Neuritic plaques are pathognomonic and terminal lesions of Alzheimer's Disease (AD). They embody AD pathogenesis because they harbor in one space critical pathologic features of the disease: amyloid deposits, neurofibrillary degeneration (NFD), neuroinflammation, iron accumulation. Neuritic plaques are thought to arise from the conversion of diffuse extracellular deposits of amyloid beta protein (Aβ), and it is believed that during conversion amyloid toxicity creates the dystrophic neurites of neuritic plaques, as well as neurofibrillary tangles (NFTs). However, recent evidence from human post-mortem studies suggests a much different mechanism of neuritic plaque formation where the first step in their creation is neuronal degeneration driven by iron overload and ferroptosis. Similarly, NFTs represent corpses of iron-laden neurons that develop independent of Aβ deposits. In this review, we will focus on the role of free redox-active iron in the development of typical AD pathology, as determined largely by evidence obtained in human temporal lobe during early, preclinical stages of AD. The findings have allowed construction of a scheme of AD pathogenesis where brain iron is center stage and is involved in every step of the sequence of events that produce characteristic AD pathology. We will discuss how the study of preclinical AD has produced a fresh and revised assessment of AD pathogenesis that may be important for reconsidering current therapeutic efforts and guiding future ones. Significance Statement This review offers a novel perspective on AD pathogenesis where elevated brain iron plays a central role and is involved throughout the development of lesions. We review arguments against the amyloid cascade theory and explain how recent findings in humans during early preclinical disease support iron-mediated cell death and endogenous iron containment mechanisms as critical components of neuritic plaque formation and the ensuing dementia.
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