Alternating hemiplegia of childhood (AHC) is a rare syndrome with repeated hemiplegic episodes, paroxysmal events and global neurological impairment. Recently, heterozygous de novo ATP1A3 missense mutations have been identified in AHC patients, but the underlying pathogenesis mechanism remains unknown. Mutation analysis of ATP1A3 in 9 unrelated AHC cases revealed mostly D801N or E815K variants. As platelets represent a good cellular model to study defects in neuropathologies, morphological and functional experiments were performed in these subjects. Platelets from the AHC patients presented with structural and functional abnormalities of granules positive for the lysosomal marker CD63. Similar structural granule abnormalities were detected in patients' fibroblasts.

Proteomic analysis of platelets and fibroblasts showed a total of 93 differentially expressed proteins in AHC mainly involved in metabolism. Interestingly, 7 of these proteins were detected in both cell types, including the lysosomal protein cathepsin. AHC fibroblasts revealed significantly increased levels of activated cathepsin B, which induces a stronger activation of apoptosis. Our study is the first to link ATP1A3 defects in AHC to a platelet and fibroblast lysosomal defect with evidence of increased apoptosis. Further studies are needed to define how this lysosomal defect is related to decreased ATPase activity.

Only recently, the genetic cause of AHC was identified as heterozygous ATP1A3 mutations, but the underlying pathophysiological mechanism still remains unknown. By performing functional, morphological and proteomic studies in AHC patients we found a structural and