Zhou_2017_Cell.Rep_19_1117

Reference

Title : Asynchronous Cholinergic Drive Correlates with Excitation-Inhibition Imbalance via a Neuronal Ca(2+) Sensor Protein - Zhou_2017_Cell.Rep_19_1117
Author(s) : Zhou K , Cherra SJ, 3rd , Goncharov A , Jin Y
Ref : Cell Rep , 19 :1117 , 2017
Abstract :

Excitation-inhibition imbalance in neural networks is widely linked to neurological and neuropsychiatric disorders. However, how genetic factors alter neuronal activity, leading to excitation-inhibition imbalance, remains unclear. Here, using the C. elegans locomotor circuit, we examine how altering neuronal activity for varying time periods affects synaptic release pattern and animal behavior. We show that while short-duration activation of excitatory cholinergic neurons elicits a reversible enhancement of presynaptic strength, persistent activation results to asynchronous and reduced cholinergic drive, inducing imbalance between endogenous excitation and inhibition. We find that the neuronal calcium sensor protein NCS-2 is required for asynchronous cholinergic release in an activity-dependent manner and dampens excitability of inhibitory neurons non-cell autonomously. The function of NCS-2 requires its Ca(2+) binding and membrane association domains. These results reveal a synaptic mechanism implicating asynchronous release in regulation of excitation-inhibition balance.

PubMedSearch : Zhou_2017_Cell.Rep_19_1117
PubMedID: 28494862

Related information

Citations formats

Zhou K, Cherra SJ, 3rd, Goncharov A, Jin Y (2017)
Asynchronous Cholinergic Drive Correlates with Excitation-Inhibition Imbalance via a Neuronal Ca(2+) Sensor Protein
Cell Rep 19 :1117

Zhou K, Cherra SJ, 3rd, Goncharov A, Jin Y (2017)
Cell Rep 19 :1117