两个品种烟草叶片发育过程中几种光合参数变化的比较

比较烟草2个品种‘NC89’和‘JYH’叶片发育过程中几个光合参数变化的结果表明,烟草叶片发育过程中光合速率变化表现为上升期、高值持续期（APD）和速降期,叶绿素含量变化经历上升期、相对稳定期（RSP）和速降期。光合功能衰退过程中,核酮糖．1,5-二磷酸羧化酶（RuBPCase）活性比电子传递活性下降快。可逆衰退阶段的2个品种类囊体膜多肽组分和‘NC89’的核酮糖-1,5-二磷酸羧化酶加氧酶（Rubisco）大亚基基本上无变化;不可逆衰退阶段的2个品种类囊体膜多肽组分、Rubisco大小亚基均快速降解,尤其是光系统Ⅱ（PSⅡ）复合体和Rubisco小亚基。‘JYH’的叶龄为10-40d的叶中各光合参数与‘NC89’的差别不大,但‘JYH’的光合功能期短,光合功能衰退过程中光合电子传递与碳同化失衡较严重,光合功能衰退比‘NC89’早而迅速。     

莲子光下萌发过程中光合膜超分子结构与27kD多肽变化

冰冻撕裂电镜观察及膜多肽组分的研究结果表明,随着莲子在光下萌发时间的延长,莲(Nelumbonucifera Gaertn.)胚芽叶的叶绿体光合膜的超分子结构发育与膜多肽组分中的27kD多肽含量变化具有明显的相关性:1.萌发2d后,胚芽叶的叶绿体巨基位变成解垛叠状态,其光合膜的超分子结构只呈现解垛叠类囊体区外质膜撕裂面(EF)和解垛叠类囊体的原生质膜撕裂面(PF)两个面;膜组分中主要是30kD多肽,而27kD多肽含量甚微。2.萌发4d后,光合膜从解垛叠开始转变成小基粒垛,垛叠区类囊体外质膜撕裂面(EFs)和垛叠类囊体的原生质膜撕裂面(PFs)开始发育;27kD多肽含量开始增加,30kD多肽含量开始减少。3.萌发6～8d后,光合膜明显分化出非垛叠膜区,非垛叠类囊体的外质膜撕裂面(EFu)和非垛叠类囊体的原生质膜撕裂面(PFu)开始呈现,EFs和PFs功能蛋白颗粒逐渐增多;27kD多肽逐渐增加,30kD多肽逐渐减少。4.萌发10～12d后,光合膜垛叠和非垛叠膜区分化完善,排列有序,EFs、PFs、EFu和PFu面功能蛋白颗粒的密度、大小、分布等超分子构象发育正常;27kD多肽更加增多,30kD多肽几乎消失。表明其超分子结构的发育动态既与其超微结构变化相一致,又与27kD多肽含量变化相吻合,却与一般高等植物的叶绿体发育相反,可为显示莲在被子植物系统演化中的独特地位提     

巨大螺旋藻PSII颗粒光合放氧与多肽组成关系的研究

由常温下培养的巨大螺旋藻制备的细胞、类囊体膜片层、ＰＳⅡ颗粒均具一定的放氧活性,且随着制备物的纯化,放氧活性逐渐提高。二价阳离子Ｃａ＾２＋对于维持光合膜放氧活性是必需的;ＰＳⅡ颗粒放氧复合物包含１２条多肽,较高等植物多肽组分复杂;类囊体膜多肽分则极为复杂;盐洗和多肽重组实验表明５５,５０,２６ｋＤ多肽与外在放氧蛋白组成及功能有关,特别是５５,２６ｋＤ多肽是放氧不可缺少的组分。     

巨大螺旋藻PSⅡ颗粒光合放氧与多肽组成关系的研究

由常温下培养的巨大螺旋藻（Ｓｐｉｒｕｌｉｎａｍａｘｉｍａ）制备的细胞、类囊体膜片层、ＰＳⅡ颗粒均具一定的放氧活性,且随着制备物的纯化,放氧活性逐步提高。二价阳离子Ｃａ￣２＋对于维持光合膜放氧活性是必需的;ＰＳⅡ颗粒放氧复合物包含有１２条多肽,较高等植物多肽组分复杂;类囊体膜多肽组分则极为复杂;盐洗和多肽重组实验表明５５,５０,２６ｋＤ多肽与外在放氧蛋白组成及功能有关,特别是５５,２６ｋＤ多肽是放氧不可缺少的组分。     

