Genetically targeted magnetic control of the nervous system.
Michael A WheelerCody J SmithMatteo OttoliniBryan S BarkerAarti M PurohitRyan M GrippoRonald P GaykemaAnthony J SpanoMark P BeenhakkerSarah KucenasManoj K PatelChristopher D DeppmannAli D GülerPublished in: Nature neuroscience (2016)
Optogenetic and chemogenetic actuators are critical for deconstructing the neural correlates of behavior. However, these tools have several limitations, including invasive modes of stimulation or slow on/off kinetics. We have overcome these disadvantages by synthesizing a single-component, magnetically sensitive actuator, "Magneto," comprising the cation channel TRPV4 fused to the paramagnetic protein ferritin. We validated noninvasive magnetic control over neuronal activity by demonstrating remote stimulation of cells using in vitro calcium imaging assays, electrophysiological recordings in brain slices, in vivo electrophysiological recordings in the brains of freely moving mice, and behavioral outputs in zebrafish and mice. As proof of concept, we used Magneto to delineate a causal role of striatal dopamine receptor 1 neurons in mediating reward behavior in mice. Together our results present Magneto as an actuator capable of remotely controlling circuits associated with complex animal behaviors.
Keyphrases
- high fat diet induced
- induced apoptosis
- high resolution
- molecularly imprinted
- spinal cord
- type diabetes
- functional connectivity
- metabolic syndrome
- cell cycle arrest
- insulin resistance
- white matter
- resting state
- cerebral ischemia
- adipose tissue
- mass spectrometry
- signaling pathway
- cancer therapy
- cell death
- binding protein
- uric acid
- amino acid
- brain injury
- prefrontal cortex
- small molecule
- liquid chromatography
- protein protein