Calcium Induces Binding and Formation of a Spin-Coupled Dimanganese(II,II) Center in the Apo-Water Oxidation Complex of Photosystem II as Precursor to the Functional Tetra-Mn/Ca Cluster

Abstract

Two new intermediates are described which form in the dark as precursors to the light-induced assembly of the photosynthetic water oxidation complex (WOC) from the inorganic components. Mn²⁺ binds to the apo-WOC−PSII protein in the absence of calcium at a high-affinity site. By using a hydrophobic chelator to remove Mn²⁺ and Ca²⁺ from the WOC and nonspecific Fe³⁺, a new EPR signal becomes visible upon binding of Mn²⁺ to this site, characterized by six-line ⁵⁵Mn hyperfine structure (ΔH_pp = 96 ± 1 G) and effective g = 8.3. These features indicate a high-spin electronic ground state (S = ⁵/₂) for Mn²⁺ and a strong ligand field with large anisotropy. This signal is eliminated if excess Ca²⁺ or Mg²⁺ is present. A second Mn²⁺ EPR signal forms in place of this signal upon addition of Ca²⁺ in the dark. The yield of this Ca-induced Mn signal is optimum at a ratio of 2 Mn/PSII, and saturates with increasing [Ca²⁺] ≥ 8 mM, exhibiting a calcium dissociation constant of K_D = 1.4 mM. The EPR signal of the Ca-induced Mn center at 25 K is asymmetric with major g value of ≈2.04 (ΔH_pp = 380 G) and a shoulder near g ≈ 3.1. It also exhibits resolved ⁵⁵Mn hyperfine splitting with separation ΔH_pp = 42−45 G. These spectral features are diagnostic of a variety of weakly interacting Mn₂(II,II) pairs with electronic spins that are magnetic dipolar coupled in the range of intermanganese separations 4.1 ± 0.4 Å, and commonly associated with one or two carboxylate bridges. The calcium requirement for induction of the Mn₂(II,II) signal matches the value observed for steady-state O₂ evolution (Michaelis constant, K_M ≈ 1.4 mM), and for light-induced assembly of the WOC by photoactivation. The Ca-induced Mn₂(II,II) center is a more efficient electron donor to the photooxidized tyrosine radical, Tyr_Z⁺, than is the mononuclear Mn center present in the absence of Ca²⁺. The Ca-induced Mn₂(II,II) signal serves as a precursor for photoactivation of the functional WOC and is abolished by the presence of Mg²⁺. Formation of the Mn₂(II,II) EPR signal by addition of Ca²⁺ correlates with reduction of flash-induced catalase activity, indicating that calcium modulates the accessibility or reactivity of the Mn₂(II,II) core with H₂O₂. We propose that calcium organizes the binding site for Mn ions in the apo-WOC protein and may even interact directly with the Mn₂(II,II) pair via solvent or protein-derived bridging ligands.