STRUCTURE AND PHYCOBILIPROTEIN COMPOSITION OF PHYCOBILISOMES FROM GRIFFITHSIA PACIFICA (RHODOPHYCEAE)1

Phycobilisomes in Griffithsia pacifica are closely spaced on the thylakoid membrane. By negative staining, attached and isolated phycobilisomes have been shown to have a block shaped appearance. They are 63 nm long, 38 nm high, and 38 nm wide, making them the largest thus far reported. Isolated phycobilisomes, shown to be functionally intact by their 675 nm fluorescence emission (excitation 545 nm) were stable for more than a day. Phycobiliproteins from dissociated phycobilisomes, separated on sucrose gradients and by polyacrylamide electrophoresis, yielded large (R-) and small (r-) molecular weight species of phycoerythrin (ca. 4:1 respectively) constituting 89% of the phycobiliprotein content, with R-phycocyanin 8%, and allophycocyanin 3% accounting for the rest. Phycobilisomes of Griffithsia pacifica and Porphyridium purpureum (Bory) Drew and Ross (P. cruentum) are structurally very similar with phycoerythrin being on the outside and surrounding a core of R-phycocyanin and allophycocyanin.     

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.     

Investigations on the arrangement and fine structure ofPorphyridium cruentum phycobilisomes

Summary Phycobilisomes ofPorphyridium cruentum were investigated in ultrathin sectionsin situ and after isolation and positive or negative staining. The phycobilisomes have the approximate shape of one half of a compressed rotation ellipsoid with the following dimensions: length 2 a=40±4 nm, width 2 b=19±2 nm, height c=28±3 nm. The phycobilisomes form rows and pillars on the thylakoid membranes. A plug-like structure (foot) which apparently fixes the phycobilisomes to the thylakoid membrane is described.     

Photosynthetic vesicles with bound phycobilisomes from Anabaena variabilis

Photosynthetically active vesicles with attached phycobilisomes from Anabaena variabilis, were isolated and shown to transfer excitation energy from phycobiliproteins to F696 chlorophyll (Photosystem II). The best results were obtained when cells were disrupted in a sucrose/phosphate/citrate mixture (0.3 : 0.5 : 0.3 M, respectiely) containing 1.5% serum albumin. The vesicles showed a phycocyanin/chlorophyll ratio essentially identical to that of whole cells, and oxygen evolution rates of 250 μmol O₂/h per mg chlorophyll (with 4 mM ferricyanide added as oxidant), whereas whole cells had rates of up to 450. Excitation of the vesicles by 600 nm light produced fluorescence peaks (?196°C) at 644, 662, 685, 695, and 730 nm. On aging of the vesicles, or upon dilution, the fluorescence yield of the 695 nm emission peak gradually decreased with an accompanying increase and final predominant peak at 685 nm. This shift was accompanied by a decrease in the quantum efficiency of Photosystem II activity from an initial 0.05 to as low as 0.01 mol O₂/einstein (605 nm), with a lesser change in the V_max values. The decrease in the quantum efficiency is mainly attributed to excitation uncoupling between phycobilisomes and Photosystem II. It is concluded that the F685 nm emission peak, often exclusively attributed to Photosystem II chlorophyll, arises from more than one component with phycobilisome emission being a major contributor. Vesicles from which phycobilisomes had been removed, as verified by electron microscopy and spectroscopy, had an almost negligible emission at 685 nm.     

