Genotypic relationships between Prochloron samples from different localities and hosts as determined by DNA-DNA reassociations

Genotypic relationships between seven Prochloron samples isolated from different didemnid ascidian hosts collected at the Palau archipelago and Munda (Solomon Islands) and one cyanobacterial (Synechocystis) strain were determined by DNA-DNA reassociations. Thermal stability values of DNA-DNA hybrids indicate that all Prochloron samples involved are mutually very closely related and only slightly related with the Synechocystis strain. It is concluded that the Prochloron samples tested are representatives of one and the same species.     

Symbiotic Chlorella sp. of the ciliate Paramecium bursaria do not prevent acidification and lysosomal fusion of host digestive vacuoles during infection

Summary. Each symbiotic Chlorella sp. of the ciliate Paramecium bursaria is enclosed in a perialgal vacuole derived from the host digestive vacuole, and thereby the alga is protected from digestion by lysosomal fusion. Algae-free cells can be reinfected with algae isolated from algae-bearing cells by ingestion into digestive vacuoles. To examine the timing of acidification and lysosomal fusion of the digestive vacuoles and of algal escape from the digestive vacuole, algae-free cells were mixed with isolated algae or yeast cells stained with pH indicator dyes at 25 ± 1 °C for 1.5 min, washed, chased, and fixed at various time points. Acidification of the vacuoles and digestion of Chlorella sp. began at 0.5 and 2 min after mixing, respectively. All single green Chlorella sp. that had been present in the host cytoplasm before 0.5 h after mixing were digested by 0.5 h. At 1 h after mixing, however, single green algae reappeared in the host cytoplasm, arising from those digestive vacuoles containing both nondigested and partially digested algae, and the percentage of such cells increased to about 40% at 3 h. At 48 h, the single green algae began to multiply by cell division, indicating that these algae had succeeded in establishing endosymbiosis. In contrast to previously published studies, our data show that an alga can successfully escape from the host’s digestive vacuole after acidosomal and lysosomal fusion with the vacuole has occurred, in order to produce endosymbiosis. Correspondence and reprints: Biological Institute, Faculty of Science, Yamaguchi University, Yoshida 1677-1, Yamaguchi 753-8512, Japan.     

Flocculation of algae using chitosan

Flocculation of three freshwater algae, Spirulina,Oscillatoria and Chlorella, and onebrackish alga, Synechocystis, using chitosan was studiedinthe pH range 4 to 9, and chlorophyll-a concentrations inthe range 80 to 800 mg m^–3, which produces aturbidity of 10 to 100 nephelometric turbidity units (NTU) in water. Chitosanreduced the algal content effectively by flocculation and settling. Theflocculation efficiency is very sensitive to pH, and reached a maximum at pH7.0for the freshwater species, but lower for the marine species. The optimalchitosan concentration that is required to effect maximum flocculation dependedon the concentration of alga. Flocculation and settling were faster whenconcentrations of chitosan higher than optimal are used. The settled algalcellsare intact and live, but will not be redispersed by mechanical agitation. Thede-algated water may be reused to produce fresh cultures of algae.     

Die stoffwechselphysiologischen Benziehungen Zwischen Paramecium bursaria Ehrbg. und Chlorella spec. in der Paramecium bursaria-Symbiose

