Abstract
Marine picocyanobacteria belonging to Synechococcus are major contributors to the global carbon cycle, however the genomic information of its cold-adapted members has been lacking to date. To fill this void the genome of a cold-adapted planktonic cyanobacterium Synechococcus sp. CS-601 (SynAce01) has been sequenced. The genome of the strain contains a single chromosome of approximately 2.75 MBp and GC content of 63.92%. Gene prediction yielded 2984 protein coding sequences and 44 tRNA genes. The genome contained evidence of horizontal gene transfer events during its evolution. CS-601 appears as a transport generalist with some specific adaptation to an oligotrophic marine environment. It has a broad repertoire of transporters of both inorganic and organic nutrients to survive in inhospitable environments. The cold adaptation of the strain exhibited characteristics of a psychrotroph rather than psychrophile. Its salt adaptation strategy is likely to rely on the uptake and synthesis of osmolytes, like glycerol or glycine betaine. Overall, the genome reveals two distinct patterns of adaptation to the inhospitable environment of Antarctica. Adaptation to an oligotrophic marine environment is likely due to an abundance of genes, probably acquired horizontally, that are associated with increased transport of nutrients, osmolytes, and light harvesting. On the other hand, adaptations to low temperatures are likely due to prolonged evolutionary changes.
Highlights
Marine picocyanobacteria belonging to Synechococcus and Prochlorococcus are major contributors to the global carbon cycle and may contribute up to half of the total biologically-fixed carbon in certain areas [1,2]
CS-601 (SynAce01) and its GC content is typical when compared to other members of Synechococcaceae
The strain belongs to most underrepresented clades of cyanobacteria, and its genome sequence will be valuable for genomic, taxonomic, phylogenetic, and functional studies of strains from cold, oligotrophic environments
Summary
Marine picocyanobacteria belonging to Synechococcus and Prochlorococcus are major contributors to the global carbon cycle and may contribute up to half of the total biologically-fixed carbon in certain areas [1,2]. Cold-adapted strains of Synechococcus are among the least studied strains of cyanobacteria with only a handful of examples available in the literature [6,7,8], despite their being predominately responsible for carbon sequestration and driving the microbial food chain in these environments [8]. This is likely to be caused by several reasons, namely challenging sampling and isolation, inability to maintain axenic cultures, and slow growth rates. Genomic details regarding abundant planktonic strains of the cryosphere are still lacking [9]
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