The structure of Gloeobacter violaceus and its phycobilisomes

The fine structure of the atypical cyanobacterium Gloeobacter violaceus has been studied on frozen-etched replicas and compared to that of a typical unicellular strain: Synechocystis 6701. The complementary fracture faces of G. violaceus cytoplasmic membrane contain particles less numerous and more heterogenous in size than either the cytoplasmic membrane or the thylakoid membranes of Synechocystis. The most frequently observed particles of the exoplasmic fracture (EF) face of the G. violaceus cytoplasmic membrane are 11 nm in diameter and occasionally form short alignments. This particle class is similar in appearance to the numerous, aligned EF particles of Synechocystis thylakoid membranes. In replicas of cross-fractured G. violaceus, a layer 50–70 nm thick, composed of rod-like elements, underlies the inner surface of the cytoplasmic membrane. The rods, 12–14 nm in diameter, are oriented perpendicularly to the cytoplasmic membrane and show a 6 nm repeat along their length.Isolated phycobilisomes of G. violaceus appear, after fixation and negative staining, as bundles of 6 parallel rodshaped elements connected to an ill-defined basal structure. The bundles are 40–45 nm wide and 75–90 nm long. The rods are 10–12 nm in width; their length varies between 50 and 70 nm. These rods are morphologically similar to those observed at the periphery of hemidiscoidal phycobilisomes of other cyanobacteria, with a strong repeat at 6 nm intervals and a weaker one at 3 nm intervals along their length.The calculated molar ratio of phycobiliproteins in isolated G. violaceus phycobilisomes corresponds to 1:3.9:2.9 for allophycocyanin, phycocyanin and phycoerythrin respectively. When excited at 500 nm, isolated phycobilisomes exhibit a major fluorescence emission band centered at 663 nm.Abbreviations PBS phycobilisome(s) - PBP phycobiliprotein(s) - AP allophycocyanin - PC phycocyanin - PE phycoerythrin - K–PO₄ buffer KH₂PO₄ titrated with KOH to a given pH     

Structure and organization of phycobilisomes on membranes of the red alga Porphyridium cruentum

In the present work, electron microscopy and single particle averaging was performed to investigate the supramolecular architecture of hemiellipsoidal phycobilisomes from the unicellular red alga Porphyridium cruentum. The dimensions were measured as 60 × 41 × 34 nm (length × width × height) for randomly ordered phycobilisomes, seen under high-light conditions. The hemiellipsoidal phycobilisomes were found to have a relatively flexible conformation. In closely packed semi-crystalline arrays, observed under low-light conditions, the width is reduced to 31 or 35 nm, about twice the width of the phycobilisome of the cyanobacterium Synechocystis sp. PCC 6803. Since the latter size matches the width of dimeric PSII, we suggest that one PBS lines up with one PSII dimer in cyanobacteria. In red algae, a similar 1:1 ratio under low-light conditions may indicate that the red algal phycobilisome is enlarged by a membrane-bound peripheral antenna which is absent in cyanobacteria. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. Ana A. Arteni and Lu-Ning Liu equally contributed to the work.     

The Supramolecular Structure of Photosystem II — Phycobilisome-Complexes of Porphyridium cruentum

The structure and arrangement of phycobilisomes of the unicellular red alga Porphyridium cruentum is compared with the organization of the thylakoid freeze-fracture particles in order to determine the relationship between phycobilisomes and photosystem II. The hemi-ellipsoidal phycobilisomes, 20 nm thick, are predominantly organized into rows; their centre to centre periodicity is 30–40 nm, so that they are well separated by a gap of 10–20 nm. The phycobilisomes are cleaved by a central faint furrow, parallel to the long axis from top to base. The organization of the exoplasmic particles in rows is similar to the arrangement of the phycobilisomes so that a structural relationship between both systems, previously demonstrated in cyanobacteria, is evident. Within the rows, the 10 nm EF-particles are grouped in tetrameric complexes separated by distances similar to those observed for phycobilisomes. We propose that the tetrameric EF-particle complexes correspond to tetrameric photosystem II complexes which bind one hemi-ellipsoidal phycobilisome on the stroma exposed surface of the thylakoid. A hypothetical model of this photosystem II-phycobilisome complex is presented.     

