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In situ Prokaryotic and Eukaryotic Communities on Microplastic Particles in a Small Headwater Stream in Germany
Frontiers in Microbiology2021
29 citations
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Citation count from OpenAlex, updated daily. May differ slightly from the publisher's own count.
Score: 40
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0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Alfons R. Weig,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Christian Laforsch
Anja F. R. M. Ramsperger,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Martin G. J. Löder,
Christian Laforsch
Martin G. J. Löder,
Martin G. J. Löder,
Martin G. J. Löder,
Alfons R. Weig,
Alfons R. Weig,
Alfons R. Weig,
Alfons R. Weig,
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Anja F. R. M. Ramsperger,
Alfons R. Weig,
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Martin G. J. Löder,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Anja F. R. M. Ramsperger,
Christian Laforsch
Christian Laforsch
Anja F. R. M. Ramsperger,
Martin G. J. Löder,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Martin G. J. Löder,
Martin G. J. Löder,
Martin G. J. Löder,
Martin G. J. Löder,
Christian Laforsch
Christian Laforsch
Martin G. J. Löder,
Martin G. J. Löder,
Martin G. J. Löder,
Martin G. J. Löder,
Martin G. J. Löder,
Martin G. J. Löder,
Martin G. J. Löder,
Martin G. J. Löder,
Martin G. J. Löder,
Martin G. J. Löder,
Alfons R. Weig,
Christian Laforsch
Alfons R. Weig,
Alfons R. Weig,
Alfons R. Weig,
Martin G. J. Löder,
Alfons R. Weig,
Alfons R. Weig,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Martin G. J. Löder,
Martin G. J. Löder,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Martin G. J. Löder,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Anja F. R. M. Ramsperger,
Alfons R. Weig,
Martin G. J. Löder,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Alfons R. Weig,
Christian Laforsch
Christian Laforsch
Anja F. R. M. Ramsperger,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Anja F. R. M. Ramsperger,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Alfons R. Weig,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Alfons R. Weig,
Christian Laforsch
Christian Laforsch
Alfons R. Weig,
Alfons R. Weig,
Anja F. R. M. Ramsperger,
Christian Laforsch
Christian Laforsch
Martin G. J. Löder,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Martin G. J. Löder,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Martin G. J. Löder,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Martin G. J. Löder,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Martin G. J. Löder,
Christian Laforsch
Martin G. J. Löder,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Anja F. R. M. Ramsperger,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Martin G. J. Löder,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Martin G. J. Löder,
Martin G. J. Löder,
Christian Laforsch
Martin G. J. Löder,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Anja F. R. M. Ramsperger,
Christian Laforsch
Christian Laforsch
Martin G. J. Löder,
Christian Laforsch
Christian Laforsch
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Christian Laforsch
Martin G. J. Löder,
Martin G. J. Löder,
Martin G. J. Löder,
Martin G. J. Löder,
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Christian Laforsch
Christian Laforsch
Anja F. R. M. Ramsperger,
Anja F. R. M. Ramsperger,
Christian Laforsch
Summary
Researchers characterized prokaryotic and eukaryotic communities colonizing microplastic particles in a German headwater stream, finding distinct plastisphere biofilms enriched in specific bacterial taxa compared to surrounding water and natural substrates.
The ubiquitous use of plastic products in our daily life is often accompanied by improper disposal. The first interactions of plastics with organisms in the environment occur by overgrowth or biofilm formation on the particle surface, which can facilitate the ingestion by animals. In order to elucidate the colonization of plastic particles by prokaryotic and eukaryotic microorganisms <i>in situ</i>, we investigated microbial communities in biofilms on four different polymer types and on mineral particles in a small headwater stream 500 m downstream of a wastewater treatment plant in Germany. Microplastic and mineral particles were exposed to the free-flowing water for 4 weeks in spring and in summer. The microbial composition of the developing biofilm was analyzed by 16S and 18S amplicon sequencing. Despite the expected seasonal differences in the microbial composition of pro- and eukaryotic communities, we repeatedly observed polymer type-specific differentiation in both seasons. The order of polymer type-specific prokaryotic and eukaryotic community distances calculated by Robust Aitchison principal component analysis (PCA) was the same in spring and summer samples. However, the magnitude of the distance differed considerably between polymer types. Prokaryotic communities on polyethylene particles exhibited the most considerable difference to other particles in summer, while eukaryotic communities on polypropylene particles showed the most considerable difference to other spring samples. The most contributing bacterial taxa to the polyethylene-specific differentiation belong to the Planctomycetales, Saccharimonadales, Bryobacterales, uncultured Acidiomicrobia, and Gemmatimonadales. The most remarkable differences in eukaryotic microorganism abundances could be observed in several distinct groups of Ciliophora (ciliates) and Chlorophytes (green algae). Prediction of community functions from taxonomic abundances revealed differences between spring and summer, and - to a lesser extent - also between polymer types and mineral surfaces. Our results show that different microplastic particles were colonized by different biofilm communities. These findings may be used for advanced experimental designs to investigate the role of microorganisms on the fate of microplastic particles in freshwater ecosystems.