Effects of calcium-activated potassium channel modulators on afterhyperpolarizing potentials in identified motor and mechanosensory neurons of the medicinal leech

Abstract

Calcium-activated potassium (K_Ca) channels contribute to multiple neuronal properties including spike frequency and afterhyperpolarizing potentials (AHPs). K_Ca channels are classified as K_Ca1.1, K_Ca2, or K_Ca3.1 based on single-channel conductance and pharmacology. Ca²⁺-dependent AHPs in vertebrates are categorized as fast, medium, or slow. Fast and medium AHPs are generated by K_Ca1.1 and K_Ca2 channels, respectively. The K_Ca subtype responsible for slow AHPs is unclear. Prolonged, Ca²⁺-dependent AHPs have been described in several leech neurons. Unfortunately, apamin and other K_Ca blockers often prove ineffective in the leech. An alternative approach is to utilize K_Ca modulators, which alter channel sensitivity to Ca²⁺. Vertebrate K_Ca2 channels are targeted selectively by the positive modulator CyPPA and the negative modulator NS8593. Here we show that AHPs in identified motor and mechanosensory leech neurons are enhanced by CyPPA and suppressed by NS8593. Our results indicate that K_Ca2 channels underlie prolonged AHPs in these neurons and suggest that K_Ca2 modulators may serve as effective tools to explore the role of K_Ca channels in leech physiology.

Keywords: Afterhyperpolarizing potentials; Calcium-activated potassium; CyPPA; Leech; NS8593.