Andrés Norambuena scite author profile

SummaryNormally post-mitotic neurons that aberrantly re-enter the cell cycle without dividing account for a substantial fraction of the neurons that die in Alzheimer's disease (AD). We now report that this ectopic cell cycle re-entry (CCR) requires soluble amyloid-b (Ab) and tau, the respective building blocks of the insoluble plaques and tangles that accumulate in AD brain. Exposure of cultured wild type (WT) neurons to Ab oligomers caused CCR and activation of the non-receptor tyrosine kinase, fyn, the cAMP-regulated protein kinase A and calcium-calmodulin kinase II, which respectively phosphorylated tau on Y18, S409 and S416. In tau knockout (KO) neurons, Ab oligomers activated all three kinases, but failed to induce CCR. Expression of WT, but not Y18F, S409A or S416A tau restored CCR in tau KO neurons. Tau-dependent CCR was also observed in vivo in an AD mouse model. CCR, a seminal step in AD pathogenesis, therefore requires signaling from Ab through tau independently of their incorporation into plaques and tangles.

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mTOR and neuronal cell cycle reentry: How impaired brain insulin signaling promotes Alzheimer's disease

Norambuena

Wallrabe

McMahon

et al. 2016

Alzheimer's & Dementia

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A major obstacle to pre-symptomatic diagnosis and disease-modifying therapy for Alzheimer's disease (AD) is inadequate understanding of molecular mechanisms of AD pathogenesis. For example, impaired brain insulin signaling is an AD hallmark, but whether and how it might contribute to the synaptic dysfunction and neuron death that underlie memory and cognitive impairment has been mysterious. Neuron death in AD is often caused by cell cycle re-entry (CCR) mediated by amyloid-β oligomers (AβOs) and tau, the precursors of plaques and tangles. We now report that CCR results from AβO-induced activation of the protein kinase complex, mTORC1, at the plasma membrane and mTORC1-dependent tau phosphorylation, and that CCR can be prevented by insulin-stimulated activation of lysosomal mTORC1. AβOs were also shown previously to reduce neuronal insulin signaling. Our data therefore indicate that the decreased insulin signaling provoked by AβOs unleashes their toxic potential to cause neuronal CCR, and by extension, neuron death.

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RalA-Exocyst Complex Regulates Integrin-Dependent Membrane Raft Exocytosis and Growth Signaling

et al. 2010

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Summary Anchorage-dependence of cell growth is a key metastasis-suppression mechanism that is mediated by effects of integrins on growth signaling pathways [1]. The small GTPase RalA is activated in metastatic cancers through multiple mechanisms and specifically induces anchorage independence [2–4]. Loss of integrin-mediated adhesion triggers caveolin-dependent internalization of cholesterol- and sphingolipid- rich lipid raft microdomains to the recycling endosomes; these domains serve as platforms for many signaling pathways and their clearance from the plasma membrane (PM) after cell detachment suppresses growth signaling [5, 6]. Conversely, re-adhesion triggers their return to the PM and restores growth signaling. Activation of Arf6 by integrins mediates exit of raft markers from the RE but is not sufficient for return to the PM. We now show that RalA but not RalB mediates integrin-dependent membrane raft exocytosis through the exocyst complex. Constitutively active RalA restores membrane raft targeting to promote anchorage independent growth signaling. Ras-transformed pancreatic cancer cells also show RalA-dependent constitutive PM raft targeting. These results identify RalA as a key determinant of integrin-dependent membrane raft trafficking and regulation of growth signaling. They therefore define a mechanism by which RalA regulates anchorage dependence and provide a new link between integrin signaling and cancer.

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Apical sorting of a voltage- and Ca ²⁺ -activated K ⁺ channel α-subunit in Madin-Darby canine kidney cells is independent of N-glycosylation

Bravo‐Zehnder

Orio

Norambuena

et al. 2000

Proc. Natl. Acad. Sci. U.S.A.

100

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The voltage-and Ca 2؉ -activated K ؉ (KV,Ca) channel is expressed in a variety of polarized epithelial cells seemingly displaying a tissuedependent apical-to-basolateral regionalization, as revealed by electrophysiology. Using domain-specific biotinylation and immunofluorescence we show that the human channel KV,Ca ␣-subunit (human Slowpoke channel, hSlo) is predominantly found in the apical plasma membrane domain of permanently transfected Madin-Darby canine kidney cells. Both the wild-type and a mutant hSlo protein lacking its only potential N-glycosylation site were efficiently transported to the cell surface and concentrated in the apical domain even when they were overexpressed to levels 200-to 300-fold higher than the density of intrinsic Slo channels. Furthermore, tunicamycin treatment did not prevent apical segregation of hSlo, indicating that endogenous glycosylated proteins (e.g., KV,Ca ␤-subunits) were not required. hSlo seems to display properties for lipid-raft targeting, as judged by its buoyant distribution in sucrose gradients after extraction with either detergent or sodium carbonate. The evidence indicates that the hSlo protein possesses intrinsic information for transport to the apical cell surface through a mechanism that may involve association with lipid rafts and that is independent of glycosylation of the channel itself or an associated protein. Thus, this particular polytopic model protein shows that glycosylation-independent apical pathways exist for endogenous membrane proteins in Madin-Darby canine kidney cells.human Slowpoke channel ͉ epithelial polarity

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A novel lysosome‐to‐mitochondria signaling pathway disrupted by amyloid‐β oligomers

et al. 2018

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The mechanisms of mitochondrial dysfunction in Alzheimer's disease are incompletely understood. Using two‐photon fluorescence lifetime microscopy of the coenzymes, NADH and NADPH, and tracking brain oxygen metabolism with multi‐parametric photoacoustic microscopy, we show that activation of lysosomal mechanistic target of rapamycin complex 1 (mTORC1) by insulin or amino acids stimulates mitochondrial activity and regulates mitochondrial DNA synthesis in neurons. Amyloid‐β oligomers, which are precursors of amyloid plaques in Alzheimer's disease brain and stimulate mTORC1 protein kinase activity at the plasma membrane but not at lysosomes, block this Nutrient‐induced Mitochondrial Activity (NiMA) by a mechanism dependent on tau, which forms neurofibrillary tangles in Alzheimer's disease brain. NiMA was also disrupted in fibroblasts derived from two patients with tuberous sclerosis complex, a genetic disorder that causes dysregulation of lysosomal mTORC1. Thus, lysosomal mTORC1 couples nutrient availability to mitochondrial activity and links mitochondrial dysfunction to Alzheimer's disease by a mechanism dependent on the soluble building blocks of the poorly soluble plaques and tangles.

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