VOLTAGE-DEPENDENT AND CA-2+-ACTIVATED ION CHANNELS IN HUMAN NEUTROPHILS

被引:79
|
作者
KRAUSE, KH
WELSH, MJ
机构
[1] UNIV IOWA,COLL MED,DEPT INTERNAL MED,DIV INFECT DIS,HOWARD HUGHES MED INST,500 EMRB,IOWA CITY,IA 52242
[2] UNIV IOWA,COLL MED,DEPT INTERNAL MED,DIV PULM DIS,HOWARD HUGHES MED INST,IOWA CITY,IA 52242
来源
JOURNAL OF CLINICAL INVESTIGATION | 1990年 / 85卷 / 02期
关键词
chloride channels; neutrophils; potassium channels;
D O I
10.1172/JCI114464
中图分类号
R-3 [医学研究方法]; R3 [基础医学];
学科分类号
1001 ;
摘要
To investigate the regulation of membrane voltage and transmembrane ion fluxes in human neutrophils, we studied plasma membrane currents using the whole-cell patch-clamp method. We observed three distinct ion channel currents: (a) a voltage-dependent K+ current, (b) a Ca2+-activated K+ current, and (c) a Ca2+-activated Cl- current. The voltage-dependent K+ current was found in cells at rest. Its conductive properties suggested an inwardly rectifying channel. The channel was activated at membrane potentials more positive than -60 mV, suggesting that it may determine the resting membrane potential of neutrophils. Activation of neutrophils by the Ca2+ ionophore ionomycin led to an increase in whole-cell K+ and Cl- currents. The Ca2+-activated K+ channel differed from the voltage-dependent K+ channel because it was insensitive to voltage, because it rectified outwardly, and because the voltage-sensitive K+ channel was Ca2+-independent. The Ca2+-activated Cl- channel showed outward rectification and no apparent voltage dependency. The Ca2+-activated K+ and Cl-channels may play a role in cell volume homeostasis and/or cellular activation.
引用
收藏
页码:491 / 498
页数:8
相关论文
共 50 条
  • [21] THE EFFECT OF TGF-β1 ON ION TRANSPORT: ROLE OF THE LARGE CONDUCTANCE, CA2+ ACTIVATED AND VOLTAGE-DEPENDENT K+ CHANNELS (BK CHANNELS)
    Manzanares, D.
    Valencia-Gattas, M.
    Schmid, N.
    Salathe, M.
    PEDIATRIC PULMONOLOGY, 2012, 47 : 251 - 251
  • [22] CA-2+-ACTIVATED K+ CONDUCTANCE OF THE HUMAN RED-CELL MEMBRANE - VOLTAGE-DEPENDENT NA+ BLOCK OF OUTWARD-GOING CURRENTS
    STAMPE, P
    VESTERGAARDBOGIND, B
    JOURNAL OF MEMBRANE BIOLOGY, 1989, 112 (01): : 9 - 14
  • [23] Contribution of Voltage-dependent Ion Channels to Subthreshold Resonance
    Kitajima, Tatsuo
    Feng, Zhonggang
    2013 9TH ASIAN CONTROL CONFERENCE (ASCC), 2013,
  • [24] VOLTAGE-DEPENDENT ION CHANNELS IN GLIAL-CELLS
    SONTHEIMER, H
    GLIA, 1994, 11 (02) : 156 - 172
  • [25] VOLTAGE-DEPENDENT ION CHANNELS IN LYMPHOCYTES-T
    DECOURSEY, TE
    CHANDY, KG
    GUPTA, S
    CAHALAN, MD
    JOURNAL OF NEUROIMMUNOLOGY, 1985, 10 (01) : 71 - 95
  • [26] The role of lipids in the operation of voltage-dependent ion channels
    May, L
    BIOPHYSICAL JOURNAL, 2004, 86 (01) : 539A - 539A
  • [27] MODULATIONS OF VOLTAGE-DEPENDENT ION CHANNELS BY EXTRACELLULAR SIGNALS
    ROSENTHAL, W
    SCHULTZ, G
    TRENDS IN PHARMACOLOGICAL SCIENCES, 1987, 8 (09) : 351 - 354
  • [28] A NOVEL MODEL FOR VOLTAGE-DEPENDENT BLOCK OF ION CHANNELS
    RUPPERSBERG, JP
    VONKITZING, E
    GUNTHER, W
    SEEBURG, PH
    KUNER, T
    SAKMANN, B
    BURNASHEV, N
    SCHOEPFER, R
    BIOPHYSICAL JOURNAL, 1994, 66 (02) : A350 - A350
  • [29] Transmembrane auxiliary subunits of voltage-dependent ion channels
    Gurnett, CA
    Campbell, KP
    JOURNAL OF BIOLOGICAL CHEMISTRY, 1996, 271 (45) : 27975 - 27978
  • [30] THE ROLE OF CA-2+ AND CA-2+-ACTIVATED PHOSPHOLIPID-DEPENDENT PROTEIN-KINASE IN DE-GRANULATION OF HUMAN-NEUTROPHILS
    KANG, D
    TSUDA, H
    TAKESHIGE, K
    SHIBATA, Y
    MINAKAMI, S
    JOURNAL OF BIOCHEMISTRY, 1985, 98 (06): : 1699 - 1706
12345