Heat Emission as a Protective Mechanism against High-irradiance Stress in Sugar Maple Leaves

High-irradiance (HI) induced changes in heat emission, fluorescence, and photosynthetic energy storage (EST) of shade grown sugar maple (Acer saccharum Marsh.) saplings were followed using modulated photoacoustic and fluorescence spectroscopic techniques. HI-treatment at 900-4400 µmol m-2 s-1 for 15 min caused an increase in heat emission and a decrease in EST. In some leaves, HI-treatment of 900 µmol m-2 s-1 for 1 min induced a rapid increase in heat emission with a marginal decrease in EST. Parallel to the increase in heat emission, there was a decrease in fluorescence, and this phenomenon was reversible in darkness. Quenching of thermal energy dissipation and a recovery in EST were observed during the first 15 min after the HI-treatment. This down-regulation of photochemical activity and its recovery may be one of the photoprotective mechanisms in shade grown sugar maple plants. The increase in thermal energy dissipation was greater in the red absorbing long wavelength (640-700 nm) region than in the blue absorbing short wavelength region of photosynthetically active excitation radiation. The photochemical activity was affected more in short wavelengths (400-520 nm) than in the long wavelength region of the spectrum. This can be due to the migration of light-harvesting chlorophyll (Chl) a/b protein complex from photosystem (PS) 2 to PS1 and/or to the disconnection of carotenoid pool from Chls in the pigment bed of photosynthetic apparatus.     

Photoinhibition of Photosynthesis in Sun and Shade Grown Leaves of Grapevine (Vitis vinifera L.)

The degree of photoinhibition of sun and shade grown leaves of grapevine was determined by means of the ratio of variable to maximum chlorophyll (Chl) fluorescence (F_v/F_m) and electron transport measurements. The potential efficiency of photosystem 2 (PS2), F_v/F_m, markedly declined under high irradiance (HI) in shade leaves with less than 10 % of F₀ level. In contrast, F_v/F_m ratio declined with about 20 % increase of F₀ level in sun leaves. In isolated thylakoids, the rate of whole chain and PS2 activity in HI shade and sun leaves was decreased by about 60 and 40 %, respectively. A smaller inhibition of photosystem 1 (PS1) activity was also observed in both leaf types. In the subsequent dark incubation, fast recovery was observed in both leaf types that reached maximum PS2 efficiencies similar to non-photoinhibited control leaves. The artificial exogenous electron donors DPC, NH₂OH, and Mn²⁺ failed to restore the HI-induced loss of PS2 activity in sun leaves, while DPC and NH₂OH were significantly restored in shade leaves. Hence HI in shade leaves inactivates on the donor side of PS2 whereas it does at the acceptor side in sun leaves, respectively. Quantification of the PS2 reaction centre protein D1 and the 33 kDa protein of water splitting complex following HI-treatment of leaves showed pronounced differences between shade and sun leaves. The marked loss of PS2 activity in HI leaves was due to the marked loss of D1 protein of the PS2 reaction centre protein and the 33 kDa protein of the water splitting complex in sun and shade leaves, respectively.     

State Transition,Is It a Photochemical or Non-photochemical Process in Leaf in Response to Irradiance?

The response of steady-state fluorescence (Fs) to irradiance in apple (Malus pumila Mill. cv. Tengmu No.1/Malus hupehensis Rehd.) leaf increased and decreased at light levels below and above 400 mmol.m-2.s-1 photosynthetic photon flux density (PPFD), respectively, while the light-adapted maximal fluorescence (Fm') and minimal fluorescence (Fo') decreased constantly with the increasing PPFD, and the closure of photosystem Ⅱ reaction center (PSⅡ RC) increased continuously, reflected by the chlorophyll fluorescence parameter of (Fs-Fo')/(Fm'-Fo'). These facts indicated that decrease of Fs above 400 mmol.m-2.s-1 PPFD was not caused by closure of PSⅡ RC, but was mainly resulted from the process of light transfer from light-harvesting complexⅡ (LHCⅡ) to PSⅡ RC. In the presence of N-ethylmaleimide (NEM), an inhibitor of photosynthetic state transition, Fs kept on increasing in apple leaf at light levels from 400 to 700 mmol.m-2.s-1, which was the photosynthetic saturation irradiance of apple leaves. In addition, Fs still increased at light levels over 700 mmol.m-2.s-1 in apple leaf pre-treated with dithiothreitol (DTT), an inhibitor of xanthophyll cycle. These changes showed that state transition and xanthophyll cycle caused a decrease of Fs in apple leaf at light levels below and above the photosynthetic saturation irradiance, respectively. When apple leaf was pre-treated with NEM, the PSⅡ apparent rate of photochemical reaction (P-rate) and photochemical quenching (qP) decreased significantly in the light range of 600-800 mmol.m-2.s-1, but the non-photochemical quenching (qN) existed a small increase at 600-800 mmol.m-2.s-1 and a decrease above 800 mmol.m-2.s-1. These phenomena suggested that state transition was mainly a photochemical and a non-photochemical process in apple leaf responding to light lower and higher than photosynthetic saturation irradiance, respectively.     

