Computational Identification of Novel Kir6 Channel Inhibitors

KATP channels consist of four Kir6.x pore–forming subunits and four regulatory sulfonylurea receptor (SUR) subunits. These channels couple the metabolic state of the cell to membrane excitability and play a key role in physiological processes such as insulin secretion in the pancreas, protection of cardiac muscle during ischemia and hypoxic vasodilation of arterial smooth muscle cells. Abnormal channel function resulting from inherited gain or loss-of-function mutations in either the Kir6.x and/or SUR subunits are associated with severe diseases such as neonatal diabetes, congenital hyperinsulinism, or Cantú syndrome (CS). CS is an ultra-rare genetic autosomal dominant disorder, caused by dominant gain-of-function mutations in SUR2A or Kir6.1 subunits. No specific pharmacotherapeutic treatment options are currently available for CS. Kir6 specific inhibitors could be beneficial for the development of novel drug therapies for CS, particular for mutations, which lack high affinity for sulfonylurea inhibitor glibenclamide. By applying a combination of computational methods including atomistic MD simulations, free energy calculations and pharmacophore modeling, we identified several novel Kir6.1 inhibitors, which might be possible candidates for drug repurposing. The in silico predictions were confirmed using inside/out patch-clamp analysis. Importantly, Cantú mutation C166S in Kir6.2 (equivalent to C176S in Kir6.1) and S1020P in SUR2A, retained high affinity toward the novel inhibitors. Summarizing, the inhibitors identified in this study might provide a starting point toward developing novel therapies for Cantú disease.

[1]  S. Seino,et al.  Cooperative binding of ATP and MgADP in the sulfonylurea receptor is modulated by glibenclamide. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[2]  Roderick MacKinnon,et al.  Crystal Structure of the Mammalian GIRK2 K+ Channel and Gating Regulation by G Proteins, PIP2, and Sodium , 2011, Cell.

[3]  J. Śanchez-Corona,et al.  A distinct osteochondrodysplasia with hypertrichosis—Individualization of a probable autosomal recessive entity , 2004, Human Genetics.

[4]  Berk Hess,et al.  LINCS: A linear constraint solver for molecular simulations , 1997 .

[5]  A. Hattersley,et al.  Glibenclamide unresponsiveness in a Brazilian child with permanent neonatal diabetes mellitus and DEND syndrome due to a C166Y mutation in KCNJ11 (Kir6.2) gene. , 2008, Arquivos brasileiros de endocrinologia e metabologia.

[6]  P. Bork,et al.  A side effect resource to capture phenotypic effects of drugs , 2010, Molecular systems biology.

[7]  M. A. van der Heyden,et al.  Glibenclamide and HMR1098 normalize Cantú syndrome‐associated gain‐of‐function currents , 2019, Journal of cellular and molecular medicine.

[8]  A. Sali,et al.  Comparative protein structure modeling of genes and genomes. , 2000, Annual review of biophysics and biomolecular structure.

[9]  C. Greyson,et al.  Thiazolidinedione drugs block cardiac KATP channels and may increase propensity for ischaemic ventricular fibrillation in pigs , 2008, Diabetologia.

[10]  Daling Zhu,et al.  Rosiglitazone selectively inhibits KATP channels by acting on the KIR6 subunit , 2012, British journal of pharmacology.

[11]  Junmei Wang,et al.  Development and testing of a general amber force field , 2004, J. Comput. Chem..

[12]  C. Nichols,et al.  KATP channels and cardiovascular disease: suddenly a syndrome. , 2013, Circulation research.

[13]  Ann K. Miller,et al.  Absorption, disposition, and metabolism of rosiglitazone, a potent thiazolidinedione insulin sensitizer, in humans. , 2000, Drug metabolism and disposition: the biological fate of chemicals.

[14]  J. Hancox Cardiac ion channel modulation by the hypoglycaemic agent rosiglitazone , 2011, British journal of pharmacology.

[15]  M. Vos,et al.  Efficient and specific cardiac IK₁ inhibition by a new pentamidine analogue. , 2013, Cardiovascular research.

[16]  G. Giebisch,et al.  The Carboxyl Termini of KATP Channels Bind Nucleotides* , 2002, The Journal of Biological Chemistry.

[17]  F. Ashcroft,et al.  Successful transfer to sulfonylureas in KCNJ11 neonatal diabetes is determined by the mutation and duration of diabetes , 2016, Diabetologia.

[18]  C. Nichols,et al.  Conserved functional consequences of disease-associated mutations in the slide helix of Kir6.1 and Kir6.2 subunits of the ATP-sensitive potassium channel , 2017, The Journal of Biological Chemistry.

[19]  T. Amachi,et al.  Different Binding Properties and Affinities for ATP and ADP among Sulfonylurea Receptor Subtypes, SUR1, SUR2A, and SUR2B* , 2000, The Journal of Biological Chemistry.

[20]  M. Parrinello,et al.  Polymorphic transitions in single crystals: A new molecular dynamics method , 1981 .

