Targeting ATP11B-YAP axis repairs mitochondrial function and inhibits neuronal ferroptosis to attenuate age-related cognitive decline
Summary
Brain aging is accompanied by cognitive decline and an increased risk of neurodegenerative disease, with neuronal aging being a key causative factor. Studies have shown that the earliest damage to blood-brain barrier (BBB) integrity occurs in the hippocampus, leading to the abnormal accumulation of Fe²⁺;however, the mechanisms underlying subsequent neuronal aging remain unclear. Using single-cell and spatial transcriptomic analyses, this study focuses on the phospholipid flippase ATP11B. W
Content
# Targeting ATP11B-YAP axis repairs mitochondrial function and inhibits neuronal ferroptosis to attenuate age-related cognitive decline
*Published: 2026 Apr 20*
Brain aging is accompanied by cognitive decline and an increased risk of
neurodegenerative disease, with neuronal aging being a key causative factor.
Studies have shown that the earliest damage to blood-brain barrier (BBB)
integrity occurs in the hippocampus, leading to the abnormal accumulation of
Fe²⁺;however, the mechanisms underlying subsequent neuronal aging remain
unclear. Using single-cell and spatial transcriptomic analyses, this study
focuses on the phospholipid flippase ATP11B. We found that ATP11B deficiency
facilitates the transport of Fe²⁺ from ependymal cells to hippocampal neurons,
activating the Hippo signaling pathway and inducing mitochondrial respiratory
dysfunction and dynamic imbalance, which results in neuronal ferroptosis and
exacerbation of aging phenotypes. Mechanistically, ATP11B blocks mitochondrial
respiratory function by regulating the chromatin accessibility of KLF4 to
mitochondrial respiratory chain complex genes. Simultaneously, it impairs the
mitochondrial quality control system, resulting in elevated levels of reactive
oxygen species(ROS) and enhanced neuronal aging. The mitochondria-associated
metabolite, lactate, facilitates histone lactylation of ferroptosis and the key
aging-related genes Acsl4, Trp53 and Cdkn1a via the TEAD-YAP complex, thereby
promoting transcription. This research uncovers the molecular mechanism through
which ATP11B mediates neuronal aging: regulating the iron
transport-mitochondrial plasticity axis. This provides a novel avenue for
targeting iron homeostasis to intervene in cognitive decline and
neurodegenerative disease.
DOI: 10.1038/s41392-026-02652-1