Photoinhibition and Recovery of photosystem 2 in Grapevine (Vitis vinifera L.) Leaves Grown Under Field Conditions

Photoinhibition of photosynthesis was investigated in grapevine (Vitis vinifera L.) exposed to 2 or 4h of high irradiance (HI) (1 700–1 800 mol m^–2 s^–1) leaves under field conditions at different sampling time in a day. The degree of photoinhibition was determined by means of the ratio of variable to maximum chlorophyll fluorescence (F_v/F_m) and photosynthetic electron transport measurements. When the photochemical efficiency of photosystem 2 (PS2), F_v/F_m, markedly declined, F₀ increased in both 2 (HI2) and 4 h (HI4) HI leaves sampled at midday. When various photosynthetic activities were followed on isolated thylakoids, HI4 leaves showed significantly higher inhibition of whole chain and PS2 activity than the HI2 leaves sampled at midday. Later, the leaves reached maximum PS2 efficiencies similar to those observed early in the morning during sampling at evening. The artificial exogenous electron donor Mn²⁺ failed to restore PS2 activity in both variants of leaves, while DPC and NH²OH significantly restored PS2 activity in HI4 midday leaf samples. Quantification of the PS2 reaction centre protein D1 and 33 kDa protein of water splitting complex following midday exposure of leaves showed pronounced differences between HI2 and HI4 leaves. The marked loss of PS2 activity noticed in midday samples was mainly due to the marked loss of D1 protein in HI2, while in HI4 it was mainly 33-kDa protein.     

饱和白光引起的光系统II捕光复合体(LHCII)从反应中心复合体脱离不同于弱红光引起的状态1向状态2的转换

我们观测了不同光照预处理对拟南芥、小麦和大豆叶片光合作用和低温(77K) 叶绿素荧光参数F685、F735和F685/F735的影响.野生型拟南芥叶片光合作用对饱和光到有限光转变的响应曲线是V型,而缺乏叶绿体蛋白激酶的突变体STN7的这一曲线为L型. 饱和白光可以引起拟南芥叶片F685/F735的明显降低,但是F735没有明显增高,而弱红光可以导致拟南芥叶片F685/F735的明显降低和F735的明显增高,表明弱红光可以引起状态1向状态2的转变,同时伴随从光系统II脱离的LHC II与光系统I的结合,而饱和白光只能引起LHC II从光系统II反应中心复合体脱离.并且,低温叶绿素荧光分析结果证明,饱和白光可以引起大豆叶片LHC II脱离,但是不能引起小麦叶片LHC II脱离,而弱红光可以引起小麦叶片的这种状态转换,却不能引起大豆叶片的这种状态转换.因此,饱和白光引起的野生型拟南芥和大豆叶片的LHC II脱离不是一个典型的状态转换现象.     