[21]  T. Langer,et al.  Computational identification of novel Kir6 channel inhibitors , 2019, bioRxiv.

[22]  H. Katus,et al.  Inhibition of inwardly rectifying Kir2.x channels by the novel anti-cancer agent gambogic acid depends on both pore block and PIP2 interference , 2017, Naunyn-Schmiedeberg's Archives of Pharmacology.

[23]  Y. Kubo,et al.  Ivermectin activates GIRK channels in a PIP2‐dependent, Gβγ‐independent manner and an amino acid residue at the slide helix governs the activation , 2017, The Journal of physiology.

[24]  B. Efron Bootstrap Methods: Another Look at the Jackknife , 1979 .

[25]  S. Robertson,et al.  Cantú syndrome: Report of nine new cases and expansion of the clinical phenotype , 2011, American journal of medical genetics. Part A.

[26]  M. Parrinello,et al.  Canonical sampling through velocity rescaling. , 2007, The Journal of chemical physics.

[27]  T. J. Wilson,et al.  M‐LDH serves as a sarcolemmal KATP channel subunit essential for cell protection against ischemia , 2002, The EMBO journal.

[28]  O. Berger,et al.  Molecular dynamics simulations of a fluid bilayer of dipalmitoylphosphatidylcholine at full hydration, constant pressure, and constant temperature. , 1997, Biophysical journal.

[29]  N. Cui,et al.  Requirement of Multiple Protein Domains and Residues for GatingK ATP Channels by Intracellular pH* , 2001, The Journal of Biological Chemistry.

[30]  Lei Chen,et al.  Ligand binding and conformational changes of SUR1 subunit in pancreatic ATP-sensitive potassium channels , 2018, Protein & Cell.

[31]  S. Hahn,et al.  Rosiglitazone inhibits Kv4.3 potassium channels by open‐channel block and acceleration of closed‐state inactivation , 2011, British journal of pharmacology.

[32]  C. Nichols,et al.  Control of Kir channel gating by cytoplasmic domain interface interactions , 2017, The Journal of general physiology.

[33]  N. Guex,et al.  SWISS‐MODEL and the Swiss‐Pdb Viewer: An environment for comparative protein modeling , 1997, Electrophoresis.

[34]  John D. Hunter,et al.  Matplotlib: A 2D Graphics Environment , 2007, Computing in Science & Engineering.

[35]  C. Nichols,et al.  Hyperinsulinism and diabetes: genetic dissection of beta cell metabolism-excitation coupling in mice. , 2009, Cell metabolism.

[36]  A. Hoischen,et al.  Cantú Syndrome Resulting from Activating Mutation in the KCNJ8 Gene , 2014, Human mutation.

[37]  Cheng He,et al.  Activation of inwardly rectifying K+ channels by distinct PtdIns(4,5)P2 interactions , 1999, Nature Cell Biology.

[38]  T. Darden,et al.  Particle mesh Ewald: An N⋅log(N) method for Ewald sums in large systems , 1993 .

[39]  C. Nichols,et al.  Diabetes induced by gain-of-function mutations in the Kir6.1 subunit of the KATP channel , 2017, The Journal of general physiology.

[40]  N. Standen,et al.  Activation of ATP‐dependent K+ channels by hypoxia in smooth muscle cells isolated from the pig coronary artery. , 1995, The Journal of physiology.

[41]  L. Verlet Computer "Experiments" on Classical Fluids. I. Thermodynamical Properties of Lennard-Jones Molecules , 1967 .

[42]  James Z. Chen,et al.  Cryo-EM structure of the ATP-sensitive potassium channel illuminates mechanisms of assembly and gating , 2016, bioRxiv.

[43]  V. Hornak,et al.  Comparison of multiple Amber force fields and development of improved protein backbone parameters , 2006, Proteins.

[44]  F. Ashcroft,et al.  Direct Photoaffinity Labeling of the Kir6.2 Subunit of the ATP-sensitive K+ Channel by 8-Azido-ATP* , 1999, The Journal of Biological Chemistry.

[45]  Stef van Lieshout,et al.  Dominant missense mutations in ABCC9 cause Cantú syndrome , 2012, Nature Genetics.

[46]  J. R. Scotti,et al.  Available From , 1973 .

[47]  D. Fardo,et al.  Novel human ABCC9/SUR2 brain‐expressed transcripts and an eQTL relevant to hippocampal sclerosis of aging , 2015, Journal of neurochemistry.

[48]  F. Reimann,et al.  Sulphonylurea action revisited: the post-cloning era , 2003, Diabetologia.

[49]  T. Opthof,et al.  The anti‐protozoal drug pentamidine blocks KIR2.x‐mediated inward rectifier current by entering the cytoplasmic pore region of the channel , 2010, British journal of pharmacology.

[50]  A. Terzic,et al.  ATP-sensitive potassium channels: metabolic sensing and cardioprotection. , 2007, Journal of applied physiology.

