Cryo-Electron Microscopy Structure of Purified γ-Secretase at 12 Å Resolution

γ-Secretase, an integral membrane protein complex, catalyzes the intramembrane cleavage of the βamyloid precursor protein (APP) during the neuronal production of the amyloid β-peptide (Aβ). As such, the protease has emerged as a key target for developing agents to treat and prevent Alzheimer's disease. Existing biochemical studies conflict on the oligomeric assembly state of the protease complex, and its detailed structure is not known. Here, we report that purified active human γsecretase in digitonin has a total molecular mass of ~230 kDa when measured by scanning transmission electron microscopy. This result supports a complex that is monomeric for each of the four component proteins. We further report the 3-dimensional structure of the γ-secretase complex at 12 Å resolution, as obtained by cryo-EM and single particle image reconstruction. The structure reveals several domains on the extracellular side, three solvent-accessible low-density cavities and a potential substrate-binding surface groove in the transmembrane region of the complex.

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