发菜藻胆体的分离和光谱特性的研究

完整藻胆体和不完整藻胆体的吸收峰都在618nm。完整藻胆体的室温荧光峰位于670nm以上,而不完整藻胆体则在670nm以下。完整藻胆体的77K荧光发射光谱中只有648nm一个荧光发射带;而在不完整藻胆体,则有2个或3个发射带,它们位于684nm,666nm和648nm,依次属于别藻蓝蛋白-B,别藻蓝蛋白和C-藻蓝蛋白的荧光。     

嗜热蓝藻层理鞭枝藻（Mastigocladus laminosus）藻胆体在解离过程中荧光发射光谱和光能传递的研究

研究了层理鞭枝藻藻胆体在不同浓度磷酸缓冲溶液中解离过程中荧光发射光谱的变化和光能传递。完整藻胆体的７７Ｋ荧光光谱中只有一个峰,位于６８５ｎｍ它是末端发射体（核心－膜连接多肽和别藻蓝蛋白－Ｂ）的荧光峰。部分解离藻胆体的荧光光谱的主峰位移至６５２ｎｍ：次峰位于６８５ｎｍ;６６０ｎｍ为一弱荧光发射肩。它们依次为Ｃ－藻蓝蛋白,末端发射体和别藻蓝蛋白的荧光。严重解离藻胆体的荧光主峰移６４４ｎｍ;次峰由６８５ｎｍ移至６８２ｎｍ;６６０ｎｍ荧光发射肩消失。这表明Ｃ－藻蓝蛋白所捕获的光能已不能传递给别藻蓝蛋白,但可传递给末端发射体洞时又表明Ｃ－藻蓝蛋白不仅与别藻蓝蛋白相连接而且还与末端发射体相连接。提出该藻胆体光能传递链如下：核心－膜连接多肽藻红蓝蛋白→Ｃ－藻蓝蛋白→别藻蓝蛋白别藻蓝蛋白－Ｂ     

嗜热蓝藻层理鞭枝藻（Mastigocladus laminosus）藻胆体在解离过程中荧光发射光谱和光能传递的研究

研究了层理鞭枝藻胆体在不同浓度磷酸冲溶液中解离过程中荧光发射光谱的变化和光能传递,完整藻胆体的７７Ｋ荧光光谱中只有一个峰,位于６８５ｎｍ,它是末端发射体（核心－膜连接多肽和别蓝蛋白－Ｂ）的荧光峰,部分解离藻胆体的荧光光谱的主峰位移至６５２ｎｍ,次峰位于６８５ｎｍ;６６０ｎｍ为一弱荧光发射肩,它们依次为Ｃ－藻蓝蛋白,末端发射体和别藻蓝蛋白的荧光。严重解离藻胆体的荧光主峰移至６４４ｎｍ;次峰由６８５ｎ     

螺旋藻(Spirulina Platensis)藻胆体的光谱特性和能量传递的研究

研究了螺旋藻藻胆体的吸收光谱,室温和液氮温度荧光发射光谱和激发光谱.完整藻胆体的室温荧光峰位于678nm,不完整藻胆体位于672nm.在完整藻胆体的液氮温度荧光光谱中只有一个发射峰,不完整藻胆作有两个峰.研究结果表明C-藻蓝蛋白与别藻蓝蛋白之间的连接和别藻蓝蛋白与别藻蓝蛋白-B之间的连接具有不同的稳定性;前者稳定性较差,易解离.对藻胆体内藻胆蛋白之间的光能传递进行了讨论.     

