SYSTEMIC FRATAXIN DEFICIENCY CAUSES TISSUE-DEPENDENT IRON HOMEOSTASIS ALTERATIONS: IMPLICATIONS FOR FRIEDREICH ATAXIA

Friedreich Ataxia (FA) is a cardio-neurodegenerative disease caused by mutations in the frataxin gene, which result in low frataxin expression. It is well-established that frataxin deficiency affects iron homeostasis, but the tissue-specificity of these alterations is poorly understood. In this study, we have analyzed iron homeostasis alterations in the FXNI151F mouse model, which presents systemic frataxin deficiency and neurological defects resembling FA patients. Iron overload is observed in the brain from 21-week old FXNI151F mice, both males and females, and it does not further accumulate in older animals. It is also observed in livers from 39-week old mutant females, but not in males. Iron signaling is altered in all tissues: in brain and liver Iron Regulatory Protein 1 (IRP1) content is decreased, while in heart increased IRP2 and decreased specific aconitase 2 activity are observed. Remarkably, these cardiac alterations are partially restored in 39- week-old animals, suggesting that the heart is activating an iron-deficiency response to compensate for deficient iron-sulfur biogenesis. Our findings demonstrate that frataxin deficiency affects iron homeostasis in a time dependent and tissue-specific manner, and that the pathological mechanisms in FA comprise both iron accumulation and limited iron availability. Understanding this specificity is crucial for the design of iron-related therapeutic interventions aiming to improve FA symptomatology.