LC3 binds externalized cardiolipin on injured mitochondria to signal mitophagy in neurons

Mitophagy, or the selective clearance of mitochondria by autophagy, plays a key role in mitochondrial quality control. Due to their postmitotic nature and metabolic dependence on mitochondria, either insufficient or unchecked mitophagy is detrimental to neurons. To better understand signals that regulate this process, we treated primary rat cortical neurons with the electron transport chain complex I inhibitor rotenone to elicit mitophagy. The lipidomic profiles of mitochondria from control or injured neurons were analyzed by mass spectrometry, revealing a significant redistribution of cardiolipin (CL) from the inner mitochondrial membrane to the outer mitochondrial surface. Direct liposome-binding studies, computational modeling, and site-directed mutagenesis indicate that microtubule-associated protein 1 light chain 3 (MAP1LC3/LC3), a defining protein of autophagic membranes, binds to CL. Preventing this interaction inhibits rotenone-induced mitochondrial delivery to autophagosomes and lysosomes and attenuates mitochondrial loss as assessed by western blot. The CL-LC3 interaction is also important for mitophagy induced by other stimuli including 6-hydroxydopamine, another chemical model of Parkinson disease. Given that a conserved LC3 phosphorylation site is adjacent to key residues involved in CL binding, signaling pathways could potentially modulate this interaction to fine-tune the mitochondrial recycling response.     

How neurons die in Alzheimer's disease: Implications for neuroinflammation

Despite the long-standing observation of vast neuronal loss in Alzheimer's disease (AD) our understanding of how and when neurons are eliminated is incomplete. While previous investigation has focused on apoptosis, several novel forms of cell death (i.e. necroptosis, parthanatos, ferroptosis, cuproptosis) have emerged that require further investigation. This review aims to collect evidence for different modes of neuronal cell death in AD and to also discuss how these different forms of cell death may impact the neuroinflammatory environment that prevails in the AD brain. Improved understanding of how neurons die may help to delineate disease pathogenesis, provide insights toward treatment, and aid in the development of improved animal models of AD.