In chloroplast, there were two pathways involved in the cyclic electron flow around photosystem 1 (PS 1). One was the NADH dehydrogenase (NDH)-dependent flow and the other was the ferredoxin quinone reductase-dependent flow. It was proposed that the NDH-dependent cyclic electron flow around PSI was related to the xanthophyll cycle-dependent non-photochemical quenching (NPQ) at chilling temperature under low irradiance (CL). The function of the chloroplastic cyclic electron flow around PS 1 was examined by comparing sweet pepper (Capsicum annuum L.) control with its antimycin A (AA)-fed leaves upon exposure to CL stress. During CL stress, the maximum photochemical efficiency of PS2 (Fv/Fm) decreased markedly in both controls and AA-fed leaves, and P700+ was also lower in AA-fed leaves than in controls. These results implied that cyclic electron flow around PS 1 functioned to protect the photosynthetic apparatus from CL stress. Under such stress, NPQ and PS2-driven electron transport rate were different between AA-fed leaves and controls. The lower NPQ in AA-fed leaves might be related to an inefficient proton gradient across thylakoid membranes (ApH) because of inhibiting cyclic electron flow around PS 1 under CL stress.
LI Xin-guo ZHAO Jin-ping XU Ping-li MENG Jing-jing HE Qi-wei
Under 30-min high irradiance (1500μmol m^-2 s^-1), the roles of the xanthophyll cycle and D1 protein turnover were investigated through chlorophyll fluorescence parameters in morning glory (Ipomoea setosa) leaves, which were dipped into water, dithiothreitol (DTT) and lincomycin (LM), respectively. During the stress, both the xanthophyll cycle and D1 protein turnover could protect PSI from photoinhibition. In DTT leaves, non-photochemical quenching (NPQ) was inhibited greatly and the oxidation level of P700 (P700^+) was the lowest one. However, the maximal photochemical efficiency of PSII (Fv/Fm) in DTT leaves was higher than that of LM leaves and was lower than that of control leaves. These results suggested that PSI was more sensitive to the loss of the xanthophyll cycle than PSII under high irradiance. In LM leaves, NPQ was partly inhibited, Fv/Fm was the lowest one among three treatments under high irradiance and P700^+ was at a similar level as that of control leaves. These results implied that inactivation of PSII reaction centers could protect PSI from further photoinhibition. Additionally, the lowest of the number of active reaction centers to one inactive reaction center for a PSII cross-section (RC/CSo), maximal trapping rate in a PSll cross-section (TRo/CSo), electron transport in a PSll cross-section (ETo/CSo) and the highest of 1-qP in LM leaves further indicated that severe photoinhibition of PSII in LM leaves was mainly induced by inactivation of PSII reaction centers, which limited electrons transporting to PSh However, relative to the LM leaves the higher level of RC/CSo, TRo/CSo, Fv/Fm and the lower level of 1-qP in DTT leaves indicated that PSI photoinhibition was mainly induced by the electron accumulation at the PSI acceptor side, which induced the decrease of P700^+ under high irradiance.
<正>The primary definition of photoinhibition was the decrease of photosynthesis under high irradiance, because...
Xin-Guo LI, Jia-Sen YANG, Ping-Li XU, Jin-Ping ZHAO, Jing-Jing MENG, Qi-Wei HE (High-Tech Research Center, Shandong Academy of Agricultural Sciences, Ji''nan, Shandong, 250100, P.R.China)
