The Hydra viridis/Chlorella symbiosis. Growth and sexual differentiation in polyps without symbionts

To investigate interactions between the basal metazoan Hydra viridis and its symbiotic Chlorella algae, we generated aposymbiotic hydra lacking algae and compared them to symbiotic ones with regard to growth and sexual differentiation. Under standard feeding conditions aposymbiotic polyps proliferated similarly to symbiotic polyps. Under moderate and low feeding conditions asexual growth was reduced in polyps lacking algae, indicating that the symbionts supply nutrients to their hosts. In addition, the Chlorella symbionts had a strong influence on the sexual reproduction of Hydra viridis: in most cases female gonads were produced only when symbiotic algae were present. Spermatogenesis proceeded similarly in symbiotic and aposymbiotic polyps. Since during oogenesis symbionts are actively transferred from endodermal epithelial cells to the ectodermal oocytes, this oogenesis promoting role could indicate that the symbionts are critically involved in the control of sexual differentiation in green hydra.     

Cycloheximide induces synchronous swelling of perialgal vacuoles enclosing symbiotic Chlorella vulgaris and digestion of the algae in the ciliate Paramecium bursaria

Cycloheximide is known to inhibit preferentially protein synthesis of symbiotic Chlorella of the ciliate Paramecium bursaria, but to hardly host protein synthesis. Treatment of algae-bearing Paramecium cells with cycloheximide induces synchronous swelling of all perialgal vacuoles that are localized immediately beneath the host's cell membrane. In this study, the space between the symbiotic algal cell wall and the perialgal vacuole membrane widened to about 25 times its normal width 24 h after treatment with cycloheximide. Then, the vacuoles detached from beneath the host's cell membrane, were condensed and stained with Gomori's solution, and the algae in the vacuoles were digested. Although this phenomenon is induced only under a fluorescent light condition, and not under a constant dark condition, this phenomenon was not induced in paramecia treated with cycloheximide in the light in the presence of the photosynthesis inhibitor 3-(3,4-dichlorophenyl)-1,1-dimethylurea. These results indicate that algal proteins synthesized in the presence of algal photosynthesis serve some important function to prevent expansion of the perialgal vacuole and to maintain the ability of the perialgal vacuole membrane to protect itself from host lysosomal fusion.     

Chlorella variabilis and Micractinium reisseri sp. nov. (Chlorellaceae,Trebouxiophyceae): Redescription of the endosymbiotic green algae of Paramecium bursaria (Peniculia,Oligohymenophorea) in the 120th year

Symbiotic algae of the ciliate Paramecium bursaria (Ehrenberg) Focker are key species in the fields of virology and molecular evolutionary biology as well as in the biology of symbiotic relationships. These symbiotic algae were once identified as Zoochlorella conductrix Brandt by the Dutch microbiologist, Beijerinck 120 years ago. However, after many twists and turns, the algae are today treated as nameless organisms. Recent molecular analyses have revealed several different algal partners depending on P. bursaria strains, but nearly all P. bursaria contains a symbiont belonging to either the so‐called ‘American’ or ‘European’ group. The absence of proper names for these algae is beginning to provoke ill effects in the above‐mentioned study areas. In the present study, we confirmed the genetic autonomy of the ‘American’ and ‘European’ groups and described the symbionts as Chlorella variabilis Shihira et Krauss and Micractinium reisseri Hoshina, Iwataki et Imamura sp. nov., respectively (Chlorellaceae, Trebouxiophyceae).     

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.     

Phylogenetic position of endosymbiotic green algae in Paramecium bursaria Ehrenberg from Japan

Endosymbiotic green algae of Japanese Paramecium bursaria were phylogenetically analyzed based on DNA sequences from the ribosomal DNA operon (18S rDNA, ITS1, 5.8S rDNA, and ITS2). Phylogenetic trees constructed using 18S rDNA sequences showed that the symbionts belong to the Chlorella sensu stricto (Trebouxiophyceae) group. They are genetically closer to the C. vulgaris Beijerinck group than to C. kessleri Fott et Nováková as proposed previously. Branching order in C. vulgaris group was unresolved in 18S rDNA trees. Compared heterogeneities of 18S rDNA, ITS1, 5.8S r, and ITS2 among symbionts and two Chlorella species, indicated that the ITS2 region (and probably also ITS1) is better able to resolve phylogenetic problems in such closely related taxa. All six symbiotic sequences obtained here (approximately 4000-bp sequences of 18S rDNA, ITS1, 5.8S rDNA, and ITS2) were completely identical in each, strongly suggesting a common origin.     

