The Iron Lung: Ferroptosis and Iron Regulation in Aging and Lung Diseases
Maunick Lefin Koloko Ngassie, Yamillie Ortiz, Preetham Ravi, Daniel A. Pfeffer-Kleemann, Niyati Borkar, Christina Pabelick, Y.S. PrakashIron is an important metal element regulating biological processes such as gene expression, electron transport, cell proliferation, differentiation and division, and cellular respiration. Regulation of iron levels is therefore critical, with excess iron accumulation leading to iron-dependent lipid peroxidation and cell death (ferroptosis). Factors such as aging and environmental exposures (e.g. high/low oxygen, particulate iron) can disrupt iron homeostasis. Iron-dependent processes influence downstream pathways such as inflammation, mitochondrial energetics, and remodeling (proliferation, fibrosis): pathways involved in lung diseases particularly at the extremes of age: from hyperoxic lung injury in neonates to chronic diseases such as asthma, chronic obstructive pulmonary disease (COPD), and pulmonary fibrosis (PF) that increase with age. While these diseases involve structural and functional changes in bronchial vs. alveolar compartments, including airway hyperreactivity, altered mucus production, cell proliferation and migration, increased extracellular matrix (ECM) remodeling, senescence and metabolic dysregulation, the casual or consequential links between iron dysregulation and disease pathology, particularly with aging, are still being investigated. The aim of this topical review is to (i) highlight current knowledge regarding iron regulation in normal lung vs. lung diseases, (ii) identify known roles of iron in lung homeostasis, and the contribution of iron dysregulation in lung diseases with aging, and (iii) explore the potential benefit of targeting iron regulation and/or ferroptosis in lung diseases.