10 research outputs found
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EphrinB3 and Eph Receptors Regulate Hippocampal Synaptic Function
EphrinB ligands and their Eph receptor tyrosine kinases are known to regulate excitatory synaptic functions in the hippocampus. In the CA3-CA1 synapse, ephrinB ligands are localized to the post-synaptic membrane, while their cognate Eph receptors can be expressed in both pre-and post-synaptic membranes. Previous studies show that interaction of ephrinB molecules with Eph receptors leads to changes in long-term potentiation (LTP), suggesting that reverse signaling through postsynaptic ephrinBs may be required for learning and memory. Our collaborative studies demonstrate that the cytoplasmic domain of ephrinB3, and hence reverse signaling, is not required for ephrinB-dependent learning and memory tasks or for LTP of these synapses. We demonstrate that ephrinB3 null mutants show changes in several synaptic proteins including reduced levels of NMDA receptor subunits. These abnormalities are not observed in ephrinB3lacZ reverse signaling mutants, supporting an Eph receptor forward signaling role for ephrinB3 in these processes. NMDA receptors are important in regulating synaptic functions and plasticity in the adult hippocampus, and Eph receptors have been shown to cluster NMDA receptors to the cell membrane. These studies show that ephrinB3 interacts with EphA4 to regulate plasma membrane levels of NR1 in Cos-1 cells and primary hippocampal neurons. In the absence of ephrinB3, NR1 levels are decreased in synaptosomal membranes, increased in microsomal tissues, but not changed in total extracts. This suggests that ephrinB3 regulates NR1 levels through protein trafficking and not gene transcription. Analysis of protein trafficking confirmed that ephrinB3 specifically interacts with EphA4 receptor to regulate NR1 exocytosis but not endocytosis in both transfected Cos-1 cells and primary hippocampal neurons. We postulate that ephrin-Eph receptor interactions are important mediators of synaptic formation and function, in part, through their regulation of NMDA receptors in the hippocampal synapse. In addition, we find that both ephrinB3KO and ephrinB3lacZ mice show an increased number of excitatory synapses, demonstrating a cytoplasmic-dependent reverse signaling role of ephrinB3 in regulating synapse number. Together, these data suggest that ephrinB3 may act like a receptor to transduce reverse signals to regulate the number of synapses formed in the hippocampus, and that it likely acts to stimulate forward signaling through Eph receptors to modulate NMDA receptor trafficking, LTP and learning
SNAP-25 Is a Target of Protein Kinase C Phosphorylation Critical to NMDA Receptor Trafficking
18 páginas, 8 figuras, 4 figuras suplementarias.Protein kinase C (PKC) enhances NMDA receptor (NMDAR)-mediated currents and promotes NMDAR delivery to the cell surface via SNARE-dependent exocytosis. Although the mechanisms of PKC potentiation are established, the molecular target of PKC is unclear. Here we show that synaptosomal-associated protein of 25 kDa (SNAP-25), a SNARE protein, is functionally relevant to PKC-dependent NMDAR insertion, and identify serine residue-187 as the molecular target of PKC phosphorylation. Constitutively active PKC delivered via the patch pipette potentiated NMDA (but not AMPA) whole-cell currents in hippocampal neurons. Expression of RNAi targeting SNAP-25 or mutant SNAP-25(S187A) and/or acute disruption of the SNARE complex by treatment with BoNT A, BoNT B or SNAP-25 C-terminal blocking peptide abolished NMDAR potentiation. A SNAP-25 peptide and function-blocking antibody suppressed PKC potentiation of NMDA EPSCs at mossy fiber-CA3 synapses. These findings identify SNAP-25 as the target of PKC phosphorylation critical to PKC-dependent incorporation of synaptic NMDARs and document a postsynaptic action of this major SNARE protein relevant to synaptic plasticity.This work was supported by National Institutes of Health Grants NS20752 (to R.S.Z.), NS45287 (to M.V.L.B.), and
BFU2006-007138 (to J.L.).Peer reviewe
Distinct roles for ephrinB3 in the formation and function of hippocampal synapses
