Mitochondrial dysfunction is a prominent feature of Alzheimer's disease (AD) neurons. In this study, we explored the involvement of an abnormal mitochondrial dynamics by investigating the changes in the expression of mitochondrial fission and fusion proteins in AD brain and the potential cause and consequence of these changes in neuronal cells. We found that mitochondria were redistributed away from axons in the pyramidal neurons of AD brain. Immunoblot analysis revealed that levels of DLP1 (also referred to as Drp1), OPA1, Mfn1, and Mfn2 were significantly reduced whereas levels of Fis1 were significantly increased in AD. Despite their differential effects on mitochondrial morphology, manipulations of these mitochondrial fission and fusion proteins in neuronal cells to mimic their expressional changes in AD caused a similar abnormal mitochondrial distribution pattern, such that mitochondrial density was reduced in the cell periphery of M17 cells or neuronal process of primary neurons and correlated with reduced spine density in the neurite. Interestingly, oligomeric amyloid--derived diffusible ligands (ADDLs) caused mitochondrial fragmentation and reduced mitochondrial density in neuronal processes. More importantly, ADDL-induced synaptic change (i.e., loss of dendritic spine and postsynaptic density protein 95 puncta) correlated with abnormal mitochondrial distribution. DLP1 overexpression, likely through repopulation of neuronal processes with mitochondria, prevented ADDL-induced synaptic loss, suggesting that abnormal mitochondrial dynamics plays an important role in ADDL-induced synaptic abnormalities. Based on these findings, we suggest that an altered balance in mitochondrial fission and fusion is likely an important mechanism leading to mitochondrial and neuronal dysfunction in AD brain.
Mitochondrial dysfunction is a prominent feature of Alzheimer disease but the underlying mechanism is unclear. In this study, we investigated the effect of amyloid precursor protein (APP) and amyloid  on mitochondrial dynamics in neurons. Confocal and electron microscopic analysis demonstrated that Ϸ40% M17 cells overexpressing WT APP (APPwt M17 cells) and more than 80% M17 cells overexpressing APPswe mutant (APPswe M17 cells) displayed alterations in mitochondrial morphology and distribution. Specifically, mitochondria exhibited a fragmented structure and an abnormal distribution accumulating around the perinuclear area. These mitochondrial changes were abolished by treatment with -site APP-cleaving enzyme inhibitor IV. From a functional perspective, APP overexpression affected mitochondria at multiple levels, including elevating reactive oxygen species levels, decreasing mitochondrial membrane potential, and reducing ATP production, and also caused neuronal dysfunction such as differentiation deficiency upon retinoic acid treatment. At the molecular level, levels of dynamin-like protein 1 and OPA1 were significantly decreased whereas levels of Fis1 were significantly increased in APPwt and APPswe M17 cells. Notably, overexpression of dynamin-like protein 1 in these cells rescued the abnormal mitochondrial distribution and differentiation deficiency, but failed to rescue mitochondrial fragmentation and functional parameters, whereas overexpression of OPA1 rescued mitochondrial fragmentation and functional parameters, but failed to restore normal mitochondrial distribution. Overexpression of APP or A-derived diffusible ligand treatment also led to mitochondrial fragmentation and reduced mitochondrial coverage in neuronal processes in differentiated primary hippocampal neurons. Based on these data, we concluded that APP, through amyloid  production, causes an imbalance of mitochondrial fission/fusion that results in mitochondrial fragmentation and abnormal distribution, which contributes to mitochondrial and neuronal dysfunction.amyloid precursor protein ͉ DLP1 ͉ mitochondrial fragmentation ͉ OPA1 ͉ perinuclear accumulation
Mitochondrial dysfunction is a prominent feature of Alzheimer's disease (AD) brain. Our prior studies demonstrated reduced mitochondrial number in susceptible hippocampal neurons in the brain from AD patients and in M17 cells overexpressing FAD-causing APP mutant (APPswe). In the current study, we investigated whether alterations in mitochondrial biogenesis contribute to mitochondrial abnormalities in AD. Mitochondrial biogenesis is regulated by the PGC-1α-NRF-TFAM pathway. Expression levels of PGC-1α, NRF 1, NRF 2, and TFAM were significantly decreased in both AD hippocampal tissues and APPswe M17 cells, suggesting a reduced mitochondrial biogenesis. Indeed, APPswe M17 cells demonstrated decreased mitochondrial DNA/nuclear DNA ratio, correlated with reduced ATP content, and decreased cytochrome C oxidase activity. Importantly, overexpression of PGC-1α could completely rescue while knockdown of PGC-1α could exacerbate impaired mitochondrial biogenesis and mitochondrial deficits in APPswe M17 cells, suggesting reduced mitochondrial biogenesis is likely involved in APPswe-induced mitochondrial deficits. We further demonstrated that reduced expression of p-CREB and PGC-1α in APPswe M17 cells could be rescued by cAMP in a dose-dependent manner, which could be inhibited by PKA inhibitor H89, suggesting that the PKA/CREB pathway plays a critical role in the regulation of PGC-1α expression in APPswe M17 cells. Overall, our study demonstrated that impaired mitochondrial biogenesis likely contributes to mitochondrial dysfunction in AD.
