Summary
Synapses play an essential role in all behaviours and damage to synapse proteins results in over a 130 brain disorders. The host Grant lab has developed methods for brain-wide mapping of protein composition at single-synapse resolution, uncovering unexpected diversity. The different synapse types show unique spatiotemporal distributions in the brain across the lifespan, which are altered in genetic models of autism and schizophrenia. Synapse proteins are assembled into multiprotein complexes and supercomplexes, but little is known about their composition and spatial organisation within individual synapses, particularly in the intact brain. In SYNarch I aim to understand this subsynaptic protein architecture, its contribution to the spatiotemporal organisation of synapse diversity, and alteration in disease. The work plan will deliver a depth of skill acquisition integrated across a range of cutting-edge biochemical, molecular imaging, ultrastructural and computational technologies. In WP1 I will optimise use of Förster resonance energy transfer (FRET) to probe the sub-10 nm spatial relationship and number of endogenously labelled PSD95 complexes within individual synapses, backed up by complementary super-resolution microscopy techniques (STORM, TIRF) and microfluidics analysis. In WP2, FRET will be integrated with synaptome mapping technology to deliver an atlas of nanoscale information on a brain-wide scale – the PSD nanoscale synaptome architecture (PNSA) of the mouse brain. In WP3 I will uncover how the PNSA is impacted in the Dlg2 schizophrenia mouse model. SYNarch will help to provide new molecular insight into brain function and dysfunction on an unprecedented scale.
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| Web resources: | https://cordis.europa.eu/project/id/101029343 |
| Start date: | 01-07-2022 |
| End date: | 30-06-2024 |
| Total budget - Public funding: | 212 933,76 Euro - 212 933,00 Euro |
Cordis data
Original description
Synapses play an essential role in all behaviours and damage to synapse proteins results in over a 130 brain disorders. The host Grant lab has developed methods for brain-wide mapping of protein composition at single-synapse resolution, uncovering unexpected diversity. The different synapse types show unique spatiotemporal distributions in the brain across the lifespan, which are altered in genetic models of autism and schizophrenia. Synapse proteins are assembled into multiprotein complexes and supercomplexes, but little is known about their composition and spatial organisation within individual synapses, particularly in the intact brain. In SYNarch I aim to understand this subsynaptic protein architecture, its contribution to the spatiotemporal organisation of synapse diversity, and alteration in disease. The work plan will deliver a depth of skill acquisition integrated across a range of cutting-edge biochemical, molecular imaging, ultrastructural and computational technologies. In WP1 I will optimise use of Förster resonance energy transfer (FRET) to probe the sub-10 nm spatial relationship and number of endogenously labelled PSD95 complexes within individual synapses, backed up by complementary super-resolution microscopy techniques (STORM, TIRF) and microfluidics analysis. In WP2, FRET will be integrated with synaptome mapping technology to deliver an atlas of nanoscale information on a brain-wide scale – the PSD nanoscale synaptome architecture (PNSA) of the mouse brain. In WP3 I will uncover how the PNSA is impacted in the Dlg2 schizophrenia mouse model. SYNarch will help to provide new molecular insight into brain function and dysfunction on an unprecedented scale.Status
SIGNEDCall topic
MSCA-IF-2020Update Date
28-04-2024
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