AAV-mediated neuronal expression of an scFv antibody selective for Aß oligomers protects synapses and rescues memory in Alzheimer models.

The accumulation of soluble oligomers of the amyloid-ß peptide (AßOs) in the brain has been implicated in synapse failure and memory impairment in Alzheimer's disease. Here, we initially show that treatment with NUsc1, a single-chain variable-fragment antibody (scFv) that selectively targets a subpopulation of AßOs and shows minimal reactivity to Aß monomers and fibrils, prevents the inhibition of long-term potentiation in hippocampal slices and memory impairment induced by AßOs in mice. As a therapeutic approach for intracerebral antibody delivery, we developed an adeno-associated virus vector to drive neuronal expression of NUsc1 (AAV-NUsc1) within the brain. Transduction by AAV-NUsc1 induced NUsc1 expression and secretion in adult human brain slices and inhibited AßO binding to neurons and AßO-induced loss of dendritic spines in primary rat hippocampal cultures. Treatment of mice with AAV-NUsc1 prevented memory impairment induced by AßOs and, remarkably, reversed memory deficits in aged APPswe/PS1ΔE9 Alzheimer's disease model mice. These results support the feasibility of immunotherapy using viral vector-mediated gene delivery of NUsc1 or other AßO-specific single-chain antibodies as a potential therapeutic approach in Alzheimer's disease.

Exercise-linked FNDC5/irisin rescues synaptic plasticity and memory defects in Alzheimer's models.

Defective brain hormonal signaling has been associated with Alzheimer's disease (AD), a disorder characterized by synapse and memory failure. Irisin is an exercise-induced myokine released on cleavage of the membrane-bound precursor protein fibronectin type III domain-containing protein 5 (FNDC5), also expressed in the hippocampus. Here we show that FNDC5/irisin levels are reduced in AD hippocampi and cerebrospinal fluid, and in experimental AD models. Knockdown of brain FNDC5/irisin impairs long-term potentiation and novel object recognition memory in mice. Conversely, boosting brain levels of FNDC5/irisin rescues synaptic plasticity and memory in AD mouse models. Peripheral overexpression of FNDC5/irisin rescues memory impairment, whereas blockade of either peripheral or brain FNDC5/irisin attenuates the neuroprotective actions of physical exercise on synaptic plasticity and memory in AD mice. By showing that FNDC5/irisin is an important mediator of the beneficial effects of exercise in AD models, our findings place FNDC5/irisin as a novel agent capable of opposing synapse failure and memory impairment in AD.

Astrocyte Transforming Growth Factor Beta 1 Protects Synapses against Aß Oligomers in Alzheimer's Disease Model.

Alzheimer's disease (AD) is characterized by progressive cognitive decline, increasingly attributed to neuronal dysfunction induced by amyloid-ß oligomers (AßOs). Although the impact of AßOs on neurons has been extensively studied, only recently have the possible effects of AßOs on astrocytes begun to be investigated. Given the key roles of astrocytes in synapse formation, plasticity, and function, we sought to investigate the impact of AßOs on astrocytes, and to determine whether this impact is related to the deleterious actions of AßOs on synapses. We found that AßOs interact with astrocytes, cause astrocyte activation and trigger abnormal generation of reactive oxygen species, which is accompanied by impairment of astrocyte neuroprotective potential in vitro We further show that both murine and human astrocyte conditioned media (CM) increase synapse density, reduce AßOs binding, and prevent AßO-induced synapse loss in cultured hippocampal neurons. Both a neutralizing anti-transforming growth factor-ß1 (TGF-ß1) antibody and siRNA-mediated knockdown of TGF-ß1, previously identified as an important synaptogenic factor secreted by astrocytes, abrogated the protective action of astrocyte CM against AßO-induced synapse loss. Notably, TGF-ß1 prevented hippocampal dendritic spine loss and memory impairment in mice that received an intracerebroventricular infusion of AßOs. Results suggest that astrocyte-derived TGF-ß1 is part of an endogenous mechanism that protects synapses against AßOs. By demonstrating that AßOs decrease astrocyte ability to protect synapses, our results unravel a new mechanism underlying the synaptotoxic action of AßOs in AD.SIGNIFICANCE STATEMENT Alzheimer's disease is characterized by progressive cognitive decline, mainly attributed to synaptotoxicity of the amyloid-ß oligomers (AßOs). Here, we investigated the impact of AßOs in astrocytes, a less known subject. We show that astrocytes prevent synapse loss induced by AßOs, via production of transforming growth factor-ß1 (TGF-ß1). We found that AßOs trigger morphological and functional alterations in astrocytes, and impair their neuroprotective potential. Notably, TGF-ß1 reduced hippocampal dendritic spine loss and memory impairment in mice that received intracerebroventricular infusions of AßOs. Our results describe a new mechanism underlying the toxicity of AßOs and indicate novel therapeutic targets for Alzheimer's disease, mainly focused on TGF-ß1 and astrocytes.

