Leptin is a pivotal regulator of energy and glucose homeostasis, and defects in leptin signaling result in obesity and diabetes. The ATP-sensitive potassium (K ATP ) channels couple glucose metabolism to insulin secretion in pancreatic β-cells. In this study, we provide evidence that leptin modulates pancreatic β-cell functions by promoting K ATP channel translocation to the plasma membrane via AMP-activated protein kinase (AMPK) signaling. K ATP channels were localized mostly to intracellular compartments of pancreatic β-cells in the fed state and translocated to the plasma membrane in the fasted state. This process was defective in leptin-deficient ob/ob mice, but restored by leptin treatment. We discovered that the molecular mechanism of leptin-induced AMPK activation involves canonical transient receptor potential 4 and calcium/calmodulindependent protein kinase kinase β. AMPK activation was dependent on both leptin and glucose concentrations, so at optimal concentrations of leptin, AMPK was activated sufficiently to induce K ATP channel trafficking and hyperpolarization of pancreatic β-cells in a physiological range of fasting glucose levels. There was a close correlation between phospho-AMPK levels and β-cell membrane potentials, suggesting that AMPK-dependent K ATP channel trafficking is a key mechanism for regulating β-cell membrane potentials. Our results present a signaling pathway whereby leptin regulates glucose homeostasis by modulating β-cell excitability.T he K ATP channel, an inwardly rectifying K + channel that consists of pore-forming Kir6.2 and regulatory sulfonylurea receptor 1 (SUR1) subunits (1), functions as an energy sensor: its gating is regulated mainly by the intracellular concentrations of ATP and ADP. In pancreatic β-cells, K ATP channels are inhibited or activated in response to the rise or fall in blood glucose levels, leading to changes in membrane excitability and insulin secretion (2, 3). Thus, K ATP channel gating has been considered an important mechanism in coupling blood glucose levels to insulin secretion. Recently, trafficking of K ATP channels to the plasma membrane was highlighted as another important mechanism for regulating K ATP channel activity (4-6).AMP-activated protein kinase (AMPK) is a key enzyme regulating energy homeostasis (7). We recently demonstrated that K ATP channels are recruited to the plasma membrane in glucosedeprived conditions via AMPK signaling in pancreatic β-cells (6). Inhibition of AMPK signaling significantly reduces K ATP currents, even after complete wash-out of intracellular ATP (6). Given these results, we proposed a model that recruitment of K ATP channels to the plasma membrane via AMPK signaling is crucial for K ATP channel activation in low-glucose conditions. However, the physiological relevance of this model remains unclear because pancreatic β-cells had to be incubated in media containing less than 3 mM glucose to recruit a sufficient number of K ATP channels to the plasma membrane (6). We thus hypothesized that there should be an e...
Background: Activation of TRPC4/5 channels is mediated by GPCR activation. Results: TRPC4/5 was activated by the G␣ i/o -coupled receptor and the G␣ i protein, which interacted directly with each other. Conclusion: G␣ i proteins play an essential role as novel activators of TRPC4/5. Significance: Our findings provide new insights into the activation mechanism of inhibitory G␣ proteins.
Transient receptor potential canonical (TRPC) 1, the first mammalian homologue of Drosophila trp gene, is distributed widely in mammalian cells and is involved in many physiological functions. TRPC1 is reported to be functional following heteromeric formation with other TRPC channels such as TRPC4 or TRPC5. It is known that the composition of this widely distributed TRPC1 is far from simple; functionality of such channels has been highly controversial. Furthermore, TRPC1 gene is known to have two splicing variants; one encodes long (TRPC1α) and the other encodes short (TRPC1β) TRPC1 isoforms, respectively. In this study, we examined the functionality of TRPC1/4 channels using various activation systems. Gq/11-coupled receptor (e.g., M1 or M3 receptors) stimulation significantly increased TRPC1α/4 currents but induced mild activation of TRPC1β/4. In addition, when expressed with TRPC4, TRPC1α acted as a pore-constituting subunit and not a β ancillary subunit. Multimerized with TRPC4, TRPC1α also generated strong pore field strength. We also found that Gi/o-coupled receptor (e.g., M2 receptor) stimulation was insufficient to activate TRPC1α/4 and TRPC1β/4 channels but selectively activated TRPC4 homomeric channels. These findings demonstrate that TRPC1/4 channel shows dynamic gating property depending on TRPC1 isoform subtypes and receptor stimulation system. Therefore, careful discrimination of the specificity of TRPC1 isoforms and upstream activation system is important in thorough understanding of TRPC1 and TRPC1/4 channels.
The transient receptor potential canonical 4 (TRPC4) channel is a Ca(2+)-permeable nonselective cation channel in mammalian cells and mediates a number of cellular functions. Many studies show that TRPC channels are activated by stimulation of Gαq-phospholipase C (PLC)-coupled receptors. However, our previous study showed that the TRPC4 current was inhibited by co-expression of a constitutively active form of Gαq (Gαq (Q209L)). A shortage of phosphatidylinositol 4,5-bisphosphate [PI(4,5)P2] in Gαq (Q209L) may be responsible for reduced TRPC4 activity. Here, we tested this hypothesis by using a rapamycin-inducible system that regulates PI(4,5)P2 acutely and specifically. Our results showed that the TRPC4β current was reduced by inducible Gαq (Q209L), but not by the mutants with impaired binding ability to PLCβ. Depletion of PI(4,5)P2 by inducing the inositol polyphosphate 5-phosphatase to HEK293 cells that express TRPC4β led to an irreversible inhibition of TRPC4β currents. In contrast, inducing phosphatidylinositol 4-phosphate 5-kinase or intracellular PI(4,5)P2 application did not activate the TRPC4β current. Finally, we revealed that PI(4,5)P2 is important in delaying the desensitization of TRPC4β. Taken together, we suggest that PI(4,5)P2 is not the activator of TRPC4β activation, but it is still necessary for regulating TRPC4β activation.
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