Despite the pivotal functions of the NMDA receptor (NMDAR) for neural circuit development and synaptic plasticity, the molecular mechanisms underlying the dynamics of NMDAR trafficking are poorly understood. The cell adhesion molecule neuroligin-1 (NL1) modifies NMDAR-dependent synaptic transmission and synaptic plasticity, but it is unclear whether NL1 controls synaptic accumulation or function of the receptors. Here, we provide evidence that NL1 regulates the abundance of NMDARs at postsynaptic sites. This function relies on extracellular, NL1 isoform-specific sequences that facilitate biochemical interactions between NL1 and the NMDAR GluN1 subunit. Our work uncovers NL1 isoform-specific cisinteractions with ionotropic glutamate receptors as a key mechanism for controlling synaptic properties.synapse | neurotranmitter receptor | neurexin N MDA receptors (NMDARs) are key regulators of the development of neural circuits and synaptic plasticity (1, 2). In humans, perturbation of NMDAR function results in psychotic conditions, and genetic animal models with altered NMDAR activity exhibit phenotypes related to cognitive disorders such as schizophrenia and autism (3-5). Activity-dependent recruitment of NMDARs to synapses controls certain forms of synaptic plasticity (6, 7). However, the molecular mechanisms underlying the recruitment and physical tethering of NMDAR complexes at synapses are incompletely understood.Neuroligin-1 (NL1), one of four postsynaptic neuroligin adhesion molecules (NL1, 2, 3, 4), contributes to NMDAR regulation (8, 9). In cultured neurons, overexpression of NL1 promotes clustering of synaptic NMDARs (8), and NL1 KO mice show decreases in NMDAR-dependent excitatory postsynaptic currents (NMDAR EPSCs) (9-11). A major question in understanding neuroligin function is how specific isoforms couple to specific neurotransmitter receptors (12, 13). NMDARs were recovered in coimmunoprecipitations with NL proteins, indicating a potential complex formation, although in those experiments, no NL isoform-specificity was apparent (14). One candidate link between NLs and glutamate receptors is through postsynaptic scaffolding molecules such as postsynaptic density 95 (PSD95) (15, 16). However, all NL isoforms contain PSD95 binding sites, and NMDARs and PSD95 were recruited to NL1 with different time courses (14).Our results demonstrate that NL1 controls synaptic abundance of NMDAR via NL1-specific extracellular determinants. Loss of these interactions results in impairment of NMDAR-mediated transmission and synaptic plasticity. Our findings uncover an unexpected mode of NL1-NMDAR coupling and demonstrate a key role for the NL1 adhesion protein in the physical incorporation and retention of NMDAR at glutamatergic synapses.Results NL1-Specific Recruitment of NMDARs Does Not Require PSD95. We examined the specificity of molecular coupling of NL isoforms (NL1, 2, 3) to NMDARs by NL overexpression in cultured hippocampal neurons. NL1 increased the density of clusters of the NMDAR subunits GluN1, GluN2A, and GluN...
BackgroundExosomes, small extracellular vesicles of endosomal origin, have been suggested to be involved in both the metabolism and aggregation of Alzheimer’s disease (AD)-associated amyloid β-protein (Aβ). Despite their ubiquitous presence and the inclusion of components which can potentially interact with Aβ, the role of exosomes in regulating synaptic dysfunction induced by Aβ has not been explored.ResultsWe here provide in vivo evidence that exosomes derived from N2a cells or human cerebrospinal fluid can abrogate the synaptic-plasticity-disrupting activity of both synthetic and AD brain-derived Aβ. Mechanistically, this effect involves sequestration of synaptotoxic Aβ assemblies by exosomal surface proteins such as PrPC rather than Aβ proteolysis.ConclusionsThese data suggest that exosomes can counteract the inhibitory action of Aβ, which contributes to perpetual capability for synaptic plasticity.
The time course and functional significance of the structural changes associated with long-term facilitation of Aplysia sensory to motor neuron synaptic connections in culture were examined by time-lapse confocal imaging of individual sensory neuron varicosities labeled with three different fluorescent markers: the whole-cell marker Alexa-594 and two presynaptic marker proteins-synaptophysin-eGFP to monitor changes in synaptic vesicle distribution and synapto-PHluorin to monitor active transmitter release sites. Repeated pulses of serotonin induce two temporally, morphologically, and molecularly distinct presynaptic changes: (1) a rapid activation of silent presynaptic terminals by filling of preexisting empty varicosities with synaptic vesicles, which parallels intermediate-term facilitation, is completed within 3-6 hr and requires translation but not transcription and (2) a slower generation of new functional varicosities which occurs between 12-18 hr and requires transcription and translation. Enrichment of empty varicosities with synaptophysin accounts for 32% of the newly activated synapses at 24 hr, whereas newly formed varicosities account for 68%.
Disrupted-in-schizophrenia 1 (DISC1) has emerged as a schizophrenia-susceptibility gene affecting various neuronal functions. In this study, we characterized Mitofilin, a mitochondrial inner membrane protein, as a mediator of the mitochondrial function of DISC1. A fraction of DISC1 was localized to the inside of mitochondria and directly interacts with Mitofilin. A reduction in DISC1 function induced mitochondrial dysfunction, evidenced by decreased mitochondrial NADH dehydrogenase activities, reduced cellular ATP contents, and perturbed mitochondrial Ca 2+ dynamics. In addition, deficiencies in DISC1 and Mitofilin induced a reduction in mitochondrial monoamine oxidase-A activity. The mitochondrial dysfunctions evoked by the deficiency of DISC1 were partially phenocopied by an overexpression of truncated DISC1 that is associated with schizophrenia in human. DISC1 deficiencies induced the ubiquitination of Mitofilin, suggesting that DISC1 is critical for the stability of Mitofilin. Finally, the mitochondrial dysfunction induced by DISC1 deficiency was partially reversed by coexpression of Mitofilin, confirming a functional link between DISC1 and Mitofilin for the normal mitochondrial function. According to these results, we propose that DISC1 plays essential roles for mitochondrial function in collaboration with a mitochondrial interacting partner, Mitofilin.IMMT | mitochondrial dysfunctions | hyperdopaminergia | calcium buffering | psychiatric disorders
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