The phytoplankton community in the oligotrophic open ocean is numerically dominated by the cyanobacterium Prochlorococcus, accounting for approximately half of all photosynthesis. In the illuminated euphotic zone where Prochlorococcus grows, reactive oxygen species are continuously generated via photochemical reactions with dissolved organic matter. However, Prochlorococcus genomes lack catalase and additional protective mechanisms common in other aerobes, and this genus is highly susceptible to oxidative damage from hydrogen peroxide (HOOH). In this study we showed that the extant microbial community plays a vital, previously unrecognized role in cross-protecting Prochlorococcus from oxidative damage in the surface mixed layer of the oligotrophic ocean. Microbes are the primary HOOH sink in marine systems, and in the absence of the microbial community, surface waters in the Atlantic and Pacific Ocean accumulated HOOH to concentrations that were lethal for Prochlorococcus cultures. In laboratory experiments with the marine heterotroph Alteromonas sp., serving as a proxy for the natural community of HOOH-degrading microbes, bacterial depletion of HOOH from the extracellular milieu prevented oxidative damage to the cell envelope and photosystems of co-cultured Prochlorococcus, and facilitated the growth of Prochlorococcus at ecologically-relevant cell concentrations. Curiously, the more recently evolved lineages of Prochlorococcus that exploit the surface mixed layer niche were also the most sensitive to HOOH. The genomic streamlining of these evolved lineages during adaptation to the high-light exposed upper euphotic zone thus appears to be coincident with an acquired dependency on the extant HOOH-consuming community. These results underscore the importance of (indirect) biotic interactions in establishing niche boundaries, and highlight the impacts that community-level responses to stress may have in the ecological and evolutionary outcomes for co-existing species.
Axenic (pure) cultures of marine unicellular cyanobacteria of the Prochlorococcus genus grow efficiently only if the inoculation concentration is large; colonies form on semisolid medium at low efficiencies. In this work, we describe a novel method for growing Prochlorococcus colonies on semisolid agar that improves the level of recovery to approximately 100%. Prochlorococcus grows robustly at low cell concentrations, in liquid or on solid medium, when cocultured with marine heterotrophic bacteria. Once the Prochlorococcus cell concentration surpasses a critical threshold, the "helper" heterotrophs can be eliminated with antibiotics to produce axenic cultures. Our preliminary evidence suggests that one mechanism by which the heterotrophs help Prochlorococcus is the reduction of oxidative stress.Members of the genus Prochlorococcus are the most abundant marine photosynthetic organisms and, as such, are major contributors to photosynthesis in the ocean (20). Over 30 strains of Prochlorococcus have been brought into culture, isolated from many locations within the band from 40°N to 40°S, including the North Atlantic, the North and South Pacific Oceans, the Mediterranean Sea, and the Arabian Sea (20). Despite this success, very few pure cultures of Prochlorococcus (e.g., those of strains PCC 9511 and MIT 9313 [18,22]) have been obtained. The vast majority of cultures contain heterotrophic microbes as contaminants; these heterotrophs were cocultured from the marine environment during the isolation procedure, which has relied thus far exclusively on liquid cultivation. While plating for contiguous lawns of Prochlorococcus has proven to be productive (15), attempts at colony formation (by pour plating or surface streak plating) have thus far met with significantly less success. Recovery efficiencies of the pour plating technique of 0.1 to 10% have been reported previously for some strains (15,24), but this technique has yet to produce pure cultures (15). The inability to readily obtain clonal, pure cultures of Prochlorococcus has severely limited progress in the genetic and physiological analysis of this ecologically important lineage.The "helper" phenotype of heterotrophic bacteria. Standard dilution streaking of contaminated Prochlorococcus cultures onto semisolid medium failed to produce axenic colonies. Colonies formed only within a visible mass of the contaminant heterotrophic bacteria; such masses appeared typically at the sites of the earliest, heaviest dilution streaks (data not shown). One interpretation of these results was that Prochlorococcus was able to grow only in the presence of the contaminating bacteria, perhaps because the bacteria provide a growth factor and/or remove an inhibitory factor. Coculturing with heterotrophic bacteria is required for the growth of some bacterial isolates (9) and is known to improve the growth of dinoflagellates (2, 7), suggesting that a similar interaction may help Prochlorococcus. To test this hypothesis, a heterotrophic contaminant (designated EZ55) of a culture of the ...
Primary production by Prochlorococcus, the smallest known free-living photosynthetic organism in terms of both physical and genomic size, is thought to have a significant role in global carbon cycles. Despite its small size and low growth rate, Prochlorococcus numerically dominates the phytoplankton community in the nutrient-poor oligotrophic ocean, the largest biome of the Earth’s surface. How nutrient limitation, and nitrogen limitation in particular, affects the fate and flux of carbon fixed by Prochlorococcus is currently unknown. To address this gap in knowledge, we compared the bulk rates of photosynthesis and organic carbon release, the concentrations of intracellular metabolites, and the rates of assimilated carbon into the metabolite pools between replete and N-limited chemostat cultures. Total photosynthesis of our N-limited cultures was less than half of those observed in replete cultures, and nitrogen limitation also appears to cause a larger proportion of total fixed carbon to be released to the environment. Our data suggest this occurs in concert with the maintenance of large slow-moving pools of metabolites, including nitrogen-rich molecules such as glutamate. Additionally, we report field data suggesting metabolisms of Prochlorococcus are comparable to results we observe in our laboratory studies. Accounting for these observations, potential metabolic mechanisms utilized by Prochlorococcus are discussed as we build upon our understanding of nutrient-limited photosynthesis and carbon metabolism. IMPORTANCE Photosynthetic microbes are the predominant sources of organic carbon in the sunlit regions of the ocean. During photosynthesis, nitrogen and carbon metabolism are coordinated to synthesize nitrogen-containing organics such as amino acids and nucleic acids. In large regions of the ocean, nitrogen is thought to limit the growth of phytoplankton. The impact of nitrogen limitation on the synthesis of organic carbon is not well understood, especially for the most abundant photosynthetic organism in the nitrogen-limited regions of the ocean, Prochlorococcus. This study compares the carbon metabolism of nitrogen-replete and nitrogen-limited Prochlorococcus spp. to determine how nitrogen availability influences inorganic carbon assimilation into an organic form. Metabolomics and physiological data revealed that cells under nitrogen limitation have reduced metabolic flux and total carbon fixation rates while maintaining elevated metabolite pool levels and releasing a larger proportion of total fixed carbon to the environment.
Page 4: In Fig. 1A, the unit of measurement on the y axis should be as shown here.
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