Antagonistic Effect of a Cytoplasmic Domain on the Basal Activity of Polymodal Potassium Channels.

TREK/TRAAK channels are polymodal K+ channels that convert very diverse stimuli, including bioactive lipids, mechanical stretch and temperature, into electrical signals. The nature of the structural changes that regulate their activity remains an open question. Here, we show that a cytoplasmic domain (the proximal C-ter domain, pCt) exerts antagonistic effects in TREK1 and TRAAK. In basal conditions, pCt favors activity in TREK1 whereas it impairs TRAAK activity. Using the conformation-dependent binding of fluoxetine, we show that TREK1 and TRAAK conformations at rest are different, and under the influence of pCt. Finally, we show that depleting PIP2 in live cells has a more pronounced inhibitory effect on TREK1 than on TRAAK. This differential regulation of TREK1 and TRAAK is related to a previously unrecognized PIP2-binding site (R329, R330, and R331) present within TREK1 pCt, but not in TRAAK pCt. Collectively, these new data point out pCt as a major regulatory domain of these channels and suggest that the binding of PIP2 to the pCt of TREK1 results in the stabilization of the conductive conformation in basal conditions.

Development of the First Two-Pore Domain Potassium Channel TWIK-Related K+ Channel 1-Selective Agonist Possessing in Vivo Antinociceptive Activity.

The TWIK-related K+ channel, TREK-1, has recently emerged as an attractive therapeutic target for the development of a novel class of analgesic drugs, suggesting that activation of TREK-1 could result in pain inhibition. Here, we report the synthesis of a series of substituted acrylic acids (1-54) based on our previous work with caffeate esters. The analogues were evaluated for their ability to modulate TREK-1 channel by electrophysiology and for their in vivo antinociceptive activity (acetic acid-induced writhing and hot plate assays), leading to the identification of a series of novel molecules able to activate TREK-1 and displaying potent antinociceptive activity in vivo. Furyl analogue 36 is the most promising of the series.

Opposing effects of bone morphogenetic protein-2 and endothelin-1 on lung fibroblast chloride currents.

Alteration in the control of bone morphogenetic protein (BMP)-regulated genes and increased expression of endothelin (ET)-1 are both believed to play important roles in the still incompletely understood pathobiology of pulmonary vascular remodeling and fibrosis. Recent studies have drawn attention to the contribution of adventitial fibroblast activation in these phenomena. Because chloride channels are involved in the control of physiological function of fibroblasts, we hypothesized that these channels are differentially regulated by BMPs and ET. We measured chloride ion currents by whole-cell path-clamping in cultured primary human pulmonary fibroblasts. The application of BMP2 prevented activation of these currents by hypotonic challenge in a time- and dose-dependent manner, partially via protein kinase C signaling. Maximal inhibition was observed after 45-minute incubation of cells in the presence of 10 ng/ml of BMP2. ET-1 did not activate chloride channels acutely; however, prolonged treatment of cells with ET-1 (100 nM, 2 h) induced the appearance of lysophosphatidic acid-activated chloride currents (a marker of differentiated myofibroblasts), and this induction could be effectively blocked by BMP2 pretreatment (10 ng/ml). BMP2 also prevented stimulation of α-smooth muscle actin gene expression and cell migration of fibroblasts induced by ET-1. We conclude that ET-1 and BMP2 have opposing effects on chloride channel activity in human fibroblasts. This is a potentially relevant mechanism involved in pulmonary vascular remodeling and fibrosis.