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Vol. 59, Issue 3, 619-626, March 2001
-Secretase from an
Insect Cell Expression System
Department of Pharmacology, Mayo Foundation for Medical Education
and Research, and the Department of Research, Mayo Clinic Jacksonville,
Jacksonville, Florida (W.D.M., D.Y., L.O., M.R.N., C.E., K.S., T.L.R.);
and Department of Chemical Enzymology, The DuPont Pharmaceuticals
Company, Wilmington, Delaware (L.M.K., J.M., R.A.C.)
The 
-site amyloid precursor protein-cleaving enzyme (BACE) cleaves
the amyloid precursor protein to produce the N terminus of the amyloid
peptide, a major component of the plaques found in the brains of
Alzheimer's disease patients. Sequence analysis of BACE indicates that
the protein contains the consensus sequences found in most known
aspartyl proteases, but otherwise has only modest homology with
aspartyl proteases of known three-dimensional structure (i.e., pepsin,
renin, or cathepsin D). Because BACE has been shown to be one of the
two proteolytic activities responsible for the production of the A
peptide, this enzyme is a prime target for the design of therapeutic
agents aimed at reducing A for the treatment of Alzheimer's
disease. Toward this ultimate goal, we have expressed a recombinant,
truncated human BACE in a Drosophila melanogaster
S2 cell expression system to generate high levels of secreted BACE
protein. The protein was convenient to purify and was enzymatically
active and specific for cleaving the -secretase site of human APP,
as demonstrated with soluble APP as the substrate in novel sandwich
enzyme-linked immunosorbent assay and Western blot assays. Further
kinetic analysis revealed no catalytic differences between this
recombinant, secreted BACE, and brain BACE. Both showed a strong
preference for substrates that contained the Swedish mutation, where NL
is substituted for KM immediately upstream of the cleavage site,
relative to the wild-type sequence, and both showed the same extent of
inhibition by a peptide-based inhibitor. The capability to produce
large quantities of BACE enzyme will facilitate protein structure
determination and inhibitor development efforts that may lead to the
evolution of useful Alzheimer's disease treatments.
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