PINK1 loss in astrocytes triggers inflammatory dysfunction and neuronal death

Genetic loss of the mitochondrial control enzyme PINK1 leads to Parkinson’s disease, characterized by dopaminergic neuron degeneration and neuroinflammation, yet its role in glia remains poorly understood. To address this gap, we investigated how the function of astrocytes and their ability to support neurons is influenced by PINK1 deficiency. For the first time, we demonstrate that human astrocytes exhibit robust PINK1 activity. Next, the first bulk transcriptomic study of human PINK1 mutant astrocytes was performed followed by biochemical validation at the protein level, uncovering homeostatic collapse. Co-culture experiments demonstrated that this astrocyte dysfunction drives neuronal damage through non-cell-autonomous mechanisms. Notably, pharmacological enhancement of autophagy successfully mitigated this inflammatory secretome, indicating that mitochondrial quality control deficits are reversible. These findings establish an unexpected role for PINK1 in glial biology, reveal that astrocytes are vulnerable to mitophagy deficits, and highlight a novel mechanistic link connecting mitochondrial dysfunction, neuroinflammation, and neurodegeneration.