Nanoplastics in Duckweed: Single-Cell Responses and Recovery
Yuan, Wenke Xu, Elvis Genbo Zhu, Dong Zhang, Weihong Liu, Wenzhi Abdolahpur Monikh, Fazel Lin, Li Li, Lianzhen Grossart, Hans-Peter Yang, Yuyi
Yuan, Wenke
Xu, Elvis Genbo
Zhu, Dong
Zhang, Weihong
Liu, Wenzhi
Abdolahpur Monikh, Fazel
Lin, Li
Li, Lianzhen
Grossart, Hans-Peter
Yang, Yuyi
Series / Report no.
Open Access
Type
Journal Article
Article
Article
Language
en
Date of publication
2025-12-16
Year of publication
Research Projects
Organizational Units
Journal Issue
Title
Nanoplastics in Duckweed: Single-Cell Responses and Recovery
Translated Title
Published in
ACS Nano 2025; 19(51):42869-42880
Abstract
Micro- and nanoplastics have emerged as critical contaminants in aquatic ecosystems due to their small size, persistent nature, and potential for bioaccumulation. Nanoplastics are particularly concerning because they can be widespread in aquatic environments and ingested by aquatic organisms, posing potential risks to ecological health and environmental sustainability. However, the response and recovery of aquatic plants to nanoplastics, as well as the cell-specific molecular mechanisms underlying these processes, remain unclear. By integrating single-cell transcriptomics, enzymatic assays, and europium-doped nanoplastic tracing, we comprehensively investigated the response of duckweed to polystyrene nanoplastics at environmentally relevant and high doses over exposure and recovery phases. Nanoplastics exposure reduced plant reproduction and root length by inducing oxidative damage, with partial recovery after removal. Single-nucleus RNA sequencing revealed cell-type-specific responses of duckweed to nanoplastics, particularly in mesophyll, mestome sheath, epidermis, and parenchyma cells. Interestingly, recovery triggered a greater number of differentially expressed genes mechanistically linked to carbon metabolism, membrane transport, and stress-responsive pathways. Nanotracer quantification demonstrated root/frond absorption and 36.8-51.4% postrecovery excretion. These multiscale lines of evidence decipher the molecular strategies of duckweed to nanoplastics at single-cell resolution, providing mechanistic insights into the interactions between aquatic plants and nanoplastics contamination.