Peter Proks

The KCNJ11-E23K gene variant hastens diabetes progression by impairing glucose-induced insulin secretion

Diabetes American Diabetes Association 70:5 (2021) 1145-1156

Authors:

Gregor Sachse, Elizabeth Haythorne, Thomas Hill, Peter Proks, Russell Joynson, Raul Terrón-Expósito, Liz Bentley, Stephen J Tucker, Roger D Cox, Frances M Ashcroft

Abstract:

The ATP-sensitive K+ (KATP) channel controls blood glucose levels by coupling glucose metabolism to insulin secretion in pancreatic β-cells. E23K, a common polymorphism in the pore-forming KATP channel subunit (KCNJ11) gene, has been linked to increased risk of type 2 diabetes. Understanding the risk-allele-specific pathogenesis has the potential to improve personalized diabetes treatment, but the underlying mechanism has remained elusive. Using a genetically engineered mouse model, we now show that the K23 variant impairs glucose-induced insulin secretion and increases diabetes risk when combined with a high-fat diet (HFD) and obesity. KATP-channels in β-cells with two K23 risk alleles (KK) showed decreased ATP inhibition, and the threshold for glucose-stimulated insulin secretion from KK islets was increased. Consequently, the insulin response to glucose and glycemic control was impaired in KK mice fed a standard diet. On an HFD, the effects of the KK genotype were exacerbated, accelerating diet-induced diabetes progression and causing β-cell failure. We conclude that the K23 variant increases diabetes risk by impairing insulin secretion at threshold glucose levels, thus accelerating loss of β-cell function in the early stages of diabetes progression.

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

Communications chemistry 3:1 (2020) 147

Authors:

Tanadet Pipatpolkai, Robin A Corey, Peter Proks, Frances M Ashcroft, Phillip J Stansfeld

Abstract:

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.

Phenotype of a transient neonatal diabetes point mutation (SUR1-R1183W) in mice

Wellcome Open Research F1000Research 5 (2020) 15

Authors:

Gregor Sachse, Elizabeth Haythorne, Peter Proks, Michelle Stewart, Heather Cater, Sian Ellard, Ben Davies, Frances M Ashcroft

Phenotype of a transient neonatal diabetes point mutation (SUR1-R1183W) in mice.

Wellcome open research 5 (2020) 15

Authors:

Gregor Sachse, Elizabeth Haythorne, Peter Proks, Michelle Stewart, Heather Cater, Sian Ellard, Ben Davies, Frances M Ashcroft

Abstract:

Background: The K _ATP channel plays a key role in glucose homeostasis by coupling metabolically generated changes in ATP to insulin secretion from pancreatic beta-cells.  Gain-of-function mutations in either the pore-forming (Kir6.2) or regulatory (SUR1) subunit of this channel are a common cause of transient neonatal diabetes mellitus (TNDM), in which diabetes presents shortly after birth but remits within the first few years of life, only to return in later life. The reasons behind this time dependence are unclear. Methods: In an attempt to understand the mechanism behind diabetes remission and relapse, we generated mice expressing the common TNDM mutation SUR1-R1183W. We employed Cre/LoxP technology for both inducible and constitutive expression of SUR1-R1183W specifically in mouse beta-cells, followed by investigation of their phenotype using glucose tolerance tests and insulin secretion from isolated islets.  Results: We found that the R1183W mutation impaired inhibition of K _ATP channels by ATP when heterologously expressed in human embryonic kidney cells. However, neither induced nor constitutive expression of SUR1-R1183W in mice resulted in changes in blood glucose homeostasis, compared to littermate controls. When challenged with a high fat diet, female mice expressing SUR1-R1183W showed increased weight gain, elevated blood glucose and impaired glycaemic control, but glucose-stimulated insulin secretion from pancreatic islets appeared unchanged. Conclusions: The mouse model of TNDM did not recapitulate the human phenotype. We discuss multiple potential reasons why this might be the case. Based on our findings, we recommend future TNDM mouse models employing a gain-of-function SUR1 mutation should be created using the minimally invasive CRISPR/Cas technology, which avoids many potential pitfalls associated with the Cre/LoxP system.

Multiple Mechanisms Underlie State-Independent Inhibitory Effects of Norfluoxetine on TREK-2 K2P Channels

(2020)

Authors:

Peter Proks, Marcus Schewe, Linus Conrad, Shanlin Rao, Kristin Rathje, Karin Rödström, Elisabeth Carpenter, Thomas Baukrowitz, Stephen Tucker

Abstract:

ABSTRACT

The TREK subfamily of Two-Pore Domain (K2P) K + channels are inhibited by fluoxetine and its metabolite, norfluoxetine (NFx). Although not the principal targets of this antidepressant, TREK channel inhibition by NFx has provided important insights into the conformational changes associated with channel gating and highlighted the role of the selectivity filter in this process. But despite the availability of TREK-2 crystal structures with NFx bound, the precise mechanisms underlying NFx inhibition remain elusive. NFx has previously been proposed to be a state-dependent inhibitor, but its binding site suggests many possible ways in which this positively charged drug might inhibit channel activity. Here we show that NFx exerts multiple effects on single channel behavior that influence both the open and closed states of the channel, and that the channel can become highly activated by 2-APB whilst remaining in the down conformation. We also show that that the inhibitory effects of NFx are unrelated to its positive charge, but can be influenced by agonists such as ML335 which alter filter stability, as well as by an intrinsic voltage-dependent gating process within the filter. NFx therefore not only inhibits channel activity by altering the equilibrium between up and down conformations, but can also directly influence filter gating. These results provide further insight into the complex allosteric mechanisms that modulate filter-gating in TREK K2P channels and highlight the different ways that filter gating can be regulated to permit polymodal regulation.