Inwardly rectifying potassium channels (Kir) in central nervous system glia: a special role for Kir4.1 in glial functions

Glia in the central nervous system (CNS) express diverse inward rectifying potassium channels (Kir). The major function of Kir is in establishing the high potassium (K+) selectivity of the glial cell membrane and strongly negative resting membrane potential (RMP), which are characteristic physiological properties of glia. The classical property of Kir is that K+ flows inwards when the RMP is negative to the equilibrium potential for K+ (Ek), but at more positive potentials outward currents are inhibited. This provides the driving force for glial uptake of K+ released during neuronal activity, by the processes of “K+ spatial buffering” and “K+ siphoning”, considered a key function of astrocytes, the main glial cell type in the CNS. Glia express multiple Kir channel subtypes, which are likely to have distinct functional roles related to their differences in conductance, and sensitivity to intracellular and extracellular factors, including pH, ATP, G‐proteins, neurotransmitters and hormones. A feature of CNS glia is their specific expression of the Kir4.1 subtype, which is a major K+ conductance in glial cell membranes and has a key role in setting the glial RMP. It is proposed that Kir4.1 have a primary function in K+ regulation, both as homomeric channels and as heteromeric channels by co‐assembley with Kir5.1 and probably Kir2.0 subtypes. Significantly, Kir4.1 are also expressed by oligodendrocytes, the myelin‐forming cells of the CNS, and the genetic ablation of Kir4.1 are also expressed by Oligodendrocytes, the myelin‐forming cells of the CNS, and the genetic ablation of Kir4.1 results in severe hypomyelination. Hence, Kir, and in particular Kir4.1, are key regulators of glial functions, which in turn determine neuronal excitability and axonal conduction.

[1]  J Wenzel,et al.  Functional Specialization and Topographic Segregation of Hippocampal Astrocytes , 1998, The Journal of Neuroscience.

[2]  H. Sontheimer Voltage‐dependent ion channels in glial cells , 1994, Glia.

[3]  E. Newman High potassium conductance in astrocyte endfeet. , 1986, Science.

[4]  T. Gotow,et al.  Expression and Clustered Distribution of an Inwardly Rectifying Potassium Channel, KAB-2/Kir4.1, on Mammalian Retinal Müller Cell Membrane: Their Regulation by Insulin and Laminin Signals , 1997, The Journal of Neuroscience.

[5]  Edmund M Talley,et al.  The TASK family: two-pore domain background K+ channels. , 2003, Molecular interventions.

[6]  S. W. Kuffler,et al.  Physiological properties of glial cells in the central nervous system of amphibia. , 1966, Journal of neurophysiology.

[7]  B. Pál,et al.  Differential distribution of TASK-1, TASK-2 and TASK-3 immunoreactivities in the rat and human cerebellum , 2004, Cellular and Molecular Life Sciences CMLS.

[8]  E A Newman,et al.  Inward-rectifying potassium channels in retinal glial (Muller) cells , 1993, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[9]  A. Karschin,et al.  KATP channel formation by the sulphonylurea receptors SUR1 with Kir6.2 subunits in rat dorsal vagal neurons in situ , 1998, The Journal of physiology.

[10]  B. Connors,et al.  Activity-dependent K+ accumulation in the developing rat optic nerve. , 1982, Science.

[11]  A. Butt,et al.  Cyclic AMP-mediated regulation of the resting membrane potential in myelin-forming oligodendrocytes in the isolated intact rat optic nerve , 2006, Experimental Neurology.

[12]  Bernd Biedermann,et al.  Kir potassium channel subunit expression in retinal glial cells: Implications for spatial potassium buffering † , 2002, Glia.

[13]  J. Adelman,et al.  Subunit positional effects revealed by novel heteromeric inwardly rectifying K+ channels. , 1996, The EMBO journal.

[14]  G. Giebisch,et al.  Renal K+ channels: structure and function. , 1997, Annual review of physiology.

[15]  H. Kettenmann,et al.  Channel expression correlates with differentiation stage during the development of Oligodendrocytes from their precursor cells in culture , 1989, Neuron.

