Neuronal swelling depends on Na+ and Cl− influx but is independent of Ca2+ influx
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Neuronal swelling after Na+ and Cl− influx causes Ca2+-independent neuronal death
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Knockdown of the ion exchanger SLC26A11 attenuates neuronal swelling
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SLC26A11-dependent Cl− influx occurs via voltage-gated Cl− channel activity
Summary
Cytotoxic brain edema triggered by neuronal swelling is the chief cause of mortality following brain trauma and cerebral infarct. Using fluorescence lifetime imaging to analyze contributions of intracellular ionic changes in brain slices, we find that intense Na+ entry triggers a secondary increase in intracellular Cl− that is required for neuronal swelling and death. Pharmacological and siRNA-mediated knockdown screening identified the ion exchanger SLC26A11 unexpectedly acting as a voltage-gated Cl− channel that is activated upon neuronal depolarization to membrane potentials lower than −20 mV. Blockade of SLC26A11 activity attenuates both neuronal swelling and cell death. Therefore cytotoxic neuronal edema occurs when sufficient Na+ influx and depolarization is followed by Cl− entry via SLC26A11. The resultant NaCl accumulation causes subsequent neuronal swelling leading to neuronal death. These findings shed light on unique elements of volume control in excitable cells and lay the ground for the development of specific treatments for brain edema.