Zusammenfassung Der endosymbiontische Verband von Paramecium bursaria Ehrbg. mit Chlorella spec. (grünes Paramecium) wurde physiologisch und cytologisch untersucht. Ein Vergleich der Eigenschaften der Symbiosecinheit mit denen der getrennt kultivierten Symbiosepartner ergab die folgenden Merkmale und Unterschiede: 1. Der symbiontische Verband hat bis zu einer Beleuchtungsstärke von 6000 lux eine stärkere Photosyntheseleistung als die aus ihm isolierte und in Massenkultur in einem definierten Medium kultivierte Alge. Algenfreie P. bursaria zeigen nur eine minimale Fähigkeit zur CO₂-Fixierung. 2. Der Kompensationspunkt der Photosynthese liegt beim algenhaltigen Paramecium bei ca. 4000–5000 lux, derjenige der getrennt kultivierten Alge bei ca. 200–400 lux. 3. Die Symbioseeinheit hat im Dunkeln im Vergleich mit algenfreien P. bursaria einen niedrigeren, im Vergleich mit der frei kultivierten Alge jedoch einen höheren Sauerstoffbedarf. 4. Das grüne Paramecium nimmt weniger Kohlenhydrate aus dem Medium auf als algenfreie Paramecien, hat aber eine höhere Aufnahmeleistung als die isoliert gezogenen Algen. 5. Im Symbioseverband besitzt die symbiontische Alge im Licht eine kompakte Lagerung der photosynthetischen Membranen und eine massive Stärkeablagerung. Die Vergiftung der Photosynthese durch 3-(3,4-Dichlorphenyl)-1,1-dimethylharnstoff (DCMU) oder die Kultur im Dunkeln führt in algenhaltigen Paramecien zu einer aufgelockerten Lagerung der Thylakoide und einer Verringerung der Stärkeablagerung. Die Algen-population unterliegt im symbiontischen Verband einem komplexen Regulationsmechanismus, bei dem u. a. der intracelluläre Kohlenhydratspiegel eine Rolle spielt. Die geschilderten Ergebnisse werden im Zusammenhang mit der Ökologie des grünen P. bursaria diskutiert.

---

The metabolic interactions between Paramecium bursaria Ehrbg. and Chlorella spec. in the Paramecium bursaria-symbiosisII. Symbiosis-specific properties of the physiology and the cytology of the symbiotic unit and their regulation

The endosymbiotic association of Paramecium bursaria Ehrbg. with Chlorella spec. (green Paramechim) was studied both physiologically and cytologically. Comparison of the properties of the symbiotic unit with those of the symbiotic partiners which bad been isolated from it revealed the following features and differences: 1. Up to 6000 lux the photosynthetic capacity of the symbiotic unit is higher than that of the isolated symbiotic algae grown independently in mass culture under defined conditions. Alga-free. Paramecium bursaria (colourless Paramecium) show a very low rate of CO₂-fixation. 2. The green Paramecium has a higher compensationpoint of photosynthesis (4000–5000 lux) than the isolated alga (200–400 lux). 3. Green paramecia consume less oxygen in darkness than colourless organisms but more than the isolated algae. 4. The uptake of carbohydrates from the culture medium by green paramecia is lower than the uptake by alga-free P. bursaria but higher than the one of the isolated algae. 5. Symbiotic algae within the intact symbiotic unit show tightly packed photosynthetic membranes and an intense deposition of starch. In the presence of 3-(3,4-Dichlorophenyl)-1,1-dimethylurea (DCMU) or in darkness the arrangement of thylakoids is less compact and the deposition of starch is reduced. The growth and the number of the symbiotic algae in situ is regulated by a complex mechanism to which the intracellular level of carbohydrates belongs. The results are discussed in connection with ecological aspects of the Paramecium bursaria-endosymbiosis.

     

Multiple origins of the symbioses in Paramecium bursaria

Many organisms have symbioses with photosynthetic algae as typified by corals, clams, lichens, and some protozoa. Paramecium bursaria contains green algal symbionts and this unicellular ciliate is a textbook example used for microscopic observation in junior high school science projects. We have determined molecular phylogenies for the green algal symbionts. The symbiotic algae are the main constituent of the Paramecium cytoplasm, and we have recognized a total of four species, of which two were newly discovered in the present study. One should be regarded genetically as Chlorella vulgaris, and it belongs phylogenetically to the Chlorella clade (Chlorellaceae, Trebouxiophyceae) as well as "American" and "European" groups, which we previously introduced. Their genetic dissimilarities are 0.50-0.83% in 18S rDNA comparisons, but those of the internal transcribed spacer 2 (ITS2) reach an unambiguous level (22.6-26.6%). These dissimilarities suggest that they are equivalent to discrete species derived from multiple origins as paramecian symbionts. Another newcomer was clearly separated from the Chlorellaceae, and this alga clustered with Coccomyxa spp. in ITS2 analyses. These symbiotic relations indicate multiple origins of symbionts.     

