Environmental Factors Support the Formation of Specific Bacterial Assemblages on Microplastics

Oberbeckmann, Sonja; Kreikemeyer, Bernd; Labrenz, Matthias

doi:10.3389/fmicb.2017.02709

Cited by 367 publications

(400 citation statements)

References 65 publications

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“…Through a multi-ocean basin biogeographical survey, Amaral-Zettler et al [77] showed that plastisphere communities developed on different polymer types in the North Pacific and North Atlantic Seas reflected primarily their biogeographic origins, and to a lesser extent the plastic type; therefore, differences in microbial communities among ocean basins were more significant than those among plastic polymers. Similar conclusions were obtained for bacterial communities colonizing plastics along an environmental gradient (from freshwater to marine), which were shaped firstly by the environmental conditions and secondarily by the plastic type [78].…”

Section: Plastic Polymerssupporting

confidence: 76%

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Microbial Colonization in Marine Environments: Overview of Current Knowledge and Emerging Research Topics

Caruso¹

2020

JMSE

104

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Microbial biofilms are biological structures composed of surface-attached microbial communities embedded in an extracellular polymeric matrix. In aquatic environments, the microbial colonization of submerged surfaces is a complex process involving several factors, related to both environmental conditions and to the physical-chemical nature of the substrates. Several studies have addressed this issue; however, more research is still needed on microbial biofilms in marine ecosystems. After a brief report on environmental drivers of biofilm formation, this study reviews current knowledge of microbial community attached to artificial substrates, as obtained by experiments performed on several material types deployed in temperate and extreme polar marine ecosystems. Depending on the substrate, different microbial communities were found, sometimes highlighting the occurrence of species-specificity. Future research challenges and concluding remarks are also considered. Emphasis is given to future perspectives in biofilm studies and their potential applications, related to biofouling prevention (such as cell-to-cell communication by quorum sensing or improved knowledge of drivers/signals affecting biological settlement) as well as to the potential use of microbial biofilms as sentinels of environmental changes and new candidates for bioremediation purposes.

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Section: Plastic Polymerssupporting

confidence: 76%

“…Oberbeckmann et al [78], investigating microbial colonization of wood, HDPE and PS over 14 days along a gradient ranging from marine (coastal Baltic Sea) to freshwater (wastewater treatment plant) conditions, found that microbial communities did not differ significantly among the polymers.…”

Section: Mixed Substratesmentioning

confidence: 99%

Microbial Colonization in Marine Environments: Overview of Current Knowledge and Emerging Research Topics

Caruso¹

2020

JMSE

104

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“…Erythrobacter spp. are marine ubiquitous aerobic anoxygenic phototrophic bacteria, which have already been reported as the major taxa of biofilm communities on artificial surfaces (Briand et al, 2017;Oberbeckmann et al, 2018). As cyanobacteria failed to be identified in the surface community of T. atomaria, Erythrobacter spp.…”

Section: Dmsp and Proline Betaine Exhibited A Key Role Within The Cormentioning

confidence: 98%

Temporal covariation of epibacterial community and surface metabolome in the Mediterranean seaweed holobiont Taonia atomaria

Paix

Othmani

Debroas

et al. 2019

Environmental Microbiology

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Summary An integrative multi‐omics approach allowed monthly variations for a year of the surface metabolome and the epibacterial community of the Mediterranean Phaeophyceae Taonia atomaria to be investigated. The LC–MS‐based metabolomics and 16S rDNA metabarcoding data sets were integrated in a multivariate meta‐omics analysis (multi‐block PLS‐DA from the MixOmic DIABLO analysis) showing a strong seasonal covariation (Mantel test: p < 0.01). A network based on positive and negative correlations between the two data sets revealed two clusters of variables, one relative to the ‘spring period’ and a second to the ‘summer period’. The ‘spring period’ cluster was mainly characterized by dipeptides positively correlated with a single bacterial taxon of the Alteromonadaceae family (BD1‐7 clade). Moreover, ‘summer’ dominant epibacterial taxa from the second cluster (including Erythrobacteraceae, Rhodospirillaceae, Oceanospirillaceae and Flammeovirgaceae) showed positive correlations with few metabolites known as macroalgal antifouling defences [e.g. dimethylsulphoniopropionate (DMSP) and proline] which exhibited a key role within the correlation network. Despite a core community that represents a significant part of the total epibacteria, changes in the microbiota structure associated with surface metabolome variations suggested that both environment and algal host shape the bacterial surface microbiota.

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“…Taken together, all isolated Saltatorellota strains apparently possess a continuous PG sacculus that might undergo intensive modulations during shapeshifting, amoeba-like locomotion or trunk-formation. All novel Saltatorellota isolates were obtained from microplastic particles incubated for two weeks either in the Baltic Sea or an inflowing river estuary with salinities of 1-1.5% as described before [47,57]. In order to exclude osmotic stress and to gain deeper insights into the natural habitat of these strains, water samples were taken along the southern and eastern coastline of the Baltic Sea.…”

Section: Fig 2 Locomotion and Shapeshifting Of Saltatorellus Feroxmentioning

confidence: 99%

“…For the isolation of E. mirabilis Pla133 T and R. mirabilis Pla163 T , microplastic and wood particles collected on 04 September 2014 were incubated for 16 days in an inflowing river estuary and at the Baltic Sea coast as previously described [57]. S. ferox Poly30 T was isolated from plastic particles collected on 08 October 2015 (incubation time two weeks) from the Baltic Sea at Heiligendamm pier, Germany.…”

Section: Isolation Cultivation and Physiological Characterization Ofmentioning

confidence: 99%

The novel shapeshifting bacterial phylumSaltatorellota

Wiegand¹,

Jogler

Kohn³

et al. 2019

Preprint

Self Cite

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Our current understanding of a free-living bacterium -capable of withstanding a variety of environmental stresses-is represented by the image of a peptidoglycan-armored rigid casket.The making and breaking of peptidoglycan greatly determines cell shape. The cytoplasmic membrane follows this shape, pressed towards the cell wall by turgor pressure. Consequently, bacteria are morphologically static organisms, in contrast to eukaryotic cells that can facilitate shape changes. Here we report the discovery of the novel bacterial phylum Saltatorellota, that challenges this concept of a bacterial cell. Members of this phylum can change their shape, are capable of amoeba-like locomotion and trunk-formation through the creation of extensive pseudopodia-like structures. Two independent Saltatorellota cells can fuse, and they employ various forms of cell division from budding to canonical binary fission. Despite their polymorphisms, members of the Saltatorellota do possess a peptidoglycan cell wall. Their genomes encode flagella and type IV pili as well as a bacterial actin homolog, the 'saltatorellin'. This protein is most similar to MamK, a dynamic filament-forming protein, that aligns and segregates magnetosome organelles via treadmilling. We found saltatorellin to form filaments in both, E. coli and Magnetospirillum gryphiswaldense, leading to the hypothesis that shapeshifting and pseudopodia formation might be driven by treadmilling of saltatorellin.

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Environmental Factors Support the Formation of Specific Bacterial Assemblages on Microplastics

Cited by 367 publications

References 65 publications

Microbial Colonization in Marine Environments: Overview of Current Knowledge and Emerging Research Topics

Microbial Colonization in Marine Environments: Overview of Current Knowledge and Emerging Research Topics

Temporal covariation of epibacterial community and surface metabolome in the Mediterranean seaweed holobiont Taonia atomaria

The novel shapeshifting bacterial phylumSaltatorellota

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