Biology (Sep 2024)
The Effect of Calcium Ions on Resting Membrane Potential
Abstract
Regulating membrane potential is key to cellular function. For many animal cells, resting membrane potential is predominantly driven by a family of K2P (two-pore domain) potassium channels. These channels are commonly referred to as leak channels, as their presence results in the membrane being permeable to K+ ions. These channels, along with various pumps and exchangers, keep the cell resting membrane potential (Rp) relatively close to potassium’s equilibrium potential (EK); however, in many cells, the resting membrane potential is more depolarized than the EK due to a small Na+ ion leak. Raising [Ca2+]O (extracellular Ca2+ concentration) can result in hyperpolarization of the membrane potential from the resting state. The mechanism for this hyperpolarization likely lies in the blockage of a Na+ leak channel (NALCN) and/or voltage-gated Na+ channels. The effects may also be connected to calcium-activated potassium channels. Using Drosophila melanogaster, we here illustrate that changing [Ca2+]O from 0.5 to 3 mM hyperpolarizes the muscle. Replacing NaCl with LiCl or choline chloride still led to hyperpolarization when increasing [Ca2+]O. Replacing CaCl2 with BaCl2 results in depolarization. K2P channel overexpression in the larval muscle greatly reduces the effects of [Ca2+]O on cell membrane potential, likely because potential is heavily driven by the EK in these muscles. These experiments provide an understanding of the mechanisms behind neuronal hypo-excitability during hypercalcemia, as well as the effects of altered expression of K2P channels on membrane potential.
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