小麦开花后iPA和ABA含量的变化及与旗叶光合,根系活力和籽？…

以２个粒重不同的小麦品种为材料,研究了开花后旗叶、根系和籽粒异戊烯基腺苷（ｉＰＡ）和脱落酸（ＡＢＡ）含量的变化及其与旗叶光合速率、根系活力和籽粒样重的关系。结果表明,高粒重的鲁麦２２较低粒重的鲁麦１４,旗叶和根系ｉＰＡ含量高且速降始期推迟,ＡＢＡ含量低且速升始期推迟;与此相对应,旗叶光合速率和根系活力高且高值持续期长。鲁麦２２籽粒ｉＰＡ含量高于鲁麦１４,其ＡＢＡ含量在花后１６ｄ内高于鲁麦１４,１６     

多粘菌素B对光合磷酸化的促进作用

多粘菌素B在低浓度的磷酸盐存在下,抑制光合磷酸化和电子传递,但在较高浓度的磷酸盐存在下,却能促进光合磷酸化和提高P/O值。多粘菌素B在促进光合磷酸化时与无机磷酸之间存在着类似竞争的关系,并显示出能增加叶绿体的毫秒延迟发光和用中性红表示的类囊体膜内外的pH变化,多粘菌素B亦能促进光下的ATP_P_j交换。根据上述实验结果;我们推测多粘菌素B在类囊体膜上可能有两个作用部位,一个在类囊体膜上,另一个在偶联因子(CF_1)的β亚单位上。     

氯化胆碱对小麦光合性能及生长的影响

盆栽和田间试验结果表明：经喷施有效作用浓度范围（２００—５００ｐｐｍ）氯化胆碱（ＣＣ）后的小麦叶片叶绿素含量略有增加,希尔反应和光合速率增高：促进了游离叶绿体非环式光合电子传递活性;叶绿体片展的发育有所改善;Ｃａ（２＋）－ＡＴＰ酶和Ｍａ（２＋）－ＡＴＰ酶活性均有所提高;对正常呼吸代谢活力无影响．但降低了光呼吸的关键酶乙醇酸氧化酶活性,利于光合提高。对田间小麦株高无明显影响,但叶面积明显增加,功能叶寿命延长;千粒重和小区产量增加;对籽粒含氮量、蛋白质、粗脂肪等含量无明显影响,但总糖量明显增加。本文对ＣＣ促进小麦光合性能之原因和有效作用浓度作了讨论。     

激素对不同发育阶段小麦旗叶光合速率调控研究

选择小麦旗叶叶绿素含量的相对稳定期、稳定期末期和速降期3个发育阶段,采用酶联免疫法测定旗叶中ABA／ZRs比值;将ABA、ZRs和二者的混合液引入3个发育阶段植株的蒸腾流,测定激素对不同发育阶段叶片光合速率的影响．结果表明,3个发育阶段植株旗叶中ABA／ZRs比值分别为4．20、41．83和14．40．ABA降低3个阶段叶片光合速率达到零值的时间,分别为49．5、39．1和38．0min;ZRs处理3个发育阶段小麦旗叶的光合速率值降至试验开始零分钟时测得的光合速率值一半的时间,分别为65、49和31min．小麦旗叶的前2个发育阶段为可调和可逆阶段,后1个阶段为不可调和不可逆阶段．     

两种高产小麦旗叶光合功能衰退特性的比较

以高产小麦宁麦8号和9号为材料,研究了自开花期旗叶光合功能衰退和品种间的差异。结果表明:开花期后,随着穗重的增加,旗叶的比叶重、相对含水量、叶绿素含量、饱和光强下的净光合速率P_nmax、光饱和点LSP、表观量子产量AQY以及PSI、PS II和全电子传递链活性不断降低,黄熟期后下降均较显著,而叶绿素a/b、光补偿点LCP和呼吸速率R_d开花期至黄熟期间缓慢升高。和宁麦8号相比,宁麦9号叶绿素含量开始时较低,衰老后期含量较高。结论:黄熟期前,旗叶对光的利用范围较光,光合功能降低缓慢;黄熟期后,利用强光和弱光能力均下降,光合功能的衰退显著。和宁麦8号相比,高产小麦宁麦9号旗叶光合功能早衰。     

黄瓜叶片光合电子传递对水分胁迫的响应

黄瓜叶片在水分胁迫下叶片相对含水量减少,类囊体室温吸收光谱的吸收峰降低,同时其NADP光还原活性、Ca^2 -ATPase活性也相应降低,全链电子传递明显受阻。类囊体膜蛋白电泳分析结果显示：类囊体膜色素蛋白复合体含量有不同程度的降低,其中PSⅡ色素蛋白复合体含量下降较多,试验结果表明水分胁迫通过限制光能的吸收,传递双及转换效率,抑制了光合电子传递过程。     

Multiple excitations in photosynthetic systems.