Nitrogen fixation associated with a hotspring green alga

A unicellular alga which can grow in the light without a combined nitrogen source was isolated from a hot spring. The cells were almost spherical, usually 5–10 m in diameter. Absorption spectra of the watersoluble pigments and of the acetone-extracted ones revealed the existence of chlorophyll a and b and the absence of phycobilins. Thin sections examined by electron microscopy revealed an eukaryotic organization with features typical of the coccoid green algae (the Chlorococcales). Cells divided by internal cytokinesis and subsequent liberation of daughter cells from the parental wall, in a way similar to Chlorella. The alga reduced acetylene to ethylene and incorporated ¹⁵N₂ into cell protoplasm when incubated in a low oxygen atmosphere. Nitrogenase activity was light-dependent, microaerophilic and thermophilic. Although the association of symbiotic nitrogen fixing prokaryotes with the cells may still be possible, any such organisms have not so far been detected.Abbreviations Used DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - Chl chlorophyll - MBM modified Bristol medium - TLC thin layer chromatography     

Preliminary survey of toxicity of the green algaCaulerpa taxifolia introduced into the Mediterranean

Caulerpa taxifolia (Vahl) C. Agardh (Ulvophyceae, Caulerpales) is an alga of tropical origin that was accidentally introduced into the Mediterranean sea in 1984, where this species can reach an abundance that has never been described in tropical endemic regions. It is known that caulerpacean algae can develop an efficient strategy against grazers consisting of the synthesis of repulsive of toxic secondary metabolites: we report here the first study of the toxicity of purified secondary metabolites and raw extracts fromC. taxifolia from the Mediterranean.Toxicity was evaluated on three models: mice (lethality), mammalian cells in culture (cytotoxicity) and sea urchin eggs (disturbance of cell proliferation). Aqueous extracts are only active on fibroblasts and mice. In the three toxicity models a seasonal variation of toxicity is observed for the crude methanol extract as well as a decrease of this activity whenC. taxifolia from the Mediterranean is kept in aquaria. Pure compounds exhibit different toxicity depending on the assay. 10,11-epoxycaulerpenyne is the most active substance on mice and fibroblasts whereas taxifolial A and D are inactive or only weakly toxic. Among the four tested compounds caulerpenyne, the major metabolite ofC. taxifolia, is the most active on sea urchin eggs. Caulerpenyne may therefore represent an ecological risk for microorganisms and the eggs of multicellular animals living close to this alga. The ecological impact of this toxicity on marine organisms and the interaction of this alga with the herbivorous fauna are discussed.     

Evaluation of central metabolism based on a genomic database of<Emphasis Type="Italic">Synechocystis</Emphasis> PCC6803

Cyanobacteria produce industrially important secondary metabolites such as lipopeptide, oligosaccharide, fatty acid (esp. sulfolipid),etc. Among them,Synechocystis PCC6803 is the first strain with a publicly available full genome sequence, as of 1996, and is one of the most extensively studied photosynthetic microorganisms. Using this genomic information, the central metabolism ofSynechocystis PCC6803 was reconstructed, including photosynthesis, oxidative phosphorylation, glycolysis, pyruvate metabolism, TCA cycle, carbon fixation, and transport system. Each biochemical reaction was carefully incorporated into the model, taking into consideration the metabolite formula, stoichiometry, charge balance, and thermodynamic properties using information from genomic and metabolic databases as well as biochemical literature. The metabolic flux of the model was calculated using flux balance analysis according to its cultivation with various carbon sources. The results of simulation were in accordance with experimental data, which suggests that the central metabolism model can properly estimate the behavior ofSynechocystis PCC6803. This model would aid in the understanding of the whole cell metabolism ofSynechocystis PCC6803, the first effort of its kind for photosynthetic bacteria.     

