Applied Biosciences (Aug 2023)

Effect of Doxapram, a K2p Channel Blocker, and pH on Heart Rate: Larval <i>Drosophila</i> Model

  • Elizabeth R. Elliott,
  • Alaina C. Taul,
  • Maya O. Abul-Khoudoud,
  • Nicole Hensley,
  • Robin L. Cooper

DOI
https://doi.org/10.3390/applbiosci2030026
Journal volume & issue
Vol. 2, no. 3
pp. 406 – 420

Abstract

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Two-P-domain K+ (K2p) channels are responsible for maintaining the resting membrane potential. K2p channels have varied expression in healthy tissue, but they also change in cancerous or diseased states. The correlation and causation as regards the alteration of K2p channel expression are still being investigated. The compound doxapram seems to block K2p channels and depolarize cells. Using Drosophila, the increased expression of the ORK1 K2p channel in cardiac and skeletal muscle was investigated. The heart rate in larval Drosophila is very sensitive to pH, and since doxapram blocks a subset of the K2p channels that are known to be acid-sensitive, it was postulated that doxapram would affect heart rate. A pH change from 7.1 to 6.5 increased the rate, while that from 7.1 to 7.5 decreased the rate. An amount of 0.1 mM of doxapram had no effect, but 0.5 of mM depressed Drosophila heart rates within five minutes. Exposure to 5 mM of doxapram immediately decreased the rate. Lipopolysaccharides (LPSs) from Gram-negative bacteria acutely increased the rate. LPSs activate K2p channels in the skeletal muscle of larvae and are blocked by doxapram. LPSs slightly reduce depression in the rate induced by doxapram. The overexpression of K2p channels in the heart and skeletal muscle depressed the heart rate and heightened pH sensitivity. At larval neuromuscular junctions, the overexpression in skeletal muscle increases the frequency of spontaneous quantal events and produces a more negative resting membrane potential.

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