Abstract
Neuroligins (Nlgs) are a family of cell adhesion molecules thought to be important for synapse maturation and function. Mammalian studies have shown that different Nlgs have different roles in synaptic maturation and function. In Drosophila melanogaster, the roles of Drosophila neuroligin1 (DNlg1), neuroligin2, and neuroligin4 have been examined. However, the roles of neuroligin3 (dnlg3) in synaptic development and function have not been determined. In this study, we used the Drosophila neuromuscular junctions (NMJs) as a model system to investigate the in vivo role of dnlg3. We showed that DNlg3 was expressed in both the CNS and NMJs where it was largely restricted to the postsynaptic site. We generated dnlg3 mutants and showed that these mutants exhibited an increased bouton number and reduced bouton size compared with the wild-type (WT) controls. Consistent with alterations in bouton properties, pre- and postsynaptic differentiations were affected in dnlg3 mutants. This included abnormal synaptic vesicle endocytosis, increased postsynaptic density length, and reduced GluRIIA recruitment. In addition to impaired synaptic development and differentiation, we found that synaptic transmission was reduced in dnlg3 mutants. Altogether, our data showed that DNlg3 was required for NMJ development, synaptic differentiation, and function.
Highlights
Postsynaptic neuroligins play essential roles in synaptic maturation and function
We found that dnlg3 mutants showed an increase in bouton number and overexpression of DNlg3 with a muscle-specific Gal4 reduced the bouton number, indicating that DNlg3 negatively regulated neuromuscular junctions (NMJs) growth
Our results showed that GluRIIA recruitment but not GluRIIB was impaired in dnlg3 mutants, suggesting that DNlg3 regulated GluRIIA-containing glutamate receptors at NMJs and maybe through direct regulation of the GluRIIA receptor
Summary
Postsynaptic neuroligins play essential roles in synaptic maturation and function. Results: Drosophila Neuroligin regulates neuromuscular junction growth, GluRIIA recruitment, synaptic vesicle recycling, and postsynaptic density maturation. Overexpression of Nlgs in cultured neurons increases the number of synapses and potentiates synaptic function [1, 13,14,15] These in vitro results suggest that Nlgs may play a key role in synapse formation. Recent in vivo studies in mice showed that deletion of Nlgs drastically affects synaptic strength, it has minimal effect on synapse number [16]. These results have led to the proposal that Nlgs are important for synaptic maturation and function but not for initial synapse formation [13, 17]. Our more recent study about dnlg suggests that DNlg is expressed in large ventral clock neurons and is essen-
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