EPR spectroscopy and isotopic substitution were used to gain increased knowledge about the proton-coupled electron transfer (PCET) mechanism for the reduction of the tyrosine D radical (YD*) in photosystem II. pL dependence (where pL is either pH or pD) of both the rate constant and kinetic isotope effect (KIE) was examined for YD* reduction. Second, the manner in which protons are transferred during the rate-limiting step for YD* reduction at alkaline pL was determined. Finally, high field electron paramagnetic resonance (EPR) spectroscopy was used to study the effect of pH on the environment surrounding both the tyrosine D radical and the tyrosine Z radical (YZ*).
At alkaline pL, it was determined that the proton and electron are both transferred in the rate-limiting step of YD* reduction. At acidic pL, the proton transfer occurs first followed by electron transfer. Proton inventory experiments indicate that there is more than one proton donation pathway available to YD* during PCET reduction at alkaline pL. Additionally, the proton inventory experiments indicate that at least one of those pathways is multiproton. High field EPR experiments indicate that both YD* and YZ* are hydrogen bonded to neutral species. The EPR gx component for YD* is invariant with respect to pH. Analysis of the EPR gx component for Yz* indicates that its environment becomes more electropositive as the pH is increased. This is most likely due to changes in the hydrogen bond strengthPh.D.Committee Chair: Bridgette Barry; Committee Member: Ingeborg Schmidt-Krey; Committee Member: Jake Soper; Committee Member: Nils Kroger; Committee Member: Wendy Kell