The transmembrane ephrinB ligands and their Eph receptor tyrosine kinases are known to regulate excitatory synaptic functions in the hippocampus. In the CA3–CA1 synapse, ephrinB ligands are localized to the post-synaptic membrane, while their cognate Eph receptors are presumed to be pre-synaptic. Interaction of ephrinB molecules with Eph receptors leads to changes in long-term potentiation (LTP), which has been reported to be mediated by reverse signaling into the post-synaptic membrane. Here, we demonstrate that the cytoplasmic domain of ephrinB3 and hence reverse signaling is not required for ephrinB dependent learning and memory tasks or for LTP of these synapses. Consistent with previous reports, we find that ephrinB3
KO null mutant mice exhibit a striking reduction in CA3–CA1 LTP that is associated with defective learning and memory tasks. We find the null mutants also show changes in both pre- and post-synaptic proteins including increased levels of synapsin and synaptobrevin and reduced levels of NMDA receptor subunits. These abnormalities are not observed in ephrinB3
lacZ reverse signaling mutants that specifically delete the ephrinB3 intracellular region, supporting a cytoplasmic domain-independent forward signaling role for ephrinB3 in these processes. We also find that both ephrinB3
KO and ephrinB3
lacZ mice show an increased number of excitatory synapses, demonstrating a cytoplasmic-dependent reverse signaling role of ephrinB3 in regulating synapse number. Together, these data suggest that ephrinB3 may act like a receptor to transduce reverse signals to regulate the number of synapses formed in the hippocampus, and that it likely acts to stimulate forward signaling to modulate a number of other proteins involved in synaptic activity and learning/memory
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Eph receptor deficiencies lead to altered cochlear function
Ephrins and Eph receptors are a family of molecules that have been implicated in many developmental processes including neuronal network formation, guidance of cell migration, and axonal pathfinding. These molecules exhibit the ability to send bidirectional signals following ligand–receptor interactions resulting from cell–cell contacts. Gene-targeted knockout mice of B-class ephrins and Eph receptors have been shown to display phenotypic responses that correlate with anatomical defects. For example, disruption of the EphB2 receptor leads to defects of the vestibular system, including pathfinding abnormalities in efferent axons and reduced endolymph production. Such developmental distortions lead to deficiencies in ionic homeostasis and repetitive circling behaviors. The present study demonstrates that B-class ephrins and Eph receptors are expressed in cochlear tissues, suggesting that they may play some role in auditory function. To determine whether ephrins and Eph receptors have a functional role in the peripheral auditory system, distortion-product otoacoustic emission (DPOAE) levels, collected across a broad frequency range, were compared between groups of mice expressing different Eph receptor genotypes. In particular, EphB1 and EphB3 receptor knockout mice exhibited significantly diminished DPOAE levels as compared to wild-type littermates, indicating that these specific Eph receptors are necessary for normal cochlear function
A Combined Optogenetic-Knockdown Strategy Reveals a Major Role of Tomosyn in Mossy Fiber Synaptic Plasticity
Neurotransmitter release probability (Pr) largely determines the dynamic properties of synapses. While much is known about the role of presynaptic proteins in transmitter release, their specific contribution to synaptic plasticity is unclear. One such protein, tomosyn, is believed to reduce Pr by interfering with the SNARE complex formation. Tomosyn is enriched at hippocampal mossy fiber-to-CA3 pyramidal cell synapses (MF-CA3), which characteristically exhibit low Pr, strong synaptic facilitation, and pre-synaptic protein kinase A (PKA)-dependent long-term potentiation (LTP). To evaluate tomosyn’s role in MF-CA3 function, we used a combined knockdown (KD)-optogenetic strategy whereby presynaptic neurons with reduced tomosyn levels were selectively activated by light. Using this approach in mouse hippocampal slices, we found that facilitation, LTP, and PKA-induced potentiation were significantly impaired at tomosyn-deficient synapses. These findings not only indicate that tomosyn is a key regulator of MF-CA3 plasticity but also highlight the power of a combined KD-optogenetic approach to determine the role of presynaptic proteins