C-Terminally Truncated Forms of Tau, But Not Full-Length Tau or Its C-Terminal Fragments, Are Released from Neurons Independently of Cell Death

Kanmert, Daniel; Cantlon, Adam; Muratore, Christina; Jin, Ming; O’Malley, Tiernan T.; Lee, Gloria; Young‐Pearse, Tracy L.; Selkoe, Dennis J.; Walsh, Dominic M.

doi:10.1523/jneurosci.0387-15.2015

Cited by 143 publications

(160 citation statements)

References 55 publications

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“…It is worth noting that hypophosphorylated intact Tau was detected in conditioned medium of neuronal cultures in a previous study [11], although such extracellular Tau was demonstrated to be non-exosome associated, as Tau is barely detected in exosomal preparations, probably due to the limited material loaded. By contrast, another report stated that only C-terminally truncated Tau lacking the microtubule binding domain is released by cultured neurons or other types of cells [50] and a small fraction of extracellular Tau (<0.2%) is indeed present in exosomes. The cause of the discrepancy (truncated Tau v.s.…”

Section: Discussionmentioning

confidence: 99%

The release and trans-synaptic transmission of Tau via exosomes

Wang

Balaji

Kaniyappan

et al. 2017

Mol Neurodegeneration

554

521

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BackgroundTau pathology in AD spreads in a hierarchical pattern, whereby it first appears in the entorhinal cortex, then spreads to the hippocampus and later to the surrounding areas. Based on this sequential appearance, AD can be classified into six stages (“Braak stages”). The mechanisms and agents underlying the progression of Tau pathology are a matter of debate. Emerging evidence indicates that the propagation of Tau pathology may be due to the transmission of Tau protein, but the underlying pathways and Tau species are not well understood. In this study we investigated the question of Tau spreading via small extracellular vesicles called exosomes.MethodsExosomes from different sources were analyzed by biochemical methods and electron microscopy (EM) and cryo-EM. Microfluidic devices that allow the culture of cell populations in different compartments were used to investigate the spreading of Tau.ResultsWe show that Tau protein is released by cultured primary neurons or by N2a cells overexpressing different Tau constructs via exosomes. Neuron-derived exosomal Tau is hypo-phosphorylated, compared with cytosolic Tau. Depolarization of neurons promotes release of Tau-containing exosomes, highlighting the importance of neuronal activity. Using microfluidic devices we show that exosomes mediate trans-neuronal transfer of Tau depending on synaptic connectivity. Tau spreading is achieved by direct transmission of exosomes between neurons. In organotypic hippocampal slices, Tau-containing exosomes in conditioned medium are taken up by neurons and microglia, not astrocytes. In N2a cells, Tau assemblies are released via exosomes. They can induce inclusions of other Tau molecules in N2a cells expressing mutant human Tau. We also studied exosomes from cerebrospinal fluid in AD and control subjects containing monomeric and oligomeric Tau. Split-luciferase complementation reveals that exosomes from CSF can promote Tau aggregation in cultured cells.ConclusionOur study demonstrates that exosomes contribute to trans-synaptic Tau transmission, and thus offer new approches to control the spreading of pathology in AD and other tauopathies.Electronic supplementary materialThe online version of this article (doi:10.1186/s13024-016-0143-y) contains supplementary material, which is available to authorized users.

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Section: Discussionmentioning

confidence: 99%

The release and trans-synaptic transmission of Tau via exosomes

Wang

Balaji

Kaniyappan

et al. 2017

Mol Neurodegeneration

554

521

View full text Add to dashboard Cite

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“…There is evidence that the N-terminal fragments of tau [13] or the "C-terminally truncated forms of Tau" [69] are secreted into the extracellular space. This extracellular tau is regulated by neuronal activity [99] and could modulate Aβ secretion [13]-although data are contradictory [69].…”

Section: In Vitromentioning

confidence: 99%

“…This extracellular tau is regulated by neuronal activity [99] and could modulate Aβ secretion [13]-although data are contradictory [69].…”

Section: In Vitromentioning

confidence: 99%

Propagation of Aß pathology: hypotheses, discoveries, and yet unresolved questions from experimental and human brain studies

Eisele

Duyckaerts

2015

Acta Neuropathol

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In brains of patients with Alzheimer's disease (AD), Aβ peptides accumulate in parenchyma and, almost invariably, also in the vascular walls. Although Aβ aggregation is, by definition, present in AD, its impact is only incompletely understood. It occurs in a stereotypical spatiotemporal distribution within neuronal networks in the course of the disease. This suggests a role for synaptic connections in propagating Aβ pathology, and possibly of axonal transport in an antero- or retrograde way-although, there is also evidence for passive, extracellular diffusion. Striking, in AD, is the conjunction of tau and Aβ pathology. Tau pathology in the cell body of neurons precedes Aβ deposition in their synaptic endings in several circuits such as the entorhino-dentate, cortico-striatal or subiculo-mammillary connections. However, genetic evidence suggests that Aβ accumulation is the first step in AD pathogenesis. To model the complexity and consequences of Aβ aggregation in vivo, various transgenic (tg) rodents have been generated. In rodents tg for the human Aβ precursor protein, focal injections of preformed Aβ aggregates can induce Aβ deposits in the vicinity of the injection site, and over time in more distant regions of the brain. This suggests that Aβ shares with α-synuclein, tau and other proteins the property to misfold and aggregate homotypic molecules. We propose to group those proteins under the term "propagons". Propagons may lack the infectivity of prions. We review findings from neuropathological examinations of human brains in different stages of AD and from studies in rodent models of Aβ aggregation and discuss putative mechanisms underlying the initiation and spread of Aβ pathology.

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“…, 2015) and may produce neurotoxic fragments (Park and Ferreira, 2005; Lang et al. , 2014), generate products that show increased release from neurons (Kanmert et al. , 2015), or produce fragments with a modified MT interaction (Derisbourg et al.…”

Section: Introductionmentioning

confidence: 99%