Oxana V. Kaluzhnaya

Cold stress defense in the freshwater sponge Lubomirskia baicalensis

The endemic freshwater sponge Lubomirskia baicalensis lives in Lake Baikal in winter (samples from March have been studied) under complete ice cover at near 0°C, and in summer in open water at 17 °C (September). In March, specimens show high metabolic activity as reflected by the production of gametes. L. baicalensis lives in symbiosis with green dinoflagellates, which are related to Gymnodinium sanguineum. Here we show that these dinoflagellates produce the toxin okadaic acid (OA), which is present as a free molecule as well as in a protein‐bound state. In metazoans OA inhibits both protein phosphatase‐2A and protein phosphatase‐1 (PP1). Only cDNA corresponding to PP1 could be identified in L. baicalensis and subsequently isolated from a L. baicalensis cDNA library. The deduced polypeptide has a molecular mass of 36 802 Da and shares the characteristic domains known from other protein phosphatases. As determined by western blot analysis, the relative amount of PP1 is almost the same in March (under ice) and September (summer). PP1 is not inhibited by low OA concentrations (100 nm); concentrations above 300 nm are required for inhibition. A sponge cell culture system (primmorphs) was used to show that at low temperatures (4 °C) expression of hsp70 is strongly induced and hsp70 synthesis is augmented after incubation with 100 nm OA to levels measured at 17 °C. In the enriched extract, PP1 activity at 4 °C is close to that measured at 17 °C. Immunoabsorption experiments revealed that hsp70 contributes to the high protein phosphatase activity at 4 °C. From these data we conclude that the toxin OA is required for the expression of hsp70 at low temperature, and therefore contributes to the cold resistance of the sponge.

Dynamics of skeleton formation in the Lake Baikal sponge Lubomirskia baicalensis. Part II. Molecular biological studies

In a preceding study it has been reported that the freshwater sponge Lubomirskia baicalensis, living in Lake Baikal (East Siberia), is composed of spicules forming a characteristic pattern which follows radiate accretive growth. Here we report that the spicules are synthesized by the enzyme silicatein, a protein which is related to cathepsin L. The cDNAs for silicatein and the related cathepsin L were isolated and used as probes to show that the mRNA levels of silicatein in the bases of the spicule skeleton of the animals are low, while the mRNA level of cathepsin L in this region exceeds that of the growing zone. This is the first comprehensive study on the importance of the axial filament/silicatein as an essential structural and functional component determining the growth and stability of demosponge spicules.

Diversity of 16S rRNA genes in metagenomic community of the freshwater sponge Lubomirskia baicalensis

Phylogenetic analysis of the nucleotide sequences of 16S rRNA genes in the metagenomic community of Lubomirskia baicalensis has revealed taxonomic diversity of bacteria associated with the endemic freshwater sponge. Fifty-four operational taxonomic units (OTUs) belonging to six bacterial phyla (Actinobacteria, Proteobacteria (class α-Proteobacteria and β-Proteobacteria) Verrucomicrobia, Bacteroidetes, Cyanobacteria, and Nitrospira) have been identified. Actinobacteria, whose representatives are known as antibiotic producers, is the dominant phylum of the community (37%, 20 OTUs). All sequences detected shared the maximal homology with unculturable microorganisms from freshwater habitats. The wide diversity of bacteria closely coexisting with the Baikal sponge indicate the complex ecological relationships in the community formed under the unique conditions of Lake Baikal.

Towards a Molecular Systematics of the Lake Baikal/Lake Tuva Sponges

Lake Baikal is famous for its extensive biodiversity that is equaled only by few other lakes. Fascinatingly, about 80% of all the animals the lake hosts are endemic. Sponges (Porifera) that live in symbiosis with photosynthetic algae are the most abundant animal taxon found in the littoral zone of Lake Baikal and have been grouped to the family Lubomirskiidae. In recent years, several attempts to determine the phylogenetic relationship between Lubomirskiidae and cosmopolitan freshwater sponges have been undertaken. Yet the results obtained remain inconclusive. Here, we strive to determine the phylogeny of freshwater sponges with the focus on endemic Lake Baikal species, also taking into account two poriferan species that were collected during an expedition in 2006 in two other isolated Siberian lakes, Lake Chagytai and Lake Tore-Khol. Since its discovery at the beginning of the twentieth century, the Lake Chagytai species was grouped to the Lubomirskiidae and called Baikalospongia dzhegatajensis. However, analyses of molecular sequence data [internal transcribed spacer 2 (ITS2), ribosomal DNA (rDNA)] and morphological markers (spicules, habitus) inferred a close relationship to the cosmopolitan genus Ephydatia and also to the Lake Tore-Khol species that had not so far been described. Thus, both species were tentatively termed Ephydatia tuva (Lake Chagytai) and E. altaiensis (Lake Tore-Khol). We hypothesize that these new species might have evolved from Ephydatia-like ancestors through adaptation to the unique environmental conditions of both lakes. To test the ITS data, an unlinked genetic locus was chosen for further phylogenetic analyses, the protein-coding gene silicatein. These analyses provided not only a more robust resolution between the Lubomirskiidae, but also corroborated the grouping of the Lake Chagytai and Lake Tore-Khol species to the genus Ephydatia. In addition, the phylogenetic analyses suggest a Spongilla-like founder generation of poriferan species in Lake Chagytai and Lake Tore-Khol. In conclusion, we propose that the process of speciation in Lake Baikal and Lake Chagytai/Lake Tore-Khol, from a cosmopolitan Spongilla-like ancestor to more than ten endemic species follows allopatric speciation patterns and is of the peripatric type.

