Role of Ca2+-activated K+ channels in human erythrocyte apoptosis.

Exposure of erythrocytes to the Ca2+ ionophore ionomycin has recently been shown to induce cell shrinkage, cell membrane blebbing, and breakdown of phosphatidylserine asymmetry, all features typical of apoptosis of nucleated cells. Although breakdown of phosphatidylserine asymmetry is thought to result from activation of a Ca2+-sensitive scramblase, the mechanism and role of cell shrinkage have not been explored. The present study was performed to test whether ionomycin-induced activation of Ca2+-sensitive Gardos K+ channels and subsequent cell shrinkage participate in ionomycin-induced breakdown of phosphatidylserine asymmetry of human erythrocytes. According to on-cell patch-clamp experiments, ionomycin (1 microM) induces activation of inwardly rectifying K+-selective channels in the erythrocyte membrane. Fluorescence-activated cell sorter analysis reveals that ionomycin leads to a significant decrease of forward scatter, reflecting cell volume, an effect blunted by an increase of extracellular K+ concentration to 25 mM and exposure to the Gardos K+ channel blockers charybdotoxin (230 nM) and clotrimazole (5 microM). As reflected by annexin binding, breakdown of phosphatidylserine asymmetry is triggered by ionomycin, an effect again blunted, but not abolished, by an increase of extracellular K+ concentration and exposure to charybdotoxin (230 nM) and clotrimazole (5 microM). Similar to ionomycin, glucose depletion leads (within 55 h) to annexin binding of erythrocytes, an effect again partially reversed by an increase of extracellular K+ concentration and exposure to charybdotoxin. K-562 human erythroleukemia cells similarly respond to ionomycin with cell shrinkage and annexin binding, effects blunted by antisense, but not sense, oligonucleotides against the small-conductance Ca2+-activated K+ channel isoform hSK4 (KCNN4). The experiments disclose a novel functional role of Ca2+-sensitive K+ channels in erythrocytes, i.e., their participation in regulation of erythrocyte apoptosis.

[1]  O. Potapova,et al.  The hSK4 (KCNN4) isoform is the Ca2+-activated K+ channel (Gardos channel) in human red blood cells , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[2]  F. Lang,et al.  Cation channels trigger apoptotic death of erythrocytes , 2003, Cell Death and Differentiation.

[3]  L. Kanz,et al.  Enhanced Erythrocyte Apoptosis in Sickle Cell Anemia, Thalassemia and Glucose-6-Phosphate Dehydrogenase Deficiency , 2002, Cellular Physiology and Biochemistry.

[4]  I. Sherman,et al.  Cytoadherence of Malaria-Infected Red Blood Cells Involves Exposure of Phosphatidylserine , 2002, Cellular Physiology and Biochemistry.

[5]  D. Dekkers,et al.  Comparison between Ca2+-induced scrambling of various fluorescently labelled lipid analogues in red blood cells. , 2002, The Biochemical journal.

[6]  F. Lang,et al.  Oxidation induces a Cl−‐dependent cation conductance in human red blood cells , 2002, The Journal of physiology.

[7]  H. Rammensee,et al.  Stimulation of TNFα expression by hyperosmotic stress , 2002, Pflügers Archiv.

[8]  S. Orlov,et al.  Swelling-Induced K+ Fluxes in Vascular Smooth Muscle Cells are Mediated by Charybdotoxin-Sensitive K+ Channels , 2001, Cellular Physiology and Biochemistry.

[9]  G. Kroemer,et al.  Erythrocytes: Death of a mummy , 2001, Cell Death and Differentiation.

[10]  I. H. Engels,et al.  Human mature red blood cells express caspase-3 and caspase-8, but are devoid of mitochondrial regulators of apoptosis , 2001, Cell Death and Differentiation.

[11]  C. Slomianny,et al.  Programmed cell death in mature erythrocytes: a model for investigating death effector pathways operating in the absence of mitochondria , 2001, Cell Death and Differentiation.

[12]  D. Strøbæk,et al.  The Ca2+-activated K+ channel of intermediate conductance: a molecular target for novel treatments? , 2001, Current drug targets.

[13]  V. Fadok,et al.  The phosphatidylserine receptor: a crucial molecular switch? , 2001, Nature Reviews Molecular Cell Biology.

