Zooming in on the phycosphere: the ecological interface for phytoplankton–bacteria relationships

Seymour, Justin R.; Amin, Shady A.; Raina, Jean-Baptiste; Stocker, Roman

doi:10.1038/nmicrobiol.2017.65

Cited by 820 publications

(870 citation statements)

References 145 publications

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“…The potential capacity of bacteria to use chemotaxis to take advantage of this microenvironment is notable given that marine heterotrophic bacteria obtain a large fraction of their carbon demand directly from phytoplankton, consuming up to 50% of phytoplankton-fixed carbon 21 . Recent studies using microfluidic experiments 22 and direct microscopic observations of chemotactic bacteria aggregating around phytoplankton cells 16 support predictions that bacterial chemotaxis will enhance bacterial uptake of phytoplankton derived carbon, as well as potentially underpinning the establishment and maintenance of important phytoplankton-bacteria relationships in the ocean 20 .…”

mentioning

confidence: 83%

“…This behaviour is also involved in pathogenicity and disease outbreaks among a wide range of marine species 32,33 , both in natural habitats 27 and in aquaculture settings 34 , sometimes with dire ecological and economic consequences. In the pelagic environment, chemotaxis plays an often pivotal role in all major biogeochemical cycles, by affecting the rates and directions of key chemical transformations 1,9,20 . For example, chemotaxis-mediated particle colonisation influences controls the amount of carbon that either sinks to the deep sea or is respired in the upper ocean, ultimately influencing global carbon budgets …”

Section: Host Associationsmentioning

confidence: 99%

“…This led to the hypothesis that marine bacteria will use chemotaxis to colonise the 'phycosphere' -the region immediately surrounding a phytoplankton cell that is enriched in exuded organic substrates 20 ( Figure 2). The potential capacity of bacteria to use chemotaxis to take advantage of this microenvironment is notable given that marine heterotrophic bacteria obtain a large fraction of their carbon demand directly from phytoplankton, consuming up to 50% of phytoplankton-fixed carbon 21 .…”

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confidence: 99%

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Swimming in the sea: chemotaxis by marine bacteria

Seymour

2018

Microbiol. Aust.

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confidence: 83%

Section: Host Associationsmentioning

confidence: 99%

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confidence: 99%

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Swimming in the sea: chemotaxis by marine bacteria

Seymour

2018

Microbiol. Aust.

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“…While numerous studies concentrate on the causes of HABs, few have considered that bacterial species coexisting with microalgae could contribute to their development. However since Bell and Mitchell reported that specific bacterial communities occur and microbial activity was altered in the so-called phycosphere (Bell and Mitchell, 1972;Bell and Lang, 1974), more and more studies suggest that such algalbacterial interactions are very specific and important (Azam and Malfatti, 2007;Amin et al, 2015;Bertrand et al, 2015;Ramanan et al, 2016;Seymour et al, 2017). A plausible hypothesis suggests that the mutualistic association of some phytoplankton and bacteria is based on nutrient exchange.…”

Section: Introductionmentioning

confidence: 99%

Iron and Harmful Algae Blooms: Potential Algal-Bacterial Mutualism Between Lingulodinium polyedrum and Marinobacter algicola

2018

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Phytoplankton blooms can cause acute effects on marine ecosystems either due to their production of endogenous toxins or due to their enormous biomass leading to major impacts on local economies and public health. Despite years of effort, the causes of harmful algal blooms (HAB) are still not fully understood. Our hypothesis is that bacteria that produce photoactive siderophores may provide a bioavailable form of iron to commensally associated phytoplankton, which could in turn affect algal growth and bloom dynamics. Here we report a laboratory-based study of binary cultures of the dinoflagellate Lingulodinium polyedrum, a major HAB species, with Marinobacter algicola DG893, a phytoplankton-associated bacterium that produces the photoactive siderophore vibrioferrin. Comparing binary cultures of L. polyedrum with both the wild type and the vibrioferrin minus mutant of M. algicola shows that bacteria are necessary to promote dinoflagellate growth and that this growth promotion effect is at least partially related to the ability of the bacterium to supply bioavailable iron via the siderophore vibrioferrin. These results support the notion of a carbon for iron mutualism in some bacterial-algal interactions.

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“…Recently, Behringer et al (2018) demonstrated that bacterial communities on diatom surfaces displayed strong conservation across diatom strains. Seymour et al (2017) elegantly summarized the main corresponding mechanisms and processes, which show an impressive array of diversity and complexity.…”

Section: Introductionmentioning

confidence: 99%

Identification of Bacterial Genes Expressed During Diatom-Bacteria Interactions Using an in Vivo Expression Technology Approach

Torres-Monroy

Ullrich

2018

Front. Mar. Sci.

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Diverse microalgae-bacteria interactions play important roles for nutrient exchange processes and marine aggregate formation leading to the cycling, mineralization, or sedimentation of organic carbon in the Oceans. The main goal of this study is to report an alternative way to assess a distinct diatom-bacteria interaction. To study this at the cellular scale, an in vitro interaction model system consisting of the diatom, Thalassiosira weissflogii, and the gamma-proteobacterium, Marinobacter adhaerens HP15, had previously been established. HP15 is able to attach to T. weissflogii cells, to induce transparent exopolymeric particle formation, and to increase marine aggregation formation. Several bacterial genes important during this interaction have been studied thus far, but genes specifically expressed in co-culture remained unknown. To identify such bacterial genes, an in vivo Expression Technology (IVET) screen was employed. For this, a promoter-trapping vector containing a fusion between a promoter-less selection marker gene and a promoterless reporter gene was constructed. Construction of a library of plasmids carrying genomic fragments upstream of the fusion and its subsequent transformation into a selection marker mutant allowed detection of 30 bacterial promoters specifically expressed during the interactions with T. weissflogii. Their sequence analyses revealed that the corresponding genes could be involved in many processes such as biochemical detection of diatom cells, bacterial attachment, metabolic exchange of nitrogen compounds, and resistance toward heavy metals. Identification of genes potentially involved in branched-chain amino acid uptake and utilization confirmed our previous results of a proteomics analysis. Since our current approach identified several additional genes to be induced in co-culture, use of IVET might be a valuable complementing strategy to proteomic or transcriptomic analysis of the diatom-bacteria crossplay. The current IVET approach demonstrated that the interaction between M. adhaerens HP15 and T. weissflogii is multifactorial and is likely to involve a complex network of physiological processes.

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Zooming in on the phycosphere: the ecological interface for phytoplankton–bacteria relationships

Cited by 820 publications

References 145 publications

Swimming in the sea: chemotaxis by marine bacteria

Swimming in the sea: chemotaxis by marine bacteria

Iron and Harmful Algae Blooms: Potential Algal-Bacterial Mutualism Between Lingulodinium polyedrum and Marinobacter algicola

Identification of Bacterial Genes Expressed During Diatom-Bacteria Interactions Using an in Vivo Expression Technology Approach

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