The redox-controlled light-harvesting chlorophyll a/b protein kinase. Deactivation by substituted quinones.

D Frid,A Gal,W Oettmeier,G Hauska,S Berger,I Ohad

doi:10.1016/s0021-9258(18)35694-1

D Frid, A Gal + Show 4 more

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https://doi.org/10.1016/s0021-9258(18)35694-1

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Abstract

The deactivation of the redox-controlled light-harvesting chlorophyll a/b protein kinase of Acetabularia acetabulum and pea thylakoids was studied. Substituted benzoquinone, naphthoquinone, and anthraquinone analogs including mono-, di-, and trihalogenated and/or alkylated quinones, which are known to inhibit the cytochrome b6/f activity, deactivate the kinase in the dark, and prevent its activation in the light. Analogs halogenated at positions 2- or 3- are the most effective deactivators. Increasing the size of the alkyl side chain and/or the number of rings lowers the deactivation effect. The activated state of the pea kinase decays with a t1/2 of 15 min, while the Acetabularia enzyme retains its active state for at least 2 h. The midpoint potential for Acetabularia kinase activity in the dark is 120 +/- 10 mV and is compatible with the involvement of plastoquinone in the kinase activation via reduction of the cytochrome complex. Deactivation of kinase by the analogs inhibiting cytochrome b6/f complex activity and the kinase copurification with the cytochrome b6/f fraction obtained from the Acetabularia thylakoid further support this conclusion. These results indicate that the process of kinase activation/deactivation includes the binding of plastoquinol or quinone analogs by the cytochrome complex and its interaction with the kinase. We propose that the latter process may constitute the rate-limiting step controlling the kinase activation/deactivation kinetics.

Highlights

From the Department of Biological Chemistry, The Hebrew University, Jerusalem 91904, Israel, the $Department of Plant Biochemistv, Ruhr Uniuersity, Bochum 0-4630, Germany, the $Department of Botany, University of Regensburg, Regensburg, 0-8400, Germany, and the ITMax-PlanckInstitute for Cell Biology, Ladenburg near Heidelberg 0-6802, Germany
Experimentalresultsobtained withcytochrome b6/f-less mutants of both algae (3, 4) and higher plants (5-7) as well as by use of specific inhibitors of cytochrome b6/f complex reduction in vitro (7-9) indicate that the plastoquinol pool itself is not the sole mediator involved in the LHCII kinase activation
Itwas reported thaitsolated LHCII kinase system can exhibit redox control in vitro (10). Using this experimenthe cytochrome be/ffraction obtained from the Aceta- talsystem,it was possible to demonstrate that a putative bularia thylakoid further support this conclusion. These results indicate that the process of kinase activation/deactivation includes the binding of plastoquinol or quinone analogs by the cytochrome complex and its interaction with the kinase

Summary

RESULTS

Stability of LHCII Kinase-activated State-The thylakoidbound LHCII kinase can be reversibly activated by redox reagents such as plastoquinol or duroquinol (15, 30, 31). Effect of Quinone Analogs on Deactivation of LHCII Kinase deactivation of the Acetabularia enzyme was measured. LHCII kinase activation aswell, Information on the propertiesof the binding site involved in the activation/deactivation process could be obtained by assaying theeffect of various substituted quinoneanalogs on the enzyme deactivation in the dark. Under these conditions the quinone analogs may not compete for the binding site with the plastoquinol pool reduced via light-driven photosystem I1 electron flow. Mg” incorporated into the 27-kDaLHCIIpolypeptide in the dark The kinase deactivation is not related to the quinone bindand light, respectively

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DISCUSSION

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