Abstract
The properties and physiological function of pore-forming α-subunits of large conductance calcium- and voltage-activated potassium (BK) channels are potently modified by their functional coupling with regulatory subunits in many tissues. However, mechanisms that might control functional coupling are very poorly understood. Here we show that S-acylation, a dynamic post-translational lipid modification of proteins, of the intracellular S0–S1 loop of the BK channel pore-forming α-subunit controls functional coupling to regulatory β1-subunits. In HEK293 cells, α-subunits that cannot be S-acylated show attenuated cell surface expression, but expression was restored by co-expression with the β1-subunit. However, we also found that nonacylation of the S0–S1 loop reduces functional coupling between α- and β1-subunits by attenuating the β1-subunit-induced left shift in the voltage for half-maximal activation. In mouse vascular smooth muscle cells expressing both α- and β1-subunits, BK channel α-subunits were endogenously S-acylated. We further noted that S-acylation is significantly reduced in mice with a genetic deletion of the palmitoyl acyltransferase (Zdhhc23) that controls S-acylation of the S0–S1 loop. Genetic deletion of Zdhhc23 or broad-spectrum pharmacological inhibition of S-acylation attenuated endogenous BK channel currents independently of changes in cell surface expression of the α-subunit. We conclude that functional effects of S-acylation on BK channels depend on the presence of β1-subunits. In the absence of β1-subunits, S-acylation promotes cell surface expression, whereas in its presence, S-acylation controls functional coupling. S-Acylation thus provides a mechanism that dynamically regulates the functional coupling with β1-subunits, enabling an additional level of conditional, cell-specific control of ion-channel physiology.
Highlights
The properties and physiological function of pore-forming ␣-subunits of large conductance calcium- and voltage-activated potassium (BK) channels are potently modified by their functional coupling with regulatory subunits in many tissues
Based on our data in HEK293 cells, we predicted that genetic deletion of Zdhhc23 or broad-spectrum pharmacological inhibition of S-acylation in vascular smooth muscle cells (VSMCs) would reduce the outward potassium conductance in VSMCs, which is largely carried by BK channels, without affecting cell surface expression of ␣-subunits compared with control. siRNA knockdown of ZDHHC23 in HEK293 cells (Fig. S1, C and D) revealed that this enzyme is not required for S-acylation of 1-subunits in contrast to its role in ␣-subunit S0 –S1 loop S-acylation
In this work we reveal a novel mode of BK channel regulation through S-acylation– dependent control of the functional coupling between the pore-forming ␣-subunits and regulatory 1-subunits
Summary
1-subunits rescue surface trafficking of S-acylation– deficient BK channel ␣-subunits. Based on our data in HEK293 cells, we predicted that genetic deletion of Zdhhc or broad-spectrum pharmacological inhibition of S-acylation in VSMC would reduce the outward potassium conductance in VSMCs, which is largely carried by BK channels, without affecting cell surface expression of ␣-subunits compared with control. To test that inhibition of BK channel ␣-subunit S-acylation would have no effect on surface expression in VSMC, as we predicted from the data in HEK293 cells in the presence of 1-subunit, we quantified surface expression of BK channel ␣-subunit in native VSMCs by immunocytochemistry and confocal imaging (Fig. 6D). Surface expression of BK channel ␣-subunits, expressed as a percentage of total cellular immunoreactivity, was not significantly reduced (F(2,202) ϭ 0.727; p ϭ 0.485, one-way ANOVA), compared with controls, in VSMCs from Zdhhc23Ϫ/Ϫ mice or WT VSMCs treated with 2-BP. The data demonstrate that inhibition of BK channel S-acylation in VSMCs reduces BK current density independently of changes in surface expression
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