The toxicity of phenolic compounds to soil algal population and toChlorella vulgaris andNostoc linckia

Summary p-Nitrophenol (PNP),m-nitrophenol (MNP), 2,4-dinitrophenol (DNP) and catechol were tested for their effects on algal population in a soil and on pure cultures of two algae isolated from soil. Both PNP and MNP, even at 0.5 kg ha⁻¹ level were toxic to the soil algae; high doses effected increase in toxicity. Inhibition of algae was relatively more with PNP compared to the other two nitrophenols. Catechol treatment up to 1.0 kg ha⁻¹ led to a significant initial enhancement of algae with a subsequent far less toxic effect. The toxicity of the phenolic compounds towardChlorella vulgaris, a green alga andNostoc linckia, a blue-green alga, decreased in the order: MNP≧PNP>DNP>Catechol. However, algicidal or algistatic effect of the test chemicals was fairly more againstC. vulgaris, suggesting that the eukaryotic alga is highly sensitive to such soil pollutants compared to the prokaryotic alga.     

Structural features of the plastid ribosomal RNA operons of two red algae: Antithamnion sp. and Cyanidium caldarium

The nucleotide sequences of the plastid 16S rDNA of the multicellular red alga Antithamnion sp. and the 16S rDNA/23S rDNA intergenic spacers of the plastid DNAs of the unicellular red alga Cyanidium caldarium and of Antithamnion sp. were determined. Sequence comparisons support the idea of a polyphyletic origin of the red algal and the higher-plant chloroplasts. Both spacer regions include the unsplit tRNA^Ile (GAU) and tRNA^Ala (UGC) genes and so the plastids of both algae form a homogeneous group with those of chromophytic algae and Cyanophora paradoxa characterized by small-sized rDNA spacers in contrast to green algae and higher plants. Nevertheless, remarkable sequence differences within the rRNA and the tRNA genes give the plastids of Cyanidium caldarium a rather isolated position.     

Hyphomorpha als Phycobiont in Flechten

Hyphomorpha, a genus of theStigonematales, is confirmed to be a phycobiont in twoSpilonema species (Coccocarpiaceae). The morphology of the symbiotic algae inSpilonema dendroides andS. schmidtii is described. The phycobiont inS. dendroides is possiblyHyphomorpha antillarum, the alga inS. schmidtii might be a species related toH. perrieri. New localities for the rare lichens are reported: Alaska forS. dendroides and Ceylon forS. schmidtii.

     

Directed inactivation of the psbl gene does not affect Photosystem II in the cyanobacterium Synechocystis sp. PCC 6803

PsbI is a small, integral membrane protein component of photosystem II (PSII), a pigment-protein complex in cyanobacteria, algae and higher plants. To understand the function of this protein, we have isolated the psbI gene from the unicellular cyanobacterium Synechocystis sp. PCC 6803 and determined its nucleotide sequence. Using an antibiotic-resistance cartridge to disrupt and replace the psbI gene, we have created mutants of Synechocystis 6803 that lack the PsbI protein. Analysis of these mutants revealed that absence of the PsbI protein results in a 25–30% loss of PSII activity. However, other PSII polypeptides are present in near wild-type amounts, indicating that no significant destabilization of the PSII complex has occurred. These results contrast with recently reported data indicating that PsbI-deficient mutants of the eukaryotic alga Chlamydomonas reinhardtii are highly light-sensitive and have a significantly lower (80–90%) titer of the PSII complex. In Synechocystis 6803, PsbI-deficient cells appear to be slightly more photosensitive than wild-type cells, suggesting that this protein, while not essential for PSII biogenesis or function, plays a role in the optimization of PSII activity.     

