Communication between neuronal cells is performed by cellular junctions called synapses. A hallmark of synapses is their ability to change their potency of signal transmission in response to patterns of neuronal activity, which is known as “synaptic plasticity”, a process that is important for allowing long-term information storage. Signal transmission through synapses is mediated by ligand-gated ion channels at the postsynapse, called ionotropic glutamate receptors (iGluRs), that are activated by the neurotransmitter glutamate. Multiple regulatory mechanisms control the magnitude of this postsynaptic response, such as the channel properties as well as the number and spatial positioning of the receptors. An important but not well studied mechanism is the regulation of iGluRs interact by extracellular proteins, notably adhesion molecules and synaptic organizer proteins, which modulate iGluR location and function. Despite their capital importance, the mechanism of iGluR modulation by synaptic organizer proteins remains highly unexplored.
The goal of this proposal was to elucidate the assembly of two iGluR subclasses (AMPA and GluD receptors) with extracellular scaffolding proteins. To this end, we aimed to determine the structure of AMPARs in complex with ESPs via protein engineering and biophysical/structural methods.
This integrative structural biology approach should reveal general structural principles of iGluR regulation by ESPs which will aid in understanding the role of ESPs in synaptic plasticity and could uncover novel therapeutic avenues for neurodegenerative diseases.