Saturating Irradiance-Induced Photoinhibition without Monomerisation of Photosystem 2 Dimer in Soybean Leaves

The oligomeric state of photosystem 2 (PS2) complex in soybean leaves treated with saturating irradiance was studied by non-denaturing polyacrylamide gel electrophoresis (PAGE) and gel filtration chromatography. PS2 dimers resolved by non-denaturing PAGE accounted for about 75 % of total PS2 complex and there was no significant difference in the ratio of PS2 dimer to monomer between samples from saturating irradiance-treated and fully dark-adapted leaves. Furthermore, BBY particles were resolved into four chlorophyll-enriched fractions by gel filtration chromatography. From their molecular masses and protein components, these fractions were deduced to be PS2 dimer, PS2 monomer, oligomeric light-harvesting complex 2 (LHC2), and monomeric LHC2. Also, no change in the proportion of PS2 dimer in total PS2 was observed in the granal region of thylakoid membranes from soybean leaves after saturating irradiation. Hence the dimer is the predominant natural form of PS2 in vivo and no monomerisation of PS2 dimer occurs during saturating irradiance-induced photoinhibition in soybean leaves.     

Inhibition of Photosynthesis by Shift in the Balance of Excitation Energy Distribution Between Photosystems in Dithiothreitol Treated Soybean Leaves

Chlorophyll fluorescence kinetics was used to investigate the effect of 1,4-dithiothreitol (DTT) on the distribution of excitation energy between photosystem 1 (PS1) and photosystem 2 (PS2) in soybean leaves under high irradiance (HI). The maximum PS2 quantum yield (F_v/F_m) was hardly affected by the presence of DTT, however, photon-saturated photosynthesis was depressed distinctly. Photochemical efficiency of open PS2 reaction centres during irradiation (F_v/F_m) was enhanced by about 30–40 % by DTT treatment, whereas photochemical quenching (q_P) was depressed by about 40 % under HI. DTT treatment caused a 30 % decrease in allocation of excitation energy to PS1 under HI and a 20 % increase to PS2. An obvious shift in the balance of excitation energy distribution between photosystems was observed in DTT-treated leaves. Though high excitation pressure (1 - q_P) resulted from DTT treatment, non-photochemical quenching (q_N) was lower. DTT completely inhibited the formation of zeaxanthin and also distinctly depressed the state transition (q_T). The shift in the balance of excitation distribution between the two photosystems induced by DTT was mainly due to the enhancement of excitation energy capture by PS2 antenna and the inhibition of state transition. It might be the shift in the balance between the two photosystems that mainly induced the depression of photosynthesis. Thus, to keep high utilization efficiency of absorbed photon energy, it is necessary to maintain the balance of excitation distribution between PS2 and PS1.     

Stress-induced degradation of D1 protein and its photoprotection by DCPIP in isolated thylakoid membranes of barley leaf

Effects of various stress treatments such as NaCl, hydrogen peroxide, hydroxyl free radical, and high irradiance (HI, 1 000 μmol m⁻² s⁻¹) on the photosystem (PS) 2 mediated electron transport rate and the degradation of D1 protein in the thylakoid membranes of barley were studied. The applied stresses caused significant reduction in the PS 2-mediated electron transport and a degradation of D1 protein that was highest during the HI-treatment. Presence of 2,6-dichlorophenol indophenol (DCPIP), which is an artificial electron acceptor from water, significantly minimizes the HI-induced deleterious effect on the PS 2-mediated electron transport rate, disarrangement of PS machinery, and degradation of the D1 protein. HI in the absence of an acceptor resulted in production of reactive oxygen species due to electron transfer to oxygen.     

Consequences of LHC II deficiency for photosynthetic regulation in chlorina mutants of barley

The light-harvesting chlorophyll a/b proteins associated with PS II (LHC II) are often considered to have a regulatory role in photosynthesis. The photosynthetic responses of four chlorina mutants of barley, which are deficient in LHC II to varying degrees, are examined to evaluate whether LHC II plays a regulatory role in photosynthesis. The efficiencies of light use for PS I and PS II photochemistry and for CO₂ assimilation in leaves of the mutants were monitored simultaneously over a wide range of photon flux densities of white light in the presence and absence of supplementary red light. It is demonstrated that the depletions of LHC II in these mutants results in a severe imbalance in the relative rates of excitation of PS I and PS II in favour of PS I, which cannot be alleviated by preferential excitation of PS II. Analyses of xanthophyll cycle pigments and fluorescence quenching in leaves of the mutants indicated that the major LHC II components are not required to facilitate the light-induced quenching associated with zeaxanthin formation. It is concluded that LHC II is important to balance the distribution of excitation energy between PS I and PS II populations over a wide range of photon flux densities. It appears that LHC II may also be important in determining the quantum efficiency of PS II photochemistry by reducing the rate of quenching of excitation energy in the PS II primary antennae.Abbreviations Fm, Fv maximal and variable fluorescence yields in a light adapted state - LHC II light harvesting chlorophyll a/b protein complex associated with PS II - q_p photochemical quenching - A₈₂₀ light-induced absorbance change at 820 nm - ø_PSI, ø_PSII relative quantum efficiencies of PS I and PS II photochemistry - øCO₂ quantum yield of CO₂ assimilation     

