Tanadet Pipatpolkai scite author profile

The ATP-sensitive potassium (K ATP) channel couples blood levels of glucose to insulin secretion from pancreatic-cells. K ATP channel closure triggers a cascade of events that results in insulin release. Metabolically generated changes in the intracellular concentrations of adenosine nucleotides are integral to this regulation, with ATP and ADP closing the channel and MgATP and MgADP increasing channel activity. Activating mutations in either of the two types of K ATP channel subunit (Kir6.2 and SUR1) result in neonatal diabetes mellitus, whereas loss-of-function mutations cause hyperinsulinaemic hypoglycaemia of infancy. Sulphonylurea and glinide drugs, which bind to SUR1, close the channel through a pathway independent of ATP and are now the primary therapy for neonatal diabetes mellitus caused by K ATP channel mutations. Insight into the molecular details of drug and nucleotide regulation of channel activity has been illuminated by cryo-electron microscopy structures that reveal the atomic-level organisation of the K ATP channel complex. Here, we review how these structures aid our understanding of how the various mutations in Kir6.2 (KCNJ11) and SUR1 (ABCC8) lead to a reduction in ATP inhibition and thereby neonatal diabetes mellitus. We also provide an update on known mutations and sulphonylurea therapy in neonatal diabetes mellitus.

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Evaluating Inositol phospholipid interactions with Inward Rectifier Potassium Channels and characterising their role in Disease

Pipatpolkai

Corey

Proks

et al. 2020

Preprint

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Membrane proteins are frequently modulated by specific protein-lipid interactions. The activation of human inward rectifying potassium (hKir) channels by phosphoinositides (PI) has been well characterised. Here, we apply a coarse-grained molecular dynamics free-energy perturbation (CG-FEP) protocol to capture the energetics of binding of PI lipids to hKir channels. By using either a single- or multi-step approach, we establish a consistent value for the binding of PIP2 to hKir channels, relative to the binding of the bulk phosphatidylcholine phospholipid. Furthermore, by perturbing amino acid side chains on hKir6.2, we show that the neonatal diabetes mutation E179K increases PIP2 affinity, while the congenital hyperinsulinism mutation K67N results in a reduced affinity. We show good agreement with electrophysiological data where E179K exhibits a reduction in neomycin sensitivity, implying that PIP2 binds more tightly E179K channels. This illustrates the application of CG-FEP to compare affinities between lipid species, and for annotating amino acid residues.

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Evaluating inositol phospholipid interactions with inward rectifier potassium channels and characterising their role in disease

et al. 2020

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An outer-pore gate modulates the pharmacology of the TMEM16A channel

Dinsdale

Pipatpolkai

Agostinelli

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

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Significance The TMEM16A calcium-gated chloride channels participate in a range of vital physiological functions. TMEM16A channels are desirable new drug targets as their dysfunction can lead to pathology. In spite of this, their pharmacology is still in its infancy. Gaining insight into the mode of action and binding sites for test compounds forms the basis for the development of new TMEM16A-interacting drugs. Here, we demonstrate that intracellular calcium triggers a conformational change in the outer mouth of the channel, which enables entry of a small molecule into the pore. Characterization of this structural rearrangement defines a critical site for pharmacological intervention and reveals an aspect of calcium gating in the TMEM16A channel.

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