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     

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     

FUNCTIONAL PHYCOBILISOMES FROM TOLYPOTHRIX TENUIS (CYANOPHYTA) GROWN HETEROTROPHICALLY IN THE DARK1

Phycobiliproteins produced in dark-grown cells of Tolypothrix tenuis Kützing formed Phycobilisomes functionally capable of energy transfer. The phycobilisomes could be recovered in high yield (80% of extracted phycobiliproteins). Phycobilisomes from cells grown without light and in red light had the same size, morphology, and spectral characteristics. They had a phycocyanin to allophycocyanin malar ratio of 3:1. Phycocyanin and allophycocyanin in phycobilisomes were energetically coupled as indicated by their fluorescence emission (maximum of ca. 690 nm at –196° C) and excitation spectra. Phycobilisomes were attached to the outer surface of thylakoids and were hemidiscoidal in shape. In thin sections they had a diameter of 42 ± 3nm, a height of 24 ± 4 nm and a thickness of 10 ± 2 nm. Isolated and negatively stained Phycobilisomes were larger with a diameter of 51 ± 2 nm and height of 33 ± 2 nm, Isolated phycobilisomes in face view had a central core of three units and six peripheral rods. Each rod appeared to be composed of three hexamers (three double discs), consistent with the observed dimensions and substructure. After Phycoerythria synthesis was induced by a 15 min green light exposure, phycobilisomes of dark-grown cells exhibited energy transfer from phycoerythrin to a long wavelength allophycocyanin, indicating that phycoerythrin synthesized in darkness was incorporated into functional phycobilisomes.     

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。       

Ultrastructure of the vegetative gametophytic cells of Porphyra leucosticta (Rhodophyta) grown in red, blue and green light

The ultrastructure of the vegetative gametophytic cells of Porphyra leucosticta Thuret grown in red, blue and green light was studied both in ultrathin sections and in replicas of rapidly frozen cells. High activity of dictyosornes and mucilage sacs results in a dramatic decrease of the protoplasmic area and in thicker cell walls in red light in comparison with blue light and the control. There are numerous well‐formed phycobili‐somes in blue light, whereas not well‐formed ones are present in red and especially in green light. There are also many phycobilisomes in the intrapyrenoidal thylakoids in blue light, fewer in green light, but they are absent in red light and in the control. It seems that in red and especially in green light, the phycobilisomes have fewer rods than in blue light. In green light, chloroplasts bear numerous genophores in contrast to blue and red light. The spacings of neighboring parallel thylakoids are as follows: control 64.3 nm, blue light 90.6 nm, red light 41.3 nm, green light 43.7 nm. Due to the relatively small spacing of the neighboring parallel thylakoids in red (41.3 nm) and in green light (43.7 nm) and of the given height of phycobilisomes (35 nm), the alternate phycobilisomes attached to neighboring lamellae are forced to interdigitate. The density of phycobilisomes per square micrometer of thylakoid surface dramatically increases in blue light (800 μm^?2) in relation to red (250 μm^?2) and green light (180 μm^?2). The protoplasmic fracture face of the thylakoids reveals numerous, tightly packed, but randomly distributed particles. The particle size distribution is uniform in the two types of fracture faces, with an average diameter of about 11.5 nm. In blue light, both the phycobilisomes and exoplasmic face particles are organized into rows with a spacing of 60–70 nm. The results (changes: in the protoplasmic area; in the spacing of the thylakoids; in phycobilisome arrangement; in structure, shape and size of phycobilisomes; and in the accumulation of plastoglobuli), have shown that the monochromatic light (blue, red and green) brings about marked changes in the package effect and consequently in the efficiency of light absorption. In addition, the blue light contributes to the intense production of chlorophyll a, phycoerythrin, phycocyanin and soluble proteins, while intense production of polysaccharidic material is attributed to red light.     

Effects of proteinase K on the energy transfer between phycobiliproteins in phycobilisomes

Spectral changes in fluorescence of phycobilisomes (PBS) of A. variabilis treated with proteinase K were studied at room and liquid nitrogen temperature. In control PBS, the relative yield of 77 K fluorescence of F686 was very high, and those of F655 and F666 were low. In PBS treated with proteinase K for less than 1 h, F686 decreased, and F655 and F666 increased. In PBS treated with proteinase K for 2 h, F655 was the main peak of fluorescence emission, F686 was the second peak, the fluorescence emission peak of F666 disappeared. In PBS treated with proteinase K for more than 8 h, F655 showed only one fluorescence emission peak.We suggested that phycobiliporteins in the PBS of A. variabilis constitute an energy transfer chain, shown as follows:{fx91-1}The linkages between APC and APC-B, C-PC and APC, and C-PC and APC-B had different sensitivity towards proteinase K.     

