Proximity of Acetate, Manganese, and Exchangeable Deuterons to Tyrosine YZ• in Acetate-Inhibited Photosystem II Membranes: Implications for the Direct Involvement of YZ• in Water-Splitting

Abstract

The environment of the photosystem II YZ. radical, trapped in the "split-signal" form, is examined in acetate-treated PSII membranes using pulsed EPR methods. The split-signal line shape is simulated with dipolar and exchange couplings to the Mn cluster of 1260 and -28 MHz, respectively. The 1260-MHz dipolar coupling corresponds to a Mn-YZ. distance of 3.5 A in the point dipole limit. A 0.117-MHz dipolar coupling is observed between nonexchangeable deuterons of methyl-deuterated acetate and YZ.. This interaction is modeled with a 3.1-A distance between an acetate methyl group deuteron and the phenoxy oxygen of YZ*. Since acetate inhibition is competitive with Cl-, this result strongly suggests a close proximity between YZ. and the Cl- cofactor binding site. Analysis of pulsed ENDOR and ESEEM experiments investigating the proximity of deuterons exchanged into the vicinity of YZ. after incubation in 2H2O-enriched buffer demonstrates that YZ. trapped in the split-signal form participates in two hydrogen-bonding interactions, in contrast to YD*, which forms a single hydrogen bond. This result is inconsistent with a simple electron transfer role for YZ* and provides direct experimental evidence for a role for YZ* in proton or hydrogen atom transfer.