Mitochondrial function relies heavily on its morphology and distribution, alterations of which have been increasingly implicated in neurodegenerative diseases, such as Alzheimer's disease (AD). In this study, we found abnormal mitochondrial distribution characterized by elongated mitochondria that accumulated in perinuclear areas in 19.3% of sporadic AD (sAD) fibroblasts, which was in marked contrast to their normally even cytoplasmic distribution in the majority of human fibroblasts from normal subjects (>95%). Interestingly, levels of dynamin-like protein 1 (DLP1), a regulator of mitochondrial fission and distribution, were decreased significantly in sAD fibroblasts. To explore the potential role of DLP1 in mediating mitochondrial abnormalities in sAD fibroblasts, both the overexpression of a dominant negative DLP1 mutant and the reduced expression of DLP1 by miR RNAi in human fibroblasts from normal subjects significantly increased mitochondrial abnormalities. Moreover, overexpression of wild-type DLP1 in sAD fibroblasts rescued these mitochondrial abnormalities. Based on these data, we conclude that DLP1 reduction causes mitochondrial abnormalities in sAD fibroblasts. We further demonstrate that elevated oxidative stress and increased amyloid  production are likely the potential pathogenic factors that cause DLP1 reduction and abnormal mitochondrial distribution in AD cells. Alzheimer's disease (AD) is the leading cause of dementia in the elderly, characterized by neurofibrillary tangles, senile plaques, and progressive loss of neuronal cells in selective brain regions.1 Whereas there are a myriad of striking alterations in the diseased brain, the pathogenesis of the disease is still currently poorly understood. Among these changes, oxidative stress is one of the earliest and may play a critical role in the disease. Mitochondria can be both targets of oxidative damage and sources of reactive oxygen species (ROS), and mitochondrial damage occurs during the aging process, 3 which is associated with memory loss. 4 In fact, damaged mitochondria are less efficient producers of ATP and more efficient producers of ROS. In AD, metabolic abnormalities 5 as well as damage to both the components and the structure of mitochondria are evident. 6 -8 Interestingly, quantitative morphometric studies not only confirm that neurons in AD demonstrate a higher percentage of damaged mitochondria but also reveal enlarged mitochondrial size with decreased mitochondria number in AD neurons. 2,9 The latter finding suggests that the normally strict regulation of mitochondria morphology is impaired, an assertion supported by work showing that AD cybrid cells also contain a significantly increased percentage of enlarged mitochondria. 10Mitochondrial morphology is dynamic and controlled by continual and balanced fission and fusion events that are regulated by a machinery involving large dynaminrelated GTPases that exert opposing effects, eg, dynamin-like protein 1 (DLP1, also referred to as Drp1, DVLP, dymple, HdynIV and DNM1P) [11][12...
Oxidative stress is one of the earliest events of Alzheimer disease (AD), with implications as an important mediator in the onset, progression and pathogenesis of the disease. The generation of reactive oxygen species (ROS) and its consequent cellular damage/response contributes to much of the hallmark AD pathology seen in susceptible neurons. The sources of ROS-mediated damage appear to be multi-faceted in AD, with interactions between abnormal mitochondria, redox transition metals, and other factors. In this review, we provide an overview of these potential causes of oxidative stress in AD.
The role of abnormal mitochondrial dynamics in the pathogenesis of Alzheimer’s disease
Abbreviations used: AD, Alzheimer's disease; APP, amyloid precursor protein; DLP1, dynamin-like protein 1; Mfn 1/2, mitofusin 1/2; NHF, normal human fibroblasts; ROS, reactive oxygen species; sAD, sporadic AD. AbstractMitochondria play critical roles in neuronal function and almost all aspects of mitochondrial function are altered in Alzheimer neurons. Emerging evidence shows that mitochondria are dynamic organelles that undergo continuous fission and fusion, the balance of which not only controls mitochondrial morphology and number, but also regulates mitochondrial function and distribution. In this review, after a brief overview of the basic mechanisms involved in the regulation of mitochondrial fission and fusion and how mitochondrial dynamics affects mitochondrial function, we will discuss in detail our and others' recent work demonstrating abnormal mitochondrial morphology and distribution in Alzheimer's disease (AD) models and how these abnormalities may contribute to mitochondrial and synaptic dysfunction in AD. We propose that abnormal mitochondrial dynamics plays a key role in causing the dysfunction of mitochondria that ultimately damage AD neurons.
Multiple lines of evidence demonstrate that oxidative stress is an early event in Alzheimer’s disease (AD), occurring prior to cytopathology, and therefore may play a key pathogenic role in AD. Oxidative stress not only temporally precedes the pathological lesions of the disease but also activates cell signaling pathways, which, in turn, contribute to lesion formation and, at the same time, provoke cellular responses such as compensatory upregulation of antioxidant enzymes found in vulnerable neurons in AD. In this review, we provide an overview of the evidence of oxidative stress and compensatory responses that occur in AD, particularly focused on potential sources of oxidative stress and the roles and mechanism of activation of stress-activated protein kinase pathways.
Mitochondrial dysfunction is a prominent feature of various neurodegenerative diseases. A deeper understanding of the remarkably dynamic nature of mitochondria, characterized by a delicate balance of fission and fusion, has helped to fertilize a recent wave of new studies demonstrating abnormal mitochondrial dynamics in neurodegenerative diseases. This review highlights mitochondrial dysfunction and abnormal mitochondrial dynamics in Alzheimer disease, Parkinson disease, amyotrophic lateral sclerosis, and Huntington disease and discusses how these abnormal mitochondrial dynamics may contribute to mitochondrial and neuronal dysfunction. We propose that abnormal mitochondrial dynamics represents a key common pathway that mediates or amplifies mitochondrial dysfunction and neuronal dysfunction during the course of neurodegeneration.
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