Photoproduction and Detoxification of Hydroxyl radicals in Chloroplasts and Leaves and Relation to Photoinactivation of Photosystems I and II

The light-dependent production of hydroxyl radicals (HO{dot})by thylakoids, chloroplasts and leaves of Spinacia oleraceawas investigated using dimethylsulfoxide as HO{dot} trappingagent. Maximum rates of HO{dot} production by thylakoids asindicated by the formation of methane sulfinic acid were observedunder aerobic conditions in the absence of added electron acceptors.They were higher than 2 µmol (mg Chl h)^–1. Saturationof HO{dot} production occurred at the low photon flux densityof 100 µmol m^–2 s^–1. Trapping of HO{dot} bydimethylsulfoxide suppressed, but did not eliminate light-dependentinactivation of PSI and II suggesting that HO{dot} formationcontributed to the photosensitivity of isolated thylakoids.DCMU inhibited HO{dot} formation. Importantly, methylviologendecreased HO{dot} formation in the absence, but stimulated itin the presence of Fe³⁺. In intact chloroplasts, HO{dot} formation became appreciableonly after KCN had been added to inhibit effective H₂O₂ scavengingby ascorbate peroxidase. It was stimulated by ferrisulfate,but not by ferricyanide which does not penetrate the chloroplastenvelope. Infiltrated spinach leaves behaved similar in principleto intact chloroplasts in regard to HO{dot} formation but HO{dot}production was very slow if detectable at all by the formationof methylsulfinic acid indicating effective radical detoxification. HO{dot} formation is interpreted to be the result of a Fenton-typereaction which produces HO{dot} in chloroplasts from H₂O₂ andreduced ferredoxin, when O₂ is electron acceptor in the Mehlerreaction and radical detoxification reactions are inhibited. (Received November 13, 1996; Accepted April 23, 1996)