螺旋藻（Spirulina platensis）藻胆体在解离过程中荧光发射光谱和光能传递的研究

对螺旋藻（Ｓｐｉｒｕｌｉｎａｐｌａｔｅｎｓｉｓ）藻胆体在室温和７７Ｋ处于不同浓度磷缓冲溶液和不同解离时间的荧光发射光谱进行了研究。藻胆体在０．９ｍｏｌ／Ｌ磷酸缓冲溶液中,由于没有发生解离,光能传递效率高,在７７Ｋ荧光发射光谱中只有一个峰,位于６８７ｎｍ,属于别藻蓝蛋白－Ｂ。当藻胆体悬浮在０．３ｍｏｌ／Ｌ磷酸缓冲溶液中１分钟,７７Ｋ荧光光谱的主峰出现在６８４ｎｍ．又出现６５５ｎｍ和６６６ｎｍ荧光峰,它们依次属子Ｃ－藻蓝蛋白和别藻蓝蛋白。在２小时;６５５ｎｍ荧先峰成为主峰,６８４ｎｍ荧光峰为次峰,６６６ｎｍ荧光肩消失。这表明Ｃ－藻蓝蛋白所捕获的先能已不能传递给别藻蓝蛋白,但能传给别藻蓝蛋白－Ｂ。我们提出在螺旋藻藻胆体中存在两类Ｃ－藻蓝蛋白,一是与别藻蓝蛋白相连接,另一是与别藻蓝蛋白－Ｂ相连接。     

螺旋藻（Spirulina platensis）藻胆体在解离过程中荧光发射光谱和光能传递的研究

对螺旋藻（Ｓｐｉｒｕｌｉｎａｐｌａｔｅｎｓｉｓ）藻胆体在室温和７７Ｋ处于不同浓度磷缓冲溶液和不同解离时间的荧光发射光谱进行了研究。藻胆体在０．９ｍｏｌ／Ｌ磷酸缓冲溶液中,由于没有发生解离,光能传递效率高,在７７Ｋ荧光发射光谱中只有一个峰,位于６８７ｎｍ,属于别藻蓝蛋白－Ｂ。当藻胆体悬浮在０．３ｍｏｌ／Ｌ磷酸缓冲溶液中１分钟,７７Ｋ荧光光谱的主峰出现在６８４ｎｍ．又出现６５５ｎｍ和６６６ｎｍ荧光峰,它们依次属子Ｃ－藻蓝蛋白和别藻蓝蛋白。在２小时;６５５ｎｍ荧先峰成为主峰,６８４ｎｍ荧光峰为次峰,６６６ｎｍ荧光肩消失。这表明Ｃ－藻蓝蛋白所捕获的先能已不能传递给别藻蓝蛋白,但能传给别藻蓝蛋白－Ｂ。我们提出在螺旋藻藻胆体中存在两类Ｃ－藻蓝蛋白,一是与别藻蓝蛋白相连接,另一是与别藻蓝蛋白－Ｂ相连接。     

柱孢鱼腥藻的藻蓝蛋白亚基和F_(678)色素蛋白

柱孢鱼腥藻的藻蓝蛋白包含有两个亚基。β亚基具有578nm吸收峰和600nm荧光发射峰,分子量19.80±0.40KD,可表明β亚基仅有一个载色团。α亚基具有578nm和630nm吸收峰及645nm的荧光发射峰,分子量17.35±0.38,α亚基可能有两个载色团。别藻蓝蛋白有635nm和650nm吸收蜂及664nm的荧光发射峰。具藻胆体的类囊体膜从高盐浓度缓冲液移至低盐浓度缓冲液时表现678nm荧光发射峰,可能柱孢鱼腥藻存在的F_(678)色素蛋白相当于GLazer(1975)的别藻蓝蛋白B。     

多变鱼腥藻藻胆体的分离和荧光鉴定其完整性与解离程度

完整藻胆体的室温荧光峰位于678nm附近,而不完整藻胆体其峰位于673nm以下。在液氮温度下,完整藻胆体的F686与F666相对荧光强度比值超过10,F686与F655之比值超过20。不完整藻胆体的F686与F666和F686与F655之比值远低于完整藻胆体。可用室温荧光峰的波长位置和液氮温度下F686与F655和F666的相对荧光强度比值来判断藻胆体的完整性和解离程度。而液氮温度下F686与F655,F666之比值是更灵敏的指标。     