The endosymbiotic unit ofClimacostomum virens andChlorella sp. I. Morphological and physiological studies on the algal partner and its localization in the host cell

Summary The ciliateClimacostomum virens forms an endosymbiotic association with coccoid chlorophycean algae which can be isolated and grown as sterile mass cultures with an inorganic medium. According to both morphological and physiological properties, the algae probably belong to the genusChlorella and have some features in common with symbiotic chlorellae isolated from the ciliatesParamecium bursaria andStentor polymorphus. These and other endosymbiotic chlorellae studied so far excrete maltose or glucose, but algae fromClimacostomum virens show a different excretion pattern by releasing glucose, fructose and xylose. Possible biosynthetic pathways are discussed. Algae inClimacostomum virens are either located individually in special perialgal vacuoles where they are probably protected against attack by host lytic enzymes or to a lesser extent in food vacuoles in different states of digestion. The endosymbiotic character of theClimacostomum virens-Chlorella sp.-association is discussed.Dedicated to Prof. H. A.von Stosch on the occasion of his 75th birthday.     

Evaluation of extraction methods for recovery of fatty acids from Botryococcus braunii LB 572 and Synechocystis sp. PCC 6803

Microalgae are a very diverse group of organisms that consist in both prokaryotic and eukaryotic forms. Some species of microalgae can be induced to overproduce particular fatty acids through simple manipulations of the physical and chemical properties of the culture medium. In this paper, the effect of different extraction techniques on the recovery of fatty acids from the freeze-dried biomass from two lipid-producing microalgal strains: Botryococcus braunii LB 572 (green algae) and Synechocystis sp. PCC 6803 (cyanobacteria) was examined. Five procedures were used: after conversion of the lipid material into the corresponding fatty acid methyl esters (FAMEs) via suitable derivatization reactions (extraction-transesterification) and direct transesterification of biomass to produce FAMEs (without the initial extraction step) that used differential types of catalysts and processing conditions. This study has shown that procedure 3, a one step practical procedure for lipid extraction and in situ methyl ester derivation could be used successfully for the determination of the fatty acid compositions of microalgae and cyanobacteria.     

Heat shock Hsp70 protein is chloroplast-encoded in the chromophytic alga Pavlova lutherii

Heat shock proteins are ubiquitous and highly conserved. Recently they have become implicated in the import of proteins into organelles. All the heat shock genes characterized to date, however, are known or assumed to be encoded in the nuclear genome even if the corresponding protein can be localised in the mitochondrion or chloroplast. In contrast, we identify here an hsp70 gene in the unicellular chromophytic alga Pavlova lutherii which is located on the chloroplast genome. Localisation of this gene to the chloroplast chromosome is confirmed by Southern blot analysis and pulse-field gel electrophoresis which also reveals that the length of the P. lutherii chloroplast chromosome is 115 kb. We compare the predicted protein of this hsp70 gene with that of maize and of the analogous proteins in the prokaryotic organisms Escherichia coli and Synechocystis PCC6803. The greatest identity is found with the cyanobacterium Synechocystis PCC6803.     

Further acetogenins from Tasmanian collections of Caulocystis cephalornithos demonstrating chemical variability

Samples of the brown alga Caulocystis cephalornithos, from five locations in southern and southeastern Tasmania, were investigated for comparison of their acetogenin content. In contrast with previously studied brown algae, including mainland Australian collections of C. cephalornithos, Tasmanian collections of C. cephalornithos were found to contain unusually high levels of tridec-1-ene, a hydrocarbon not previously reported from a marine alga. The novel metabolite (E)-nonadec-3-en-2-one was also isolated. Compounds previously described from this alga were present, together with a suite of homologues not previously observed in this species. The compounds present suggested that the alkyl chain of the orsellinic acid derivatives was present prior to cyclisation. Large variations in relative metabolite content were observed both within and between collection sites.     