[51]  M. Ishii,et al.  Carvedilol blocks cardiac KATP and KG but not IK1 channels by acting at the bundle-crossing regions. , 2006, European journal of pharmacology.

[52]  F. Ashcroft,et al.  Molecular Analysis of ATP-sensitive K Channel Gating and Implications for Channel Inhibition by ATP , 1998, The Journal of general physiology.

[53]  Daniela Ponce-Balbuena,et al.  Carvedilol inhibits Kir2.3 channels by interference with PIP₂-channel interaction. , 2011, European journal of pharmacology.

[54]  F. Ashcroft ATP-sensitive potassium channelopathies: focus on insulin secretion. , 2005, The Journal of clinical investigation.

[55]  C. Ahern,et al.  A Conserved Residue Cluster That Governs Kinetics of ATP-dependent Gating of Kir6.2 Potassium Channels* , 2015, The Journal of Biological Chemistry.

[56]  Thierry Langer,et al.  LigandScout: 3-D Pharmacophores Derived from Protein-Bound Ligands and Their Use as Virtual Screening Filters , 2005, J. Chem. Inf. Model..

[57]  Peer Bork,et al.  The SIDER database of drugs and side effects , 2015, Nucleic Acids Res..

[58]  F. Ashcroft,et al.  Switching from insulin to oral sulfonylureas in patients with diabetes due to Kir6.2 mutations. , 2006, The New England journal of medicine.

[59]  Thierry Langer,et al.  Common Hits Approach: Combining Pharmacophore Modeling and Molecular Dynamics Simulations , 2017, J. Chem. Inf. Model..

[60]  David S. Wishart,et al.  DrugBank 4.0: shedding new light on drug metabolism , 2013, Nucleic Acids Res..

[61]  T. Straatsma,et al.  THE MISSING TERM IN EFFECTIVE PAIR POTENTIALS , 1987 .

[62]  C. Nichols,et al.  Membrane phospholipid control of nucleotide sensitivity of KATP channels. , 1998, Science.

[63]  Peter G. Kusalik,et al.  The Spatial Structure in Liquid Water , 1994, Science.

[64]  N. Gao,et al.  Structure of a Pancreatic ATP-Sensitive Potassium Channel , 2017, Cell.

[65]  B. V. van Bon,et al.  Cantú syndrome is caused by mutations in ABCC9. , 2012, American journal of human genetics.

[66]  G. Giebisch,et al.  Nucleotides and phospholipids compete for binding to the C terminus of KATP channels , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[67]  Bert L. de Groot,et al.  g_wham—A Free Weighted Histogram Analysis Implementation Including Robust Error and Autocorrelation Estimates , 2010 .

[68]  T. Amachi,et al.  ATP Binding Properties of the Nucleotide-binding Folds of SUR1* , 1999, The Journal of Biological Chemistry.

[69]  C. Yoshioka,et al.  Anti-diabetic drug binding site in a mammalian KATP channel revealed by Cryo-EM , 2017, eLife.

[70]  C. Nichols,et al.  The shifting landscape of KATP channelopathies and the need for 'sharper' therapeutics. , 2016, Future medicinal chemistry.

[71]  J. Plutzky,et al.  Peroxisome proliferator-activated receptors as transcriptional nodal points and therapeutic targets. , 2007, Circulation.

[72]  C. Nichols,et al.  Structural basis of control of inward rectifier Kir2 channel gating by bulk anionic phospholipids , 2016, The Journal of general physiology.

[73]  W. Lederer,et al.  Adenosine triphosphate-sensitive potassium channels in the cardiovascular system. , 1991, The American journal of physiology.

[74]  Meghan C Towne,et al.  Mutation of KCNJ8 in a patient with Cantú syndrome with unique vascular abnormalities - support for the role of K(ATP) channels in this condition. , 2013, European journal of medical genetics.

[75]  N. Cui,et al.  Rosiglitazone inhibits vascular KATP channels and coronary vasodilation produced by isoprenaline , 2011, British journal of pharmacology.

[76]  S. Shyng,et al.  Stabilization of the Activity of ATP-sensitive Potassium Channels by Ion Pairs Formed between Adjacent Kir6.2 Subunits , 2003, The Journal of general physiology.

[77]  Berk Hess,et al.  GROMACS: High performance molecular simulations through multi-level parallelism from laptops to supercomputers , 2015 .

[78]  R. MacKinnon,et al.  Molecular structure of human KATP in complex with ATP and ADP , 2017, bioRxiv.

[79]  P. Kollman,et al.  Automatic atom type and bond type perception in molecular mechanical calculations. , 2006, Journal of molecular graphics & modelling.

[80]  D. Hilgemann,et al.  Direct activation of inward rectifier potassium channels by PIP2 and its stabilization by Gβγ , 1998, Nature.

[81]  T. Bányász,et al.  Effects of rosiglitazone on the configuration of action potentials and ion currents in canine ventricular cells , 2011, British journal of pharmacology.

[82]  P Willett,et al.  Development and validation of a genetic algorithm for flexible docking. , 1997, Journal of molecular biology.