Yeast growth selection system for the identification of cell-active inhibitors of beta-secretase.

Abeta peptides, which are believed to be at the origin of Alzheimer's disease (AD), are produced through the sequential processing of the transmembrane amyloid precursor protein (APP) by the beta- and gamma-secretase. The identification of small molecules that penetrate the brain and inhibit these secretases is of great therapeutic potential. Here, we describe a cellular selection system in yeast for the identification of inhibitors of the human beta-secretase BACE-1. Similar to the natural situation in mammalian cells, BACE-1 and its substrate APP are bound to membranes in secretory pathway compartments. Yeast cells expressing these human proteins have been engineered so as to grow under selective conditions only upon reduction of BACE-1 activity, thus allowing identification of compounds that, in addition to inhibiting BACE-1, must permeate cellular membranes and present no cytotoxic effects. Our results show that gradual reduction of BACE-1 expression in the engineered yeast strain resulted in gradual increase of cell growth rate. Moreover, two validated BACE-1 inhibitors, which have IC50 values between 7 and 8 microM in mammalian cell assays, stimulated yeast growth in a concentration-dependent manner. This effect was specific for BACE-1 since these compounds had no effect on yeast cells expressing a different secretase cleaving the APP substrate at the alpha-site. The target-specific cellular assay presented here is applicable in high-throughput screens for selecting inhibitors of defined secretases acting on natural substrates in a membrane-bound protein configuration.

Searching for the most effective screening system to identify cell-active inhibitors of beta-secretase.

The beta-secretase BACE1 is an attractive drug target for reducing the level of the Alzheimer's disease-promoting Abeta peptide in the brain. Whereas potent peptidomimetic in vitro inhibitors of BACE1 have been designed, screening approaches to identify cell-permeable small molecule inhibitors have had limited success so far. In the present minireview we summarize existing screening methods, discuss their scope of application in the drug discovery process and compare them to a novel cell-based screening system to identify BACE1 inhibitors by a positive yeast growth selection.

Human beta-secretase activity in yeast detected by a novel cellular growth selection system.

Sequential processing of the transmembrane amyloid precursor protein (APP) by the beta-secretase BACE and by the gamma-secretase causes secretion of Abeta peptides. Extracellular aggregation of these peptides in the brain is a major hallmark of Alzheimer's disease. For therapeutic purposes and the development of specific inhibitors, it is important to characterize these secretases. We have established a cellular growth selection system for functional expression of human BACE in the yeast Saccharomyces cerevisiae. A fragment of APP bearing the beta-site, the transmembrane domain and the cytosolic tail was fused to the C-terminus of the yeast enzyme invertase, which is normally secreted to allow cell growth in the presence of sucrose as the sole carbon source. The resulting invertase-APP fusion protein was expressed as a type-I transmembrane protein in intracellular compartments of yeast cells lacking endogenous invertase. In these cells, co-expression of human BACE restored cell growth on selective plates upon cleavage of the invertase-APP fusion protein. The cellular growth selection system presented here can be generally applied to screen for secretases that specifically cleave membrane-bound substrates. Furthermore, this system provides the basis for a high-throughput screen for identifying secretase inhibitors that are active in eukaryotic cells.