Selenium nanoparticles(Se NPs) are less toxic and more biocompatible than selenite or selenate. However, studies involving spraying with Se NPs for reducing accumulation of cadmium(Cd) and lead(Pb) in rice grains have...Selenium nanoparticles(Se NPs) are less toxic and more biocompatible than selenite or selenate. However, studies involving spraying with Se NPs for reducing accumulation of cadmium(Cd) and lead(Pb) in rice grains have been rarely reported as yet. Herein, indica rice seedlings cultivated in Cd + Pb-spiked paddy soils(denoted as positive control) were sprayed with Se NPs sols for four times from tillering to booting stage. Compared to positive control, 50–100 μmol/L Se NPs downregulated Cd transporters-related genes such as Os LCT 1, OsH MA 2 and Os CCX2 in leaves and OsLCT1, Os PCR1 and Os CCX2 genes in node I at filling stage. Meanwhile, Se-binding protein 1 was distinctly elevated, involving the repression of Cd and Pb transportation to rice grains. Se NPs also differentially improved RuBP carboxylase and chlorophylls especially some key genes and proteins involving photosynthetic system. Besides, 25–50 μmol/L Se NPs diminished reactive oxygen species overproduction from NADPH oxidases whereas boosted glutathione peroxidase, reducing protein carbonylation in rice seedlings. However, the antioxidant isozymes and oxidatively modified proteins were slightly rebounded at 100 μmol/L. Se contents were noticeably elevated and confirmed to exist as selenomethionine in the rice grains following all the treatments by Se NPs. Thus, the optimal dosage of Se NPs for foliar application is 50 μmol/L, which significantly decreased Cd accumulation, improved photosynthesis and Se enrichment whereas caused no distinct reduction of Pb in the grains. Thus, an appropriate dosage of Se NPs can be conducted to decrease Cd accumulation, improve photosynthesis, and organic Se contents in rice grains.展开更多
The current strategy of co-delivering copper ions and disulfiram(DSF)to generate cytotoxic CuET faces limitations in achieving rapid and substantial CuET production,specifically in tumor lesions.To overcome this chall...The current strategy of co-delivering copper ions and disulfiram(DSF)to generate cytotoxic CuET faces limitations in achieving rapid and substantial CuET production,specifically in tumor lesions.To overcome this challenge,we introduce a novel burst-release cascade reactor composed of phase change materials(PCMs)encapsulating ultrasmall Cu_(2-x)Se nanoparticles(NPs)and DSF(DSF/Cu_(2-x)Se@PCM).Once triggered by second near-infrared(NIR-II)light irradiation,the reactor swiftly releases Cu_(2-x)Se NPs and DSF,enabling catalytic reactions that lead to the rapid and massive production of Cu_(2-x)Se-ET complexes,thereby achieving in situ chemotherapy.The mechanism of the burst reaction is due to the unique properties of ultrasmall Cu_(2-x)Se NPs,including their small size,multiple defects,and high surface activity.These characteristics allow DSF to be directly reduced and chelated on the surface defect sites of Cu_(2-x)Se,forming Cu_(2-x)Se-ET complexes without the need for copper ion release.Additionally,Cu_(2-x)Se-ET has demonstrated a similar(to CuET)anti-tumor activity through increased autophagy,but with even greater potency due to its unique two-dimensional-like structure.The light-triggered cascade of interlocking reactions,coupled with in situ explosive generation of tumor-suppressive substances mediated by the size and valence of Cu_(2-x)Se,presents a promising approach for the development of innovative nanoplatforms in the field of precise tumor chemotherapy.展开更多
基金supported by the Major Project of Science and Technology of Anhui Province(No.18030701189)。
文摘Selenium nanoparticles(Se NPs) are less toxic and more biocompatible than selenite or selenate. However, studies involving spraying with Se NPs for reducing accumulation of cadmium(Cd) and lead(Pb) in rice grains have been rarely reported as yet. Herein, indica rice seedlings cultivated in Cd + Pb-spiked paddy soils(denoted as positive control) were sprayed with Se NPs sols for four times from tillering to booting stage. Compared to positive control, 50–100 μmol/L Se NPs downregulated Cd transporters-related genes such as Os LCT 1, OsH MA 2 and Os CCX2 in leaves and OsLCT1, Os PCR1 and Os CCX2 genes in node I at filling stage. Meanwhile, Se-binding protein 1 was distinctly elevated, involving the repression of Cd and Pb transportation to rice grains. Se NPs also differentially improved RuBP carboxylase and chlorophylls especially some key genes and proteins involving photosynthetic system. Besides, 25–50 μmol/L Se NPs diminished reactive oxygen species overproduction from NADPH oxidases whereas boosted glutathione peroxidase, reducing protein carbonylation in rice seedlings. However, the antioxidant isozymes and oxidatively modified proteins were slightly rebounded at 100 μmol/L. Se contents were noticeably elevated and confirmed to exist as selenomethionine in the rice grains following all the treatments by Se NPs. Thus, the optimal dosage of Se NPs for foliar application is 50 μmol/L, which significantly decreased Cd accumulation, improved photosynthesis and Se enrichment whereas caused no distinct reduction of Pb in the grains. Thus, an appropriate dosage of Se NPs can be conducted to decrease Cd accumulation, improve photosynthesis, and organic Se contents in rice grains.
基金support from the National Natural Science Foundation of China(NSFC,81971734,32071323,32271410,and 82202330)the National Key Research&Development Program of China(2019YFE0113600)+1 种基金the Science and Technology Projects in Fujian Province(2022FX1,2023Y4008)the Program for Innovative Research Team in Science and Technology in Fujian Province University,and the Scientific Research Funds of Huaqiao University(23BS113).
文摘The current strategy of co-delivering copper ions and disulfiram(DSF)to generate cytotoxic CuET faces limitations in achieving rapid and substantial CuET production,specifically in tumor lesions.To overcome this challenge,we introduce a novel burst-release cascade reactor composed of phase change materials(PCMs)encapsulating ultrasmall Cu_(2-x)Se nanoparticles(NPs)and DSF(DSF/Cu_(2-x)Se@PCM).Once triggered by second near-infrared(NIR-II)light irradiation,the reactor swiftly releases Cu_(2-x)Se NPs and DSF,enabling catalytic reactions that lead to the rapid and massive production of Cu_(2-x)Se-ET complexes,thereby achieving in situ chemotherapy.The mechanism of the burst reaction is due to the unique properties of ultrasmall Cu_(2-x)Se NPs,including their small size,multiple defects,and high surface activity.These characteristics allow DSF to be directly reduced and chelated on the surface defect sites of Cu_(2-x)Se,forming Cu_(2-x)Se-ET complexes without the need for copper ion release.Additionally,Cu_(2-x)Se-ET has demonstrated a similar(to CuET)anti-tumor activity through increased autophagy,but with even greater potency due to its unique two-dimensional-like structure.The light-triggered cascade of interlocking reactions,coupled with in situ explosive generation of tumor-suppressive substances mediated by the size and valence of Cu_(2-x)Se,presents a promising approach for the development of innovative nanoplatforms in the field of precise tumor chemotherapy.