Phylogenetic diversity of microorganisms associated with the deep-water sponge Baikalospongia intermedia

The diversity of bacteria associated with deep-water sponge Baikalospongia intermedia was evaluated by sequence analysis of 16S rRNA genes from two sponge samples collected in Lake Baikal from depths of 550 and 1204 m. A total of 64 operational taxonomic units, belonging to nine bacterial phyla, Proteobacteria (classes Alphaproteobacteria, Betaproteobacteria, Gammaproteobacteria, and Deltaproteobacteria), Actinobacteria, Planctomycetes, Cloroflexi, Verrucomicrobia, Acidobacteria, Chlorobi, and Nitrospirae, including candidate phylum WS5, were identified. Phylogenetic analysis showed that the examined communities contained phylotypes exhibiting homology to uncultured bacteria from different lake ecosystems, freshwater sediments, soil and geological formations. Moreover, a number of phylotypes were relative to psychrophilic, methane-oxidizing, sulfate-reducing bacteria, and to microorganisms resistant to the influence of heavy metals. It is noted that the unusual habitation conditions of deep-water sponges contribute to the taxonomic diversity of associated bacteria and have an influence on the presence of functionally important microorganisms in bacterial communities.

Symbiotic Interaction Between Dinoflagellates and the Demosponge Lubomirskia baicalensis: Aquaporin-Mediated Glycerol Transport

Lake Baikal is rich in endemic sponge species, among them the arborescently growing species Lubomirskia baicalensis. During winter when the lake is covered by ice, this species reproduces sexually, reflecting a high metabolic activity. Throughout the year, L. baicalensis lives in association with dinoflagellates, which - according to the data presented herein - are symbiotic. The dinoflagellates have been determined on the basis of their rDNA/ITS characteristics and were found to display high sequence similarity to Gymnodinium sanguineum. The dinoflagellates give the sponge its characteristic green color, reflecting the high chlorophyll content (chlorophyll-a content in March and September of 3.2 +/- 0.6 microg/g and 1.9 +/- 0.5 microg/g of protein, respectively). With the in vitro cell culture system for sponges, the primmorphs, it could be demonstrated that [(14)C] glycerol is readily taken up by sponge cells; this process can be inhibited by phloretin, an aquaporin channel blocker. In order to prove the effect of cholesterol on the intermediate metabolism of the sponge cells, molecule probes, cDNAs for key enzymes in gluconeogenesis, glycolysis, and citric acid, have been applied in Northern blot studies. The data revealed that the genes coding for the enzymes citrate synthase and fructose-1,6-bisphosphatase are strongly upregulated after exposure of primmorphs to glycerol. This effect is abolished by phloretin. The genes encoding the phosphoglucose isomerase and pyruvate dehydrogenase do not respond to glycerol supply, suggesting that their expression is not under genetic control in L. baicalensis. To prove the assumption that the aquaporin channel is involved in the influx of glycerol in sponge cells, this cDNA was cloned and applied for in situ hybridization studies. The results obtained show that cells surrounding the dinoflagellates become brightly stained after hybridization with the aquaporin this probe. This demonstrates that L. baicalensis cells respond to glycerol, a metabolite which might be supplied by the dinoflagellates and imported via the aquaporin channel into the sponge cells.

