Ferroptosis promotes aortic stenosis through 5-lipoxygenase
European Heart Journal, 2026
Qin Z., Haftbaradaran Esfahani P., Pawelzik S., Shu S., Bosman M., Goovaerts B., De Wilde L., Yang Y., Bergström G., Guns P., Franco-Cereceda A., Bäck M.
| Disease area | Application area | Sample type | Products |
|---|---|---|---|
CVD | Pathophysiology | Plasma |  Olink Target 96  Olink Explore 3072/384 |
Abstract
Background and Aims
Calcific aortic valve disease (CAVD) culminates in severe aortic stenosis, currently lacking pharmacological treatment. Intra-leaflet haemorrhage-induced iron overload promotes valvular ferroptosis. This study identifies a druggable ferroptosis pathway and validates its translational relevance across large-scale population cohorts.
Methods
Bulk- and single-cell transcriptomics, whole-mount histology, immunohistochemistry, and primary human valvular interstitial cell (VIC) models of 212 aortic valves from surgical patients were integrated for mechanistic insights. In vivo, valvular ferroptosis and thickness were assessed in a doxorubicin-induced ferroptosis mice model, and a wire injury model with ferroptosis inhibition was utilized to evaluate remodelling and haemodynamic obstruction. A total of 4874 participants of the Swedish CArdioPulmonary bioImage Study (SCAPIS) underwent cardiac computed tomography for aortic valve calcification determination and 273 550 individuals from the UK Biobank were followed for aortic stenosis incidence.
Results
Intra-leaflet haemorrhage was prevalent in calcified aortic valves and correlated positively with calcification and circulating ferroptosis biomarker. Bulk transcriptomics and single-cell RNA sequencing identified lipid peroxidation as the dominating valvular ferroptosis pathway centred on arachidonate 5-lipoxygenase (ALOX5). Inducing ferroptosis in VIC triggered lipid peroxidation and calcification while reducing viability, which were reversed by targeting the ALOX5–ACSL4 axis. In vivo, doxorubicin-induced valvular ferroptosis exacerbated valvular thickening in apoE−/− mice through ALOX5–ACSL4 upregulation. ALOX5 inhibition reduced valve thickness and haemodynamically improved valve function in the wire injury model. Arachidonic acid levels independently predicted aortic valve calcification and incident aortic stenosis in SCAPIS and UK Biobank, respectively, and positively correlated with circulating ferroptotic marker.
Conclusions
These findings establish the ALOX5–ACSL4 axis as a critical mediator of ferroptosis in CAVD and promising repurposing target for clinical intervention.