We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
A functional gene-array analysis of microbial communities settling on microplastics in a peat-draining environment
Summary
Researchers exposed polyethylene terephthalate and polylactic acid microplastics in a peat-draining river in Malaysia for six months, using functional gene arrays to characterize the microbial communities colonizing the plastic surfaces compared to surrounding water.
Concerns about microplastic (MP) pollution arise from the rafting potential of these durable particles which potentially propagate harmful chemicals and bacteria across wide spatial gradients. While many studies have been conducted in the marine environment, knowledge of MPs in coastal and freshwater systems is limited. For this study, we exposed two MPs (polyethylene terephthalate and polylactic acid) to the undisturbed peat-draining Maludam River in Malaysia, for 6 months. The microbial communities on these MPs and the surrounding water were sequenced by MiSeq, while the genetic responses of these communities were assessed by GeoChip 5.0S. Microbial communities were dominated by the phyla Proteobacteria, Acidobacteria and Actinobacteria. Metabolic processes involved with carbon, nitrogen, sulfur, metal homeostasis, organic remediation and virulence had significantly different gene expression among the communities on MPs and in the surrounding water. Our study is the first to look at changes in gene expression of whole plastisphere communities.
Sign in to start a discussion.
More Papers Like This
Distinct community structure and microbial functions of biofilms colonizing microplastics
Biofilm communities were established on polyethylene, polypropylene, cobblestone, and wood substrates over 21 days under controlled conditions and compared by 16S rRNA sequencing, finding that plastic substrates harbored distinct microbial communities and functional profiles compared to natural materials. The study demonstrates that microplastics in freshwater environments provide a selective niche that enriches for distinct microbial taxa and metabolic functions.
Distinctive patterns of bacterial community succession in the riverine micro-plastisphere in view of biofilm development and ecological niches
Scientists studied how bacterial communities develop on microplastics versus natural materials in river water and found that plastics support a distinct pattern of microbial colonization. The research identified specific bacteria capable of degrading microplastics and revealed that competition among microbes on plastic surfaces follows unexpected patterns compared to natural substrates.
Microbial colonization and succession on polylactic acid microplastics (PLA MPs) in mangrove forests - the role of environmental conditions and plastic properties
Researchers incubated two types of biodegradable polylactic acid microplastics in mangrove ecosystems across four environmental settings for 90 days to study microbial colonization patterns. They found that microbial colonization progressed more rapidly in sediment than in water, and the type of plastic influenced which microbial communities developed. The study suggests that environmental conditions and plastic properties together shape how microorganisms interact with biodegradable plastics in natural settings.
Biofilms on plastic litter in an urban river: Community composition and activity vary by substrate type
Researchers examined biofilms colonizing plastic litter versus natural surfaces in an urban river, finding that community composition and metabolic activity vary by substrate type, with plastic surfaces hosting distinct microbial communities that may influence plastic degradation rates.
Diversity and structure of microbial biofilms on microplastics in riverine waters of the Pearl River Delta, China
Microbial biofilm communities on microplastics in Pearl River Delta waterways showed distinct composition and diversity compared to surrounding water and natural surfaces, with river environmental conditions more influential than plastic polymer type in shaping biofilm structure.