Phycobilisomes of Porphyridium cruentum. I. Isolation

A procedure was developed for the isolation of phycobilisomes from Porphyridium cruentum. The cell homogenate, suspended in phosphate buffer (pH 6.8), was treated with 1% Triton X-100, and its supernatant fraction was centrifuged on a sucrose step gradient. Phycobilisomes were recovered in the 1 M sucrose band. The phycobilisome fraction was identified by the characteristic appearance of the phycobilisomes, and the absorbance of the component pigments: phycoerythrin, R-phycocyanin, and allophycocyanin Isolated phycobilisomes had a prolate shape, with one particle axis longer than the other. Their size varied somewhat with their integrity, but was about 400–500 A (long axis) by 300–320 A (short axis). Phycobilisome recovery was determined at six phosphate buffer concentrations from 0.067 M to 1.0 M. In 0.5 M phosphate, phycobilisome yield (60%) and preservation were optimal. Such a preparation had a phycoerythrin 545 nm/phycocyanin 620 nm ratio of 8.4. Of the detergents tested (Triton X-100, Tween 80, and sodium deoxycholate), Triton X-100 gave the best results Freezing of the cells caused destruction of phycobilisomes.     

Interaction between Phycobilisomes from <Emphasis Type="Italic">Porphyridium cruentum</Emphasis> and Thylakoid Membranes from <Emphasis Type="Italic">Gymnodinium</Emphasis> sp. or Spinach

Thylakoid membranes were isolated from Gymnodinium sp. and spinach, whereas the phycobilisomes were isolated and purified from red alga Porphyridium cruentum. The absorption spectra of the purified phycobilisomes (PBS) showed three peaks at 548, 564, and 624 nm, respectively, and the ratio of the fluorescence intensity at the ₆₈₀ ^em to that at ₅₈₀ ^em was about 7.3. All these results demonstrated that the purified PBS remained intact. The thylakoid membranes were incubated with the purified phycobilisomes, and the thylakoid membranes, which harbored the phycobilisomes, were purified by sucrose density gradient centrifugation. Meantime, the conjugates of phycobilisome-thylakoid membranes were constructed using glutaraldehyde and further purified. Their characteristics were studied by measuring the absorption spectra and fluorescence emission spectra. The results showed that the phycobilisomes from Porphyridium cruentum can attach to the thylakoid membranes from Gymnodinium sp. and spinach without covalent cross-linking, but the excited energy transfer did not occur. The conjugate of phycobilisome-thylakoid membranes with covalent cross-linking exhibits the excited energy transfer between the phycobilisomes and the thylakoid membranes.__________From Fiziologiya Rastenii, Vol. 52, No. 3, 2005, pp. 331–337.Original English Text Copyright © 2005 by Zhu, Wang, Tseng.This article was submitted by the authors in English.     

Comparison of main emissions at--196?C from phycobilisomes of two blue-green algae Anabaena cylindrica and Anacystis nidulans

