To systematically investigate the molecular mechanisms mediating UPS-dependent stabilization of synaptic transmission, we combined genetic screens with detailed electrophysiological quantification of synaptic transmission. This approach, which is currently only feasible in Drosophila, established several new molecular links between UPS-mediated protein degradation and homeostatic stabilization of synaptic transmission. In particular, we realized the first systematic analysis of the roles of E3 ubiquitin ligases, a class of enzymes regulating protein degradation-mediated proteostasis, in synaptic transmission. This screen identified several genes encoding for evolutionarily conserved E3 ubiquitin ligases that are required for homeostatic control of neurotransmitter release. Among those genes was thin, the Drosophila homolog of human tripartite motif-containing 32 (TRIM32), a gene linked to several neurological disorders, including autism spectrum disorder and schizophrenia. Furthermore, we revealed that thin acts through dysbindin, a gene linked to homeostatic plasticity in Drosophila and schizophrenia in humans.
Additionally, we studied the nano-architecture of synapses during homeostatic stabilization of synaptic transmission employing super-resolution light microscopy. We discovered that glutamatergic neurotransmitter receptors are arranged in stereotypic ‘nano-rings’ at the Drosophila neuromuscular junction (NMJ). Interestingly, these receptor rings aligned with presynaptic rings formed by proteins located with the nerve terminal. Moreover, these transsynaptically-aligned rings were modulated during homeostatic plasticity, and we identified the first gene that is required for homeostatic regulation of transsynaptic nano-architecture and homeostatic plasticity.
Finally, we provided the first evidence for rapid homeostatic stabilization of synaptic transmission in the mammalian central nervous system (CNS). Studying synaptic transmission in acute brain slices of the mouse cerebellum, we discovered that cerebellar synapses homeostatically regulate synaptic efficacy within minutes upon activity perturbation, at least an order of magnitude faster than previously thought. This is achieved by specific mechanisms that regulate neurotransmitter release from the nerve terminals.