Establishment of axenic endosymbiotic strains of Japanese Paramecium bursaria and the utilization of carbohydrate and nitrogen compounds by the isolated algae

Cells of the green paramecium, Paramecium bursaria, contain several hundred endosymbiont cells. The properties of the symbionts are considered to vary depending on the collection site of the host. Difficulties in achieving axenic cells and maintenance of axenic strains for long periods have been reported for symbiotic algae from P. bursaria isolated in Japan. To establish axenic algal strains from such Japanese P. bursaria, symbionts were isolated carefully, and isolated axenic strains were grown on an agar medium containing organic nitrogen compounds. Symbiotic algal strains were obtained from three Japanese P. bursaria strains and their axenicity was confirmed by DAPI staining, cultural tests of bacterial contamination, and DGGE-PCR. These axenic strains have been maintained for over 2 years. Utilization of carbohydrates and nitrogen compounds by symbionts was examined. Monosaccharides (glucose and fructose) increased the growth of the symbiont but disaccharides (maltose and sucrose) did not. Japanese axenic symbionts were able to use ammonia and amino acids, but not nitrate or nitrite. While potent nitrite reductase activity was stimulated by nitrate induction, nitrate reductase activity was not. Nitrate utilization of Japanese symbionts differed from that reported for European and American symbionts.     

Association of Paramecium bursaria Chlorella viruses with Paramecium bursaria cells: ultrastructural studies

Paramecium bursaria Chlorella viruses were observed by applying transmission electron microscopy in the native symbiotic system Paramecium bursaria (Ciliophora, Oligohymenophorea) and the green algae Chlorella (Chlorellaceae, Trebouxiophyceae). Virus particles were abundant and localized in the ciliary pits of the cortex and in the buccal cavity of P. bursaria. This was shown for two types of the symbiotic systems associated with two types of Chlorella viruses - Pbi or NC64A. A novel quantitative stereological approach was applied to test whether virus particles were distributed randomly on the Paramecium surface or preferentially occupied certain zones. The ability of the virus to form an association with the ciliate was investigated experimentally; virus particles were mixed with P. bursaria or with symbiont-free species P. caudatum. Our results confirmed that in the freshwater ecosystems two types of P. bursaria -Chlorella symbiotic systems exist, those without Chlorella viruses and those associated with a large amount of the viruses. The fate of Chlorella virus particles at the Paramecium surface was determined based on obtained statistical data and taking into account ciliate feeding currents and cortical reorganization during cell division. A life cycle of the viruses in the complete symbiotic system is proposed.     

An experimental test of the symbiosis specificity between the ciliate Paramecium bursaria and strains of the unicellular green alga Chlorella

The ciliate Paramecium bursaria living in mutualistic relationship with the unicellular green alga Chlorella is known to be easily infected by various potential symbionts/parasites such as bacteria, yeasts and other algae. Permanent symbiosis, however, seems to be restricted to Chlorella taxa. To test the specificity of this association, we designed infection experiments with two aposymbiotic P. bursaria strains and Chlorella symbionts isolated from four Paramecium strains, seven other ciliate hosts and two Hydra strains, as well as three free-living Chlorella species. Paramecium bursaria established stable symbioses with all tested Chlorella symbionts of ciliates, but never with symbiotic Chlorella of Hydra viridissima or with free-living Chlorella. Furthermore, we tested the infection specificity of P. bursaria with a 1:1:1 mixture of three compatible Chlorella strains, including the native symbiont, and then identified the strain of the newly established symbiosis by sequencing the internal transcribed spacer region 1 of the 18S rRNA gene. The results indicated that P. bursaria established symbiosis with its native symbiont. We conclude that despite clear preferences for their native Chlorella, the host-symbiont relationship in P. bursaria is flexible.     

