What question did this study set out to answer?

The study aims to understand how polystyrene nanoplastics affect rice's ability to recover from salt stress.

March 18, 2026

Polystyrene Nanoplastics Impair Transcriptional Resilience to Salt Stress in Rice

Key Points

The study aims to understand how polystyrene nanoplastics affect rice's ability to recover from salt stress.
Investigated the impact of polystyrene nanoplastics on rice under salt stress conditions.
Measured Na+/K+ ion ratios to determine ionic toxicity.
Conducted transcriptomic analysis to evaluate gene expression changes.
Polystyrene nanoplastics increased Na+/K+ ratios by 48% during stress and 60% during recovery.
Plants exposed to both salt and nanoplastics had 34% fewer differentially expressed genes compared to those exposed to salt only.
The interaction between NPs and salt shifted from additive to antagonistic, disrupting critical stress recovery pathways.

Abstract

Nanoplastics (NPs) and salinity increasingly co-occur in agricultural systems. Here, we investigated how polystyrene NPs (502 nm, 10 mg L-1) impair rice (Oryza sativa L.) recovery from salt (50 mM NaCl). During stress, NPs synergistically amplified ionic toxicity, elevating Na+/K+ ratios 48% above additive predictions. Crucially, this synergism intensified to 60% during recovery, preventing homeostasis restoration. Transcriptomic analysis revealed that NP-salt interactions shifted from additive to antagonistic poststress, disrupting trehalose pathway regulation critical for osmotic adjustment. Additionally, coexposed plants failed to switch from stress- to growth-associated gene modules, exhibiting 34% fewer differentially expressed genes than salt-only plants. These findings demonstrate that NPs compromise transcriptional resilience by disrupting adaptive reprogramming, emphasizing the need for recovery-inclusive risk assessments.

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Polystyrene Nanoplastics Impair Transcriptional Resilience to Salt Stress in Rice

Key Points

Abstract

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