Kainate receptors (KARs) are heteromeric ionotropic glutamate receptors (GluRs) that play various roles in the regulation of synaptic transmission. The KAR subunits GluR5 and GluR6 exist under different splice variant isoforms in the C-terminal domain (GluR5a, GluR5b, GluR5c, GluR6a, GluR6b). The differential role of KAR subunit splice variants is presently unknown. In transfected COS-7 cells and neurons from wild-type and GluR5 ϫ GluR6 mice, we have found that the subcellular localization and membrane delivery differed between these splice variants. GluR6a was highly expressed at the plasma membrane. GluR6b, GluR5a, and GluR5b were detected at lower levels in the plasma membrane and mainly colocalized with calreticulin in the endoplasmic reticulum (ER). GluR5c was strongly retained in the ER by an RXR motif. GluR6a acted as a key subunit splice variant promoting surface expression of ER-retained subunit splice variants when assembled in heteromeric KARs. Surface expression of GluR6a was independent of its PDZ (postsynaptic density-95/discs large/zona occludens-1) binding motif and was promoted by a stretch of four basic amino acid residues at its C terminus. Overall, splice variants and subunit composition of KARs regulate receptor trafficking from the endoplasmic reticulum to the plasma membrane.
Kainate receptors (KAR) are composed of several distinct subunits and splice variants, but the functional relevance of this diversity remains largely unclear. Here we show that two splice variants of the GluR6 subunit, GluR6a and GluR6b, which differ in their C-terminal domains, do not show distinct functional properties, but coassemble as heteromers in vitro and in vivo. Using a proteomic approach combining affinity purification and MALDI-TOF mass spectrometry, we found that GluR6a and GluR6b interact with two distinct subsets of cytosolic proteins mainly involved in Ca(2+) regulation of channel function and intracellular trafficking. Guided by these results, we provide evidence that the regulation of native KAR function by NMDA receptors depends on the heteromerization of GluR6a and GluR6b and interaction of calcineurin with GluR6b. Thus, GluR6a and GluR6b bring in close proximity two separate subsets of interacting proteins that contribute to the fine regulation of KAR trafficking and function.
The surface expression and localization of AMPA receptors (AMPARs) at dendritic spines are tightly controlled to regulate synaptic transmission. Here we show that de novo exocytosis of the GluR2 AMPAR subunit occurs at the dendritic shaft and that new AMPARs diffuse into spines by lateral diffusion in the membrane. However, membrane topology restricts this lateral diffusion. We therefore investigated which mechanisms recruit AMPARs to spines from the shaft and demonstrated that inhibition of dynamin GTPase activity reduced lateral diffusion of membrane-anchored green fluorescent protein and superecliptic pHluorin (SEP)-GluR2 into spines. In addition, the activation of synaptic N-methyl-D-aspartate (NMDA) receptors enhanced lateral diffusion of SEP-GluR2 and increased the number of endogenous AMPARs in spines. The NMDA-invoked effects were prevented by dynamin inhibition, suggesting that activity-dependent dynamin-mediated endocytosis within spines generates a net inward membrane drift that overrides lateral diffusion barriers to enhance membrane protein delivery into spines. These results provide a novel mechanistic explanation of how AMPARs and other membrane proteins are recruited to spines by synaptic activity. AMPA3 receptors (AMPARs) are of fundamental importance because they mediate the majority of fast excitatory synaptic transmission in the mammalian central nervous system (1). Most excitatory synapses are characterized morphologically by dendritic spines that contain an electron-dense postsynaptic density (PSD) at their head (2, 3). PSD is highly enriched in AMPARs and associated proteins equired for synaptic transmission and signal transduction (4 -6). Activityevoked changes in functional postsynaptic AMPARs mediate the two main forms of synaptic plasticity believed to underlie learning and memory in the hippocampus (7). Long term potentiation involves the activity-dependent recruitment of AMPARs to the postsynaptic membrane and a concurrent increase in AMPA-mediated transmission, whereas long term depression is a decrease in synaptic AMPAR function (8).The number and subunit composition of synaptic AMPARs are stringently regulated, but despite intense investigation, the processes by which AMPARs are delivered to and retained at the PSD remain controversial. Using photoreactive antagonists and electrophysiology, it has been proposed that AMPARs are only inserted in the plasma membrane at the cell body and laterally diffuse long distances to synapses (9). In direct contrast, approaches using real-time imaging have suggested that AMPARs are inserted in the plasma membrane of the dendritic shaft close to, but not at, dendritic spines (10). It has also been suggested that AMPARs could be inserted directly into the plasma membrane of the PSD (11).Independent of the route of delivery for new AMPARs to synapses, it is well established that lateral diffusion in the plasma membrane allows the exchange of receptors in and out of the PSD (12-14). Using palmitoylated membrane-anchored GFP (mGFP), which partitions ...