Bleaching of Baikalian Sponge Affects The Taxonomic Composition of Symbiotic Microorganisms

The diversity of 16S rRNA genes in the microbial community of endemic sponge Lubomirskia baicalensis with bleached patches of tissue was studied. Eight bacterial phyla were identified in the sponge microbiome: Cyanobacteria (27.3%; n = 36; 2 OTU, operational taxonomic unit), Proteobacteria (22.7%; n = 30; 5 OTU), Actinobacteria (16.7%; n = 22; 7 OTU), Verrucomicrobia (15.2%; n = 20; 4 OTU), Planctomycetes (9%; n = 12; 3 OTU), Bacteroidetes (4.5%; n = 6; 3 OTU), WS5 (3%; n = 4; 1 OTU), and TM7 (1.5%; n = 2; 1 OTU). The basic phyla typical for freshwater sponge microbiomes are present in the community. However, in contrast to previously studied L. baicalensis bacterial associations in the bleached sponge community, a dominance of Cyanobacteria and a low number of representatives of the Bacteroidetes and Betaproteobacteria were observed. Phylotypes exhibiting a high percentage of similarity with the microorganisms inhabiting substrates rich in organic matter were also found. Clearly, the bleaching processes of Baikal sponges affect the composition and the ratio of the major taxonomic groups of sponge-associated bacteria.

Identification of silicateins in freshwater sponge Lubomirskia baicalensis

Siliceous spicules of Baikal freshwater sponge Lubomirskia baicalensis contain several proteins, including silicateins. Analysis of a L. baicalensis cDNA library revealed four different mRNAs coding for proteins related to marine sponge silicatein α (α1, α2, α3, and α4). The intron-exon structure was determined forthe genomic α1 silicatein gene. The gene is 1988 bp from the initiation to the termination codon and consists of six intron (total size 1007 bp) and seven exons (total size 981 bp). Mass spectrometry of a tryptic digest of spicule proteins revealed peptides of two silicateins α.

Distinctive features of the microbial diversity and the polyketide synthase genes spectrum in the community of the endemic Baikal sponge Swartschewskia papyracea

The diversity of the symbiotic community of the endemic Baikal sponge Swartschewskia papyracea was studied, and an analysis of the polyketide synthases genes spectrum in sponge-associated microorganisms was carried out. Six bacterial phyla were detected in the S. papyracea microbiome: Verrucomicrobia, Cyanobacteria, Actinobacteria, Bacteroidetes, Proteobacteria, and Planctomycetes. Unlike the microbial associations of other freshwater sponges, the community under study was dominated by the phylaVerrucomicrobia (42.1%) and Cyanobacteria (17.5%), while the proportion of the Proteobacteria was unusually low (9.7%). In the S. papyracea community metagenome, there were identified 18 polyketide synthases genes fragments, the closest homologues of which included the polyketide synthases of the microorganisms belonging to the bacterial phyla Cyanobacteria, Proteobacteria (classes Betaproteobacteria, Deltaproteobacteria, and Gammaproteobacteria), and Acidobacteria as well as the eukaryotic algae of the phylum Heterokonta (class Eustigmatophyceae). Polyketide synthase sequences from S. papyracea formed three groups on the phylogenetic tree: a group of hybrid NRPS/PKS complexes, a group of cyanobacterial polyketide synthases, and a group of homologues of the eukaryotic alga Nannochloropsis gaditana. Notably, the identified polyketide synthase genes fragments showed only a 57–88% similarity to the sequences from the databases, which implies the presence of genes controlling the synthesis of the novel, still unstudied, polyketide compounds in the S. papyracea community. It was proposed that the habitat conditions of S. papyracea affect the taxonomic composition of the microorganisms associated with the sponge, including the diversity of the producers of secondary metabolites.

Diversity of Polyketide Synthase (PKS) genes in metagenomic community of freshwater sponge Lubomirskia baicalensis

The screening of metagenomic DNA of the microbial community associated with the Baikalian sponge Lubomirskia baicalensis was performed in order to investigate the presence of polyketide synthase (PKS) genes. PKS enzyme systems take part in the synthesis of a great number of biologically active substances. The cloning and sequencing of amplified products of the ketosynthase domain section of the PKS gene cluster revealed 15 fragments of PKS genes with amino acid sequences differing from each other by 35–65%. A BLASTX analysis showed that all of these sequences belong to KS domains identified in various groups of microorganisms, i.e., Alpha-, Beta-, and Deltaproteobacteria; Verrucomicrobia; Cyanobacteria; and Chlorophyta. Some sequences were related to genes that participate in the biosynthesis of curacin A (CurI, CurJ), stigmatellin (StiC, StiG), nostophycin (NpnB), and cryptophycin (CrpB). The homology of the found sequences with those of the EMBL database lies in the range of 50–82%, which indicates that the freshwater sponge community contains genes that encode new, not yet studied polyketide substances of potential biotechnological significance.