饱和白光引起的光系统Ⅱ捕光复合体（LHCⅡ）从反应中心复合体脱离不同于弱红光引起的状态1向状态2的转换

我们观测了不同光照预处理对拟南芥、小麦和大豆叶片光合作用和低温（77K）叶绿素荧光参数F685、F735和F685／F735的影响。野生型拟南芥叶片光合作用对饱和光到有限光转变的响应曲线是V型,而缺乏叶绿体蛋白激酶的突变体STN7的这一曲线为L型。饱和白光可以引起拟南芥叶片F685／F735的明显降低,但是F735没有明显增高,而弱红光可以导致拟南芥叶片F685／F735的明显降低和F735的明显增高,表明弱红光可以引起状态1向状态2的转变,同时伴随从光系统Ⅱ脱离的LHCⅡ与光系统Ⅰ的结合,而饱和白光只能引起LHCⅡ从光系统Ⅱ反应中心复合体脱离。并且,低温叶绿素荧光分析结果证明,饱和白光可以引起大豆叶片LHCⅡ脱离,但是不能引起小麦叶片LHCⅡ脱离,而弱红光可以引起小麦叶片的这种状态转换,却不能引起大豆叶片的这种状态转换。因此,饱和白光引起的野生型拟南芥和大豆叶片的LHCⅡ脱离不是一个典型的状态转换现象。     

Composition and Characteristic Differences in Photosynthetic Membranes of Two Ecotypes of Reed (Phragmites communis L.) from Different Habitats

As compared with the swamp reed (SR) ecotype of Phragmites communis growing in the desert region of northwest China, plants of the dune reed (DR) ecotype from the same region possessed lower chlorophyll (Chl) content in leaves, and less thylakoids and grana stacks in chloroplasts. Tube gel electrophoresis without stain showed that the contents of Chl-protein (Pro) components related to photosystem 2 (PS2) were markedly lower in the DR thylakoid membranes than in the SR thylakoid membranes, while the contents of Chl-Pro components associated with PS1 were almost the same in both types. SDS-PAGE analysis indicated that the content of polypeptides of the light-harvesting Chl a/b complex of PS2 (LHC2) was lower in the DR thylakoids. Besides, the conformation of LHC2 within the DR thylakoid membranes was also altered as indicated by circular dichroism spectra. Hence in the DR, reduced energy harvesting by declining the size of LHC2 might be responsible for the down-regulated PS2 activity. Chl fluorescence parameters. F_v/F_m and quantum efficiency of PS2 (_PS2), were lower in the DR leaves than in the SR ones. However, non-photochemical quenching coefficient (q_N) was greater in DR than that in SR, implying other energy dissipation way exists in the DR photosynthetic membranes.     

The consequences of chlorophyll deficiency for photosynthetic light use efficiency in a single nuclear gene mutation of cowpea

The light harvesting and photosynthetic characteristics of a chlorophyll-deficient mutant of cowpea (Vigna unguilata), resulting from a single nuclear gene mutation, are examined. The 40% reduction in total chlorophyll content per leaf area in the mutant is associated with a 55% reduction in pigment-proteins of the light harvesting complex associated with Photosystem II (LHC II), and to a lesser extent (35%) in the light harvesting complex associated with Photosystem I (LHC I). No significant differences were found in the Photosystem I (PS I) and Photosystem II (PS II) contents per leaf area of the mutant compared to the wildtype parent. The decreases in the PS I and PS II antennae sizes in the mutant were not accompanied by any major changes in quantum efficiencies of PS I and PS II in leaves at non-saturating light levels for CO₂ assimilation. Although the chlorophyll deficiency resulted in an 11% decrease in light absorption by mutant leaves, their maximum quantum yield and light saturated rate of CO₂ assimilation were similar to those of wildtype leaves. Consequently, the large and different decreases in the antennae of PS II and PS I in the mutant are not associated with any loss of light use efficiency in photosynthesis.Abbreviations LHC I, LHC II light harvesting chlorophyll a/b protein complexes associated with PS I and PS II - A₈₂₀ light-induced absorbance change at 820 nm - ø_{PS I}, ø_{PS II} relative quantum efficiencies of PS I and PS II photochemistry     