Main emissions at—196?C from phycobilisomes of two blue-greenalgae Anabaena cylindrica and Anacystis nidulans were studiedwith special reference to allophycocyanin (APC) B content. Supplementaryexperiments were done with Anabaena variabilis (M-2 and M-3).The main emission from phycobilisome of Anacystis nidulans richin APC B was located at 681 nm. The location was identical tothat of the main emission from APC B but at a shorter wavelengththan that of in vivo emission (685 nm). Results indicate thatAPC B acts as the energy output of phycobilisomes, but thatthe in vivo 685 nm emission is not attributed to APC B. The main emission of the phycobilisome of Anabaena cylindricawas always located at 685 nm irrespective of the preparationmethod; 0.75 M phosphate buffer [Plant Physiol., 63: 615–620(1979)] or 30% polyethylene glycol [Special Issue of Plant &Cell Physiol., No. 3, p. 23–31 (1977)]. This alga alsocontained a special form of APC, but its content was very low.The location of its emission band (681 nm) was identical tothat of APC B, but shorter than that of the main band of phycobilisomes(685 nm). The 685 nm emitter in phycobilisomes showed a charactersimilar to chlorophyll a but not phycobiliproteins in treatmentsfor aqueous extraction or methanol extraction. Results indicatethat the pigment is probably chlorophyll a as we assumed previously.The 685 nm emission from phycobilisomes of Anabaena variabilis(M-2 and M-3) showed the same character. Results were interpreted as indicating that (i) the contentof the special form of APC varies with the species or strainof blue-green algae and (ii) the energy at the phycobilin levelis transferred directly from APC to pigment system II chlorophylla when the amount of the special form of APC is low. (Received October 24, 1979; )     

A new type of complementary chromatic adaptation exemplified byPhormidium sp. C86: Changes in the number of peripheral rods and in the stoichiometry of core complexes in phycobilisomes

The marine cyanobacterium Phormidium sp. strain C86 changes the phycobilisome type depending on light quality. Red-light-adapted cells contained hemidiscoidal phycobilisomes with a photosystem II:phycobilisome ratio of 2.2, while green-light-adapted cells exhibited hemiellipsoidal phycobilisomes with a photosystem II:phycobilisome ratio of 4.4, as determined by a combined analysis of freeze-fractured thylakoid membranes and ultrathin sections and by photochemical determinations of photosystems and phycobilisomes. Core complexes of phycobilisomes of red- and green-light-adapted cells were isolated by affinity chromatography and were subsequently separated into two allophycocyanin-containing fractions. The high-molecular-weight fraction, with a sedimentation coefficient of 24 S and a calculated mol. wt. of 860,000, contained complexes of the quaternary structure (α^AP ₉β^AP ₈β^19.5AP)₂· (L_CM)₂ and tricylindrical shape, previously designated AP_CM. This fraction was similar in size in red- and green-light-adapted cells; however, differences were detected in the low-molecular-weight allophycocyanin fraction containing the "trimeric" complexes with a sedimentation coefficient of 6 S. As shown by comparison of spectral and stoichiometric data of intact phycobilisomes and isolated core complexes, the amount of the α^APB-containing core complex (α^AP ₂α^APBβ^AP ₃) · L_C ¹⁰ was greater in core fractions of green-light phycobilisomes, whereas the amount of the core complexes (α^AP ₃β^AP ₃) · L_C ¹⁰, designated AP · L_C ¹⁰, was higher in cores of red-light phycobilisomes. Phormidium sp. is the first organism examined that exhibits a new type of complementary chromatic adaptation by altering the composition of the phycobilisome core and the number and composition of peripheral rods and by changing the ratio of photosystem II to phycobilisomes. A model summarizing the structural consequences of the results is presented. Received: 5 December 1995 / Accepted: 10 April 1995     

Cylindrical Phycobilisomes from a Blue-Green Alga, Anabaena variabilis

Cylindrical 52.5-nm-long phycobilisomes were observed in Anabaenavariabilis, differing from the generally accepted hemidiscoidalmorphology. The central part of such a phycobilisome has a network-likefine structure of slightly greater diameter (16 nm) than theconnected end parts of stacked-disc structure (12 nm in diameter).On the basis of this morphology, the molecular mass of thisphycobilisome was calculated to be 3.27?10⁶, about 60% of whichis accounted for by phycocyanin with the rest being due to allophycocyanin.Separately prepared 23 S allophycocyanin particles with a molecularmass of 1.13?10⁶ have the dimensions (16?23 nm) and network-likefine structure similar to the central part of phycobilisomes,while an aggregate form of phycocyanin (18 S) has a fine structureof stacked discs similar to the connecting end part of phycobilisomes,suggesting that the central part constitutes the core at whichthese phycobilisomes attach to the thylakoid membranes. (Received June 5, 1982; Accepted September 21, 1982)