Modeling the early stages of Alzheimer's disease by administering intracerebroventricular injections of human native Aß oligomers to rats.

Alzheimer's disease (AD) is a progressive and irreversible neurodegenerative disease characterized by the accumulation of aggregated amyloid beta (Aß) and hyperphosphorylated tau along with a slow decline in cognitive functions. Unlike advanced AD, the initial steps of AD pathophysiology have been poorly investigated, partially due to limited availability of animal models focused on the early, plaque-free stages of the disease. The aim of this study was to evaluate the early behavioral, anatomical and molecular alterations in wild-type rats following intracerebroventricular injections of human Aß oligomers (AßOs). Bioactive human AD and nondemented control brain tissue extracts were characterized using ELISA and proteomics approaches. Following a bilateral infusion, rats underwent behavioral testing, including the elevated plus maze, social recognition test, Morris water maze and Y-maze within 6 weeks postinjection. An analysis of brain structure was performed with manganese-enhanced MRI. Collected brain tissues were analyzed using stereology, immunohistochemistry, ELISA and qPCR. No sensorimotor deficits affecting motor performance on different maze tasks were observed, nor was spatial memory disturbed in AD rats. In contrast, a significant impairment of social memory became evident at 21 days postinjection. This deficit was associated with a significantly decreased volume of the lateral entorhinal cortex and a tendency toward a decrease in the total brain volume. Significant increase of cleaved caspase-3-positive cells, microglial activation and proinflammatory responses accompanied by altered expression of synaptic markers were observed in the hippocampus of AD rats with immunohistochemical and qPCR approaches at 6 weeks postinjection. Our data suggest that the social memory impairment observed in AßO-injected rats might be determined by neuroinflammatory responses and synaptopathy. An infusion of native oligomeric Aß in the rat brain represents a feasible tool to model early plaque-free events associated with AD.

Short erythropoietin-derived peptide enhances memory, improves long-term potentiation, and counteracts amyloid beta-induced pathology.

Neurodegenerative disorders such as Alzheimer's disease (AD) are characterized by the irreversible neuronal loss and memory impairment, and current treatments are merely symptomatic. Erythropoietin (EPO) has been shown to possess neurotrophic, neuroprotective, anti-inflammatory, and memory-enhancing effects, which could be therapeutically beneficial in the different aspects of AD. However, the hematopoietic effect of EPO has hampered its potential as a neuroprotective and procognitive agent. In this study, we characterized a novel small peptide, NL100, derived from a conserved C-helix region of EPO. NL100 was shown to bind to the EPO receptor, induce neuritogenesis, and protect hippocampal neurons from oxidative- and Aß25-35-induced neurodegeneration in vitro. Importantly, long-term NL100 treatment did not induce hematopoiesis, overcoming this challenge associated with EPO. Memory-enhancing effects were demonstrated after NL100 treatment in social recognition test for short-term memory, in both healthy rats and rats challenged centrally with Aß25-35 peptide, and in the Morris water maze test for spatial memory. Moreover, NL100 was shown to reverse Aß25-35-induced hippocampal degeneration and gliosis as well as pilocarpine-induced suppression of long-term potentiation in rats. In conclusion, NL100 is a novel EPO-derived nonhematopoietic peptide with neuroprotective and memory-enhancing effects and could therefore be a potential candidate for the development of new treatments for neurodegenerative disorders and dementia.

The C-terminal flanking peptide of neuropeptide Y (NPY) is not essential for seizure-suppressant actions of prepro-NPY overexpression in male rats.

The full coding sequence of neuropeptide Y (NPY), prepro-NPY, is sequentially metabolized into three peptides; an N-terminus 28-amino acid signaling peptide, the NPY peptide itself (NPY1-36), and a 30-amino acid C-terminus peptide, known as the C-terminal flanking peptide of neuropeptide-Y (CPON). While the signaling peptide directs intracellular trafficking and NPY1-36 is well characterized, the biological function of CPON is unknown. This is noteworthy because CPON is co-stored and co-released along with NPY1-36 and could thus potentially serve important functions. To assess the role of CPON, we adapted a viral genetic approach using two different vector designs encoding NPY, but where the CPON coding sequence was excluded from one of the vectors. Thus, the effect of CPON was indirectly assessed. Male rats received intrahippocampal injections of either a vector encoding NPY1-39 whose metabolism yields NPY1-36 and not CPON, or a prepro-NPY vector encoding both NPY1-36 and CPON. A third vector encoding EGFP served as control. We subsequently studied to what extent CPON might affect seizure susceptibility and memory performance, respectively, to address two important questions to evaluate the potential of NPY gene therapy in epilepsy. Both NPY vectors, as compared to EGFP control, were found to be equally effective at suppressing acute kainate-induced seizures, and both did not influence learning and memory performance in the Morris water maze. Thus CPON itself does not appear to aid actions governed by vector-mediated overexpression of NPY1-36 within the hippocampus. Whether CPON serves other important functions remains to be determined.