[16]  J. Deitmer,et al.  5‐Hydroxytryptamine activates a barium‐sensitive, cAMP‐mediated potassium conductance in the leech giant glial cell , 2005, Glia.

[17]  P. Stanfield,et al.  Constitutively active and G-protein coupled inward rectifier K+ channels: Kir2.0 and Kir3.0. , 2002, Reviews of physiology, biochemistry and pharmacology.

[18]  Y. Kurachi,et al.  An inward rectifier K+ channel at the basolateral membrane of the mouse distal convoluted tubule: similarities with Kir4‐Kir5.1 heteromeric channels , 2002, The Journal of physiology.

[19]  J. Simard,et al.  Inward rectifier K+ channel Kir2.3 (IRK3) in reactive astrocytes from adult rat brain , 2000, Glia.

[20]  Yoshihisa Kurachi,et al.  A Novel ATP-dependent Inward Rectifier Potassium Channel Expressed Predominantly in Glial Cells (*) , 1995, The Journal of Biological Chemistry.

[21]  J. Adelman,et al.  Inhibitory Interactions between Two Inward Rectifier K Channel Subunits Mediated by the Transmembrane Domains (*) , 1996, The Journal of Biological Chemistry.

[22]  C. Nichols,et al.  Inward rectifier potassium channels. , 1997, Annual review of physiology.

[23]  H. Sontheimer,et al.  Mislocalization of Kir channels in malignant glia , 2004, Glia.

[24]  S. Ferroni,et al.  Arachidonic acid activates an open rectifier potassium channel in cultured rat cortical astrocytes , 2003, Journal of neuroscience research.

[25]  K. Holthoff,et al.  Directed spatial potassium redistribution in rat neocortex , 2000, Glia.

[26]  C. Yost,et al.  Protective effects of TASK-3 (KCNK9) and related 2P K channels during cellular stress , 2005, Brain Research.

[27]  C. Vandenberg,et al.  Inward rectifier potassium channel Kir2.2 is associated with synapse-associated protein SAP97. , 2001, Journal of cell science.

[28]  A. Karschin,et al.  Identification of G protein-regulated inwardly rectifying K+ channels in rat brain oligodendrocytes , 1995, Neuroscience Letters.

[29]  D. Clapham,et al.  The G-protein-gated atrial K+ channel IKAch is a heteromultimer of two inwardly rectifying K+-channel proteins , 1995, Nature.

[30]  J. Ruppersberg,et al.  Functional and Molecular Diversity Classifies the Family of Inward-Rectifier K+ Channels , 1996 .

[31]  Y. Kurachi,et al.  An inwardly rectifying K(+) channel, Kir4.1, expressed in astrocytes surrounds synapses and blood vessels in brain. , 2001, American journal of physiology. Cell physiology.

[32]  L. Li,et al.  Identification of an inward rectifier potassium channel gene expressed in mouse cortical astrocytes , 2001, Glia.

[33]  J. Ruppersberg,et al.  Intracellular regulation of inward rectifier K+ channels , 2000, Pflügers Archiv.

[34]  H. Lester,et al.  The inward rectifier potassium channel family , 1995, Current Opinion in Neurobiology.

[35]  S. Tucker,et al.  Identification of a Heteromeric Interaction That Influences the Rectification, Gating, and pH Sensitivity of Kir4.1/Kir5.1 Potassium Channels* , 2003, Journal of Biological Chemistry.

[36]  R. Jabs,et al.  Functional and Molecular Properties of Human Astrocytes in Acute Hippocampal Slices Obtained from Patients with Temporal Lobe Epilepsy , 2000, Epilepsia.

[37]  A. Karschin,et al.  Kir6.1 Is the Principal Pore-Forming Subunit of Astrocyte but Not Neuronal Plasma Membrane K-ATP Channels , 2001, Molecular and Cellular Neuroscience.

[38]  W. J. Brammar,et al.  Characterisation of Kir2.0 proteins in the rat cerebellum and hippocampus by polyclonal antibodies , 1999, Histochemistry and Cell Biology.

[39]  K. Grzeschik,et al.  Genetic and functional linkage of Kir5.1 and Kir2.1 channel subunits , 2001, FEBS letters.