The yield of fluorescence in Chlorella from a 7 ns pulse of light is found to decrease gradually as a function of the number of hits in the photosynthetic units. The fivefold decrease in yield is spread over some three orders of magnitude of pulse energy and strongly suggests another random process in addition to that of photon absorption. Evidence supports the view that this random process is not in the time but in the spatial domain. The model used to fit the data is that of a unit with multiple traps for the singlet excitation. An excitation is captured by an open trap or destroyed by a filled trap with equal probability. These studies give evidence for the connectivity of the photosynthetic energy transfer apparatus on the short time scale. The short fluorescence lifetimes following picosecond pulse excitation of photosynthetic systems reported by several laboratories may be explained by the effect of multiple excitations.     

Canopy photosynthetic production in a Japanese larch forest. II. Estimation of the canopy photosynthetic production

Seasonal changes and yearly gross canopy photosynthetic production were estimated for an 18 year old Japanese larch (Larix leptolepis) forest between 1982 and 1984. A canopy photosynthesis model was applied for the estimation, which took into account the effect of light interception by the non-photosynthetic organs. Seasonal changes in photosynthetic ability, amount of canopy leaf area and light environment within the canopy were also taken into account. Amount of leaf area was estimated by the leaf area growth of a single leaf. The change of light environment within the canopy during the growing season was estimated with a light penetration model and the leaf increment within the canopy. Canopy respiration and surplus production were calculated as seasonal and yearly values for the three years studied. Mean yearly estimates of canopy photosynthesis, canopy respiration and surplus production were 37, 13 and 23 tCO₂ ha⁻¹ year⁻¹, respectively. Vertical trend, seasonal changes and yearly values of the estimates were analyzed in relation to environmental and stand factors.     

玉米光合性能的杂种优势

以4个不同光合速率的玉米自交系及组配的2个杂交种为材料, 在吐丝期进行了光合速率(P_n)、蒸腾速率(T_r)、气孔导度(G_s)、水分利用效率(WUE)等光合性能指标日变化的测定,以探明玉米杂种优势光合性能的日变化规律.结果表明：光合性能中P_n、T_r和G_s 3项指标均呈明显的单峰曲线变化,峰值出现的时间分别为10:00—12:00、12:00和10:00—12:00,其中G_s、P_n早于T_r;WUE日变化规律与其它光合性能指标相反,呈现“V”趋势,低谷值出现在12:00点左右.P_n、T_r的日变化均与G_s密切相关,说明G_s在P_n、T_r日变化中起着重要的调节作用.对光合性能杂种优势率日变化进行分析表明,杂交种P_n、T_r、G_s具有午后优势现象,而WUE杂种优势率表现为上午高于下午,说明午后的环境条件更有利于杂交种抗性的发挥,为筛选高光效品种提供了一项可参考的指标.     

The mechanism of photosynthetic water splitting.

Oxygenic photosynthesis, which provides the biosphere with most of its chemical energy, uses water as its source of electrons. Water is photochemically oxidized by the protein complex photosystem II (PSII), which is found, along with other proteins of the photosynthetic light reactions, in the thylakoid membranes of cyanobacteria and of green plant chloroplasts. Water splitting is catalyzed by the oxygen-evolving complex (OEC) of PSII, producing dioxygen gas, protons and electrons. O(2) is released into the atmosphere, sustaining all aerobic life on earth; product protons are released into the thylakoid lumen, augmenting a proton concentration gradient across the membrane; and photo-energized electrons pass to the rest of the electron-transfer pathway. The OEC contains four manganese ions, one calcium ion and (almost certainly) a chloride ion, but its precise structure and catalytic mechanism remain unclear. In this paper, we develop a chemically complete structure of the OEC and its environment by using molecular mechanics calculations to extend and slightly adjust the recently-obtained X-ray crystallographic model with reference to this structure and to some important recent experimental results.