Abstract
Synaptic mitochondria are thought to be critical in supporting neuronal energy requirements at the synapse, and bioenergetic failure at the synapse may impair neural transmission and contribute to neurodegeneration. However, little is known about the energy requirements of synaptic vesicle release or whether these energy requirements go unmet in disease, primarily due to a lack of appropriate tools and sensitive assays. To determine the dependence of synaptic vesicle cycling on mitochondrially derived ATP levels, we developed two complementary assays sensitive to mitochondrially derived ATP in individual, living hippocampal boutons. The first is a functional assay for mitochondrially derived ATP that uses the extent of synaptic vesicle cycling as a surrogate for ATP level. The second uses ATP FRET sensors to directly measure ATP at the synapse. Using these assays, we show that endocytosis has high ATP requirements and that vesicle reacidification and exocytosis require comparatively little energy. We then show that to meet these energy needs, mitochondrially derived ATP is rapidly dispersed in axons, thereby maintaining near normal levels of ATP even in boutons lacking mitochondria. As a result, the capacity for synaptic vesicle cycling is similar in boutons without mitochondria as in those with mitochondria. Finally, we show that loss of a key respiratory subunit implicated in Leigh disease markedly decreases mitochondrially derived ATP levels in axons, thus inhibiting synaptic vesicle cycling. This proves that mitochondria-based energy failure can occur and be detected in individual neurons that have a genetic mitochondrial defect.
Highlights
The ATP requirements of synaptic vesicle release are poorly understood
We show that acutely or chronically inhibiting the respiratory chain drops mitochondrially derived ATP levels below the threshold needed to sustain endocytosis, especially when energy consumption is increased by greater neural activity
A chronic mitochondrial deficit that arises from losing a key mitochondrial protein, NDUFS4, which is lost in the neurodegenerative disorder Leigh disease [44], can cause energy failure in individual neurons
Summary
The ATP requirements of synaptic vesicle release are poorly understood. Results: Mitochondrially derived ATP supports the function of boutons with and without mitochondria. We show that loss of a key respiratory subunit implicated in Leigh disease markedly decreases mitochondrially derived ATP levels in axons, inhibiting synaptic vesicle cycling To measure mitochondrially derived energy at the synapse, we designed sensitive ATP assays that suppress glycolysis so neurons must rely on mitochondria for energy Using these assays, we identified the energy threshold needed to support synaptic vesicle cycling and showed that, when ATP drops below this threshold, endocytosis is blocked at or before the vesicle scission step. We showed that loss of a mitochondrial protein known to cause neurodegeneration (Leigh disease) causes mitochondrially derived energy levels to drop enough in individual neurons to impair synaptic function, proving that mitochondrionbased energy failure can occur and be detected in individual neurons with genetic mitochondrial defects
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