[40]  B. Soliven,et al.  Expression and modulation of K+ currents in oligodendrocytes: possible role in myelinogenesis. , 1989, Developmental neuroscience.

[41]  C. Steinhäuser,et al.  AMPA Receptor-Mediated Modulation of Inward Rectifier K+ Channels in Astrocytes of Mouse Hippocampus , 2002, Molecular and Cellular Neuroscience.

[42]  R. D’Ambrosio,et al.  Differential role of KIR channel and Na(+)/K(+)-pump in the regulation of extracellular K(+) in rat hippocampus. , 2002, Journal of neurophysiology.

[43]  M. Zhou,et al.  A re‐examination of adult mouse nicotinic acetylcholine receptor channel activation kinetics , 1999, The Journal of physiology.

[44]  T. Berger,et al.  Developmental changes in the membrane current pattern, K+ buffer capacity, and morphology of glial cells in the corpus callosum slice , 1991, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[45]  Y. Kurachi,et al.  Inwardly rectifying potassium channels: their molecular heterogeneity and function. , 1997, The Japanese journal of physiology.

[46]  R. D’Ambrosio,et al.  Heterogeneity of Astrocyte Resting Membrane Potentials and Intercellular Coupling Revealed by Whole-Cell and Gramicidin-Perforated Patch Recordings from Cultured Neocortical and Hippocampal Slice Astrocytes , 1997, The Journal of Neuroscience.

[47]  A. Reichenbach,et al.  Tandem‐pore domain potassium channels are functionally expressed in retinal (Müller) glial cells , 2006, Glia.

[48]  K. Sanders,et al.  Two‐pore‐domain potassium channels in smooth muscles: new components of myogenic regulation , 2006, The Journal of physiology.

[49]  R. Keynes The ionic channels in excitable membranes. , 1975, Ciba Foundation symposium.

[50]  A. Reichenbach,et al.  SUR1 and Kir6.1 subunits of KATP-channels are co-localized in retinal glial (Müller) cells , 2002, Neuroreport.

[51]  A. Reichenbach,et al.  Tandem-pore K+channels display an uneven distribution in amphibian retina , 2004, Neuroreport.

[52]  S. Korn,et al.  Potassium channels , 2005, IEEE Transactions on NanoBioscience.

[53]  A. Reichenbach,et al.  Kir subfamily in frog retina: specific spatial distribution of Kir 6.1 in glial (Müller) cells , 2001, Neuroreport.

[54]  T. Balla,et al.  PIP2 hydrolysis underlies agonist‐induced inhibition and regulates voltage gating of two‐pore domain K+ channels , 2005, The Journal of physiology.

[55]  N. Rawson,et al.  Distribution and phenotype of neurons containing the ATP-sensitive K+ channel in rat brain , 1998, Brain Research.

[56]  H. V. Van Tol,et al.  Co-expression of human Kir3 subunits can yield channels with different functional properties. , 1999, Cellular signalling.

[57]  H. Lester,et al.  Fast Inhibition of Inwardly Rectifying K+ Channels by Multiple Neurotransmitter Receptors in Oligodendroglia , 1994, The European journal of neuroscience.

[58]  Y. Horio,et al.  Immunolocalization of an inwardly rectifying K+ channel, KAB‐2 (Kir4.1), in the basolateral membrane of renal distal tubular epithelia , 1996, FEBS letters.

[59]  S Poopalasundaram,et al.  Glial heterogeneity in expression of the inwardly rectifying K+ channel, Kir4.1, in adult rat CNS , 2000, Glia.

[60]  Masaru Ishii,et al.  Differential expression and distribution of Kir5.1 and Kir4.1 inwardly rectifying K+ channels in retina. , 2003, American journal of physiology. Cell physiology.

[61]  Yoshihisa Kurachi,et al.  Differential Assembly of Inwardly Rectifying K+ Channel Subunits, Kir4.1 and Kir5.1, in Brain Astrocytes* , 2004, Journal of Biological Chemistry.

[62]  H. Lodish,et al.  GH3 Pituitary Tumor Cells Contain Heteromeric Type I and Type II Receptor Complexes for Transforming Growth Factor and Activin-A (*) , 1995, The Journal of Biological Chemistry.

