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(Received for publication, August 17,
1995; and in revised form, September 29, 1995) The herpes simplex virus type 1 protease is expressed as an
80,000-dalton polypeptide, encoded within the 635-amino acid open
reading frame of the UL26 gene. The two known protein substrates for
this enzyme are the protease itself and the capsid assembly protein
ICP35 (Liu, F., and Roizman, B.(1991) J. Virol. 65,
5149-5156). In this report we describe the use of a rapid and
quantitative assay for characterizing the protease. The assay uses a
glutathione S-transferase fusion protein containing the
COOH-terminal cleavage site of ICP35 as the substrate (GST-56). The
protease consists of N
Volume 270,
Number 50,
Issue of December 15, 1995 pp. 30168-30172
©1995 by The American Society for Biochemistry and Molecular Biology, Inc.
, the NH
-terminal 247
amino acid catalytic domain of the UL26 gene product, also expressed as
a GST fusion protein. Upon cleavage with N, a single 25-mer
peptide is released from GST-56, which is soluble in trichloroacetic
acid. Using this assay, the protease displayed a pH optimum between 7
and 9 but most importantly had an absolute requirement for high
concentrations of an antichaeotrophic agent. Strong salting out salts
such as NaSO
and KPO (
1 M) stimulated activity, whereas NaCl and KCl had no effect.
The degree of stimulation by 1.25 M NaSO and KPO were 100-150- and 200-300-fold,
respectively. Using the fluorescent probe 1-anilino-8-naphthalene
sulfonate, the protease was shown to bind the dye in the presence of
1.25 M NaSO or KPO, but
not at low ionic strength or in the presence of 1.25 or 2.2 M NaCl. This binding was most likely at the protease active site
because a high affinity cleavage site peptide, but not a control
peptide, could displace the dye. In addition to cleaving GST-56, the
herpes simplex virus type I protease also cleaved the purified 56-mer
peptide. Circular dichroism and NMR spectroscopy showed the peptide to
be primarily random coil under physiological conditions, suggesting
that antichaeotrophic agents affect the conformation of the substrate
as well as the protease.
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