Can Microplastic Pollution Change Soil-Water Dynamics? Results from Controlled Laboratory Experiments

Jazaei, Farhad; Chy, Tareq Jamal; Salehi, Maryam

doi:10.3390/w14213430

Cited by 7 publications

(2 citation statements)

References 68 publications

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“…The most directly applicable information that can be transferred from work in agricultural soils relates to effects on the mineral soil, as discussed in the current literature [5,55,68]. To summarize, there are effects on soil structure (e.g., the decrease in bulk density and aggregate strength [76,77]), soil water dynamics (e.g., increased water infiltration [78]), material flows and cycles (e.g., hindered soil microbial processes [79][80][81], macroinvertebrates activity [8,80] or plant growth [6,7]) and sorption and desorption processes with other soil pollutants (e.g., trace metals and organic pollutants [82]).…”

Section: Effects On Forest Soil Systemsmentioning

confidence: 99%

Mind the gap: forest soils as a hidden hub for global micro- and nanoplastic pollution

Weber,

Rillig,

Bigalke

2023

Micropl.&Nanopl.

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Global plastic pollution has become a major concern because of its effects on environmental and human health. A major fraction of environmental plastics is likely stored temporarily within terrestrial soils. However, even though forests represent the third most common type of land cover on Earth, almost nothing is known about plastics in forest soils. The atmospheric transport of micro- and nanoplastics provides ample opportunity for forest canopies to intercept plastic particles. These plastic particles, together with local plastic sources like litter and items used in forest management, eventually reach forest soils. In this paper we discuss the potential role of forest soils as a hub within global plastic cycles; transport processes from the atmosphere to the soil; and the integration of plastics into forest material cycles. Taken together, plastic in forests could have a major impact on sensitive ecosystems, economically important functions and global environmental plastic budgets. We also develop a roadmap for further investigation into plastics in forest soil systems.

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Section: Effects On Forest Soil Systemsmentioning

confidence: 99%

Mind the gap: forest soils as a hidden hub for global micro- and nanoplastic pollution

Weber,

Rillig,

Bigalke

2023

Micropl.&Nanopl.

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“…Once littered to the ground and incorporated into the soil matrix, plastic debris can compromise a number of important healthy soil properties such as soil aggregation [11], hydraulic conductivity and water holding capacity [12]. It furthermore shows negative dose-dependent effects on agricultural crop growth [13,14].…”

Section: Introductionmentioning

confidence: 99%

Metatranscriptomics of microbial biofilm succession on HDPE foil: uncovering plastic-degrading potential in soil communities

MacLean

Bartholomäus

Blukis

et al. 2023

Preprint

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Background Microbial communities in soil are a complex and sensitive system which secures soil health, nutrient cycling and the degradation of natural and xenobiotic substances. Even though plastic pollution is increasing worldwide, very little is known about microbial processes that take place once plastic debris gets incorporated into the soil matrix. In this study, we conducted the first metatranscriptome analysis of polyethylene (PE)-associated biofilm communities in a highly polluted landfill soil and compared their gene expressions to those of a forest soil community within a 53-day period.Results Our findings indicate that the microbial population present in soil contaminated with plastic debris carries a predisposition to both inhabit and degrade plastic surfaces. Surprisingly, the microbial community from an undisturbed forest soil contained a diverse array of plastic-associated genes (PETase, alkB etc.), indicating the presence of an enzymatic machinery capable of plastic degradation. Plastic-degrading taxa were upregulated in the early stages of biofilm and the PE-degrading enzymes alkB1/alkM and transporters such as FadL, livG, livF, livH and livM and fatty acid β-oxidation pathway were active during the maturation of the biofilm. We also found an increase in nitrogen fixation genes in the plastic soil community (but not in forest soil), indicating an essential metabolic adaptation of biofilm communities in the plastisphere.Conclusion With this study, we address the underlying patterns of gene expression during biofilm development of a PE-associated plastisphere in soil and address the pressing question whether or not natural microbial communities carry the potential to biodegrade petrochemical-based plastic in the (soil) environment.

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Assessment of Microplastics from Surface Water Bodies: Challenges and Future Scopes

Sonbhadra

Pandey

2023

Water Air Soil Pollut

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Can Microplastic Pollution Change Soil-Water Dynamics? Results from Controlled Laboratory Experiments

Cited by 7 publications

References 68 publications

Mind the gap: forest soils as a hidden hub for global micro- and nanoplastic pollution

Mind the gap: forest soils as a hidden hub for global micro- and nanoplastic pollution

Metatranscriptomics of microbial biofilm succession on HDPE foil: uncovering plastic-degrading potential in soil communities

Assessment of Microplastics from Surface Water Bodies: Challenges and Future Scopes

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