%0 Journal Article %1 sarnataro2024mitochondrial %A Sarnataro, Raffaele %A Velasco, Cecilia D. %A Monaco, Nicholas %A Kempf, Anissa %A Miesenböck, Gero %D 2024 %I Cold Spring Harbor Laboratory %J bioRxiv %K biology brain mitochondria neuroscience sleep %R 10.1101/2024.02.23.581770 %T Mitochondrial origins of the pressure to sleep %U https://www.biorxiv.org/content/early/2024/02/25/2024.02.23.581770 %X The neural control of sleep requires that sleep need is sensed during waking and discharged during sleep. To obtain a comprehensive, unbiased view of molecular changes in the brain that may underpin these processes, we have characterized the transcriptomes of single cells isolated from rested and sleep-deprived flies. Transcripts upregulated after sleep deprivation, in sleep-control neurons projecting to the dorsal fan-shaped body (dFBNs) but not ubiquitously in the brain, encode almost exclusively proteins with roles in mitochondrial respiration and ATP synthesis. These gene expression changes are accompanied by mitochondrial fragmentation, enhanced mitophagy, and an increase in the number of contacts between mitochondria and the endoplasmic reticulum, creating conduits for the replenishment of peroxidized lipids. The morphological changes are reversible after recovery sleep and blunted by the installation of an electron overflow in the respiratory chain. Inducing or preventing mitochondrial fission or fusion in dFBNs alters sleep and the electrical properties of sleep-control cells in opposite directions: hyperfused mitochondria increase, whereas fragmented mitochondria decrease, neuronal excitability and sleep. ATP levels in dFBNs rise after enforced waking because of diminished ATP consumption during the arousal-mediated inhibition of these neurons, which predisposes them to heightened oxidative stress. Consistent with this view, uncoupling electron flux from ATP synthesis relieves the pressure to sleep, while exacerbating mismatches between electron supply and ATP demand (by powering ATP synthesis with a light-driven proton pump) promotes sleep. Sleep, like ageing, may be an inescapable consequence of aerobic metabolism.Competing Interest StatementThe authors have declared no competing interest.

@article{sarnataro2024mitochondrial, abstract = {The neural control of sleep requires that sleep need is sensed during waking and discharged during sleep. To obtain a comprehensive, unbiased view of molecular changes in the brain that may underpin these processes, we have characterized the transcriptomes of single cells isolated from rested and sleep-deprived flies. Transcripts upregulated after sleep deprivation, in sleep-control neurons projecting to the dorsal fan-shaped body (dFBNs) but not ubiquitously in the brain, encode almost exclusively proteins with roles in mitochondrial respiration and ATP synthesis. These gene expression changes are accompanied by mitochondrial fragmentation, enhanced mitophagy, and an increase in the number of contacts between mitochondria and the endoplasmic reticulum, creating conduits for the replenishment of peroxidized lipids. The morphological changes are reversible after recovery sleep and blunted by the installation of an electron overflow in the respiratory chain. Inducing or preventing mitochondrial fission or fusion in dFBNs alters sleep and the electrical properties of sleep-control cells in opposite directions: hyperfused mitochondria increase, whereas fragmented mitochondria decrease, neuronal excitability and sleep. ATP levels in dFBNs rise after enforced waking because of diminished ATP consumption during the arousal-mediated inhibition of these neurons, which predisposes them to heightened oxidative stress. Consistent with this view, uncoupling electron flux from ATP synthesis relieves the pressure to sleep, while exacerbating mismatches between electron supply and ATP demand (by powering ATP synthesis with a light-driven proton pump) promotes sleep. Sleep, like ageing, may be an inescapable consequence of aerobic metabolism.Competing Interest StatementThe authors have declared no competing interest.}, added-at = {2024-02-28T12:50:10.000+0100}, author = {Sarnataro, Raffaele and Velasco, Cecilia D. and Monaco, Nicholas and Kempf, Anissa and Miesenb{\"o}ck, Gero}, biburl = {https://www.bibsonomy.org/bibtex/231f5034b41ec9817f7af050234f7280a/tabularii}, description = {Mitochondrial origins of the pressure to sleep | bioRxiv}, doi = {10.1101/2024.02.23.581770}, elocation-id = {2024.02.23.581770}, eprint = {https://www.biorxiv.org/content/early/2024/02/25/2024.02.23.581770.full.pdf}, interhash = {0a2fa9ddbadbb6a6e547acf72d9b5273}, intrahash = {31f5034b41ec9817f7af050234f7280a}, journal = {bioRxiv}, keywords = {biology brain mitochondria neuroscience sleep}, publisher = {Cold Spring Harbor Laboratory}, timestamp = {2024-02-28T12:50:10.000+0100}, title = {Mitochondrial origins of the pressure to sleep}, url = {https://www.biorxiv.org/content/early/2024/02/25/2024.02.23.581770}, year = 2024 }