Fluorescence lifetime-based biosensor for monitoring compartmentalized autophagy dynamics in the intact mammalian brain
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Abstract
Autophagy is a key process in regulation of neuronal development, plasticity, and local metabolism. Yet, autophagy dynamics and regulation within intact neuronal circuits remains poorly understood. Here, we developed a pH sensitive fluorescence lifetime-based imaging method which allows to monitor autophagy dynamics in the living mouse brain. This approach allowed us to uncover compartmentalized autophagic activity across soma, dendrites, and axons of layer 2/3 cortical neurons. We found pronounced differences in dendritic dynamics of autophagic vesicles in vivo, where distal dendrites showed elevated vesicle motility compared to proximal dendrites. Notably, sensory experience modulated dendritic autophagy dynamics in the somatosensory cortex. We further combined in vivo autophagy imaging with disease associated genetic perturbation to uncover novel autophagy related phenotypes. Altogether, this approach highlights the spatial and functional complexity of autophagy in the intact mammalian brain and establishes a framework for investigating its role in synaptic regulation during development, plasticity, and aging.
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- europepmc
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