Value of the Hydra model system for studying symbiosis

Green Hydra is used as a classical example for explaining symbiosis in schools as well as an excellent research model. Indeed the cosmopolitan green Hydra (Hydra viridissima) provides a potent experimental framework to investigate the symbiotic relationships between a complex eumetazoan organism and a unicellular photoautotrophic green algae named Chlorella. Chlorella populates a single somatic cell type, the gastrodermal myoepithelial cells (also named digestive cells) and the oocyte at the time of sexual reproduction. This symbiotic relationship is stable, well-determined and provides biological advantages to the algal symbionts, but also to green Hydra over the related non-symbiotic Hydra i.e. brown hydra. These advantages likely result from the bidirectional flow of metabolites between the host and the symbiont. Moreover genetic flow through horizontal gene transfer might also participate in the establishment of these selective advantages. However, these relationships between the host and the symbionts may be more complex. Thus, Jolley and Smith showed that the reproductive rate of the algae increases dramatically outside of Hydra cells, although this endosymbiont isolation is debated. Recently it became possible to keep different species of endosymbionts isolated from green Hydra in stable and permanent cultures and compare them to free-living Chlorella species. Future studies testing metabolic relationships and genetic flow should help elucidate the mechanisms that support the maintenance of symbiosis in a eumetazoan species.     

Amino acids as a nitrogen source for Chlorella symbiotic with green hydra

Supply of amino acids may be important in controlling cell division of Chlorella symbiotic with green hydra. Freshly isolated symbionts display characteristics of N-limited algae, and low pH in perialgal vacuoles and high levels of host glutamine synthetase (GS) limit uptake of ammonium. Movement of tritiated amino acids from host to algal pools suggests that symbiotic algae utilize amino acids derived from host digestion of prey. Amounts are significant in relation to host and algal amino acids pools. During host starvation, glutamine produced by host GS may be important as a nitrogen supply to the algae, which take up this amino acid at high rates at low pH.     

Slow algae, fast fungi: exceptionally high nucleotide substitution rate differences between lichenized fungi Omphalina and their symbiotic green algae Coccomyxa

Omphalina basidiolichens are obligate mutualistic associations of a fungus of the genus Omphalina (the exhabitant) and a unicellular green alga of the genus Coccomyxa (the inhabitant). It has been suggested that symbiotic inhabitants have a lower rate of genetic change compared to exhabitants because the latter are more exposed to abiotic environmental variation and competition from other organisms. In order to test this hypothesis we compared substitution rates in the nuclear ribosomal internal transcribed spacer region (ITS1, 5.8S, ITS2) among fungal species with rates among their respective algal symbionts. To ensure valid comparisons, only taxon pairs (12) with a common evolutionary history were used. On average, substitution rates in the ITS1 portion of Omphalina pairs were 27.5 times higher than rates in the corresponding pairs of Coccomyxa since divergence from their respective ancestor at the base of the Omphalina/Coccomyxa lineage. Substitution rates in the 5.8S and the ITS2 portions were 2.4 and 18.0 times higher, respectively. The highest rate difference (43.0) was found in the ITS1 region. These are, to our knowledge, the highest differences of substitution rates reported for symbiotic organisms. We conclude that the Omphalina model system conforms to the proposed hypothesis of lower substitution rates in the inhabitant, but that the mode of transmission of the inhabitant (vertical versus horizontal) could be a prevailing factor in the regulation of unequal rates of nucleotide substitution between co-evolving symbionts. Our phylogenetic study of Coccomyxa revealed three main lineages within this genus, corresponding to free-living Coccomyxa, individuals isolated from basidiolichens Omphalina and Coccomyxa isolated from ascolichens belonging to the Peltigerales.     

Genotype versus phenotype variability in Chlorella and Micractinium (Chlorophyta, Trebouxiophyceae)

The most recent revision of the genus Chlorella, based on biochemical and SSU rDNA analyses, suggested a reduction to a set of four "true" spherical Chlorella species, while a growing number of morphologically different species such as Micractinium (formerly Micractiniaceae) were found to cluster within the clade of "true"Chlorella. In this study, the generic concept in Chlorellaceae to Chlorella and Micractinium was evaluated by means of combined SSU and ITS-2 rDNA sequence analyses and biotests to induce development of bristles on the cell wall. Molecular phylogenetic analyses of Chlorella and Micractinium strains confirmed their separation into two different genera. In addition, non-homoplasious synapomorphies (NHS) and compensatory base changes (CBC) in the secondary structures of SSU and ITS-2 rDNA sequences were found for both genera using this approach. The Micractinium clade can be differentiated into three different genotypes. Using culture medium of the rotifer Brachionus calyciflorus, phenotypic plasticity in Chlorella and Micractinium was studied. Non-bristled Micractinium cells developed bristles during incubation with Brachionus culture medium, whereas Chlorella did not produce bristles. Grazing experiments with Brachionus showed the rotifer preferred to feed on non-bristled cells. The dominance of colonies versus solitary cells in the Micractinium culture was not correlated with the "Brachionus factor". These results suggest that morphological characteristics like formation of bristles represent phenotypic adaptations to the conditions in the ecosystem.     

