UC Berkeley

Drosophila neuromuscular junctions (NMJs) exhibit structural and physiological homeostasis during larval development in which the number of boutons and the amount of neurotransmitter released increases in coordination with larval muscle size growth. The Bone Morphogenetic Protein (BMP) signaling pathway, including Glass bottom-boat (Gbb), a BMP ligand, and Wishful thinking (Wit), its presynaptic BMP receptor, are important for regulating this homeostatic growth in larvae. Genetic analysis of Gbb suggests it is released as a retrograde signal from the postsynaptic muscle to initiate presynaptic BMP signaling for synaptic growth. However, muscle expression of Gbb fails to rescue synaptic transmission defects in the gbb mutant, which is instead rescued by nervous system expression of Gbb. To resolve this conflicting data and elucidate the role of Gbb at the NMJ, we investigated the expression of Gbb during Drosophila development at the NMJ. We fused EclipiticGFP to Gbb for visualizing its expression pattern at third-instar larval NMJs. Finally, we demonstrate genetic rescue of the gbb mutant with our transgenic line and provide evidence that Gbb released from the muscle may play a role in higher order synapses beyond the NMJ.

Development of the larval neuromuscular junction (NMJ) in Drosophila has been well characterized using genetic mutants and advanced imaging methods. However, the time course of activity-dependent changes in synaptic strength at the larval NMJ has not yet been fully investigated. To further understand the time course of synaptic plasticity at the NMJ, we used the Gal4/UAS system to express the Light-Gated Glutamate Receptor (LiGluR) in the muscle to precisely control postsynaptic activity while performing electrophysiological recordings. Our experiments reveal that long-term postsynaptic LiGluR expression during development induces a homeostatic decrease in bouton density and evoked synaptic transmission. With acute activation of LiGluRs, we potentiate synaptic transmission during high frequency stimulation. CamKII activity is required for this enhancement in synaptic strength by rapid LiGluR activation but it is not necessary for the long-term decrease in bouton density. Finally, we provide evidence that suggests the Wit BMP receptor is not required for the rapid potentiation of synaptic transmission but we provide data to possibly implicate cAMP signaling as a downstream mediator of this effect. These results suggest that a transient increase in postsynaptic activity generated by LiGluR activation may produce a rapid retrograde signal that enhances neurotransmitter release.