The use of two complementary techniques-based on a chromophore-labeled subs
trate and a fluorescently labeled enzyme-have provided a self-consistent pi
cture of the role of soil in protecting amylase from deactivation by a pero
xygen bleach. Amylase in solution is completely deactivated by the peracid
N,N-phthaloylaminoperoxycaproic acid (PAP) via a mechanism which consists o
f a rapid initial step followed by a much slower second step. Over 80% of t
he enzyme activity is lost, under the conditions of the experiment, within
10 min of exposure to PAP. Amylase achieves steady state adsorption on to g
ranular potato starch within a period of about 5 min. On retrograded starch
films, this state is apparently reached within 60 s. The physical state of
the substrate associated amylase is one of adsorption, with the enzyme not
entering the soil matrix on the time scale of our experiments. Once adsorb
ed, amylase is partially protected against the effects of a peroxygen bleac
h due to the apparent inaccessibility of the active site coupled with the f
act that a fraction of the adsorbed enzyme is resistant (on the time scale
of our experiment) to being rinsed off by solvent. This fraction of enzyme
is sensibly invariant with respect to adsorption time or adsorption level a
nd is thought to be controlled by the heterogeneous nature of the substrate
/amylase interaction.