Biofilms of Pseudomonas and Lysinibacillus Marine Strains on High-Density Polyethylene

Environmental pollution by plastic debris is estimated on a scale of 100 million metric tons, a portion of which is fragmented into micro- and nanoplastics. These fragments are often colonized by bacterial species in marine environments, possibly contributing to the biodegradation of such materials....

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Bibliographic Details
Published in:Microbial ecology 2021-05, Vol.81 (4), p.833-846
Main Authors: Oliveira, Maiara Monteiro, Proenca, Audrey Menegaz, Moreira-Silva, Eduardo, de Castro, Aline Machado, dos Santos, Francine Melise, Marconatto, Letícia, Medina-Silva, Renata
Format: Article
Language:English
Subjects:
Abiotic factors
Adhesion
Bacteria
Biodegradation
Biofilms
Biomedical and Life Sciences
Cell adhesion
Colonization
Deep sea
Deep water
Ecology
Extracellular
Extracellular matrix
Fragments
Geoecology/Natural Processes
High density polyethylenes
Incubation period
Life Sciences
Lysinibacillus
Marine environment
Marine pollution
Microbial Ecology
Microbiological strains
Microbiology
Microbiology of Aquatic Systems
Nature Conservation
Plastic debris
Plastic pollution
Polyethylene
Polymers
Pseudomonas
Pseudomonas aeruginosa
Strains (organisms)
Water Quality/Water Pollution
Weathering
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Summary:Environmental pollution by plastic debris is estimated on a scale of 100 million metric tons, a portion of which is fragmented into micro- and nanoplastics. These fragments are often colonized by bacterial species in marine environments, possibly contributing to the biodegradation of such materials. However, further investigations are necessary to determine the impact of abiotic polymer weathering on biofilm adhesion, as well as the specific biofilm formation strategies employed by marine isolates. Here, we evaluate deep-sea sediment bacterial isolates for biofilm adhesion, extracellular matrix production, and polymer degradation ability. Our study focuses on high-density polyethylene (HDPE) fragments for their high durability and environmental persistence, subjecting fragments to abiotic weathering prior to bacterial colonization. Marine isolates identified as Pseudomonas sp. and Lysinibacillus sp. exhibited decreasing biofilm formation on weathered HDPE, especially over the first 24 h of incubation. This effect was countered by increased extracellular matrix production, likely improving cell adhesion to surfaces roughened by abiotic degradation. These adhesion strategies were contrasted with a reference Pseudomonas aeruginosa strain, which displayed high levels of biofilm formation on non-weathered HDPE and lower extracellular matrix production over the first 24 h of incubation. Furthermore, our results suggest that an increase in biofilm biomass correlated with changes to HDPE structure, indicating that these strains have a potential for biodegradation of plastic fragments. Therefore, this work provides a detailed account of biofilm formation strategies and bacteria-plastic interactions that represent crucial steps in the biodegradation of plastic fragments in marine environments.
ISSN:0095-3628
1432-184X
DOI:10.1007/s00248-020-01666-8