Study Status: Not yet recruiting
Recruit Status: Not yet recruiting
Study Type: Observational
Official Title: Mechanisms of Auto-immune Encephalitis
Brief Summary:
Neurological and psychiatric diseases are one of the major health problems worldwide. Decades of fundamental and clinical research have led to the model that these disorders results from synaptic imbalance between excitatory, inhibitory and modulatory systems in key brain structures. Although the network and neurotransmitter systems involved have been delineated, the mechanisms leading to improper neurotransmissions remain poorly understood. One major limitation lays in the difficulty to transpose the identified dysregulation in humans to relevant animal models in which molecular and cellular targets can be manipulated.
The amino-acid glutamate mediates the vast majority of excitatory neurotransmission in the mammalian brain. We know that the glutamatergic synapses can change their strength by regulating surface expression and dynamics of their postsynaptic receptors, through changes in receptor recycling and/or lateral diffusion. This synaptic plasticity underlies higher cognitive functions such as learning and memory and is likely compromised in several disease states. Regulating glutamate receptor number and function is thus of primary importance. New subcellular imaging technique rendered possible the study of receptor trafficking and receptor regulation in various conditions including pathological models opening new fundamental questions. Moreover, recent breakthroughs on glutamate receptor structure offer unprecedented clues on the molecular and structural mechanisms underpinning receptor dysfunction at the atomic level.
Recently, description of encephalitis associated with specific autoantibodies (Abs) directed against neuronal synaptic receptors or proteins (NSA-Abs) opens new lights in the pathophysiological mechanisms of some human brain disorders. The best example and the most frequent syndrome is the synaptic a