Abstract
PsbT is a small chloroplast-encoded hydrophobic polypeptide associated with the photosystem II (PSII) core complex. A psbT-deficient mutant (Delta psbT) of the green alga Chlamydomonas reinhardtii grows photoautotrophically, whereas its growth is significantly impaired in strong light. To understand the photosensitivity of Delta psbT, we have studied the effect of strong illumination on PSII activity and proteins. It is shown that the level of PSII activity and proteins is reduced in the Delta psbT more significantly than in wild type under strong light. When recovery of the photodamaged PSII is inhibited by a chloroplast protein synthesis inhibitor, the light-induced inactivation and degradation of PSII occur similarly in wild-type and mutant cells. On the contrary, the recovery of PSII activity after partial photoinactivation is remarkably delayed in the Delta psbT cells, suggesting that PsbT is required for efficient recovery of the photodamaged PSII complex. These results therefore present the first evidence for involvement of this small PSII polypeptide in the recovery process. Partial disintegration of the purified PSII core complex and localization of PSII proteins in the resulting PSII subcore complexes have revealed that PsbT is associated with D1/D2 heterodimer. A possible role of PsbT in the recovery process is discussed.
Highlights
Light energy is converted into redox energy by two photosystems, photosystem I (PSI)1 and photosystem II (PSII), and is used to drive photosynthetic electron transport from water to NADPϩ
PsbT Is a New Component of PSII Reaction Center—It has already been observed that PsbT is co-purified with PSII core complex in Chlamydomonas [10] and is present in a PSII subcore complex depleted of CP43 in spinach [24]
Partial disintegration of the PSII core complex and subsequent fractionation has shown that PsbT is associated with the D1/D2 heterodimer, the PSII reaction center
Summary
Light energy is converted into redox energy by two photosystems, photosystem I (PSI) and photosystem II (PSII), and is used to drive photosynthetic electron transport from water to NADPϩ. The damaged D1 is degraded and subsequently replaced by a newly synthesized copy This light-induced rapid turnover of D1 as well as replacement of cofactors are essential for maintaining PSII activity in light [6]. In addition to this acceptor side photoinhibition, donor side photoinhibition occurs when the oxygen-evolving complex is inhibited. Since the activity and amount of PSII in the mutant were only slightly impaired as compared with those in wild-type cells, it was concluded that PsbT is not essential for synthesis, stability, and function of the PSII complex. This finding suggests that PSII is more photosensitive in the ⌬psbT mutant cells than in wild-type cells
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