多变鱼腥藻(Anabaena variabilis)藻胆体——类囊体膜光能传递的研究

多变鱼腥藻(Anabaena variabilis)藻胆体一类囊体膜的吸收峰位于678,624,490,438和418nm.当用580nm波长光激发藻胆体一类囊体膜中藻胆蛋白时,室温荧光峰位于662nm,在680nm附近有一肩;液氮温度荧光峰位于655,666,695和730nm.这说明藻胆蛋白捕获的光能能有效地传给叶绿素a.当用436nm波长光激发藻胆体一类囊性膜中叶绿素a时,室温荧光峰(?)于683nm;液氮温室荧光峰在730nm,另一小峰在695nm.表明叶绿素a捕获的光能不能传递给藻胆蛋白.藻胆体一类囊体膜放氧速率为245μmoleO_2/小时,毫克叶绿素,电境照片显示在类囊体膜上有大量藻胆体.用0.3M蔗糖,O.05M磷酸缓冲溶液洗藻胆体一类囊体膜,能使藻胆体与类囊体膜分开.对藻胆体与类囊体之间的光能传递进行了讨论.     

铜离子对钝顶螺旋藻完整细胞中光系统Ⅱ活性和藻胆体能量传递的影响

Cu2 抑制钝顶螺旋藻 ( Spirulina platensis)完整细胞中电子传递活性 ( H2 O→ MV) ,并抑制 PS 的放氧活性。低浓度的 Cu2 处理 ,使钝顶螺旋藻细胞中藻蓝蛋白荧光发射峰位置蓝移、发射强度改变 ,表明藻胆体中能量传递发生了变化。Cu2 处理纯化的藻蓝蛋白 ,使其在长波区 ( 61 6— 62 0 nm)吸收减小、荧光发射峰蓝移 ( 64 7nm→ 64 3nm) ;而变藻蓝蛋白不受影响 ,说明 Cu2 选择性作用于藻蓝蛋白。     

多变鱼腥藻藻胆体的分离和荧光鉴定其完整性与解离程度

完整藻胆体的室温荧光峰位于678nm附近,而不完整藻胆体其峰位于673nm以下。在液氮温度下,完整藻胆体的F686与F666相对荧光强度比值超过10,F686与F655之比值超过20。不完整藻胆体的F686与F666和F686与F655之比值远低于完整藻胆体。可用室温荧光峰的波长位置和液氮温度下F686与F655和F666的相对荧光强度比值来判断藻胆体的完整性和解离程度。而液氮温度下F686与F655,F666之比值是更灵敏的指标。       

光系统Ⅱ反应中心D_1-D_2-Cyt b_(559)复合物低温(77K)荧光发射差异的研究

对菠菜光系统Ⅱ反应中心D_1-D_2-Cytb_(559)复合物进行了系统的低温(77K)荧光发射性质研究。结果表明,D_1-D_2-Cytb_(559)复合物具有681nm和684nm两种波长的低温荧光发射,但两者通常并不是同时存在,而是取决于Ca-680与Ca-670Chla分子的相对含量的。Ca-670Chla含量的增加,会使其低温荧光发射出现在681nm;而Ca-680Chla含量的增加,则会使其低温荧光发射出现在684nm。Ca-670与Ca-680Chla分子的相对含量与不同状态的菠菜叶材料有关。PSⅡ反应中心内周天线CP-47,CP-43多肽的存在是D_1-D_2-Cytb_(591)复合物低温荧光发射红移的原因,而D_1-D_2-Cytb_(559)复合物的不稳定变化则与其蓝移的低温荧光发射有关。     

Isolation and biliprotein characterization of phycobilisomes from the thermophilic cyanobacterium Mastigocladus laminosus Cohn

A method for the effective isolation of functionally intact phycobilisomes from the thermophilic cyanobacterium M. laminosus is presented, using an unconventional high buffer molarity for stabilizing the aggregates and introducing a DNAse treatment of the disrupted cells to obtain sharp banding of the phycobilisomes in the linear sucrose density gradients.The structural integrity of the isolated phycobilisomes is demonstrated by a fluorescence emission maximum at 673 nm of aggregated allophycocyanin and by electron microscopy.Besides C-phycocyanin and allophycocyanin, phycoerythrocyanin is a constituent pigment of the phycobilisomes. These pigments indicated in the absorption spectrum of phycobilisomes with a maximum at 610 nm and two shoulders at 650 and 580 nm, respectively, were characterized by spectral data and isoelectric points.     