Carotenoid distribution and deepoxidation in thylakoid pigment-protein complexes from cotton leaves and bundle-sheath cells of maize

In response to excess light, the xanthophyll violaxanthin (V) is deepoxidized to zeaxanthin (Z) via antheraxanthin (A) and the degree of this deepoxidation is strongly correlated with dissipation of excess energy and photoprotection in PS II. However, little is known about the site of V deepoxidation and the localization of Z within the thylakoid membranes. To gain insight into this problem, thylakoids were isolated from cotton leaves and bundle-sheath strands of maize, the pigment protein-complexes separated on Deriphat gels, electroeluted, and the pigments analyzed by HPLC. In cotton thylakoids, 30% of the xanthophyll cycle pigments were associated with the PS I holocomplex, including the PS I light-harvesting complexes and PS I core complex proteins (CC I), and about 50% with the PS II light-harvesting complexes (LHC II). The Chl was evenly distributed between PS I and PS II. Less than 2% of the neoxanthin, about 18% of the lutein, and as much as 76% of the -carotene of the thylakoids were associated with PS I. Exposure of pre-darkened cotton leaves to a high photon flux density for 20 min prior to thylakoid isolation caused about one-half of the V to be converted to Z. The distribution of Z among the pigment-protein complexes was found to be similar to that of V. The distribution of the other carotenoids was unaffected by the light treatment. Similarly, in field-grown maize leaves and in the bundle-sheath strands isolated from them, about 40% of the V present at dawn had been converted to Z at solar noon. Light treatment of isolated bundle-sheath strands which initially contained little Z caused a similar degree of conversion of V to Z. As in cotton thylakoids, about 30% the V+A+Z pool in bundle-sheath thylakoids from maize was associated with the PS I holocomplex and the CC I bands and 46% with the LHC II bands, regardless of the extent of deepoxidation. These results demonstrate that Z is present in PS I as well as in PS II and that deepoxidation evidently takes place within the pigment-protein complexes of both photosystems.Abbreviations A antheraxanthin - CC I, CC II Core or reaction center complex of PS I, PS II - CP Chl protein - EPS epoxidation state - F_m Chl fluorescence at closed PS II reaction centers - IEF isoelectric focussing gels - LHC I, LHC II light-harvesting complex of PS I, PS II - OE oxygen evolving polypeptide - PFD photon flux density - PS I^* PS I holocomplex - V violaxanthin - Z zeaxanthin - antibody against C.I.W.-D.P.B. Publication No. 1127.     

Role of calcium ion in protection against heat and high irradiance stress-induced oxidative damage to photosynthesis of wheat leaves

Cross stress of heat and high irradiance (HI) resulted in the accumulation of active oxygen species and photo-oxidative damage to photosynthetic apparatus of wheat leaves during grain development. Pre-treatment with calcium ion protected the photosynthetic system from oxidative damage by reducing O^-. ₂ production, inhibiting lipid peroxidation, and retarding electrolyte leakage from cell. Therefore, high F_v/F_m [maximal photochemical efficiency of photosystem 2 (PS2) while all PS2 reaction centres are open], F_m/F₀ (another expression for the maximal photochemical efficiency of PS2), Φ_PS2 (actual quantum yield of PS2 under actinic irradiation), q_P (photochemical quenching coefficient), and P _N (net photosynthetic rate) were maintained, and lower q_NP (non-photochemical quenching coefficient) of the leaves was kept under heat and HI stress. EGTA (a chelant of calcium ion) and LaCl₃ (a blocker of Ca²⁺ channel in cytoplasmic membrane) had the opposite effect. Thus Ca ion may help protect the photosynthetic system of wheat leaves from oxidative damage induced by the cross stress of heat and HI.     

