Involvement of astrocytic two-pore domain K+ channels in ischemic pathology

Information

  • Research Project
  • 7987672
  • ApplicationId
    7987672
  • Core Project Number
    R01NS062784
  • Full Project Number
    1R01NS062784-01A1
  • Serial Number
    62784
  • FOA Number
    PA-07-070
  • Sub Project Id
  • Project Start Date
    7/1/2010 - 14 years ago
  • Project End Date
    5/31/2015 - 9 years ago
  • Program Officer Name
    SILBERBERG, SHAI D
  • Budget Start Date
    7/1/2010 - 14 years ago
  • Budget End Date
    5/31/2011 - 13 years ago
  • Fiscal Year
    2010
  • Support Year
    1
  • Suffix
    A1
  • Award Notice Date
    6/21/2010 - 14 years ago

Involvement of astrocytic two-pore domain K+ channels in ischemic pathology

DESCRIPTION (provided by applicant): Astrocytes are the most numerous cell types in the brain and are known to provide structural, metabolic and homeostatic support to the central nervous system (CNS). Although astrocytes can better survive than neurons in cerebral ischemia, the mechanisms accounting for such a different susceptibility among different brain cells are not clear. Predominant expression of a voltage-independent K+ channel conductance, or passive conductance, is a hallmark of mature astrocytes and essential for the homeostatic support of astrocytes to the CNS. Now we know that two members of the two-pore domain K+ channels (K2Ps) K+ channels, TWIK-1 and TREK-1, are among the long-sought for K+ channels accounting for astrocyte passive conductance. K2Ps can be dynamically modulated by a variety of physiochemical and pathological stimuli, including cerebral-ischemia-produced-neuronal-injury-factors (CIPNJFs), such as hypoxia, hypoglycemia, acidosis and pathological release of neurotransmitters. Pathological induction of K2P expression also contributes to the necrotic and apoptotic cell death and cell proliferation that are the two prominent pathological events occurring in the ischemic infarct and penumbra regions. To understand how the physiological expression of astrocyte K2Ps offers protection to astrocytes against early ischemic insults, and how the long-term ischemic conditions induce altered K2P expression in reactive astrocytes and its consequence on the post-stroke outcomes, we hypothesize that the activity of astrocytic K2Ps can be modulated by CIPNJFs in a manner protecting astrocytes against early ischemic insults, and the altered expression of K2P in reactive astrocytes contributes to the compromised homeostatic function in the peri- infarct penumbra region. Five specific aims are proposed to explore these completely unknown areas. 1) Modulation of astrocyte membrane potential and passive conductance by CIPNJFs. This will be done in rat hippocampal slices with gramicidin perforated patch recording to monitor K2Ps modulation without interfering with the CIPNJFs mediated intracellular energy failure and altered signal transduction;2) Modulation of electrophysiological response of astrocytes to CIPNJFs by neuroprotectant and TREK-1 channel modulator riluzole and sipatrigine;3) Identify specific K2P-CIPNJF interaction mechanisms by selective silencing of astrocytic K2Ps with siRNAs in organotypic hippocampal slice cultures;4) Identify K2P expression in rat hippocampal reactive astrocytes in slices prepared from the penumbra region after reversible middle carotid artery occlusion (rMCAO) by confocal immunocytochemistry. 5) Identify functional K2P in reactive astrocytes in rat focal ischemia penumbra region using electrophysiology in acutely prepared hippocampal slices from the rat rMCAO penumbra region. The proposed studies should provide novel insights into the physiological roles and pathological involvement of astrocytic K2P in cerebral ischemia and whether these predominant astrocytic K+ channels could be potential targets for stroke therapeutic strategy. PUBLIC HEALTH RELEVANCE: By testing a hypothesis that physiological expression of the two newly identified astrocyte two-pore domain K+ channels, TWIK-1 and TREK-1, offers early protection to astrocytes early on in a cerebral ischemia attack, and how the K2P expression alters in the reactive astrocytes and can underlie compromised homeostatic functions of astrocytes in stroke pathology, the proposed studies will provide novel insights into the roles of astrocyte K2Ps in cerebral ischemia. The results should also shed light on future stroke treatment options based on these newly appreciated and functionally significant astrocytic K+ channels.

IC Name
NATIONAL INSTITUTE OF NEUROLOGICAL DISORDERS AND STROKE
  • Activity
    R01
  • Administering IC
    NS
  • Application Type
    1
  • Direct Cost Amount
  • Indirect Cost Amount
  • Total Cost
    384125
  • Sub Project Total Cost
  • ARRA Funded
    False
  • CFDA Code
    853
  • Ed Inst. Type
  • Funding ICs
    NINDS:384125\
  • Funding Mechanism
    Research Projects
  • Study Section
    CMBG
  • Study Section Name
    Cellular and Molecular Biology of Glia Study Section
  • Organization Name
    ORDWAY RESEARCH INSTITUTE, INC.
  • Organization Department
  • Organization DUNS
    124361945
  • Organization City
    ALBANY
  • Organization State
    NY
  • Organization Country
    UNITED STATES
  • Organization Zip Code
    122083423
  • Organization District
    UNITED STATES