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(Received for publication, March 1, 1996)
From the Department of Biochemistry and Molecular Biology,
University of Florida, Gainesville, Florida 32610-0245
To obtain a recombinant model of human cathepsin
D with kinetic properties that are identical with native human liver
enzyme, we have addressed the significant differences in structure and
catalytic function between naturally occurring enzyme and bacterially
derived pseudocathepsin D. Human procathepsin D was expressed in
a baculovirus system to obtain correctly folded, glycosylated enzyme
that upon acidification completely converts to the active intermediate,
pseudocathepsin D. The oligosaccharide moieties of this recombinant
enzyme contributed to about 5% of the apparent molecular mass of the
enzyme, and the carbohydrate composition was quite similar to the
native material. However, specificity constants
(kcat/Km) of this
glycosylated pseudoform for several synthetic chromogenic substrates
were considerably less (33%-50%) than those for the native
enzyme and were virtually identical with those observed with
nonglycosylated pseudocathepsin D.
A cleavable junction suitable for self-processing at the normal
maturation point of human cathepsin D was engineered into procathepsin
D according to known specificity requirements of this enzyme, and the
construct was expressed using baculovirus. Following experiments that
demonstrated that the new proenzyme failed to process to the expected
point, the new cleavage junction was moved 6 residues toward the amino
terminus of procathepsin D and expressed in Escherichia
coli. After refolding, the protein containing the newly
engineered junction self-processed, generating a shortened mutant form
of pseudocathepsin D that is 6 residues longer at the amino terminus
than the native material. The kinetic properties of this newly
engineered pseudoform proved to be identical with those of the native
enzyme, thus establishing an improved recombinant model for this
important aspartic proteinase.
Volume 271, Number 26,
Issue of June 28, 1996
pp. 15590-15596
©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
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