Interaction of amyloid-ß (Aß) oligomers with neurexin 2α and neuroligin 1 mediates synapse damage and memory loss in mice.

Brain accumulation of the amyloid-ß protein (Aß) and synapse loss are neuropathological hallmarks of Alzheimer disease (AD). Aß oligomers (AßOs) are synaptotoxins that build up in the brains of patients and are thought to contribute to memory impairment in AD. Thus, identification of novel synaptic components that are targeted by AßOs may contribute to the elucidation of disease-relevant mechanisms. Trans-synaptic interactions between neurexins (Nrxs) and neuroligins (NLs) are essential for synapse structure, stability, and function, and reduced NL levels have been associated recently with AD. Here we investigated whether the interaction of AßOs with Nrxs or NLs mediates synapse damage and cognitive impairment in AD models. We found that AßOs interact with different isoforms of Nrx and NL, including Nrx2α and NL1. Anti-Nrx2α and anti-NL1 antibodies reduced AßO binding to hippocampal neurons and prevented AßO-induced neuronal oxidative stress and synapse loss. Anti-Nrx2α and anti-NL1 antibodies further blocked memory impairment induced by AßOs in mice. The results indicate that Nrx2α and NL1 are targets of AßOs and that prevention of this interaction reduces the deleterious impact of AßOs on synapses and cognition. Identification of Nrx2α and NL1 as synaptic components that interact with AßOs may pave the way for development of novel approaches aimed at halting synapse failure and cognitive loss in AD.

Amyloid-ß oligomers transiently inhibit AMP-activated kinase and cause metabolic defects in hippocampal neurons.

AMP-activated kinase (AMPK) is a key player in energy sensing and metabolic reprogramming under cellular energy restriction. Several studies have linked impaired AMPK function to peripheral metabolic diseases such as diabetes. However, the impact of neurological disorders, such as Alzheimer disease (AD), on AMPK function and downstream effects of altered AMPK activity on neuronal metabolism have been investigated only recently. Here, we report the impact of Aß oligomers (AßOs), synaptotoxins that accumulate in AD brains, on neuronal AMPK activity. Short-term exposure of cultured rat hippocampal neurons or ex vivo human cortical slices to AßOs transiently decreased intracellular ATP levels and AMPK activity, as evaluated by its phosphorylation at threonine residue 172 (AMPK-Thr(P)172). The AßO-dependent reduction in AMPK-Thr(P)172 levels was mediated by glutamate receptors of the N-methyl-d-aspartate (NMDA) subtype and resulted in removal of glucose transporters (GLUTs) from the surfaces of dendritic processes in hippocampal neurons. Importantly, insulin prevented the AßO-induced inhibition of AMPK. Our results establish a novel toxic impact of AßOs on neuronal metabolism and suggest that AßO-induced, NMDA receptor-mediated AMPK inhibition may play a key role in early brain metabolic defects in AD.

Amyloid-ß oligomers induce differential gene expression in adult human brain slices.

Cognitive decline in Alzheimer disease (AD) is increasingly attributed to the neuronal impact of soluble oligomers of the amyloid-ß peptide (AßOs). Current knowledge on the molecular and cellular mechanisms underlying the toxicity of AßOs stems largely from rodent-derived cell/tissue culture experiments or from transgenic models of AD, which do not necessarily recapitulate the complexity of the human disease. Here, we used DNA microarray and RT-PCR to investigate changes in transcription in adult human cortical slices exposed to sublethal doses of AßOs. The results revealed a set of 27 genes that showed consistent differential expression upon exposure of slices from three different donors to AßOs. Functional classification of differentially expressed genes revealed that AßOs impact pathways important for neuronal physiology and known to be dysregulated in AD, including vesicle trafficking, cell adhesion, actin cytoskeleton dynamics, and insulin signaling. Most genes (70%) were down-regulated by AßO treatment, suggesting a predominantly inhibitory effect on the corresponding pathways. Significantly, AßOs induced down-regulation of synaptophysin, a presynaptic vesicle membrane protein, suggesting a mechanism by which oligomers cause synapse failure. The results provide insight into early mechanisms of pathogenesis of AD and suggest that the neuronal pathways affected by AßOs may be targets for the development of novel diagnostic or therapeutic approaches.