Quantification of microbial community assembly processes during degradation on diverse plastispheres based on physicochemical characters and phylogenetic bin-based null model analysis

To understand the differences in degradation processes depending on the chemical properties of polymers, it is necessary to both quantify the microbiome composition and evaluate the process of microbial turnover (i.e., community assembly processes) in a variety of polymer materials. In this study, u...

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Bibliographic Details
Published in:The Science of the total environment 2024-06, Vol.931, p.172401-172401, Article 172401
Main Authors: Yokoyama, Daiki, Tsuboi, Yuri, Abe, Hideki, Nagahata, Ritsuko, Konno, Hideo, Yoshida, Masaru, Kikuchi, Jun
Format: Article
Language:English
Subjects:
Community assembly
Determinism
Microbiome
Plastic
Stochasticity
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Summary:To understand the differences in degradation processes depending on the chemical properties of polymers, it is necessary to both quantify the microbiome composition and evaluate the process of microbial turnover (i.e., community assembly processes) in a variety of polymer materials. In this study, using a phylogenetic bin-based null model analysis (i.e., iCAMP), we evaluated community assembly processes from original estuary water to 37 types of polymers, which provide overwhelmingly diverse niches for microbes, in 14-day incubation experiments. First, we evaluated the polymer properties related to degradation rates. Polymers with higher adipic acid (AdA) monomer exhibited higher motility, hydrophilicity, and degradation rates, whereas those with higher aromatic monomer exhibited the opposite trends. Second, microbiome composition analysis was performed, and the microbiomes were significantly changed by the AdA or aromatic content. This was consistent with the polymer properties, suggesting that polymer motility and hydrophilicity attributable to the first-order structure modify the accessibility of the enzyme to the reaction site and hence the degradation rate, resulting in differences in microbiome community composition. Finally, we determined community assembly processes from estuary water to plastics using a phylogenetic bin-based null model analysis. The importance of heterogeneous selection was higher in mobile, hydrophilic, and fast-degrading polymers, while that of homogeneous selection was lower. This suggests that the environmental difference between before and after incubation becomes significant under rapid degradation, which select microbes adapted to biofilm environments. In addition, the more stochastic turnover prevailed, the more variation in the communities (i.e., β-diversity) increased. This suggests that turnover processes not dictated by the environment lead to instability in community compositions. [Display omitted] •Polymer with more adipate are more mobile, hydrophilic, and rapidly decomposable.•Polymer with more aroma are more rigid, hydrophobic, and slowly decomposable.•Heterogeneous selection prevails with community turnover in large environmental gaps.•Stochastic community turnover generates variance in community compositions.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2024.172401