Christa J. Maynard scite author profile

SummaryMounting evidence is demonstrating roles for the amyloid precursor protein (APP) and its proteolytic product Ab in metal homeostasis. Furthermore, aberrant metal homeostasis is observed in patients with Alzheimer's disease (AD), and this may contribute to AD pathogenesis, by enhancing the formation of reactive oxygen species and toxic Ab oligomers and facilitating the formation of the hallmark amyloid deposits in AD brain. Indeed, zinc released from synaptic activity has been shown to induce parenchymal and cerebrovascular amyloid in transgenic mice. On the other hand, abnormal metabolism of APP and Ab may impair brain metal homeostasis as part of the AD pathogenic process. Ab and APP expression have both been shown to decrease brain copper (Cu) levels, whereas increasing brain Cu availability results in decreased levels of Ab and amyloid plaque formation in transgenic mice. Lowering Cu concentrations can downregulate the transcription of APP, strengthening the hypothesis that APP and Ab form part of the Cu homeostatic machinery in the brain. This is a complex pathway, and it appears that when the sensitive metal balance in the brain is sufficiently disrupted, it can lead to the self-perpetuating pathogenesis of AD. Clinical trials are currently studying agents that can remedy abnormal Ab-metal interactions.

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A Fluorescent Broad-Spectrum Proteasome Inhibitor for Labeling Proteasomes In Vitro and In Vivo

Verdoes

Florea

Menéndez‐Benito

et al. 2006

Chemistry & Biology

182

207

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The proteasome is an essential evolutionary conserved protease involved in many regulatory systems. Here, we describe the synthesis and characterization of the activity-based, fluorescent, and cell-permeable inhibitor Bodipy TMR-Ahx(3)L(3)VS (MV151), which specifically targets all active subunits of the proteasome and immunoproteasome in living cells, allowing for rapid and sensitive in-gel detection. The inhibition profile of a panel of commonly used proteasome inhibitors could be readily determined by MV151 labeling. Administration of MV151 to mice allowed for in vivo labeling of proteasomes, which correlated with inhibition of proteasomal degradation in the affected tissues. This probe can be used for many applications ranging from clinical profiling of proteasome activity, to biochemical analysis of subunit specificity of inhibitors, and to cell biological analysis of the proteasome function and dynamics in living cells.

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Functional alterations of the ubiquitin-proteasome system in motor neurons of a mouse model of familial amyotrophic lateral sclerosis†

Cheroni¹,

Marino²,

Tortarolo³

et al. 2008

142

113

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Acute Polyglutamine Expression in Inducible Mouse Model Unravels Ubiquitin/Proteasome System Impairment and Permanent Recovery Attributable to Aggregate Formation

Ortega¹,

Dı́az-Hernández²,

Maynard³

et al. 2010

J. Neurosci.

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The presence of intracellular ubiquitylated inclusions in neurodegenerative disorders and the role of the ubiquitin/proteasome system (UPS) in degrading abnormal hazardous proteins have given rise to the hypothesis that UPS-impairment underlies neurodegenerative processes. However, this remains controversial for polyglutamine disorders such as Huntington disease (HD). Whereas studies in cellular models have provided evidence in favor of UPS-impairment attributable to expression of the N-terminal fragment of mutant huntingtin (N-mutHtt), similar studies on mouse models failed to do so. Furthermore, we have recently shown that the increase in polyubiquitin conjugates reported in the brain of N-mutHtt mice occurs in the absence of a general UPS-impairment. In the present study we aim to clarify the potential of N-mutHtt to impair UPS function in vivo as well as the mechanisms by which neurons may adapt after prolonged exposure to N-mutHtt in genetic models. By combining UPS reporter mice with an inducible mouse model of HD, we demonstrate for the first time polyglutamine-induced global UPS-impairment in vivo. UPS-impairment occurred transiently after acute N-mutHtt expression and restoration correlated with appearance of inclusion bodies (IBs). Consistently, UPS recovery did not take place when IB formation was prevented through administration of N-mutHtt aggregation-inhibitors in both cellular and animal models. Finally, no UPSimpairment was detected in old mice constitutively expressing N-mutHtt despite the age-associated decrease in brain proteasome activity. Therefore, our data reconcile previous contradictory reports by showing that N-mutHtt can indeed impair UPS function in vivo and that N-mutHtt aggregation leads to long lasting restoration of UPS function.

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