Abstract
Accumulated research has demonstrated the beneficial effects of dietary restriction on extending lifespan and increasing cellular stress resistance. However, reducing nutrient intake has also been shown to direct animal behaviors toward food acquisition. Under food-limiting conditions, behavioral changes suggest that neuronal and muscle activities in circuits that are not involved in nutrient acquisition are down-regulated. These dietary-regulated mechanisms, if understood better, might provide an approach to compensate for defects in molecules that regulate cell excitability. We previously reported that a neuromuscular circuit used in Caenorhabditis elegans male mating behavior is attenuated under food-limiting conditions. During periods between matings, sex-specific muscles that control movements of the male's copulatory spicules are kept inactive by UNC-103 ether-a-go-go–related gene (ERG)–like K+ channels. Deletion of unc-103 causes ∼30%–40% of virgin males to display sex-muscle seizures; however, when food is deprived from males, the incidence of spontaneous muscle contractions drops to 9%–11%. In this work, we used genetics and pharmacology to address the mechanisms that act parallel with UNC-103 to suppress muscle seizures in males that lack ERG-like K+ channel function. We identify calcium/calmodulin-dependent protein kinase II as a regulator that uses different mechanisms in food and nonfood conditions to compensate for reduced ERG-like K+ channel activity. We found that in food-deprived conditions, calcium/calmodulin-dependent protein kinase II acts cell-autonomously with ether-a-go-go K+ channels to inhibit spontaneous muscle contractions. Our work suggests that upregulating mechanisms used by food deprivation can suppress muscle seizures.
Highlights
The excitability of neuromuscular circuits must be regulated to ensure appropriate behavioral responses under different conditions
In the roundworm Caenorhabditis elegans, males must display the proper behavioral response to potential food sources or mating partners. This regulation is disrupted by loss of ether-a-go-go–related gene (ERG)-like Kþ channel function
For the percentage of Kþ channel–defective males that do not display spontaneous sex-muscle seizure, we show that abnormal muscle contraction is attenuated by the calcium/calmodulindependent protein kinase II (CaMKII)
Summary
The excitability of neuromuscular circuits must be regulated to ensure appropriate behavioral responses under different conditions. When cell excitability is irregular due to channelopathy defects, inappropriate motor output can lead to different medical conditions. One member of the ether-a-go-go (EAG) family of Kþ channels, the human ether-a-gogo–related gene (hERG)–encoded, delayed inward, rectifying voltage-gated Kþ channel, has received attention due to its association with the cardiac condition long QT syndrome [1]. Most mutations in hERG reduce channel conductance, which causes prolonged depolarizations that result in cardiac arrhythmias [2,3,4,5,6]. Due to the physiological significance of this protein, there is ongoing research into the biophysical properties of hERG Kþ channel function. Little is known about other signaling pathways that act with these channels to control excitable output within specific physiological contexts
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