The two-pore-domain potassium channels TASK-1, TASK-3 and TASK-5 possess a conserved C-terminal motif of five amino acids. Truncation of the C-terminus of TASK-1 strongly reduced the currents measured after heterologous expression in Xenopus oocytes or HEK293 cells and decreased surface membrane expression of GFP-tagged channel proteins. Two-hybrid analysis showed that the C-terminal domain of TASK-1, TASK-3 and TASK-5, but not TASK-4, interacts with isoforms of the adapter protein 14-3-3. A pentapeptide motif at the extreme C-terminus of TASK-1, RRx(S/T)x, was found to be sufficient for weak but significant interaction with 14-3-3, whereas the last 40 amino acids of TASK-1 were required for strong binding. Deletion of a single amino acid at the C-terminal end of TASK-1 or TASK-3 abolished binding of 14-3-3 and strongly reduced the macroscopic currents observed in Xenopus oocytes. TASK-1 mutants that failed to interact with 14-3-3 isoforms (V411*, S410A, S410D) also produced only very weak macroscopic currents. In contrast, the mutant TASK-1 S409A, which interacts with 14-3-3-like wild-type channels, displayed normal macroscopic currents. Co-injection of 14-3-3z cRNA increased TASK-1 current in Xenopus oocytes by about 70 %. After co-transfection in HEK293 cells, TASK-1 and 14-3-3z (but not TASK-1DC5 and 14-3-3z) could be co-immunoprecipitated. Furthermore, TASK-1 and 14-3-3 could be coimmunoprecipitated in synaptic membrane extracts and postsynaptic density membranes. Our findings suggest that interaction of 14-3-3 with TASK-1 or TASK-3 may promote the trafficking of the channels to the surface membrane.
Two-pore domain potassium (K2P) channels play a key role in setting the membrane potential of excitable cells. Despite their role as putative targets for drugs and general anesthetics, little is known about the structure and the drug binding site of K2P channels. We describe A1899 as a potent and highly selective blocker of the K2P channel TASK-1. As A1899 acts as an open-channel blocker and binds to residues forming the wall of the central cavity, the drug was used to further our understanding of the channel pore. Using alanine mutagenesis screens, we have identified residues in both pore loops, the M2 and M4 segments, and the halothane response element to form the drug binding site of TASK-1. Our experimental data were used to validate a K2P open-pore homology model of TASK-1, providing structural insights for future rational design of drugs targeting K2P channels.
Small-molecule stabilization of protein-protein interactions is an emerging field in chemical biology. We show how fusicoccanes, originally identified as fungal toxins acting on plants, promote the interaction of 14-3-3 proteins with the human potassium channel TASK-3 and present a semisynthetic fusicoccane derivative (FC-THF) that targets the 14-3-3 recognition motif (mode 3) in TASK-3. In the presence of FC-THF, the binding of 14-3-3 proteins to TASK-3 was increased 19-fold and protein crystallography provided the atomic details of the effects of FC-THF on this interaction. We also tested the functional effects of FC-THF on TASK channels heterologously expressed in Xenopus oocytes. Incubation with 10 μM FC-THF was found to promote the transport of TASK channels to the cell membrane, leading to a significantly higher density of channels at the surface membrane and increased potassium current.
The effects of low concentrations of extracellular ATP on cytosolic Ca 2؉ , membrane potential, and transcription of IL-6 were studied in monocyte-derived human macrophages. During inflammation or infection many cells secrete ATP. We show here that application of 10 M ATP or 10 M UTP induces oscillations in cytosolic Ca 2؉ with a frequency of Ϸ12 min ؊1 and oscillations in membrane potential. RT-PCR analysis showed expression of P2Y 1, P2Y2, P2Y11, P2X1, P2X 4, and P2X7 receptors, large-conductance (KCNMA1 and KCNMB1-4), and intermediate-conductance (KCNN4) Ca 2؉ -activated K ؉ channels. The Ca 2؉ oscillations were unchanged after removal of extracellular Ca 2؉ , indicating that they were mainly due to movements of Ca 2؉ between intracellular compartments. Comparison of the effects of different nucleotides suggests that the Ca 2؉ oscillations were elicited by activation of P2Y2 receptors coupled to phospholipase C. Patch-clamp experiments showed that ATP induced a transient depolarization, probably mediated by activation of P2X 4 receptors, followed by membrane potential oscillations due to opening of Ca 2؉ -activated K ؉ channels. We also found that 10 M ATP␥S increased transcription of IL-6 Ϸ40-fold within 2 h. This effect was abolished by blockade of P2Y receptors with 100 M suramin. Our results suggest that ATP released from inflamed, damaged, or metabolically impaired cells represents a ''danger signal'' that plays a major role in activating the innate immune system.
The interaction of the adaptor protein p11, also denoted S100A10, with the C‐terminus of the two‐pore‐domain K+ channel TASK‐1 was studied using yeast two‐hybrid analysis, glutathione S‐transferase pulldown, and co‐immunoprecipitation. We found that p11 interacts with a 40 amino‐acid region in the proximal C‐terminus of the channel. In heterologous expression systems, deletion of the p11‐interacting domain enhanced surface expression of TASK‐1. Attachment of the p11‐interacting domain to the cytosolic tail of the reporter protein CD8 caused retention/retrieval of the construct in the endoplasmic reticulum (ER). Attachment of the last 36 amino acids of p11 to CD8 also caused ER localization, which was abolished by removal or mutation of a putative retention motif (H/K)xKxxx, at the C‐terminal end of p11. Imaging of EGFP‐tagged TASK‐1 channels in COS cells suggested that wild‐type TASK‐1 was largely retained in the ER. Knockdown of p11 with siRNA enhanced trafficking of TASK‐1 to the surface membrane. Our results suggest that binding of p11 to TASK‐1 retards the surface expression of the channel, most likely by virtue of a di‐lysine retention signal at the C‐terminus of p11. Thus, the cytosolic protein p11 may represent a ‘retention factor’ that causes localization of the channel to the ER.
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