杂交酸模叶片线粒体交替氧化酶呼吸途径在光破坏防御中的作用

以杂交酸模(Rumex K-1)为试材,研究了不同光强下线粒体交替氧化酶呼吸途径(AOX途径)对酸模叶片光破坏的防御作用.结果表明:在200 μmol·m-2·s-1弱光下,用水杨基羟肟酸抑制AOX途径后,Rumex K-1叶片的PSⅡ实际光化学效率、光合线性电子传递速率以及光合放氧速率均显著下降,非还原性QB反应中心显著升高,加重了叶片的光抑制,而活性氧清除机制上调,避免了活性氧的过量积累,部分缓解了Rumex K-1叶片的光抑制;在800 μmol·m-2·s-1强光下,AOX途径受抑,导致Rumex K-1叶片发生严重的光抑制,而此时活性氧清除机制的上调不足以缓解活性氧过量的积累.无论在强光还是弱光下,AOX途径在Rumex K-1叶片的光破坏防御过程中都起着重要作用,而且在强光下,AOX途径对叶片的光破坏防御作用是叶绿体内其他光破坏防御途径所不能代替的.     

珊瑚树阳生和阴生叶片光合特性和状态转换的比较

珊瑚树阳生和阴生叶片是在不同光照环境中长期生长的,它们的光合特性有一些明显的差异.与阳生叶片相比,阴生叶片单位干重的叶绿素含量较多,类囊体膜垛叠程度较高(即每个基粒的类囊体膜垛叠层数较多,基粒类囊体的直径较大),而叶绿素a/b比值、光合作用的饱和光强和最大净光合速率等较低.用弱红光诱导阳生和阴生叶片向状态2转换时,叶绿素荧光Fm/Fo和F685/F735先迅速下降再逐渐回升,这表明两种叶片都先后通过满溢和LHCⅡ转移调节激发能在PSⅡ和PSⅠ之间的分配,改善光能利用,但阳生叶片Fm/Fo和F685/F735下降的幅度较大.     

Light-dependent, chilling effects on phosphorylation of thylakoid proteins and consequences for associated photochemical activities in maize

When maize ( Zea mays L. cv. LG11) leaves are exposed to low temperatures and high light modifications to both photosystem 2 (PS2) and the light-harvesting chlorophyll a/b protein complex associated with photosystem 2 (LHC2) occur. This study examines the consequences of these modifications for phosphorylation of LHC2 and PS2 polypeptides and the associated changes in electron transport. Maize leaves were chilled at 5°C for 6 h under photon flux densities of 1 500 and 250 μmol m^-2 s^-1. Thylakoids were then isolated from the leaves and their abilities to phosphorylate LHC2 and PS2 polypeptides and modify electron transport activities were determined. Measurements of chlorophyll fluorescence induction in the thylakoids were also made. Thylakoids isolated from leaves chilled under high light and from leaves kept in the ambient growth environment had similar phosphoprotein profiles. However, polypeptide phosphorylation in thylakoids from the chilled leaves did not produce a decrease in PS2 electron transport. Chilling leaves under low light produced a decrease in the ability of isolated thylakoids to phosphorylate PS2, but not LHC2, polypeptides, which was not associated with any change in the phosphorylation-induced decrease in PS2 electron transport. Chilling under high, but not low, light appears to produce changes in membrane organisation that do not affect the ability of the thylakoids to phosphorylate PS2 and LHC2 polypeptides, but which do prevent the phosphorylation-induced decrease in excitation energy transfer from LHC2 to PS2.     

