Satellite Glial Cells Drive Homeostatic Synaptic Structural Plasticity in Sympathetic Neurons

Sympathetic neuronal (SN) activity critically regulates the development and function of peripheral organs and tissues. Activity-dependent plasticity has been shown to modulate SN output, suggesting that compensatory forms of plasticity could contribute to maintaining stability of sympathetic circuits. Early SN hyperactivity drives the development of hypertension in humans and in the spontaneously hypertensive rat (SHR). In this study we used chemogenetic and pharmacological approaches, and took advantage of the enhanced activity of SHR SNs, to examine how long-term changes in activity impact synaptic properties in neonatal SN cultures. We showed that bidirectional changes in SN activity resu