Characterization of β-amyloid peptide precursor processing by the yeast Yap3 and Mkc7 proteases

摘要

Two proteases, denoted β- and γ-secretase, process the β-amyloid peptide precursor (APP) to yield the Aβ peptides involved in Alzheimer's disease. A third protein, α-secretase, cleaves APP near the middle of the Aβ sequence and thus prevents Aβ formation. These enzymes have defied identification. Because of its similarity to the systems of mammalian cells the yeast secretory system has provided important clues for finding mammalian processing enzymes. When expressed in Saccharomyces cerevisiae APP is processed by enzymes that possess the specificity of the α-secretases of multicellular organisms. APP processing by α-secretases occurred in sec1 and sec7 mutants, in which transport to the cell surface or to the vacuole is blocked, but not in sec17 or sec18 mutants, in which transport from the endoplasmic reticulum to the Golgi is blocked. Neutralization of the vacuole by NH4Cl did not block α-secretase action. The time course of processing of a pro-α-factor leader-APP chimera showed that processing by Kex2 protease, a Golgi protease that removes the leader, preceded processing by α-secretase. Deletions of the genes encoding the GPI-linked aspartyl proteases Yap3 and Mkc7 decreased α-secretase activity by 56 and 29%, respectively; whereas, the double deletion decreased the activity by 86%. An altered form of APP-695, in which glutamine replaced Lys-612 at the cleavage site, is cleaved by Yap3 at 5% the rate of the wild-type APP. Mkc7 protease cleaved APP (K612Q) at about 20% the rate of wild-type APP. The simplest interpretation of these results is that Yap3 and Mkc7 proteases are α-secretases which act on APP in the late Golgi. They suggest that GPI-linked aspartyl proteases should be investigated as candidate secretases in mammalian tissues.