Daniel Markx scite author profile

The deposition of amyloid fibrils as plaques is a key feature of several neurodegenerative diseases including in particular Alzheimer’s. This disease is characterized, if not provoked, by amyloid aggregates formed from Aβ peptide that deposit inside the brain or are toxic to neuronal cells. We here used scanning transmission electron microscopy (STEM) to determine the fibril network structure and interactions of Aβ fibrils within a cell culture model of Alzheimer’s disease. STEM images taken from the formed Aβ amyloid deposits revealed three main types of fibril network structures, termed amorphous meshwork, fibril bundle and amyloid star. All three were infiltrated by different types of lipid inclusions from small-sized exosome-like structures (50–100 nm diameter) to large-sized extracellular vesicles (up to 300 nm). The fibrils also presented strong interactions with the surrounding cells such that fibril bundles extended into tubular invaginations of the plasma membrane. Amyloid formation in the cell model was previously found to have an intracellular origin and we show here that it functionally destroys the integrity of the intracellular membranes as it leads to lysosomal leakage. These data provide a mechanistic link to explain why intracellular fibril formation is toxic to the cell.

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In Vivo Protein Complementation Demonstrates Presynaptic α-Synuclein Oligomerization and Age-Dependent Accumulation of 8–16-mer Oligomer Species

Kiechle

Einem

Höfs

et al. 2019

Cell Reports

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Intracellular accumulation of a-synuclein (a-syn) and formation of Lewy bodies are neuropathological characteristics of Parkinson's disease (PD) and related a-synucleinopathies. Oligomerization and spreading of a-syn from neuron to neuron have been suggested as key events contributing to the progression of PD. To directly visualize and characterize a-syn oligomerization and spreading in vivo, we generated two independent conditional transgenic mouse models based on a-syn protein complementation assays using neuron-specifically expressed split Gaussia luciferase or split Venus yellow fluorescent protein (YFP). These transgenic mice allow direct assessment of the quantity and subcellular distribution of a-syn oligomers in vivo. Using these mouse models, we demonstrate an age-dependent accumulation of a specific subtype of a-syn oligomers. We provide in vivo evidence that, although a-syn is found throughout neurons, a-syn oligomerization takes place at the presynapse. Furthermore, our mouse models provide strong evidence for a transsynaptic cell-to-cell transfer of de novo generated a-syn oligomers in vivo.

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Generation and Characterization of Virus-Enhancing Peptide Nanofibrils Functionalized with Fluorescent Labels

Rode¹,

Hayn²,

Röcker³

et al. 2017

Bioconjugate Chem.

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Retroviral gene transfer is the method of choice for the stable introduction of genetic material into the cellular genome. However, efficient gene transfer is often limited by low transduction rates of the viral vectors. We have recently described a 12-mer peptide, termed EF-C, that forms amyloid-like peptide nanofibrils (PNF), strongly increasing viral transduction efficiencies. These nanofibrils are polycationic and bind negatively charged membranes of virions and cells, thereby overcoming charge repulsions and resulting in increased rates of virion attachment and gene transfer. EF-C PNF enhance vector transduction more efficiently than other soluble additives and offer prospects for clinical applications. However, while the transduction-enhancing activity of PNF has been well-characterized, the exact mechanism and the kinetics underlying infection enhancement as well as the cellular fate of the fibrils are hardly explored. This is partially due to the fact that current labeling techniques for PNF rely on amyloid probes that cause high background staining or lose signal intensities after cellular uptake. Here, we sought to generate EF-C PNF covalently coupled with fluorescent labels. To achieve such covalent bioconjugates, the free amino groups of the EF-C peptide were coupled to the ATTO 495 or 647N NHS ester dyes. When small amounts of the labeled peptides were mixed with a 100- to 10 000-fold excess of the native peptide, PNF formed that were morphologically indistinguishable from those derived from the unlabeled peptide. The fluorescence of the fibrils could be readily detected using fluorescence spectroscopy, microscopy, and flow cytometry. In addition, labeled and nonlabeled fibrils captured viral particles and increased retroviral transduction with similar efficacy. These covalently fluorescence-labeled PNF are valuable tools with which to elucidate the mechanism(s) underlying transduction attachment and the fate of the fibrils in cells, tissues, and animal models.

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Arginine 313 of the putative 8th helix mediates Gαq/14 coupling of human CC chemokine receptors CCR2a and CCR2b

Markx

Schuhholz

Abadier

et al. 2019

Cellular Signalling

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Molecular architecture of Aβ fibrils grown in cerebrospinal fluid solution and in a cell culture model of Aβ plaque formation

Garvey

Baumann

Wulff

et al. 2016

Amyloid

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Daniel Markx

Amyloid plaque structure and cell surface interactions of β-amyloid fibrils revealed by electron tomography

In Vivo Protein Complementation Demonstrates Presynaptic α-Synuclein Oligomerization and Age-Dependent Accumulation of 8–16-mer Oligomer Species

Generation and Characterization of Virus-Enhancing Peptide Nanofibrils Functionalized with Fluorescent Labels

Arginine 313 of the putative 8th helix mediates Gαq/14 coupling of human CC chemokine receptors CCR2a and CCR2b

Molecular architecture of Aβ fibrils grown in cerebrospinal fluid solution and in a cell culture model of Aβ plaque formation

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