Phagosome-lysosome fusion inhibited by algal symbionts of Hydra viridis

Certain species of Chlorella live within the digestive cells of the fresh water cnidarian Hydra viridis. When introduced into the hydra gut, these symbiotic algae are phagocytized by digestive cells but avoid host digestion and persist at relatively constant numbers within host cells. In contrast, heat-killed symbionts are rapidly degraded after phagocytosis. Live symbionts appear to persist because host lysosomes fail to fuse with phagosomes containing live symbionts. Neither acid phosphatase nor ferritin was delivered via lysosomes into phagosomes containing live symbionts, whereas these lysosomal markers were found in 50% of the vacuoles containing heat-killed symbionts 1 h after phagocytosis. Treatment of symbiotic algae before phagocytosis with polycationic polypeptides abolishes algal persistence and perturbs the ability of these algae to control the release of photosynthate in vitro. Similarly, inhibition of photosynthesis and hence of the release of photosynthetic products as a result of prolonged darkness and 3-(3,4- dichlorophenyl)-1,1-dimethyl urea (DCMU) treatment also abolishes persistence. Symbiotic algae are not only protected from host digestive attack but are also selectively transported within host cells, moving from the apical site of phagocytosis to a basal position of permanent residence. This process too is disrupted by polycationic polypeptides, DCMU and darkness. Both algal persistence and transport may, therefore, be a function of the release of products from living, photosynthesizing symbionts. Vinblastine treatment of host animals blocked the movement of algae within host cells but did not perturb algal persistence: algal persistence and the transport of algae may be initiated by the same signal, but they are not interdependent processes.     

Identification of an algal carbon fixation-enhancing factor extracted from Paramecium bursaria

The green ciliate Paramecium bursaria contains several hundred symbiotic Chlorella species. We previously reported that symbiotic algal carbon fixation is enhanced by P. bursaria extracts and that the enhancing factor is a heat-stable, low-molecular-weight, water-soluble compound. To identify the factor, further experiments were carried out. The enhancing activity remained even when organic compounds in the extract were completely combusted at 700 degrees C, suggesting that the factor is an inorganic substance. Measurement of the major cations, K+, Ca2+, and Mg2+, by an electrode and titration of the extract resulted in concentrations of 0.90 mM, 0.55 mM, and 0.21 mM, respectively. To evaluate the effect of these cations, a mixture of the cations at the measured concentrations was prepared, and symbiotic algal carbon fixation was measured in the solution. The results demonstrated that the fixation was enhanced to the same extent as with the P. bursaria extract, and thus this mixture of K+, Ca2+, and Mg2+ was concluded to be the carbon fixation-enhancing factor. There was no effect of the cation mixture on free-living C. vulgaris. Comparison of the cation concentrations of nonsymbiotic and symbiotic Paramecium extracts revealed that the concentrations of K+ and Mg2+ in nonsymbiotic Paramecium extracts were too low to enhance symbiotic algal carbon fixation, suggesting that symbiotic P. bursaria provide suitable cation conditions for photosynthesis to its symbiotic Chlorella.     

Die stoffwechselphysiologischen Beziehungen zwischen Paramecium bursaria Ehrbg. und Chlorella spec. in der Paramecium bursaria-Symbiose

Zusammenfassung Infektionsexperimente algenfreier Paramecium bursaria mit aus diesen isolierten und unter Stickstoffmangel-Bedingungen vorkultivierten Algen deuten darauf hin, daß die Versorgung der endosymbiontischen Algen mit stickstoffhaltigen Verbindungen durch ihren Wirt in einem zu gutem Wachstum und Vermehrung der Alge ausreichendem Maße möglich ist. Die Bedeutung dieser stoffwechselphysiologischen Beziehung für die Symbiosepartner wird diskutiert.Die Vergiftung der Photosynthese der endosymbiontischen Chlorella durch 3-(3,4-Dichlorphenyl)-1,1-dimethylharnstoff (DCMU) führt in grünen Paramecium bursaria durch Beeinflussung des Kohlenstoff-Stoffwechsels zu einer Entkoppelung des symbiontischen steady state-Systems und damit zur Auflösung der Symbiose. Eine ausreichende heterotrophe Ernährung der Alge durch das Paramecium ist in der Symbiose offenbar nicht möglich.Die Anwendung von 3-(3,4-Dichlorphenyl)-1,1-dimethylharnstoff (DCMU) kann als neue Methode zur Züchtung algenfreier Paramecium bursaria dienen.

