Modulation of deep neural circuits with sonogenetics.
Quanxiang XianZhihai QiuSuresh MurugappanShashwati KalaKin Fung WongDanni LiGuofeng LiYizhou JiangYong WuMin SuXuandi HouJiejun ZhuJinghui GuoWeibao QiuLei SunPublished in: Proceedings of the National Academy of Sciences of the United States of America (2023)
Noninvasive control of neuronal activity in the deep brain can be illuminating for probing brain function and treating dysfunctions. Here, we present a sonogenetic approach for controlling distinct mouse behavior with circuit specificity and subsecond temporal resolution. Targeted neurons in subcortical regions were made to express a mutant large conductance mechanosensitive ion channel (MscL-G22S), enabling ultrasound to trigger activity in MscL-expressing neurons in the dorsal striatum and increase locomotion in freely moving mice. Ultrasound stimulation of MscL-expressing neurons in the ventral tegmental area could activate the mesolimbic pathway to trigger dopamine release in the nucleus accumbens and modulate appetitive conditioning. Moreover, sonogenetic stimulation of the subthalamic nuclei of Parkinson's disease model mice improved their motor coordination and mobile time. Neuronal responses to ultrasound pulse trains were rapid, reversible, and repeatable. We also confirmed that the MscL-G22S mutant is more effective to sensitize neurons to ultrasound compared to the wild-type MscL. Altogether, we lay out a sonogenetic approach which can selectively manipulate targeted cells to activate defined neural pathways, affect specific behaviors, and relieve symptoms of neurodegenerative disease.
Keyphrases
- wild type
- spinal cord
- magnetic resonance imaging
- white matter
- cerebral ischemia
- deep brain stimulation
- contrast enhanced ultrasound
- resting state
- neuropathic pain
- blood pressure
- induced apoptosis
- ultrasound guided
- spinal cord injury
- single molecule
- metabolic syndrome
- high fat diet induced
- multiple sclerosis
- mass spectrometry
- computed tomography
- endoplasmic reticulum stress
- uric acid
- molecular dynamics simulations
- high resolution
- drug delivery
- skeletal muscle
- pi k akt
- adipose tissue