小球藻Rubisco在叶绿体中的免疫金标定位

应用免疫技术对Rubisco在中国小球藻(Chlorellaspp.640909)叶绿体中进行了分子定位及Native-PAGE电泳、SDS-PAGE电泳及其Westen印迹分析,并对小球藻淀粉核(Pyrenoid)超微结构进行了观察.结果显示Native-PAGE电泳图谱主要为一条主带,Westen印迹反应证明该条带即为Rubisco酶,SDS-PAGE电泳及其Western印迹图谱显示Rubisco大亚基分子量大约为55kD.中国小球藻淀粉核为椭圆形,被淀粉鞘所包围,中央有一条由2个类囊体组成的纵向通道,并在蛋白核内段处稍膨胀.淀粉核与叶绿体基质存在多处联系.免疫分子定位显示Rubisco大亚基和全酶分子主要分布于叶绿体的淀粉核上,且Rubisco在淀粉鞘部位也有少量分布,极少部分分布在叶绿体基质中,表明叶绿体淀粉核与光合作用关系密切.Rubisco聚集于淀粉核可能有利于藻类对CO2固定.     

CO2浓度对条浒苔Rubisco酶聚集蛋白核的影响

以生长快速、细胞具多个蛋白核的大型海藻条浒苔作为材料研究CO2浓度对条浒苔Rubisco酶在蛋白核和叶绿体基质之间迁移的影响.应用金标免疫电镜分子定位技术对Rubisco酶集中蛋白核程度进行数值化分析.电镜下可观察到标记Rubisco的金颗粒大部分集中分布在蛋白核中.根据Morita(1997)提出的方法,设定PR-ratio值(蛋白核内分布的Rubisco酶总量与蛋白核外类囊体基质中的Rubisco酶总量之比)作为衡量Rubisco集中蛋白核程度的分析指标.不同CO2浓度对于Kubisco酶分布的长期影响和短期影响研究均显示CO2浓度升高时,Rubisco倾向于向叶绿体基质中扩散;CO2浓度较低或无CO2培养时,Kubisco酶不断向蛋白核中集中.研究结果显示,蛋白核可能在光合作用和CCM机制中具有重要作用.     

泡状饶氏藻营养细胞的超微结构研究

本文报道我国特有的一种绿藻门植物－泡状饶氏藻营养细胞的超微结构特征,植物体由3层细胞组成,外层细胞最小,细胞质比较丰富,含有较多的各种细胞器,液泡体积较小,中层细胞具有很大的中央液泡,细胞质成为贴壁的薄层,各种细胞器结构仍清晰可见,内层细胞极度液泡化,细胞质呈现退化状态,周生的片状叶绿体上有许多大小不等的穿孔,使叶绿体呈网孔状外貌,叶绿体主要由许多成对的类囊体组成,叶绿体上往往有几个蛋白核,蛋白核经常被1或2条类囊体穿过,呈现分隔状,本文也报道了泡状饶氏藻的线粒体,质体,内质网,高尔基体和核内微管的结构特征,根据泡状饶氏藻的类囊体形态与Ulva mutabilis非常相似以及蛋白核的超微结构特征,它与石莼科植物可能有较密切的亲缘关系,属于绿藻门中进化的类群。     

泡状饶氏藻营养细胞的超微结构研究

本文报道我国特有的一种绿藻门植物－泡状饶氏藻营养细胞的超微结构特征,植物体由3层细胞组成,外层细胞最小,细胞质比较丰富,含有较多的各种细胞器,液泡体积较小,中层细胞具有很大的中央液泡,细胞质成为贴壁的薄层,各种细胞器结构仍清晰可见,内层细胞极度液泡化,细胞质呈现退化状态,周生的片状叶绿体上有许多大小不等的穿孔,使叶绿体呈网孔状外貌,叶绿体主要由许多成对的类囊体组成,叶绿体上往往有几个蛋白核,蛋白核经常被1或2条类囊体穿过,呈现分隔状,本文也报道了泡状饶氏藻的线粒体,质体,内质网,高尔基体和核内微管的结构特征,根据泡状饶氏藻的类囊体形态与Ulva mutabilis非常相似以及蛋白核的超微结构特征,它与石莼科植物可能有较密切的亲缘关系,属于绿藻门中进化的类群。     

