BACE/APPV717F double-transgenic mice develop cerebral amyloidosis and inflammation.

Most of the transgenic mice generated to model Alzheimer's disease express human amyloid precursor protein (APP) mutants alone or in conjunction with presenilin mutants. We have generated a mouse model by overexpressing human BACE and human APP with the V717F mutation. The combination of a mutation at the gamma-secretase cleavage site of APP and of increased beta-secretase activity should favour the production of amyloid peptides. We analysed double BACE/APPIn and single APPIn transgenic mice at 16-18 months for amyloid load, brain histopathology and behavioural deficits. We show that overexpression of BACE induces an increase in APP CTFbeta and total brain Abeta peptides. Brain histopathology shows clearly enhanced amyloid deposits in the cortex, hippocampus and in brain vasculature when compared to single APPIn transgenic mice. Amyloid deposits are mostly diffuse and predominantly composed of Abeta(42). A strong inflammatory reaction is evidenced by the presence of microglial cells around the most mature amyloid deposits and astrocytosis over the entire cerebral cortex. At the same age, the APPIn single-transgenic mice show only very limited pathology. When assessed for their cognitive performance at 12 months, BACE/APPIn mice show impaired spatial acquisition in the Morris water maze test. However, these deficits are not greater than those observed in the APPIn single-transgenic animals.

Substrate and inhibitor profile of BACE (beta-secretase) and comparison with other mammalian aspartic proteases.

The full-length and ectodomain forms of beta-site APP cleavage enzyme (BACE) have been cloned, expressed in Sf9 cells, and purified to homogeneity. This aspartic protease cleaves the amyloid precursor protein at the beta-secretase site, a critical step in the Alzheimer's disease pathogenesis. Comparison of BACE to other aspartic proteases such as cathepsin D and E, napsin A, pepsin, and renin revealed little similarity with respect to the substrate preference and inhibitor profile. On the other hand, these parameters are all very similar for the homologous enzyme BACE2. Based on a collection of decameric substrates, it was found that BACE has a loose substrate specificity and that the substrate recognition site in BACE extends over several amino acids. In common with the aspartic proteases mentioned above, BACE prefers a leucine residue at position P1. Unlike cathepsin D etc., BACE accepts polar or acidic residues at positions P2'0 and P1 but prefers bulky hydrophobic residues at position P3. BACE displays poor kinetic constants toward its known substrates (wild-type substrate, SEVKM/DAEFR, K(m) = 7 microm, K(cat) = 0.002 s(-1); Swedish mutant, SEVNL/DAEFR, K(m) = 9 microm, K(cat) = 0.02 s(-1)). A new substrate (VVEVDA/AVTP, K(m) = 1 microm, K(cat) = 0.004) was identified by serendipity.