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The metabolic interactions between Paramecium bursaria Ehrbg. and Chlorella spec. in the Paramecium bursaria-symbiosisI. The nitrogen and the carbon metabolism

Symbiotic Chlorellae have been isolated from Paramecium bursaria Ehrbg. and cultivated under conditions of nitrogen deficiency. Reinfection of Chlorella-free Paramecium bursaria with these nitrogen-deficient algae resulted in a complete regeneration and multiplication of the algae within the host cells. The endosymbiotic algal cells of the Paramecium bursaria-symbiosis can be supplied by their host with nitrogen.The inhibition of photosynthesis by 3-(3,4-Dichlorophenyl)-1,1-dimethylurea (DCMU) leads in green Paramecium bursaria to a breakdown of the symbiotic steady state-system resulting in a loss of algal cells. Obviously the endosymbiotic algae cannot be fed heterotrophically by their host to such an extent that a stable symbiosis is maintained.The application of 3-(3,4-Dichlorophenyl)-1,1-dimethylurea (DCMU) can be used as a new method for culturing Chlorella-free Paramecium bursaria.

     

Comparative studies on photosynthetic enzymes of the symbiotic Chlorella from Paramecium bursaria and other symbiotic and non-symbiotic Chlorella strains

The activities of ribulose 1,5-bisphosphate carboxylase and of carbonic anhydrase were studied in cell-free extracts of two symbiotic Chlorella strains isolated from Paramecium bursaria and from Spongilla sp., and of two nonsymbiotic strains of Chlorella (Chlorella fusca and Chlorella vulgaris) cultivated at varied CO₂-concentrations. The symbiotic Chlorella of Paramecium bursaria differs distinctly from the other Chlorella strains by a higher activity of ribulose 1,5-bisphosphate carboxylase, which is independent of the actual CO₂-concentration, and by a lack of carbonic anhydrase activity. These properties are discussed with respect to their ecological significance.Abbreviations CA carbonic anhydrase - Pbi Paramecium bursaria isolate - RuBP ribulose 1,5-bisphosphate Dedicated to Prof. Dr. André Pirson on the occasion of his 70th birthday     

Delay in migration of symbiotic algae in Hydra viridis by inhibitors of microtubule protein polymerization

An English strain of the fresh water symbiotic coelenterate Hydra viridis was experimentally "bleached" of its Chlorella algae and maintained indefinitely by feeding. The algal symbiosis could be re-established by injecting other symbiotic algae into aposymbionts. Although algal uptake and recognition were not affected by microtubule protein polymerization inhibitors, these compounds i.e., podophyllotoxin, beta-peltatin and vinblastine had delaying effects on the migration of the algae through the host digestive cells. Picropodophyllotoxin did not delay migration. The rates, the reversibility and the sensitivity of algal migration to low concentrations of drugs known to bind tubulin suggests the symbionts migrate somehow via labile polymerization of host hydra tubulin into microtubules.     

Glucose uptake by symbiotic Chlorella in the green-hydra symbiosis

There is a correlation between the ability of symbiotic Chlorella algae to take up glucose and their survival in green hydra grown in continuous darkness. Although normal symbionts of European green hydra, which persist at a stable level in dark-grown animals, possessed no detectable constitutive ability to take up glucose when grown in light, uptake was induced after incubation in a medium containing glucose. Further, symbionts isolated from hydra grown in darkness for two weeks had acquired a constitutive uptake ability. Neither NC64A nor 3N813A strains of algae, in artificial symbiosis with hydra, persisted in dark-grown animals, and they showed little or no uptake ability, although in culture NC64A possessed both constitutive and inducible glucose-uptake mechanisms. In contrast, mitotic indices in all three types of algae in symbiosis with hydra increased after host feeding, indicating that the factor which stimulates algal cell division is not identical to the substrate utilised during heterotrophic growth.Abbreviations E/E normal Hydra-Chlorella symbiosis - E/NC, E/3N artificial symbioses between Hydra and Chlorella strains NC64A and 3N813A, respectively - 3-OMG 3-O-methyl-D-glucose - SDS sodium dodecyl sulfate     

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.