Abstract
Proteolysis within the membrane is catalyzed by a diverse family of proteases immersed within the hydrophobic environment of cellular membranes. These ubiquitous intramembrane-cleaving proteases (I-CLiPs) hydrolyze the transmembrane domains of a large variety of membrane-embedded proteins to facilitate signaling events essential to normal biological functions found in all forms of life. The importance of this unique class of enzyme is highlighted by its central involvement in a variety of human pathologies, including Alzheimer's disease (AD), Parkinson's disease, cancer, and the virulence of a number of viral, bacterial, and fungal pathogens. I-CLiPs therefore represent promising targets for the therapeutic treatment of numerous diseases. The key to understanding the normal biological function of I-CLiPs and capitalizing on their therapeutic potential is through a thorough understanding of the complex catalytic mechanisms that govern this unusual class of enzyme. This is an intrinsically difficult endeavor, given that these enzymes and their substrates reside within lipid membranes, making any in vitro assay technically challenging to design and execute. Here, we describe several in vitro enzymatic assays for the study of the AD-associated γ-secretase protease, which have aided the development of potent γ-secretase-targeting compounds as candidate therapeutics. These assays have also been applied in various forms for the study of other I-CLiPs, providing valuable mechanistic insights into some of the functional similarities and differences between several members of this fascinating family of proteases.