Abstract
Inhibitors of human two-pore channels (TPC1 and TPC2), i.e., verapamil, tetrandrine, and NED-19, are promising medicines used in treatment of serious diseases. In the present study, the impact of these substances on action potentials (APs) and vacuolar channel activity was examined in the aquatic characean algae Nitellopsis obtusa and in the terrestrial liverwort Marchantia polymorpha. In both plant species, verapamil (20–300 µM) caused reduction of AP amplitudes, indicating impaired Ca2+ transport. In N. obtusa, it depolarized the AP excitation threshold and resting potential and prolonged AP duration. In isolated vacuoles of M. polymorpha, verapamil caused a reduction of the open probability of slow vacuolar SV/TPC channels but had almost no effect on K+ channels in the tonoplast of N. obtusa. In both species, tetrandrine (20–100 µM) evoked a pleiotropic effect: reduction of resting potential and AP amplitudes and prolongation of AP repolarization phases, especially in M. polymorpha, but it did not alter vacuolar SV/TPC activity. NED-19 (75 µM) caused both specific and unspecific effects on N. obtusa APs. In M. polymorpha, NED-19 increased the duration of repolarization. However, no inhibition of SV/TPC channels was observed in Marchantia vacuoles, but an increase in open probability and channel flickering. The results indicate an effect on Ca2+ -permeable channels governing plant excitation.
Highlights
Mammalian cells, including human cells, harbor two genes hTPC1 and hTPC2 encoding two-pore-Na+ -selective ion channels located in endosomes and lysosomes, respectively [1]
We examined the impact of these compounds on longdistance electrical signals in phylogenetically ancient plants: a characean alga (Nitellopsis obtusa) and a liverwort (Marchantia polymorpha)
Both action potentials (APs) peak potential Vmax and AP amplitude Ath were unaffected by verapamil; AP amplitude ARP was significantly decreased from 254 ± 14 mV
Summary
Mammalian cells, including human cells, harbor two genes hTPC1 and hTPC2 encoding two-pore-Na+ -selective ion channels located in endosomes and lysosomes, respectively [1]. These endomembrane ion channels have attracted the attention of researchers since they are involved in many severe diseases including Ebola virus infection [2], neoangiogenesis in several types of tumors, arrhythmias, etc. Slow-vacuolar (SV) cation channels are located in the tonoplast, i.e., the vacuolar membrane and exhibit slow kinetics of activation. They were among the first channels discovered in plant cells long before characterization of their animal counterparts [4]. Rice and tobacco TPC channels have been suggested to play a role in defense and oxidative stress signaling [10,11,12]
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