Kinetic analysis of the induction period in lipoxygenase catalysis
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Publication date
1993
Authors
Vliegenthart, J.F.G.
Schilstra, M.J.
Veldink, G.A.
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Abstract
The dioxygenation of 50 mu M linoleate at 0.1 mu M (13s)-hydroperoxylinoleate, 240 mu M 02, pH
10, and 25 O C , catalyzed by varying amounts of soybean lipoxygenase-1, was studied with rapid kinetic
techniques. The aim was to assess the effect of transient redistributions of the Fe(I1) and Fe(II1) enzyme
forms on the shape of the reaction progress curves. Reactions initiated with iron(I1) lipoxygenase show
an initial increase in rate, the kinetic lag phase or induction period. The duration of this induction
period varies from approximately 1 s at [lipoxygenase] > 20 nM to 5 s at [lipoxygenase] = 3 nM. At
[lipoxygenase] < 2 nM, the duration of the induction period in these curves is inversely proportional to
[lipoxygenase]. The integrated steady-state rate equation for the single fatty acid binding site model of
lipoxygenase catalysis [Schilstra et al. (1992) Biochemistry 31,7692-76991 also shows an induction period
whose duration is inversely proportional to [lipoxygenase]. These observations, in combination with nonsteady-
state numerical simulations, lead to the conclusion that, at [lipoxygenase] < 2 nM, pre-steady-state
redistributions of enzyme intermediates occur fast with respect to the rate at which the concentrations of
substrates and products change. At higher lipoxygenase concentrations, the pre-steady-state redistributions
contribute significantly to the induction period. From a nonlinear least-squares fit to the steady-state rate
equation of data obtained at lipoxygenase concentrations of 0.5 and 1 nM, it was calculated that 1% of the
linoleate radicals that are formed after hydrogen abstraction dissociate from the active site before enzymic
oxygen insertion has occurred.