Nascent Aß42 Fibrillization in Synaptic Endosomes Precedes Plaque Formation in a Mouse Model of Alzheimer's-like ß-Amyloidosis.

Accumulation of amyloid-ß peptide (Aß) aggregates in synapses may contribute to the profound synaptic loss characteristic of Alzheimer's disease (AD). The origin of synaptic Aß aggregates remains elusive, but loss of endosomal proteostasis may trigger their formation. In this study, we identified the synaptic compartments where Aß accumulates, and performed a longitudinal analysis of synaptosomes isolated from brains of TgCRND8 APP transgenic mice of either sex. To evaluate the specific contribution of Aß-degrading protease endothelin-converting enzyme (ECE-1) to synaptic/endosomal Aß homeostasis, we analyzed the effect of partial Ece1 KO in brain and complete ECE1 KO in SH-SY5Y cells. Global inhibition of ECE family members was used to further assess their role in preventing synaptic Aß accumulation. Results showed that, before extracellular amyloid deposition, synapses were burdened with detergent-soluble Aß monomers, oligomers, and fibrils. Levels of all soluble Aß species declined thereafter, as Aß42 turned progressively insoluble and accumulated in Aß-producing synaptic endosomal vesicles with characteristics of multivesicular bodies. Accordingly, fibrillar Aß was detected in brain exosomes. ECE-1-deficient mice had significantly increased endogenous synaptosomal Aß42 levels, and protease inhibitor experiments showed that, in TgCRND8 mice, synaptic Aß42 became nearly resistant to degradation by ECE-related proteases. Our study supports that Aß accumulating in synapses is produced locally, within endosomes, and does not require the presence of amyloid plaques. ECE-1 is a determinant factor controlling the accumulation and fibrillization of nascent Aß in endosomes and, in TgCRND8 mice, Aß overproduction causes rapid loss of Aß42 solubility that curtails ECE-mediated degradation.SIGNIFICANCE STATEMENT Deposition of aggregated Aß in extracellular plaques is a defining feature of AD. Aß aggregates also accumulate in synapses and may contribute to the profound synaptic loss and cognitive dysfunction typical of the disease. However, it is not clear whether synaptotoxic Aß is mainly derived from plaques or if it is produced and aggregated locally, within affected synaptic compartments. Filling this knowledge gap is important for the development of an effective treatment for AD, as extracellular and intrasynaptic pools of Aß may not be equally modulated by immunotherapies or other therapeutic approaches. In this manuscript, we provide evidence that Aß aggregates building up in synapses are formed locally, within synaptic endosomes, because of disruptions in nascent Aß proteostasis.

A new class of monoclonal Aß antibodies selectively targets and triggers deposition of Aß protofibrils.

Aggregation and accumulation of amyloid-ß peptide (Aß) are a critical trigger for the onset of Alzheimer's disease (AD). While the plaques are the most outstanding Aß pathological feature, much of the recent research emphasis has been on soluble Aß species because of their diffusible, proinflammatory, and toxic properties. The focus on soluble aggregated Aß species has also increased the interest in antibodies that are selective for different Aß conformations. In the current study, we developed and characterized a new class of monoclonal antibodies (referred to as mAbSL) that are selective for Aß protofibrils. Cloning and sequencing of the heavy and light chain variable regions for multiple antibodies identified sequence characteristics that may impart the conformational selectivity by the antibodies. Transfection of FreeStyle 293F cells with the plasmids permitted in-house expression and purification of mAbSL antibodies along with non-conformation-selective Aß monoclonal antibodies (Aß mAbs). Several of the purified mAbSL antibodies demonstrated significant affinity and selectivity for Aß42 protofibrils compared with Aß42 monomers and Aß42 fibrils. Competition ELISA assays assessing the best overall antibody, mAbSL 113, yielded affinity constants of 7 nM for the antibody-Aß42 protofibril interaction, while the affinity for either Aß42 monomers or Aß42 fibrils was roughly 80 times higher. mAbSL 113 significantly inhibited Aß42 monomer aggregation by a unique mechanism compared with the inhibition displayed by Aß mAb 513. Aß42 protofibril dynamics were also markedly altered in the presence of mAbSL 113, whereby insoluble complex formation and protofibril deposition were stimulated by the antibody at low substoichiometric molar ratios. As the field contemplates the therapeutic effectiveness of Aß conformation-selective antibodies, the findings presented here demonstrate new information on a monoclonal antibody that selectively targets Aß protofibrils and impacts Aß dynamics.