浮丝藻生活史及其亚显微结构特征的研究

通过观察浮丝藻（Ｐｌａｎｋｔｏｎｅｍａ）的生活史、显微和亚显微结构、细胞分裂方式,系统地研究了其藻丝体的生物学特性。浮丝藻为单列细胞不分枝的丝状体,细胞圆柱形或椭圆形,细胞之间主要靠筒状的纤维素细胞壁相互连接。藻细胞中含叶绿素ａ、ｂ和β－胡萝卜素。电镜下,细胞壁明显分层,绝大多数是２～３层;色素体片状、周生,通常２至多条类囊体重叠;１～２个蛋白核在色素体体上,蛋白核外常有淀粉鞘,有时１至多条类囊体重叠;１～２个蛋白核在色素体上,蛋白核外常有淀粉鞘,有时１至多条类囊体侵入蛋白核内;１～２个线粒体位于色素体旁,嵴不分枝;高尔基复合体靠近细胞周边,分泌许多潴泡;细胞核１个,球形或不规则方形,常靠近细胞的一端;光镜下细胞两端的折光亮点在电镜下是１至多个泡囊,泡囊内通常含些被染色很深的物质。浮丝藻的形态学、细胞分裂和生活史观察结果都证明,浮丝藻的细胞在整个生活史中没有营养分裂,细胞分裂时母细胞产生两个有独立、完整细胞壁的似亲孢子,一系列似亲孢子通过存留的、不连续的筒状或杯状母细胞壁连接成形状上象丝状体的结构。因此,藻丝体形成和成长的过程是一个无性繁殖过程,这样的藻丝体本质上是一种假丝体。     

光和暗条件培养的眼虫藻(Euglena gracilis)内RuBP羧化酶的免疫定位

应用免疫金标记技术证明,在眼虫藻和其它藻类中RuBP羧化酶主要分布在蛋白核部位,这与高等植物中RuBP羧化酶分布不同,在眼虫藻叶绿体间质中有少量RuBP羧化酶存在,这与高等植物中RuBP羧化酶的分布也有相似之处。 暗中培养的眼虫藻不能形成类囊体,无RuBP羧化酶,无光合能力,只能进行异养代谢。     

光和暗条件培养的眼虫藻内RuBP羧化酶的免疫定位

应用免疫金标记技术证明,在眼虫藻和其它藻类中ＲｕＢＰ羧化酶主要分布在蛋白核部位,这与高等植物中ＲｕＢＰ羧化酶分布不同,在眼虫藻叶绿体间质中有少量ＲｕＢＰ羧化酶存在,这与高等植物中ＲｕＢＰ羧化酶的分布也有相似之处。暗中培养的眼虫藻不能形成类囊体,无ＲｕＢＰ羧化酶,无光合能力,只能进行异养代谢。     

2010年—2011年山东近海石莼属绿潮藻的种类鉴定

山东近海近年来连续遭遇绿潮危害,绿潮种类组成是否发生变化?尚未有研究加以解决。2010年—2011年,对山东近海海域漂浮藻进行了调查和取样,选取采集的29株漂浮石莼属样品和2株固着石莼属样品,进行了形态学观察,并对其核糖体ITS、叶绿体rbcL基因和5S rDNA间隔序列进行了分子系统发育分析。结果表明,山东近海石莼属绿潮由浒苔U.prolifera、孔石莼U.pertusa和扁浒苔U.compressa共同构成,浒苔是优势绿潮藻种群,其次为孔石莼,扁浒苔发生很少。     

一个新的水稻斑马叶突变(zebraleaf1)对叶绿体发育的影响(简报)

通过γ射线诱变,在水稻粳稻栽培品种9522中得到一个斑马叶突变体zebra leaf 1.为了研究zl1的功能,我们对突变体进行了形态学和细胞学的分析,同时也对此基因突变以后对叶绿体发育和光合作用的影响作了评价.突变体叶片上绿色和枯白色条纹相同,叶绿素含量显著的下降.电镜显示叶绿体类囊体的排列被打乱,变得杂乱无章.这表明zl1突变体在叶绿体发育过程中出现障碍.zl1基因的突变使得净光合速率显著的下降.参与光合作用的一些关键蛋白,比如核酮糖1,5-二磷酸羧化酶/加氧酶(Rubisco)、Rubisco活化酶、Dl蛋白、CF1β亚基的表达量也显著的下调.但是,zl1突变体对外界环境非常敏感,有时会没有表型.     

