Nitric oxide mitigates the phytotoxicity of imidazolium-based ionic liquids in Arabidopsis.

Ionic liquids (ILs) have many beneficial properties that are extensively used in various fields. Despite their utility, the phytotoxic aspects of ILs are poorly known. This is especially true at the transcriptomic level and the role of nitric oxide (NO) in this process. Herein, we studied the mechanism by which endogenous NO reduces the toxicity of ILs in Arabidopsis. We examined the effects of two imidazolium-based ILs (IILs) on three Arabidopsis lines, each characterized by distinct endogenous NO levels, using a combination of physiological and transcriptomics methods. IILs impaired seed germination, seedling development, chlorophyll content, and redox homeostasis in Arabidopsis. Notably, 1,3-dibutyl imidazole bromide had greater toxicity than 1-butyl-3-methylimidazolium chloride. Nox1, a mutant with an elevated NO level, had enhanced resistance, while nia1nia2, a mutant with a diminished NO level, had increased susceptibility compared to the wild type. RNA sequencing results suggested that NO mitigates IILs-induced phytotoxicity by modulating the metabolism of chlorophyll and secondary metabolites, and by bolstering the antioxidant defense system. These findings illustrate the complex molecular networks that respond to IIL stress and reveal the potential of endogenous NO as a mitigating factor in plant stress physiology.

Ozone-Induced Rapid and Green Synthesis of Polydopamine Coatings with High Uniformity and Enhanced Stability.

The development of green, controllable, and simplified pathways for rapid dopamine polymerization holds significant importance in the field of polydopamine (PDA) surface chemistry. In this study, a green strategy is successfully devised to accelerate and control the polymerization of dopamine through the introduction of ozone (O3 ). The findings reveal that ozone serves as an eco-friendly trigger, significantly accelerating the dopamine polymerization process across a broad pH range, spanning from 4.0 to 10.0. Notably, the deposition rate of PDA coatings on a silicon wafer reaches an impressive value of ≈64.8 nm h-1 (pH 8.5), which is 30 times higher than that of traditional air-assisted PDA and comparable to the fastest reported method. Furthermore, ozone exhibits the ability to accelerate dopamine polymerization even under low temperatures. It also enables control over the inhibition-initiation of the polymerization process by regulating the "ON/OFF" mode of the ozone gas. Moreover, the ozone-induced PDA coatings demonstrate exceptional characteristics, including high homogeneity, good hydrophilicity, and remarkable chemical and mechanical stability. Additionally, the ozone-induced PDA coatings can be rapidly and effectively deposited onto a wide range of substrates, particularly those that are adhesion-resistant, such as polytetrafluoroethylene (PTFE).