Neuromuscular synapse formation is driven by two nerve-derived molecules, agrin and neuregulin. Agrin is believed to signal through a Muscle Specific Kinase (MuSK)/Lrp4 receptor complex to cluster existing acetylcholine receptors (AChRs) in the postsynaptic membrane via a rapsyn-mediated mechanism, while neuregulin signals via ErbB kinase receptors to induce synaptic gene transcription. Recent studies suggest that neuregulin-ErbB signalling may also cross-signal to the agrin-MuSK pathway to modulate agrin’s ability to cluster AChRs. This thesis aimed to further elucidate this idea. Results of this thesis present two novel findings. First, there is a direct interaction between two tyrosine kinase signalling pathways at the neuromuscular synapse and second, neuregulin plays an important role in modulating, modifying and refining AChRs at developing synapses. Here I show that neuregulin can modulate two distinct processes. In the presence of agrin, neuregulin was able to potentiate both agrin-induced AChR clustering and agrin-induced AChR cluster dispersal, and this modulation by neuregulin occurred independently of any transcriptional mechanism. In vitro, I observed a marked effect by neuregulin on the number and size of AChR clusters that were induced by agrin. Treatment of myotubes for 4hrs with agrin and neuregulin led to a significant potentiation in agrin-induced AChR clustering compared to agrin treatment alone. Neuregulin on its own had no measurable effect on AChR clustering. When incubation times were much longer (12hrs), neuregulin promoted a further significant decrease in AChR cluster number compared to agrin treatment alone. Thus at 12hrs, rather than inhibit AChR clustering, as has been previously suggested, neuregulin promoted the dispersal of AChRs from pre-existing agrin-induced clusters. Follow-up in vivo studies into the potentiating ability of neuregulin in agrin-induced AChR clustering showed that the injection of exogenous neuregulin into developing mouse sternomastoid musculature led to an increase in the size of AChRs. Collectively, these data suggest interactions between the signalling pathways initiated by agrin and neuregulin. Subsequent investigation into the second messengers downstream of agrin-MuSK and neuregulin-ErbB signalling revealed that cyclin-dependent kinase 5 (Cdk5) and Shp2 played a role in neuregulin’s modulation of AChR cluster formation and dispersal. It appears that neuregulin enhances the phosphorylation status of MuSK by inhibiting the Shp2-dependent negative feedback loop on MuSK phosphorylation, thereby leading to an increase in AChR cluster numbers. By contrast, the way in which neuregulin disperses agrin-induced AChR clusters seems to occur partially, via a Cdk5 signalling-dependent mechanism. While it is accepted that neuregulin acts in a transcriptional manner during neuromuscular synapse formation, real-time PCR and immunoblot results suggest that transcriptional regulation was not involved in neuregulin’s modulation of agrin-induced AChR clustering.
| Identifer | oai:union.ndltd.org:ADTP/279135 |
| Creators | Shyuan Ngo |
| Source Sets | Australiasian Digital Theses Program |
| Detected Language | English |
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