The understanding of learning and memory in our brain at cellular and molecular levels, and specifically, the role of AMPA receptors’ mobility regulation at the synaptic site in neurons is of special interest. The regulation of AMPAR trafficking is crucial to its synaptic function. Indeed, the widely accepted model at present is that AMPARs are in dynamic equilibrium between synaptic, extrasynaptic and intracellular compartments. The changes in this equilibrium, affects AMPAR numbers at the synaptic sites what underlies long term plasticity of the efficacy of synaptic transmission, such as LTP (long term potentiation) and LTD (long term depression). This dynamic regulation is the basis of current molecular theories of learning and memory. Despite being a core locus of molecular information storage, the nature of this regulation is not yet completely understood because of the lack in technical tools. The principal aim of this project was to develop innovative methods to control AMPAR mobility, and to monitor the resulting effects with unique spatial and temporal resolution. This addressed technical limitations and allowed investigating with a unique spatiotemporal resolution the impact of AMPARs mobility in short and long term plasticity in the brain function. More precisely, we aimed to design tools that provide a control of endogenous or genetically modified AMPARs mobility by way of light-controlled crosslinking. This project consisted on developing innovative methods to photoreversibly control receptor clustering/stabilization in order to be able to investigate how the dynamics of AMPAR is linked to the functional properties of synaptic transmission in normal and pathological brain states. I used a two-step strategy to achieve our goals, where we first focused on the photosensitive domain optimization and then implemented our work to more efficient binders. The project was organized around the following three objectives: (1) Design and production of a first generation of photocrosslinkers, (2) Validate and characterize the system in cellular environments and (3) Expand the photocrosslinking systems to minimally invasive epitope/binder pairs (2nd generation photocrosslinkers).