衣藻叶绿体表达系统的研究

真核藻类作为一种新型的蛋白表达系统,因其培养方法简单,成本低廉并且能大规模繁殖,最近几年成为人们关注的焦点.作为一种模式生物,单细胞的真核生物莱茵衣藻已经成为人们研究的重点.外源蛋白不仅能在衣藻核中进行表达而且也能在叶绿体中表达,但衣藻叶绿体的表达系统较之核表达有巨大的优越性.在到目前为止,已经有许多的药用蛋白在莱茵衣藻的叶绿体中成功表达的报道,证明了莱茵衣藻叶绿体作为生物反应器的能力.将对衣藻叶绿体的表达做详细的描述.     

Immunogold localization of ribulose-1,5-bisphosphate carborylsae/oxygenase in chloroplasts of Chlorella]

Ribulose 1,5-bisphosphate carboxylase/oxygenase (Rubisco) is a first key enzyme in the Calvin Circle of plant cell photosynthesis. This paper mainly studied gold immunolocalization of Rubisco of Chlorella spp. 640909, and the Native-PAGE and, SDS-PAGE and Western bloting analysis, as well as the observation to pyrenoid ultra structure. The Native-PAGE result showed a main band, evidenced as the Rubisco band by the Western blot with the antibody against the Rubisco from C. prototothecoides, The special immunoacton of Rubisco from Chlorella spp. 640909 and the antibody to large subunit of Rubisco from C. prothecoides showed the large subunit proteins of Rubisco in the two species of Chlorella shared the high homology. The SDS-PAGE and Western blotting maps showed the molecule weight of the large subunit of Rubisco of Chlorella spp. 640909 was about 55 KD. The shape of pyrenoid ultra structure of the electronic microscope was oblong, and was embedded in starch sheath, with 2 swelling thylakoids through out a center portrait channel of the pyrenoid. There were some connections between pyrenoid and the chloroplast stroma. The distribution of the large subunits and the whole Rubisco in the chloroplast of Chrolella spp. 640909 was studied by immunoelectron microscopy by embedded sections with antibody to large subunit and whole enzyme followed by second antibody, goad anti-rabbit immunoglobulin G conjugated to 10 nm gold particles(Sigma production). The result showed the antibodies against large subunit and whole enzyme heavily labeled the pyrenoid, as well as starch sheath region, whereas the thylakoid region of the plastid was lightly labeled. And the whole Rubisco antibody labeled the pyrenoid surface more heavily than the large subunit antibody did. It is demonstrated the pyrenoid and starch sheath have the photosynthesis function. Rubisco concentrating in pyrenoid and starch sheath is valuable to fix CO2 for photosynthesis in algae.     

HIGH LOCALIZATION OF RIBULOSE-1,5-BISPHOSPHATE CARBOXULASE/OXYGENASE IN THE PYRENOIDS OF CHLAMYDOMONAS REINHARDTII (CHLOROPHYTA), AS REVEALED BY CRYOFIXATION AND IMMUNOGOLD ELECTRON MICROSCOPY

The distribution of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) in the chloroplasts of the unicellular green alga Chlamydomonas reinhardtii Dangeard was examined using cryotechnique and conventional fixation for immunogold electron microscopy. Both methods provided essentially identical results, although somewhat higher densities of gold particles indicating Rubisco molecules were recognized in the pyrenoids of cryofixed cells. The gold particles were highly concentrated in the pyrenoid matrix within the chloroplasts. Even when considering the vast difference in volume between the pyrenoid and the rest of the Chloroplast, more than 99% of the total Rubisco labeling in the chloroplast was calculated to be present in the pyrenoid matrix. High localization of Rubisco in the pyrenoid matrix was also recognized regardless of cell age, based on immunofluorescence microscopy of the same en bloc samples. These results are inconsistent with a recent immunocytochemical study employing cryotechnique in which more than 90% of the total Rubisco was recognized in the thylakoid region (thylakoid membranes and stroma) of C. reinhardtii cells. Rubisco highly localized in the pyrenoid matrix may take part in active photosynthetic CO₂ fixation and/or the CO₂ concentrating mechanism .     