[14]  J. Cidlowski,et al.  Identification of Potassium-Dependent and -Independent Components of the Apoptotic Machinery in Mouse Ovarian Germ Cells and Granulosa Cells1 , 2000, Biology of reproduction.

[15]  F. Lang,et al.  Physiology of apoptosis. , 2000, American journal of physiology. Renal physiology.

[16]  J. Pfeilschifter,et al.  New insights into the mechanism for clearance of apoptotic cells. , 2000, BioEssays : news and reviews in molecular, cellular and developmental biology.

[17]  C. Bortner,et al.  Protein Kinase C (PKC) Inhibits Fas Receptor-induced Apoptosis through Modulation of the Loss of K+ and Cell Shrinkage , 2000, The Journal of Biological Chemistry.

[18]  V. Fadok,et al.  A receptor for phosphatidylserine-specific clearance of apoptotic cells , 2000, Nature.

[19]  C. Bortner,et al.  A necessary role for reduced intracellular potassium during the DNA degradation phase of apoptosis , 1999, Steroids.

[20]  A. Schwab,et al.  Molecular and functional characterization of the small Ca2+-regulated K+ channel (rSK4) of colonic crypts , 1999, Pflügers Archiv.

[21]  C. Bortner,et al.  Caspase Independent/Dependent Regulation of K+, Cell Shrinkage, and Mitochondrial Membrane Potential during Lymphocyte Apoptosis* , 1999, The Journal of Biological Chemistry.

[22]  J. Cidlowski,et al.  Potassium is a critical regulator of apoptotic enzymes in vitro and in vivo. , 1999, Advances in enzyme regulation.

[23]  E. Kable,et al.  Ca2+ sensitivity of phospholipid scrambling in human red cell ghosts. , 1999, Cell calcium.

[24]  J C Reed,et al.  Mitochondria and apoptosis. , 1998, Science.

[25]  F. Boas,et al.  Phosphatidylserine exposure and red cell viability in red cell aging and in hemolytic anemia. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[26]  C. Bortner,et al.  A Primary Role for K+ and Na+ Efflux in the Activation of Apoptosis* , 1997, The Journal of Biological Chemistry.

[27]  C. Bortner,et al.  Intracellular K+ Suppresses the Activation of Apoptosis in Lymphocytes* , 1997, The Journal of Biological Chemistry.

[28]  Michael Karin,et al.  Ultraviolet Light and Osmotic Stress: Activation of the JNK Cascade Through Multiple Growth Factor and Cytokine Receptors , 1996, Science.

[29]  P. Low,et al.  Prostaglandin E2 Stimulates a Ca2+-dependent K+ Channel in Human Erythrocytes and Alters Cell Volume and Filterability* , 1996, The Journal of Biological Chemistry.

[30]  S. Alper,et al.  Inhibition of Ca(2+)-dependent K+ transport and cell dehydration in sickle erythrocytes by clotrimazole and other imidazole derivatives. , 1993, The Journal of clinical investigation.

[31]  C. Joiner,et al.  Cation transport and volume regulation in sickle red blood cells. , 1993, The American journal of physiology.

[32]  V. Lew,et al.  Osmotic effects of protein polymerization: Analysis of volume changes in sickle cell anemia red cells following deoxy-hemoglobin S polymerization , 1991, The Journal of Membrane Biology.

[33]  H C Hemker,et al.  Binding of vascular anticoagulant alpha (VAC alpha) to planar phospholipid bilayers. , 1990, The Journal of biological chemistry.

[34]  A. Halestrap Red cell membrane transport in health and disease , 2003 .

[35]  F. Lang,et al.  Chloride conductance and volume-regulatory nonselective cation conductance in human red blood cell ghosts , 2000, Pflügers Archiv.

[36]  D. Häussinger,et al.  Functional significance of cell volume regulatory mechanisms. , 1998, Physiological reviews.

[37]  M. Palascak,et al.  Dehydration of transferrin receptor-positive sickle reticulocytes during continuous or cyclic deoxygenation: role of KCl cotransport and extracellular calcium. , 1996, Blood.

[38]  V. Lew,et al.  Activation of calcium-dependent potassium channels in deoxygenated sickled red cells. , 1987, Progress in clinical and biological research.

[39]  K. Janáček,et al.  Cell Membrane Transport , 1975, Springer US.