J. Tso scite author profile

EPR studies have revealed that removal of calcium using citric acid from the site in spinach photosystem II which is coupled to the photosynthetic O2-evolving process produces a structural change in the manganese cluster responsible for water oxidation. If done in the dark, this yields a modified S1' oxidation state which can be photooxidized above 250 K to form a structurally altered S2' state, as seen by formation of a "modified" multiline EPR signal. Compared to the "normal" S2 state, this new S2'-state EPR signal has more lines (at least 25) and 25% narrower 55Mn hyperfine splittings, indicative of disruption of the ligands to manganese. The calcium-depleted S2' oxidation state is greatly stabilized compared to the native S2 oxidation state, as seen by a large increase in the lifetime of the S2' EPR signal. Calcium reconstitution results in the reduction of the oxidized tyrosine residue 161YD+ (Em approximately 0.7-0.8 V, NHE) within the reaction center D1 protein in both the S1' and S2' states, as monitored by its EPR signal intensity. We attribute this to reduction by Mn. Thus a possible structural role which calcium plays is to bring YD+ into redox equilibrium with the Mn cluster. Photooxidation of S2' above 250 K produces a higher S state (S3 or S4) having a new EPR signal at g = 2.004 +/- 0.003 and a symmetric line width of 163 +/- 3 G, suggestive of oxidation of an organic donor, possibly an amino acid, in magnetic contact with the Mn cluster. This EPR signal forms in a stoichiometry of 1-2 relative to YD+.(ABSTRACT TRUNCATED AT 250 WORDS)

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Calcium limits substrate accessibility or reactivity at the manganese cluster in photosynthetic water oxidation

Tso¹,

Sivaraja²,

Dismukes³

1991

Biochemistry

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The structural changes which the tetramanganese cluster responsible for catalyzing photosynthetic water oxidation undergoes upon calcium depletion of photosystem II membranes via the citrate extraction method has been further characterized. The modified multiline EPR signal which forms has been further identified with an S2' oxidation state. The increased number of hyperfine lines (at least 26) and 25% narrower hyperfine splittings from 55Mn versus the normal S2-state signal indicate a redistribution of spin density, most likely within a spin-coupled tetranuclear Mn cluster. A simpler binuclear Mn description for this signal can be eliminated. Slow conformational changes occur over 30 min which cause subtle changes in the hyperfine structure. Comparison to the modified multiline signals produced by Sr2+ replacement of Ca2+ and NH3-treated PSII reveal similarities suggestive of formation of the same spin S = 1/2 state. Substrate accessibility in the dark S1' state, measured as Mn2+ release upon incubation with NH2OH, is increased by 10-fold over calcium-containing PSII centers. Diphenylcarbazide, an efficient electron donor to Tyr-Z+ only in PSII membranes in which Mn is removed or dislocated, was found to donate electrons in Ca(2+)-depleted PSII, indicating altered accessibility or reactivity. These results suggest a possible "gatekeeper" role for Ca2+ in limiting access of substrate water to the Mn cluster. These changes are not due to release of the three extrinsic polypeptides of PSII which remain bound. Citrate treatment also causes partial air oxidation of the reaction-center Fe2+ ion, associated with the quinone electron acceptors. The resulting Fe3+ possesses an EPR signal at g = 4.37 arising from conversion to a rhombic symmetry ligand field.

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Distonic oxonium and ammonium radical cations. A neutralization-reionization and collisional activation study

Wesdemiotis¹,

Danis²,

Ren³

et al. 1985

J. Am. Chem. Soc.

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Calcium depletion from the photosynthetic water-oxidizing complex reveals photooxidation of a protein residue

Tso¹,

Sivaraja²,

Philo³

et al. 1991

Biochemistry

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A new intermediate in the water-oxidizing reaction has been observed in spinach photosystem II (PSII) membranes that are depleted of Ca2+ from the site which is conformationally coupled to the manganese cluster comprising the water-oxidizing complex (WOC). It gives rise to a recently identified EPR signal (symmetric line shape with width 163 +/- 5 G, g = 2.004 +/- 0.005), which forms in samples inhibited either by depletion of Ca2+ [Boussac, A., Zimmerman, J.-L., & 28, 8984-8989; Sivaraja, M., Tso, J., & Dismukes, G.C. (1989) Biochemistry 28 9459-9464] or by substitution of Cl- by F- (Baumgarten, Philo, and Dismukes, submitted for publication). Further characterization of this EPR signal has revealed the following: (1) it forms independently of the local structure of the PSII acceptors; (2) it arises from photooxidation of a PSII species that donates an electron to Tyr-Z+ or to the Mn cluster in competition with an exogenous donor (DPC); (3) the Curie temperature dependence of the intensity suggests an isolated doublet ground state, attributable to a spin S = 1/2 radical; (4) the electron spin orientation relaxes 1000-fold more rapidly than typical for a free radical, exhibiting a strong temperature dependence of P1/2 (half-saturation power approximately T3.4) and a broad inhomogeneous line width; (5) it yields an undetectable change in the magnetic susceptibility upon formation by a laser flash; (6) it disappears in parallel with release of Mn during reduction with NH2OH, indicating that it forms only in the presence of the modified Mn cluster. (ABSTRACT TRUNCATED AT 250 WORDS)

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A new mechanism-based inhibitor of photosynthetic water oxidation: acetone hydrazone. 1. Equilibrium reactions

Tso¹,

Petrouleas²,

Dismukes³

1990

Biochemistry

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The process of photosynthetic water oxidation has been investigated by using a new type of water oxidation inhibitor, the alkyl hydrazones. Acetone hydrazone (AceH), (CH3)2CNNH2, inhibits water oxidation by a mechanism that is analogous to that of NH2OH. This involves binding to the water-oxidizing complex (WOC), followed by photoreversible reduction of manganese (loss of the S1----S2 reaction). At higher AceH concentrations the S1 state is reduced in the dark and Mn is released, albeit to a lesser extent than with NH2OH. Following extraction of Mn, AceH is able to donate electrons rapidly to the reaction center tyrosine radical Z+ (161Tyr-D1 protein), more slowly to a reaction center radical C+, and not at all to the dark-stable tyrosine radical D+ (160Tyr-D2 protein) which must be sequestered in an inaccessible site. Manganese, Z+, and C+ thus appear to be located in a common protein domain, with Mn being the first accessible donor, followed by Z+ and then C+. Photooxidation of Cyt b-559 is suppressed by AceH, indicating either reduction or competition for donation to P680+. Unexpectedly, Cl- was found not to interfere or compete with AceH for binding to the WOC in the S1 state, in contrast to the reported rate of binding of N,N-dimethylhydroxylamine, (CH3)2NOH [Beck, W., & Brudvig, G. (1988) J. Am. Chem. Soc. 110, 1517-1523]. We interpret the latter behavior as due to ionic screening of the thylakoid membrane, rather than a specific Cl- site involved in water oxidation.(ABSTRACT TRUNCATED AT 250 WORDS)

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J. Tso

A calcium-specific site influences the structure and activity of the manganese cluster responsible for photosynthetic water oxidation

Calcium limits substrate accessibility or reactivity at the manganese cluster in photosynthetic water oxidation

Distonic oxonium and ammonium radical cations. A neutralization-reionization and collisional activation study

Calcium depletion from the photosynthetic water-oxidizing complex reveals photooxidation of a protein residue

A new mechanism-based inhibitor of photosynthetic water oxidation: acetone hydrazone. 1. Equilibrium reactions

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