of AChR phosphorylation and aggregation in our experiments was due to a slightly altered conformation of the agrin receptor complex in response to antibody-induced but not agrin-induced MuSK dimerization and/or an incomplete activation of the kinase domain of MuSK (Fig. 7). While the mode of activation of MuSK has not been analyzed so far, a stepwise autophosphorylation and activation process has previously been described for other receptor tyrosine kinases, e.g. the insulin receptor (45).


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Fig. 7.   Model of agrin receptor activation by three different methods. The left panel shows a schematic view of the physiological activation of MuSK by agrin. In addition to MuSK, two hypothetical components of the agrin receptor complex are depicted that have not been identified so far: a MASC, which mediates agrin-binding, and a RATL, connecting the extracellular domain of MuSK with Rapsyn, which itself is closely associated with AChRs. The middle panel shows the activation of the receptor by anti-MuSK antibodies. The slightly tilted MuSK-dimer symbolizes a reduced activation state. Both MuSK and RATL are shown associated with MuSK under these conditions, although the presence of only one of these receptor components would be sufficient to account for AChR aggregation as explained here. In the right panel, the activation of a chimeric receptor is depicted, consisting of the intracellular domain of MuSK and an extracellular domain taken from the TrkC molecule, which is activated by binding of neurotrophin 3 (NT3) (33). In all three cases, the kinase function of MuSK is activated (signal 1), which is sufficient to trigger AChR phosphorylation. In contrast, signal 2, required for AChR aggregation in addition to signal 1, is only activated in the first two scenarios. This signal, which is not well characterized, is inhibited by heparin. It is generated by the presence of MASC and/or RATL, which could build a molecular scaffold concentrating AChRs and other synaptic proteins.

While this manuscript was in preparation, another report described the activation of MuSK by a single chain antibody (46). In agreement with our results, this activation was sufficient to trigger the phosphorylation and aggregation of AChRs, although these effects were not studied quantitatively. In contrast to our antibodies directed against the N terminus of MuSK, several monovalent antibodies directed against unknown regions of the extracellular domain of MuSK caused the activation of the kinase. Surprisingly, bivalency of these antibodies was not required, suggesting a different mode of activation (47).

The effects of antibody-induced activation of MuSK described here demonstrate that anti-MuSK antibodies are a useful tool for elucidating MuSK's role in the agrin pathway. The comparison of our results with those of other attempts to activate MuSK agrin-independently (33) highlights a major difference between MuSK and other receptor tyrosine kinases: the crucial role of the extracellular domain of MuSK. Glass et al. (33) stimulated a chimeric receptor consisting of the extracellular domain of TrkC and the intracellular domain of MuSK with neurotrophin 3 and thereby efficiently induced phosphorylation of the chimera and the AChR. However, activation of TrkC/MuSK did not lead to the aggregation of AChR on the surface of C2C12 myotubes (Fig. 7). Clearly, stimulating the kinase activity of MuSK alone cannot account for AChR aggregation. In addition to the MuSK/TrkC chimera, antibody-induced dimerization of the full-length MuSK molecule and concomitant redistribution of putative MuSK-associated proteins was able to induce not only the phosphorylation of AChRs but also their aggregation.

This functional difference directly points at an essential role of the extracellular domain of MuSK. An inherent organizing function has previously been suggested by cotransfection experiments in a quail fibroblast cell line (31, 32). In this system, a kinase-defective mutant of the Torpedo MuSK ortholog (31) and a MuSK fragment in which most of the cytoplasmic domain had been deleted (32) were aggregated by cotransfected rapsyn. In muscle cells, a kinase-defective mutant of rat MuSK suppressed AChR clustering (33), demonstrating the requirement of tyrosine kinase activity for this process.

Our data complement the suggestion that two signals are necessary to induce the aggregation of AChRs in myotubes (Fig. 7) (32, 48); the first signal is the kinase activity of MuSK, and the second signal appears to originate from the physical association of other proteins with MuSK. It is neither known in which way this scaffolding depends on MuSK activation nor which proteins associate with MuSK. The most likely candidate appears to be RATL, which might directly tether rapsyn and the stoichiometrically complexed AChRs to MuSK (32). Alternatively, the passive redistribution of MASC induced by MuSK dimerization could be important for AChR aggregation. This second possibility appears less likely, since our data showed that a direct activation of MASC by the binding of agrin is not essential for this pathway. Any signal that might be triggered by the binding of agrin to MASC can be bypassed by the dimerization of MuSK.

Two types of inhibitors of the agrin pathway have been characterized so far. Staurosporin, an inhibitor of tyrosine kinases, blocks both phosphorylation and aggregation of AChRs (17) and apparently inhibits the first signal in the pathway (Fig. 7); our data suggest that heparin represents a second type of inhibitor, which interferes with the second signal. Heparin treatment caused a MuSK/TrkC-like "phenotype"; it inhibited AChR aggregation induced by a non-heparin-binding agrin isoform (34) and by anti-MuSK antibodies by more than 80%. Strikingly, it did not affect the phosphorylation of either MuSK or AChRs. This selective interference with receptor aggregation would be expected from a reagent interfering exclusively with the second signal in the agrin pathway. The extracellular domain of MuSK, which is involved in this step, is accessible to heparin and other polyanions added into the medium. The protein directly interacting with heparin has not been identified so far, but RATL is an interesting candidate.

The availability of specific activators and inhibitors of the agrin signaling pathway should be useful in the future to identify the missing players and understand how they interact with the already identified components.

    ACKNOWLEDGEMENTS

We thank Sigrun Helms and Vicky Kastner for excellent technical assistance, Axel Ullrich and Jon Lindstrom for the generous gift of antibodies, and Rongxing Gan and Uli Schwarz for critical reading of the manuscript. We also express our gratitude to Uli Schwarz for support.

    FOOTNOTES

* This work was supported by the Max-Planck Society.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger Supported by the Graduiertenkolleg Neurobiologie Tübingen.

§ To whom correspondence should be addressed: Max-Planck-Institut für Entwicklungsbiologie, Abteilung Biochemie, Spemannstr. 35, D-72076 Tübingen, Germany. Tel.: 07071-601415; Fax: 07071-601447; E-mail: werner.hoch{at}tuebingen.mpg.de.

1 The abbreviations used are: AChR, nicotinic acetylcholine receptor; DMEM, Dulbecco's modified Eagle's medium; MuSK, muscle-specific kinase; MASC, MuSK-accessory specificity component; mAb, monoclonal antibody; pAb, polyclonal antibody; RATL, rapsyn-associated transmembrane linker; s-agrin, soluble agrin; PAGE, polyacrylamide gel electrophoresis; TGFbeta R I, transforming growth factor beta  receptor I.

2 C. Hopf and W. Hoch, submitted for publication.

3 C. Hopf and W. Hoch, unpublished results.

    REFERENCES
Top
Abstract
Introduction
Procedures
Results
Discussion
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