Exosome-associated AAV vector as a robust and convenient neuroscience tool.

Adeno-associated virus (AAV) vectors are showing promise in gene therapy trials and have proven to be extremely efficient biological tools in basic neuroscience research. One major limitation to their widespread use in the neuroscience laboratory is the cost, labor, skill and time-intense purification process of AAV. We have recently shown that AAV can associate with exosomes (exo-AAV) when the vector is isolated from conditioned media of producer cells, and the exo-AAV is more resistant to neutralizing anti-AAV antibodies compared with standard AAV. Here, we demonstrate that simple pelleting of exo-AAV from media via ultracentrifugation results in high-titer vector preparations capable of efficient transduction of central nervous system (CNS) cells after systemic injection in mice. We observed that exo-AAV is more efficient at gene delivery to the brain at low vector doses relative to conventional AAV, even when derived from a serotype that does not normally efficiently cross the blood-brain barrier. Similar cell types were transduced by exo-AAV and conventionally purified vector. Importantly, no cellular toxicity was noted in exo-AAV-transduced cells. We demonstrated the utility and robustness of exo-AAV-mediated gene delivery by detecting direct GFP fluorescence after systemic injection, allowing three-dimensional reconstruction of transduced Purkinje cells in the cerebellum using ex vivo serial two-photon tomography. The ease of isolation combined with the high efficiency of transgene expression in the CNS, may enable the widespread use of exo-AAV as a neuroscience research tool. Furthermore, the ability of exo-AAV to evade neutralizing antibodies while still transducing CNS after peripheral delivery is clinically relevant.

Activation of glycogen synthase kinase-3 beta mediates ß-amyloid induced neuritic damage in Alzheimer's disease.

ß-Amyloid (Aß) plaques in Alzheimer (AD) brains are surrounded by severe dendritic and axonal changes, including local spine loss, axonal swellings and distorted neurite trajectories. Whether and how plaques induce these neuropil abnormalities remains unknown. We tested the hypothesis that oligomeric assemblies of Aß, seen in the periphery of plaques, mediate the neurodegenerative phenotype of AD by triggering activation of the enzyme GSK-3ß, which in turn appears to inhibit a transcriptional program mediated by CREB. We detect increased activity of GSK-3ß after exposure to oligomeric Aß in neurons in culture, in the brain of double transgenic APP/tau mice and in AD brains. Activation of GSK-3ß, even in the absence of Aß, is sufficient to produce a phenocopy of Aß-induced dendritic spine loss in neurons in culture, while pharmacological inhibition of GSK-3ß prevents spine loss and increases expression of CREB-target genes like BDNF. Of note, in transgenic mice GSK-3ß inhibition ameliorated plaque-related neuritic changes and increased CREB-mediated gene expression. Moreover, GSK-3ß inhibition robustly decreased the oligomeric Aß load in the mouse brain. All these findings support the idea that GSK3ß is aberrantly activated by the presence of Aß, and contributes, at least in part, to the neuronal anatomical derangement associated with Aß plaques in AD brains and to Aß pathology itself.

A human immunoglobulin in myeloma protein with anti-gastric parietal cell autoantigen activity.

A previously characterised IgA Kappa myeloma protein was isolated and purified. The (Fab) alpha fragments of this immunoglobulin were obtained. The IgA and Fab fragments reacted in vitro with gastric parietal cells (GPC) using animal gastric sections and with smooth cytoplasmic membranes obtained from rabbit fundus (gastric) mucosa. This was seen macroscopically and by light and electron microscopy. Evidence is thus provided which supports the concept that this homogeneous immunoglobulin is a typical monoclonal autoantibody.