In Situ Association of Calvin Cycle Enzymes,Ribulose-1,5-Bisphosphate Carboxylase/Oxygenase Activase,Ferredoxin-NADP+ Reductase,and Nitrite Reductase with Thylakoid and Pyrenoid Membranes of Chlamydomonas reinhardtii Chloroplasts as Revealed by Immunoelectron Microscopy

The in situ localization of the chloroplast enzymes ribulose-1,5-bisphosphate carboxylase (Rubisco), Rubisco activase, ribose-5-phosphate isomerase, glyceraldehyde-3-phosphate dehydrogenase, aldolase, nitrite reductase, ferredoxin-NADP+ reductase, and H+-ATP synthase was studied by immunoelectron microscopy in Chlamydomonas reinhardtii. Immunogold labeling revealed that, despite Rubisco in the pyrenoid matrix, Calvin cycle enzymes, Rubisco activase, nitrite reductase, ferredoxin-NADP+ reductase, and H+-ATP synthase are associated predominantly with chloroplast thylakoid membranes and the inner surface of the pyrenoid membrane. This is in accord with previous enzyme localization studies in higher plants (K.H. Suss, C. Arkona, R. Manteuffel, K. Adler [1993] Proc Natl Acad Sci USA 90: 5514-5518). Pyrenoid tubules do not contain these enzymes. The pyrenoid matrix consists of Rubisco but is devoid of the other photosynthetic enzymes investigated. Evidence for the occurrence of two Rubisco forms differing in their spatial localization has also been obtained: Rubisco form I appears to be membrane associated like other Calvin cycle components, whereas Rubisco form II is confined to the pyrenoid matrix. It is proposed that enzyme form I represents an active Rubisco when assembled into Calvin cycle enzyme complexes, whereas Rubisco form II may be part of a CO2-concentrating mechanism. Pyrenoidal Calvin cycle complexes are thought to be highly active in CO2 fixation and important for the synthesis of starch around the pyrenoid.     

STRUCTURE AND FUNCTION OF THE ALGAL PYRENOID. I. ULTRASTRUCTURE AND CYTOCHEMISTRY DURING ZOOSPOROGENESIS OF TETRACYSTIS EXCENTRICA1

The fine structure of the pyrenoid in the mature vegetative cell of Tetracystis excentrica Brown and Bold is described. During zoosporogenesis, the pyrenoid undergoes regression, and the ultrastructure of this process is described in detail. The ground substance undergoes dissolution, and reticulate fibrillar structures appear as well as intruding chloroplast thylakoids. Pyrenoid-associated starch plates diminish, and quantities of starch not associated with the pyrenoid are produced. New pyrenoids appear late in the division cycle after all other major organelles associated with the motile cell have been formed. Zoospore pyrenoids develop in thylakoid-free spaces of the chloroplast which are similar to the DNA-containing regions. The new pyrenoid ground substance, which is loosely fibrillar, arises in close proximity to starch grains which may be formed in the stroma. Then the zoospore pyrenoid produces 2 hemispherical starch plates identical to those in the mature vegetative cell. Zoospore pyrenoids lack the 2 convoluted thylakoids between the starch plates and the ground substance characteristic of those in the mature vegetative cell. Instead, the thylakoids are identical to those of the chloroplast at first, and then develop into a convoluted state in the vegetative cell. Cytochemical tests for DNA, RNA, and protein were made for the cytoplasm, nucleus, nucleolus, and pyrenoid. Conclusive evidence is presented for the presence of RNA in the cytoplasm and nucleolus, DNA in the nucleus, and protein in the pyrenoid. The tests did not conclusively demonstrate the presence or absence of DNA and RNA in the pyrenoid; however, they suggested that small amounts of both DNA and RNA may be present.     