Isolation and characterization of disc-shaped phycobilisomes from the red alga rhodella violacea

Disc-shaped phycobilisomes were purified from Triton X100 treated cell homogenates of the unicellular marine red alga, Rhodella violacea. Their absorption spectrum had principal maxima at 544 and 568 nm (B-phycoerythrin), 624 nm (C-phycocyanin) and a distinct shoulder at 652 nm (allophycocyanin). Intermolecular energy transfer within the phycobilisomes was clearly demonstrated by fluorescence data. Excited at 546 nm intact phycobilisomes showed a main fluorescence emission maximum at 665 nm, a minor one at 577 nm and a shoulder at 730 nm.Dissociated phycobilisomes revealed a composition of 58% B-phycoerythrin, 25% C-phycocyanin and 17% allophycocyanin under the cultural conditions used. Analytical methods resolved no other components than phycobiliproteins. In addition to the defined C-phycocyanin and two isoproteins of B-phycoerythrin a stable heterogeneous aggregate of B-phycoerythrin/C-phycocyanin was separated in considerable amounts.In the electron microscope negatively stained phycobilisomes appeared as elliptical aggregates having dimensions slightly above the values found in ultrathin sections and a detailed subunit structure. All observations and data suggest a new rhodophytan phycobilisome type in Rhodella violacea.Abbreviations PBS phycobilisome(s) - PE B-phycoerythrin - PC C-phycocyanin - APC allophycocyanin - C concentration (mg/ml) - E extinction     

Energy transfer in phycobilisomes from phycoerythrin to allophycocyanin

Allophycocyanin appears to be the pigment through which energy trapped by phycobiliproteins is funneled to the chloroplast lamellae. Isolated, intact phycobilisomes from Porphyridium cruentum have a maximum fluorescence emission peak at 675–680 nm when excited at 545 nm. Upon dissociation, when the energy transfer is interrupted the 675–680-nm peak declines. Excitation at 435 nm produced no significant fluorescence at this wavelength.     

Cyanobacterial phycobilisomes. Characterization of the phycobilisomes of Synechococcus sp. 6301.

A procedure is described for the preparation of stable phycobilisomes from the unicellular cyanobacterium Synechococcus sp. 6301 (also known as Anacystis nidulans). Excitation of the phycocyanin in these particles at 580 nm leads to maximum fluorescence emission, from allophycocyanin and allophycocyanin B, at 673 nm. Electron microscopy shows that the phycobilisomes are clusters of rods. The rods are made up of stacks of discs which exhibit the dimensions of short stacks made up primarily of phycocyanin (Eiserling, F. A., and Glazer, A. N. (1974) J. Ultrastruct. Res. 47, 16-25). Loss of the clusters, by dissociation into rods under suitable conditions, is associated with loss of energy transfer as shown by a shift in fluorescence emission maximum to 652 nm. Synechococcus sp. 6301 phycobilisomes were shown to contain five nonpigmented polypeptides in addition to the colored subunits (which carry the covalently bound tetrapyrrole prosthetic groups) of the phycobiliproteins. Evidence is presented to demonstrate that these colorless polypeptides are genuine components of the phycobilisome. The nonpigmented polypeptides represent approximately 12% of the protein of the phycobilisomes; phycocyanin, approximately 75%, and allophycocyanin, approximately 12%. Spectroscopic studies that phycocyanin is in the hexamer form, (alpha beta)6, in intact phycobilisomes, and that the circular dichroism and absorbance of this aggregate are little affected by incorporation into the phycobilisome structure.