Altered Expression of Mitoferrin and Frataxin, Larger Labile Iron Pool and Greater Mitochondrial DNA Damage in the Skeletal Muscle of Older Adults.
Anna PiccaSunil K SainiRobert T MankowskiGeorge D KamenovStephen D AntonTodd M ManiniThomas W BufordStephanie E WohlgemuthRui XiaoRiccardo CalvaniHelio Jose Coelho-JuniorFrancesco LandiRoberto BernabeiDavid A HoodEmanuele MarzettiChristiaan LeeuwenburghPublished in: Cells (2020)
Mitochondrial dysfunction and iron (Fe) dyshomeostasis are invoked among the mechanisms contributing to muscle aging, possibly via a detrimental mitochondrial-iron feed-forward loop. We quantified the labile Fe pool, Fe isotopes, and the expression of mitochondrial Fe handling proteins in muscle biopsies obtained from young and older adults. The expression of key proteins of mitochondrial quality control (MQC) and the abundance of the mitochondrial DNA common deletion (mtDNA4977) were also assessed. An inverse association was found between total Fe and the heavier Fe isotope (56Fe), indicating an increase in labile Fe abundance in cells with greater Fe content. The highest levels of labile Fe were detected in old participants with a Short Physical Performance Battery (SPPB) score ≤ 7 (low-functioning, LF). Protein levels of mitoferrin and frataxin were, respectively, higher and lower in the LF group relative to young participants and older adults with SPPB scores ≥ 11 (high-functioning, HF). The mtDNA4977 relative abundance was greater in old than in young participants, regardless of SPPB category. Higher protein levels of Pink1 were detected in LF participants compared with young and HF groups. Finally, the ratio between lipidated and non-lipidated microtubule-associated protein 1A/1B-light chain 3 (i.e., LC3B II/I), as well as p62 protein expression was lower in old participants regardless of SPPB scores. Our findings indicate that cellular and mitochondrial Fe homeostasis is perturbed in the aged muscle (especially in LF older adults), as reflected by altered levels of mitoferrin and frataxin, which, together with MQC derangements, might contribute to loss of mtDNA stability.
Keyphrases
- mitochondrial dna
- skeletal muscle
- oxidative stress
- metal organic framework
- copy number
- physical activity
- dna damage
- aqueous solution
- quality control
- type diabetes
- visible light
- mental health
- metabolic syndrome
- induced apoptosis
- gene expression
- heart failure
- atrial fibrillation
- insulin resistance
- small molecule
- wastewater treatment
- microbial community
- cell cycle arrest
- ultrasound guided
- acute heart failure