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“Introduction Plants need light to be able to perform photosynthesis. At the level of individual cells, the light intensity varies in an unpredictable manner. Leaves can adjust to changes in light intensity in various ways. However,
ML323 in vitro when plants are exposed to irradiances that are much higher than those they are adapted to, they use mechanisms to dissipate the excess energy (Prásil et al. 1992; Van Rensen and Curwiel 2000; Tyystjärvi 2008; Takahashi and Badger 2011). If these mechanisms are overloaded, the photosynthetic apparatus becomes damaged, leading to photoinhibition. This phenomenon
was first studied by Kok (1956). At present several hypotheses are available with respect to the primary mechanism of the photoinhibitory damage. According to the so called acceptor-side mechanism (Vass et al. 1992) reduction of the plastoquinone pool promotes double reduction, stiripentol protonation, and loss of the primary quinone electron acceptor of photosystem II (PSII), QA. In this situation, recombination reactions between QA − and P680 + can lead to the formation of triplet chlorophyll, that may react with oxygen to produce harmful singlet oxygen. In the donor-side mechanism (Callahan et al. 1986; Anderson et al. 1998) the oxidized primary donor of PSII, P680 +, has such a high oxidative potential that it can oxidize pigment molecules if electron transfer from the oxygen evolving complex does not function, this is what sometimes appears to occur. According to the low-light mechanism (Keren et al. 1997) generation of triplet chlorophyll in recombination reactions cause photoinhibition when the electron transport is slow. In the singlet oxygen mechanism (Jung and Kim 1990), photoinhibition is initiated by generation of singlet oxygen by iron-sulfur centers or cytochromes.