Genomic and funcional analysis of the cyanobacterium Nostoc sp. CENA67 and characterization of its associated microbial community

Nostoc is a cyanobacterial genus with ubiquitous distribution that is important in several ecosystems. However, few genomes are currently available for this genus. While Nostoc spp. are the most commonly reported cyanobacteria in symbiotic relationship with fungi, animals, plants, and other organisms, associations with other microorganisms have not received similar attention. As a consequence of tight interactions between cyanobacteria and heterotrophs, non-axenic cultures are usually achieved in the isolation of these bacteria, which provides an interesting opportunity for carrying out both genomic as metagenomic studies. This work aimed to investigate the genomic and functional characteristics of the strain Nostoc sp. CENA67, isolated from anthropogenic dark earth, and to study its associated community. For this purpose, cells from a non-axenic culture of Nostoc sp. CENA67 were sequenced with the platforms MiSeq and Ion PGM and analyzed with genomic and metagenomic tools. The strain CENA67 indeed belongs to the family Nostocaceae and presents some characteristics in common with cyanobacteria of the genus Nostoc, but diverges in certain morphological and phylogenetic aspects of the typical Nostoc group, suggesting that it is a representative of a new taxon. In addition, its genome presents differences in relation to the genomes currently available for cyanobacteria related to this genus. Genome mining revealed 31 gene clusters hypothetically related to the synthesis of secondary metabolites, most of which did not show significant similarity to known clusters. The analysis of a microviridin gene cluster unveiled a larger diversity of precursor genes for this molecule than was previously believed, suggesting that a considerable number of variants is still to be found. The taxonomic analysis of the associated community confirmed the dominance of cyanobacteria in the culture, but also revealed the presence of a great number of microbial genera that are usually capable of fixing atmospheric nitrogen and establishing symbiosis with plants, including Mesorhizobium, Sinorhizobium, and Starkeya, among others. Genomic drafts were obtained for Bradyrhizobium diazoefficiens, Bradyrhizobium japonicum, Burkholderia lata, and Hyphomicrobium nitrativorans. Nevertheless, genes for nitrogen fixation were not detected in these genomes, despite being found in the cyanobacterial genome and the community metagenome, suggesting that some populations might be under selection pressure for the loss of the ability to fix nitrogen, probably due to this nutrient being provided for the most abundant organism in this culture, the cyanobacterium. Functional analysis indicated pathways exclusive both to the cyanobacterium as to the associated community, and suggested the complementarity of certain metabolisms. The results allow the increase of the knowledge about the molecular and chemical diversity of the phylum Cyanobacteria and raise possible interactions with symbiotic microorganisms (AU)