Immunocytochemical Localization of Phosphoribulokinase in Microalgae

Employing immunogold electron microscopy, the subcellular location of the Calvin cycle enzyme phosphoribulokinase (PRK) was determined for two diverse species of microalgae. In both the red alga Porphyridium cruentum and the green alga Chlamydomonas reinhardtii, PRK was distributed throughout the thylakoid-containing chloroplast stroma. In contrast, the next enzyme in the pathway, ribulose 1,5-bisphosphate carboxylase/oxygenase, was predominantly pyrenoid-localized in both species. In Porphyridium, the chloroplast stroma abuts the pyrenoid but in Chlamydomonas and other green algae, the pyrenoid appears encased in a starch sheath. Unique inclusions found in the pyrenoid of Chlamydomonas were immunolabelled by anti-PRK and thus identified as regions of chloroplast stroma. It is postulated that such PRK-containing stromal inclusions in the pyrenoids of Chlamydomonas and perhaps other green algae provide a means for exchange of Calvin cycle metabolites between pyrenoid and stroma.     

The induction of the CO2-concentrating mechanism is correlated with the formation of the starch sheath around the pyrenoid of Chlamydomonas reinhardtii

The pyrenoid is a prominent proteinaceous structure found in the stroma of the chloroplast in unicellular eukaryotic algae, most multicellular algae, and some hornworts. The pyrenoid contains the enzyme ribulose-1,5-bisphosphate carboxylase/oxygenase and is sometimes surrounded by a carbohydrate sheath. We have observed in the unicellular green alga Chlamydomonas reinhardtii Dangeard that the pyrenoid starch sheath is formed rapidly in response to a decrease in the CO₂ concentration in the environment. This formation of the starch sheath occurs coincidentally with the induction of the CO₂-concentrating mechanism. Pyrenoid starch-sheath formation is partly inhibited by the presence of acetate in the growth medium under light and low-CO₂ conditions. These growth conditions also partly inhibit the induction of the CO₂-concentrating mechanism. When cells are grown with acetate in the dark, the CO₂-concentrating mechanism is not induced and the pyrenoid starch sheath is not formed even though there is a large accumulation of starch in the chloroplast stroma. These observations indicate that pyrenoid starch-sheath formation correlates with induction of the CO₂-concentrating mechanism under low-CO₂ conditions. We suggest that this ultrastructural reorganization under lowCO₂ conditions plays a role in the CO₂-concentrating mechanism C. reinhardtii as well as in other eukaryotic algae.     

CO2 浓度变化对两种淡水绿藻的显微结构和超微结构的影响

为了探讨淡水绿藻在适应CO2浓度变化过程中细胞形态和结构的变化,通过普通显微镜和电子显微镜观察了在不同CO2浓度培养下的莱因衣藻(Chlamydomonas reinhardtii Dang)和斜生栅藻(Scenedesmus obliquus Kütz)细胞.结果表明,CO2浓度变化对莱因衣藻细胞体积没有明显的影响,但斜生栅藻在低浓度CO2培养下细胞体积明显增大,并可见细胞内含有大量颗粒.两种绿藻细胞的超微结构显示,在低浓度CO2培养下,细胞内叶绿体数目明显减少,并可见明显的淀粉盘包围的蛋白核;细胞内还可见大量的淀粉粒.而在高浓度CO2培养下,这两种绿藻细胞内均未见明显的蛋白核和大量淀粉粒出现.     

The compound internal pyrenoid in cultured cells of the green algaMonoraphidium griffithii (Berkel.) Komar.-Legner.

Summary The chloroplast ultrastructure ofMonoraphidium griffithii (Berkel.) Komar.-Legner. has been studied in axenic cultures of various ages. The algae have grown in a complete nutrient solution (illumination about 3,000 lx) and on its agar medium (illumination about 600 lx).The large parietal cup-shaped chloroplast of the cells includes a multiformed compound internal pyrenoid that is situated, especially in older cells, in the central part of the chloroplast opposite to the dictyosome and the nucleus. The chloroplast thylakoids either reach the edge of the pyrenoid or penetrate its matrix and run there parallel in more or less long bits. Starch grains were not found to form any sheath around the pyrenoid regions. The number of starch grains increased with the age of the cell.