饱和白光引起的光系统II 捕光复合体(LHCII ) 从反应中心复合体脱离不同于弱红光引起的状态1 向状态2 的转换

我们观测了不同光照预处理对拟南芥、小麦和大豆叶片光合作用和低温( 77K) 叶绿素荧光参数F685、F735 和F685􊄯F735 的影响。野生型拟南芥叶片光合作用对饱和光到有限光转变的响应曲线是V 型,而缺乏叶绿体蛋白激酶的突变体STN7 的这一曲线为L 型。饱和白光可以引起拟南芥叶片F685􊄯F735 的明显降低, 但是F735 没有明显增高, 而弱红光可以导致拟南芥叶片F685􊄯F735 的明显降低和F735 的明显增高, 表明弱红光可以引起状态1 向状态2 的转变, 同时伴随从光系统II 脱离的LHC II 与光系统I 的结合, 而饱和白光只能引起LHC II 从光系统II 反应中心复合体脱离。并且, 低温叶绿素荧光分析结果证明, 饱和白光可以引起大豆叶片LHC II 脱离, 但是不能引起小麦叶片LHC II 脱离, 而弱红光可以引起小麦叶片的这种状态转换, 却不能引起大豆叶片的这种状态转换。因此, 饱和白光引起的野生型拟南芥和大豆叶片的LHC II 脱离不是一个典型的状态转换现象。     

Role of Light-harvesting Complex 2 Dissociation in Protecting the Photosystem 2 Reaction Centres Against Photodamage in Soybean Leaves and Thylakoids

The protective role of light-harvesting complex 2 (LHC2) dissociation from photosystem 2 (PS2) complex was explored by the 5-p-fluorosulfonylbenzoyl adenosine (FSBA, an inhibitor of protein kinase) treatment at saturating irradiance (SI) in soybean leaves and thylakoids. The dissociation of some LHC2s from PS2 complex occurred after SI treatment, but FSBA treatment inhibited the dissociation as demonstrated by analysis of sucrose density gradient centrifugation of thylakoid preparation and low-temperature (77 K) chlorophyll (Chl) fluorescence. A significant increase in F₀ and decrease in F_v/F_m occurred after SI, and the two parameters could largely recover to the levels of dark-adapted leaves after subsequent 3 h in the dark, but they could not recover in the FSBA-treated leaves at SI. Neither the electron transport activity of PS2 nor the D1 protein amount in vivo had significant change after SI without FSBA, whereas FSBA treatment at SI could result in significant decreases in both the PS2 electron transport activity and the D1 protein amount. When thylakoids instead of leaves were used, the PS2 electron transport activity and the D1 protein amount declined more after SI with FSBA than without FSBA. The phosphorylation level of PS2 core proteins increased, while the phosphorylation level of LHC2 proteins was reduced after SI. Also, the phosphorylation of PS2 core proteins could be greatly inhibited by the FSBA treatment at SI. Hence in soybean leaf the LHC2 dissociation is an effective strategy protecting PS2 reaction centres against over-excitation and photodamage by reducing the amount of photons transferred to the centres under SI, and the phosphorylation of PS2 core proteins plays an important role in the dissociation.     

超高产杂交稻‘华安3号’冠层不同衰老程度叶片的光合功能

 较系统地研究了抽穗期超高产杂交稻‘华安3号’（`X075’×`紫恢100’）冠层顶部5片叶片的光合功能。结果表明,‘华安3号’剑叶的光系统Ⅱ（PSＩＩ）光化学最大效率(Fv/Fm)、开放的PSⅡ反应中心捕获激发能效率（Fv′/Fm′）、PSⅡ电子传递量子效率（ΦPSⅡ）、光化学猝灭系数（qP）、表观电子传递效率（ETR）、光合色素尤其是叶绿素（Chl）和类胡萝卜素（Car）中的新黄素、黄体素和β-胡萝卜素（β-Car）的含量等均优于其下的各叶,而PSⅡ的激发压力（1-qP）低于其它叶片。经对叶片低温（77K）荧光发射光谱的Gaussian解析,与其它各叶片相比,剑叶PSⅡ核心天线复合物CP47和光系统Ⅰ（PSⅠ）的含量较高,而非活性的PSⅡ捕光色素蛋白复合体（LHCⅡ）聚集态含量较少。研究证明：1）水稻在决定籽粒产量的生育后期,其干物质的积累主要是由冠层最上面的3片叶的光合作用所提供;2）在叶片衰老过程中,光合反应中心的衰老早于天线系统;3）杂交稻的光保护途径之一,可能在于光抑制条件下通过增加PSⅠ含量及其对光能的吸收并刺激环式电子传递高速运转,从而对光合器起保护作用;4）水稻叶片在衰老过程中,可能通过部分Chl b还原为Chl a,以降低LHCⅡ的含量,从而减少对光能的捕获,达到降低光抑制的伤害。