Physiological and biochemical effects of polystyrene micro/nano plastics on Arabidopsis thaliana.

Microplastics have garnered global attention due to their potential ecological risks. Research shows micro/nano-plastics pollution has adverse effects on plant growth, development, and physiological characteristics. However, the mechanisms underlying these effects remain unclear. The study examined the effects of polystyrene micro/nano-plastics with varying sizes and concentrations on different physiological and biochemical markers of A. thaliana. The indicators assessed include seed viability, growth, chlorophyll content, accumulation of root reactive oxygen species, and root exudates. Using fluorescence labeling, we investigated the absorption and translocation processes of micro/nano-plastics in A. thaliana. We also performed transcriptomic analysis to better understand the particular mechanisms of micro/nano-plastics. It indicated that micro/nano-plastics had an adverse effect on seed germination, especially under high concentration and small particle size treatments. This effect diminished with prolonged exposure. High concentrations at 50 nm and 100 nm treatment groups significantly inhibited the growth. Conversely, low concentrations of 1000 nm had a promoting effect. Exposure to micro/nano-plastics potentially resulted in decreased chlorophyll content, the accumulation of H 2 O 2 in roots, and stimulated root secretion of oxalic acid. Through transcriptomic analysis, the gene expression linked to micro/nano-plastic treatments of varying sizes enriched multiple metabolic pathways, impacting plant growth, development, environmental adaptation, metabolism, pigment synthesis, and stress response. [Display omitted] • Polystyrene micro/nanoplastics impact Arabidopsis thaliana physiology & biochemistry. • Low-concentration of 1000 nm polystyrene micro/nanoplastics promoted A. thaliana growth. • A. thaliana 's absorption & accumulation polystyrene micro/nanoplastics from 50–1000 nm. • Polystyrene micro/nanoplastics' size impacts gene expression in A. thaliana leaves & roots. [ABSTRACT FROM AUTHOR]