Kainate receptors (KARs) are heteromeric ionotropic glutamate receptors that play a variety of roles in the regulation of synaptic network activity. The function of glutamate receptors (GluRs) is highly dependent on their surface density in specific neuronal domains. Alternative splicing is known to regulate surface expression of GluR5 and GluR6 subunits. The KAR subunit GluR7 exists under different splice variant isoforms in the C-terminal domain (GluR7a and GluR7b). Here we have studied the trafficking of GluR7 splice variants in cultured hippocampal neurons from wild-type and KAR mutant mice. We have found that alternative splicing regulates surface expression of GluR7-containing KARs. GluR7a and GluR7b differentially traffic from the ER to the plasma membrane. GluR7a is highly expressed at the plasma membrane, and its trafficking is dependent on a stretch of positively charged amino acids also found in GluR6a. In contrast, GluR7b is detected at the plasma membrane at a low level and retained mostly in the endoplasmic reticulum (ER). The RXR motif of GluR7b does not act as an ER retention motif, at variance with other receptors and ion channels, but might be involved during the assembly process. Like GluR6a, GluR7a promotes surface expression of ER-retained subunit splice variants when assembled in heteromeric KARs. However, our results also suggest that this positive regulation of KAR trafficking is limited by the ability of different combinations of subunits to form heteromeric receptor assemblies. These data further define the complex rules that govern membrane delivery and subcellular distribution of KARs.
Activity dependent modification of receptors in the post-synaptic density is a key determinant in regulating the strength of synaptic transmission during development and plasticity. A major mechanism for this recruitment and removal of postsynaptic proteins is the lateral diffusion in the plane of the plasma membrane. Therefore, the processes that regulate this lateral mobility are of fundamental importance. In recent years significant progress has been achieved using optical approaches such as single particle tracking (SPT) and fluorescence recovery after photobleach (FRAP). Here, we provide an overview of the principles and methodology of these techniques and highlight the contributions they have made to current understanding of protein mobility in the plasma membrane.
Axonal growth cones are responsible for the correct guidance of developing axons and the establishment of functional neural networks. They are highly motile because of fast and continuous rearrangements of their actin-rich cytoskeleton. Here we have used live imaging of axonal growth cones of hippocampal neurons in culture and quantified their motility with a temporal resolution of 2 s. Using novel methods of analysis of growth cone dynamics, we show that transient activation of kainate receptors by bath-applied kainate induced a fast and reversible growth cone stalling. This effect depends on electrical activity and can be mimicked by the transient discharge of action potentials elicited in the neuron by intracellular current injections at the somatic level through a patch pipette. Growth cone stalling induced by electrical stimulation is mediated by calcium entry from the extracellular medium as well as by calcium release from intracellular stores that define spatially restricted microdomains directly affecting cytoskeletal dynamics. We propose that growth cone motility is dynamically controlled by transient bursts of spontaneous electrical activity, which constitutes a prominent feature of developing neural networks in vivo.
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