Chemotaxis by natural populations of coral reef bacteria

Tout, Jessica; Jeffries, Thomas C.; Petrou, Katherina; Tyson, Gene W.; Webster, Nicole S.; Garren, Melissa; Stocker, Roman; Ralph, Peter J.; Seymour, Justin R.

doi:10.1038/ismej.2014.261

Cited by 69 publications

(67 citation statements)

References 94 publications

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“…Our results are supported by previously reported chemotactic response factors to the same concentrations of DMSP among coral‐associated bacteria (Tout et al., ). Besides DMSP, there might be other metabolites which attract Roseovarius sp.…”

Section: Resultssupporting

confidence: 93%

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Macroalgal–bacterial interactions: Role of dimethylsulfoniopropionate in microbial gardening by Ulva (Chlorophyta)

et al. 2018

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The marine macroalga Ulva mutabilis (Chlorophyta) develops into callus-like colonies consisting of undifferentiated cells and abnormal cell walls under axenic conditions. Ulva mutabilis is routinely cultured with two bacteria, the Roseovarius sp. MS2 strain and the Maribacter sp. MS6 strain, which release morphogenetic compounds and ensure proper algal morphogenesis. Using this tripartite community as an emerging model system, we tested the hypothesis that the bacterial-algal interactions evolved as a result of mutually taking advantage of signals in the environment. Our study aimed to determine whether cross-kingdom crosstalk is mediated by the attraction of bacteria through algal chemotactic signals. Roseovarius sp. MS2 senses the known osmolyte dimethylsulfoniopropionate (DMSP) released by Ulva into the growth medium. Roseovarius sp. is attracted by DMSP and takes it up rapidly such that DMSP can only be determined in axenic growth media. As DMSP did not promote bacterial growth under the tested conditions, Roseovarius benefited solely from glycerol as the carbon source provided by Ulva. Roseovarius quickly catabolized DMSP into methanethiol (MeSH) and dimethylsulphide (DMS). We conclude that many bacteria can use DMSP as a reliable signal indicating a food source and promote the subsequent development and morphogenesis in Ulva.

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Section: Resultssupporting

confidence: 93%

“…Similar to the protocol by Tout et al. (), the chemoattractant gradually leaks into the external environment through the pipette tip via molecular diffusion, creating a gradient in the surrounding sea water that triggers the migration of chemotactic bacteria into the pipette. After 5 or 10 min of deployment, the capillary contents were sampled.…”

Section: Methodsmentioning

confidence: 99%

Macroalgal–bacterial interactions: Role of dimethylsulfoniopropionate in microbial gardening by Ulva (Chlorophyta)

et al. 2018

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“…was found to be chemotactic toward inorganic phosphate during starvation, a behavior consistent with its natural habitat of the ultraoligotrophic eastern Mediterranean Sea (393). A recent study showed that coral surfaceassociated bacteria exhibited significantly higher levels of chemotaxis than free-living bacteria in nearby non-coral-associated waters (394). Numerous processes, such as cell lysis, phytoplankton exudation, animal excretion, food vacuole egestion, and particle degradation and dissolution, provide point sources rich in organic substrates and inorganic nutrients in marine waters (186,392,395).…”

Section: Microbial Chemotaxismentioning

confidence: 94%

Microbial Surface Colonization and Biofilm Development in Marine Environments

Dang

Lovell

2016

Microbiol Mol Biol Rev

829

636

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SUMMARYBiotic and abiotic surfaces in marine waters are rapidly colonized by microorganisms. Surface colonization and subsequent biofilm formation and development provide numerous advantages to these organisms and support critical ecological and biogeochemical functions in the changing marine environment. Microbial surface association also contributes to deleterious effects such as biofouling, biocorrosion, and the persistence and transmission of harmful or pathogenic microorganisms and their genetic determinants. The processes and mechanisms of colonization as well as key players among the surface-associated microbiota have been studied for several decades. Accumulating evidence indicates that specific cell-surface, cell-cell, and interpopulation interactions shape the composition, structure, spatiotemporal dynamics, and functions of surface-associated microbial communities. Several key microbial processes and mechanisms, including (i) surface, population, and community sensing and signaling, (ii) intraspecies and interspecies communication and interaction, and (iii) the regulatory balance between cooperation and competition, have been identified as critical for the microbial surface association lifestyle. In this review, recent progress in the study of marine microbial surface colonization and biofilm development is synthesized and discussed. Major gaps in our knowledge remain. We pose questions for targeted investigation of surface-specific community-level microbial features, answers to which would advance our understanding of surface-associated microbial community ecology and the biogeochemical functions of these communities at levels from molecular mechanistic details through systems biological integration.

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“…Under business as usual forecasts for greenhouse gas emissions, it is projected that pathogen virulence will increase for 440% of reefs worldwide by 2030 (Maynard et al, 2015). Given that all currently known putative coral pathogens are motile (Garren et al, 2014) and that chemotaxis is both a common feature in the reef environment (Tout et al, 2015a) and implicated in the success of bacterial pathogens of corals (Banin et al, 2001;Meron et al, 2009), our observations that both chemotactic and chemokinetic behaviors of V. coralliilyticus are influenced by temperature add to our current understanding of coral disease to suggest that motility adaptations under future climate scenarios have the potential to favor bacterial pathogens over their coral hosts (Garren et al, 2014;Maynard et al, 2015).…”

Section: Discussionmentioning

confidence: 99%

Temperature-induced behavioral switches in a bacterial coral pathogen

et al. 2015

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Evidence to date indicates that elevated seawater temperatures increase the occurrence of coral disease, which is frequently microbial in origin. Microbial behaviors such as motility and chemotaxis are often implicated in coral colonization and infection, yet little is known about the effect of warming temperatures on these behaviors. Here we present data demonstrating that increasing water temperatures induce two behavioral switches in the coral pathogen Vibrio coralliilyticus that considerably augment the bacterium's performance in tracking the chemical signals of its coral host, Pocillopora damicornis. Coupling field-based heat-stress manipulations with laboratory-based observations in microfluidic devices, we recorded the swimming behavior of thousands of individual pathogen cells at different temperatures, associated with current and future climate scenarios. When temperature reached ⩾ 23°C, we found that the pathogen's chemotactic ability toward coral mucus increased by 460%, denoting an enhanced capability to track host-derived chemical cues. Raising the temperature further, to 30°C, increased the pathogen's chemokinetic ability by 457%, denoting an enhanced capability of cells to accelerate in favorable, mucus-rich chemical conditions. This work demonstrates that increasing temperature can have strong, multifarious effects that enhance the motile behaviors and host-seeking efficiency of a marine bacterial pathogen.

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Chemotaxis by natural populations of coral reef bacteria

Cited by 69 publications

References 94 publications

Macroalgal–bacterial interactions: Role of dimethylsulfoniopropionate in microbial gardening by Ulva (Chlorophyta)

Macroalgal–bacterial interactions: Role of dimethylsulfoniopropionate in microbial gardening by Ulva (Chlorophyta)

Microbial Surface Colonization and Biofilm Development in Marine Environments

Temperature-induced behavioral switches in a bacterial coral pathogen

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