Freshwater prokaryote and virus communities can adapt to a controlled increase in salinity through changes in their structure and interactions

• Published in: Estuarine, coastal and shelf science Vol. 133; pp. 58 - 66
• Main Authors: Marine, Combe, Thierry, Bouvier, Olivier, Pringault, Emma, Rochelle-Newall, Corinne, Bouvier, Martin, Agis, The Thu, Pham, Jean-Pascal, Torreton, Van Thuoc, Chu, Bettarel, Yvan
• Format: Journal Article
• Language: English
• Published: Kidlington Elsevier Ltd 20.11.2013; Elsevier
• Subjects: Animal and plant ecology; Animal, plant and microbial ecology; Bacteriology; Biodiversity and Ecology; Biological and medical sciences; Brackish water ecosystems; Ecology, environment; Ecosystems; Emerging diseases; Environmental Sciences; estuaries; Fresh water ecosystems; Fundamental and applied biological sciences. Psychology; General aspects; Global Changes; Health; Human health and pathology; Infectious diseases; Life Sciences; lysogeny; microbial ecology; Microbiology; Microbiology and Parasitology; prokaryote; Replicative cycle, interference, host-virus relations, pathogenicity, miscellaneous strains; salinity; Synecology; tropical aquatic ecosystems; Virology; virus; salinity; lysogeny; estuaries; prokaryote; microbial ecology; virus; tropical aquatic ecosystems; Brackish water environment; Interaction; Lysogeny; Estuaries; Environmental factor; Ecology; Salinity; Freshwater environment; Virus; Aquatic environment; Ecosystem; Prokaryote; Microorganism; Community; Adaptation
• ISSN: 0272-7714; 1096-0015
• DOI: 10.1016/j.ecss.2013.08.013

Little information exists on the ecological adaptive responses of riverine microorganisms to the salinity changes that typically occur in transitional waters. This study examined the precise effects of a gradual increase in salinity (+3 units per day for 12 days) on freshwater virus and prokaryote communities collected in the Red River Delta (northern Vietnam). The abundance, activity, morphology and diversity of both communities were examined along this simulated salinity gradient (0–36). Three main successive ecological stages were observed: (1) a continuous decline in prokaryotic and viral abundance from the start of the salinization process up to salinity 12–15 together with a strong decrease in the proportion of active cells, (2) a shift in both community compositions (salinity 9–15) and (3) a marked prevalence of lysogenic over lytic cycles up to salinity 21 followed by a collapse of both types of viral infection. Finally, after salinity 21, and up to seawater salinities (i.e. 36) the prokaryotic community showed multiple signs of recovery with their abundance and function even reaching initial levels. These results suggest that most of the physiological and phylogenetic changes that occurred within the salinity range 10–20 seemed to favor the installation of osmotically adapted prokaryotes accompanied by a specific cortege of viral parasites which might both be able to survive and even proliferate in saltwater conditions.