Astrocyte-specific deletion of LRRC8A causes neurological dysfunction but not chronic white matter edema

Volume-regulated anion channels (VRACs) are central to cell volume homeostasis. They mediate swelling-induced efflux of chloride and organic osmolytes to drive regulatory volume decrease. In the brain, VRACs have been proposed to play a key role in astrocytic volume regulation. Genetic defects in astrocytic VRAC modulating proteins (MLC1, GlialCAM, Aquaporin-4, GPRC5B) cause the leukodystrophy Megalencephalic leukoencephalopathy with subcortical cysts (MLC), characterized by chronic white matter edema and myelin vacuolization. Disrupted VRAC activity in MLC-patient-derived lymphoblasts and primary astrocytes from MLC mice further supports a pathogenic link between defective VRAC activity and MLC. Here, we studied the physiological and pathological consequences of astrocyte-specific removal of the essential VRAC subunit LRRC8A. In contrast to established MLC mouse models, astrocyte specific Lrrc8a knockout mice had normal brain water content, no myelin vacuolization, and preserved expression of MLC-related proteins. At a late age they developed a mildly ataxic gait and displayed increased severity of kainate-induced seizures. Two-photon imaging in acute brain slices revealed that astrocytes lacking LRRC8A show normal volume recovery and chloride dynamics upon high potassium-induced cell swelling. Together, these findings demonstrate that astrocyte LRRC8A is not essential for volume regulation in situ and that its loss alone is insufficient to cause the chronic white matter edema typical of MLC. The mild neurological deficits indicate a physiological role for astrocyte LRRC8A, but MLC pathology likely arises from broader dysregulation of the astrocytic protein complex coordinating ion and water homeostasis.