Muramic acid in the cell walls of Prochloron

Muramic acid has been detected in Prochloron with the aid of two different techniques. It was assayed by cleaving D-lactate from muramic acid and then reducing NAD with D-lactate dehydrogenase and measuring the NADH with bacterial luciferase. Gas-liquid chromatography of trimethylsilyl derivatives of cell extracts confirmed that muramic acid was present in about the quantity given by the D-lactate assay. The amount of muramic acid present was 1.7±0.2 g/mg dry weight or 1.3fg/m² of cell surface. This suggests that the thickness of the peptidoglycan layer in Prochloron is similar to that in blue-green algae.Abbreviations D-LDH d-lactate dehydrogenase - MA muramic acid - TMS trimethylsilyl - TLE thin layer electrophoresis - GLC gas-liquid chromatography     

Intracellular coagulation inhibits the extraction of proteins from Prochloron

Protein extraction from the prokaryotic alga Prochloron LP (isolated from the ascidian host Lissoclinum patella) was complicated by an irrevers     

Divergence of the mitochondrial electron transport chains from the green alga Chlamydomonas reinhardtii and its colorless close relative Polytomella sp.

Compelling evidence exists that the colorless algae of the genus Polytomella arose from a green Chlamydomonas-like ancestor by losing its functional photosynthetic apparatus. Due to the close relationship between the colorless and the green chlorophyte, Polytomella sp. appeared as a useful indicative framework for structural studies of Chlamydomonas reinhardtii mitochondria. However, comparative studies reported here unexpectedly revealed significant differences between the mitochondrial respiratory systems of the two algae. Two-dimensional blue native/SDS-PAGE of isolated mitochondria indicated that cytochrome-containing respiratory complexes III and IV in the two chlorophytes contrast in size, subunit composition and relative abundance. Complex IV in Polytomella is smaller than its counterpart in C. reinhardtii and occurs in two forms that differ presumably in the presence of subunit COXIII. The cytochrome c and the iron-sulfur Rieske protein of both chlorophytes revealed structural differences on the amino acid sequence level. Under comparable culture conditions, the colorless alga exhibits lower levels of cytochrome c and complex IV but a higher respiratory activity than the green alga. Cytochrome c levels were also found to be differently regulated by the growth conditions in both algae. The divergence between the respiratory systems in the two related chlorophytes can be viewed as a consequence of the loss of photosynthetic activity and/or of the adaptation to the environment via the acquisition of a more flexible, heterotrophic metabolism. Our understanding of mitochondrial function and evolution is expected to be greatly enhanced via further parallel studies of photosynthetic/non-photosynthetic algae, for which this study forms an incentive.     

Photobehaviour of Paramecium bursaria infected with different symbiotic and aposymbiotic species of Chlorella

The endosymbiotic unit of Paramecium bursaria and Chlorella spec. shows two types of photobehaviour: 1) A step-up photophobic response which possibly depends on photosensitive agents in the ciliate cell itself — as is also shown by alga-free Paramecium bursaria - and can be drastically enhanced by photosynthetic activity of symbiotic algae; and 2) a step-down photophobic response. The step-down response leads to photoaccumulation of green paramecia. Both types of photobehaviour in Paramecium bursaria do not depend on any special kind of algal partners: The infection of alga-free Paramecium bursaria with different Chlorella species results in new ciliatealgae-associations. They are formed not only by combination of the original symbiotic algae with their host, but also by infection with other symbiotic or free-living (aposymbiotic) chlorellae, respecitively. Systems with other than the original algae are not permanently stable — algae are lost under stress conditions — but show the same types of photobehaviour. Photoaccumulation in general requires algal photosynthesis and occurs only with ciliates containing more than fifty algae/cell. It is not mediated by a chemotactic response to oxygen in the medium, since it occurs at light fluence rates not sufficient for a release of oxygen by the symbiotic system, e.g., below its photosynthetic compensation point. Photoresponses can be inhibited by 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU). Sensory transduction does not depend on any special symbiotic features of the algae, e.g., sugar excretion. The participation of oxygen in the Paramecium cell, of its cytoplasmic pH and of ions released or taken up by endosymbiotic algae in sensory transduction is discussed.