[63]  N. Franks,et al.  The TREK K2P channels and their role in general anaesthesia and neuroprotection. , 2004, Trends in pharmacological sciences.

[64]  D. A. Brown G-proteins and potassium currents in neurons. , 1990, Annual review of physiology.

[65]  M. Frotscher,et al.  Heterogeneity in the Membrane Current Pattern of Identified Glial Cells in the Hippocampal Slice , 1992, The European journal of neuroscience.

[66]  H. Lester,et al.  Genetic Inactivation of an Inwardly Rectifying Potassium Channel (Kir4.1 Subunit) in Mice: Phenotypic Impact in Retina , 2000, The Journal of Neuroscience.

[67]  J. Deitmer,et al.  Developmental downregulation of ATP‐sensitive potassium conductance in astrocytes in situ , 2000, Glia.

[68]  E. Newman,et al.  Control of extracellular potassium levels by retinal glial cell K+ siphoning. , 1984, Science.

[69]  F. Ashcroft,et al.  Properties and functions of ATP-sensitive K-channels. , 1990, Cellular signalling.

[70]  C. Steinhäuser,et al.  Ion channels in glial cells , 2000, Brain Research Reviews.

[71]  H. Lester,et al.  Kir4.1 Potassium Channel Subunit Is Crucial for Oligodendrocyte Development and In Vivo Myelination , 2001, The Journal of Neuroscience.

[72]  H. Kimelberg,et al.  Freshly isolated astrocytes from rat hippocampus show two distinct current patterns and different [K(+)](o) uptake capabilities. , 2000, Journal of neurophysiology.

[73]  J. Grosche,et al.  Developmental regulation of voltage-gated K+ channel and GABAA receptor expression in Bergmann glial cells , 1994, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[74]  A. Konnerth,et al.  Cell-type specific expression of ATP-sensitive potassium channels in the rat hippocampus. , 1999, The Journal of physiology.

[75]  G. Wilkin,et al.  Kir4.1 expression by astrocytes and oligodendrocytes in CNS white matter: a developmental study in the rat optic nerve , 2004, Journal of anatomy.

[76]  G. Isenberg,et al.  The stretch-activated potassium channel TREK-1 in rat cardiac ventricular muscle. , 2006, Cardiovascular research.

[77]  J. Ruppersberg,et al.  Heterooligomeric assembly of inward-rectifier K+ channels from subunits of different subfamilies: Kir2.1 (IRK1) and Kir4.1 (BIR10) , 1996, Pflügers Archiv.

[78]  A. Reichenbach,et al.  Diversity of Kir channel subunit mRNA expressed by retinal glial cells of the guinea-pig , 2002, Neuroreport.

[79]  M. Lazdunski,et al.  The 2P-domain K+ channels: role in apoptosis and tumorigenesis , 2004, Pflügers Archiv.

[80]  F. Lesage Pharmacology of neuronal background potassium channels , 2003, Neuropharmacology.

[81]  S. W. Kuffler,et al.  Effect of nerve impulses on the membrane potential of glial cells in the central nervous system of amphibia. , 1966, Journal of neurophysiology.

[82]  A. Reichenbach,et al.  Functional expression of Kir 6.1/SUR1‐KATP channels in frog retinal Müller glial cells , 2002, Glia.

[83]  H. Sontheimer,et al.  β‐Adrenergic Modulation of Glial Inwardly Rectifying Potassium Channels , 1995, Journal of neurochemistry.

[84]  R. Luján,et al.  Molecular and Cellular Diversity of Neuronal G-Protein-Gated Potassium Channels , 2005, The Journal of Neuroscience.

[85]  Masaki Sekiguchi,et al.  Localization of pore-forming subunit of the ATP-sensitive K(+)-channel, Kir6.2, in rat brain neurons and glial cells. , 2002, Brain research. Molecular brain research.

[86]  E. Newman,et al.  Potassium buffering in the central nervous system , 2004, Neuroscience.

[87]  Donghee Kim,et al.  Functional expression of TREK-2 K+ channel in cultured rat brain astrocytes , 2002, Brain Research.