Abstract
The kinetics of pulsed-light photoactivation, the light-induced reassembly of the water-oxidizing complex (WOC) of PSII in the presence of essential inorganic cofactors, has been studied using two improvements: a new efficient chelator, N,N,N',N'-tetrapropionato-1,3-bis(aminomethyl)benzene (TPDBA), for complete extraction of {Mn4} and Ca2+ and an ultrasensitive polarographic cell for O2 detection [Ananyev, G.M., & Dismukes, G.C. (1996) Biochemistry 35, 4102-4109]. Measurements have been made of the initial half-time, t1/2 (sum of the lag time for formation of the first intermediate, IM1, plus the half-time for formation of the second intermediate, IM2), and the steady-state yield, Yss, for recovery of O2 evolution (proportional to the number of active centers). The following conclusions have been reached: (1) cations (Ca2+, Mg2+, and Na+) slow the rate of photoactivation, even though Ca2+ is essential for activity. Two distinct mechanisms appear to be involved: binding to one or both of the first two Mn(2+)-specific sites and screening of negative charges on apo-WOC that are responsible for concentrating Mn2+ ions by electrostatic steering; (2) the Michaelis constant for the calcium requirement for Yss at sufficiently low Mn2+ concentrations (8 microM) that competition at the calcium site does not occur is K(m) = 1.4 mM. Numerically, K(m) is the same for reactivation of O2 evolution in Ca-depleted PSII membranes which retain four Mn ions; (3) in the absence of Ca2+ but in the presence of saturating amounts of Mn2+ (8 Mn/apo-WOC) and Cl-(35 mM) assembly of a stable tetra-Mn cluster occurs neither under illumination nor in the dark after subsequent addition of CaCl2. However, in the presence of suboptimal concentrations of calcium required for maximum Yss, calcium-dependent assembly of stable yet inactive clusters occurs in the light; (4) protons in equilibrium with the buffer greatly increase the half-time 3-fold between pH 6.75 and 5.4, indicating ionization of one or more protons from the first photo-oxidized intermediate formed prior to the rate-limiting step (photo-oxidation of the second Mn2+); (5) the lipophilic membrane soluble anion tetraphenylboron (TPB-), a known reductant of intact WOC, increases the half-time 2.5-fold (< or = 40 microM) and paradoxically stimulates Yss by 50% at 20 microM concentration. These results suggest that TPB- increases the local concentration of Mn2+ adjacent to apo-WOC (Yss increase), while also reducing the S2 and S3 states of the intact WOC at higher concentrations (t1/2 increase). The effects of anions and cations indicates that overcoming the surface potential of the membrane/protein PSII complex may play an important role in the kinetics of reassembly of the {Mn4} cluster; (6) the ratio Y4/Y3 in the kinetics of O2 evolution from a series of single-turnover flashes, a ratio that typically reflects the probability of misses (alpha), grows noticeably larger with increasing extent of recovery of O2 evolving activity and also with increase in the amount of Mn2+, indicating competition between substrate water and excess Mn2+ for reduction of the functional {Mn4} cluster. On the basis of these results, we extend the model for photoactivation to include the antagonistic effects of H+ and Ca2+ in the formation of the first two intermediates.
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