Nickel(Ni)toxicity significantly impairs plant growth,photosynthesis,and metabolism by inducing oxidative stress.This study evaluates the potential of exogenous Alpha-Ketoglutarate(AKG)in mitigating Ni-induced stress ...Nickel(Ni)toxicity significantly impairs plant growth,photosynthesis,and metabolism by inducing oxidative stress.This study evaluates the potential of exogenous Alpha-Ketoglutarate(AKG)in mitigating Ni-induced stress in Peganum harmala L.Seedlings were exposed to 0,200,500,and 750μM NiCl2,with or without AKG supplementation.Under 750μM Ni stress,dry weight(DW)decreased by 33.7%,tissue water content(TWC)by 39.9%,and chlorophyll a and total chlorophyll levels were reduced by 17%and 15%,respectively.Ni exposure also significantly increased secondary metabolite production,with leaf anthocyanin content rising by 131%,and superoxide dismutase(SOD)and catalase(CAT)activities increasing by 228%and 53%,respectively,in roots at 500μM Ni.AKG treatment alleviated Ni toxicity by enhancing TWC by 39%and promoting root and shoot growth.Additionally,AKG treatment boosted the synthesis of phenolic compounds and flavonoids,contributing to improved tolerance against Ni stress.These findings demonstrate the potential of AKG in enhancing Ni tolerance in P.harmala,suggesting its promising role in bioremediation of metal-contaminated soils.This is the first study to report the beneficial effects of exogenous AKG in alleviating nickel toxicity in P.harmala L.,offering a new approach for improving plant resilience to heavy metal stress.展开更多
In recent years, the world has faced rising global temperatures, accumulative pollution, and energy crises, stimulating scientists worldwide to strive for eco-friendly and cost-effective solutions. Biochar has materia...In recent years, the world has faced rising global temperatures, accumulative pollution, and energy crises, stimulating scientists worldwide to strive for eco-friendly and cost-effective solutions. Biochar has materialized as a favorable tool for environmental remediation, indicating efficacy as an efficient sorbent substance for both inorganic and organic pollutants in environmental field. These unique properties exclude improved surface functionality, porous morphology, large specific surface area (SSA), cation exchange capacity (CEC), robust adsorption capabilities, environmental stability, and embedded micronutrients. Biochar exhibited potential characteristics for environmental oversight, greenhouse gas (GHG) emission reduction, and soil fertility improvement. This review explores the impact of fundamental factors such as retention time, pyrolysis temperature, gas flow rate, and reactor design on biochar yield and properties. Collected data revealed the various applications of biochar, ranging from waste management and construction materials to the adsorptive removal of hydrocarbon lubricants from aqueous media, contaminant immobilization, and carbon sequestration. It has played mostly a significant share in climate change mitigation and an important role in soil amendments. Biochar improves soil improvement by increasing water retention (10%–30%), carbon sequestration, soil surface functionality, and providing high surface area with chemical stability. The assessment also reports the prospects and contests associated with biochar application uses in various agriculture cropping ecosystems. Inclusive, this review highlights the multifaceted characteristics of biochar as an adjustable on top of a sustainable solution addressing greenhouse gas emission, carbon sequestration, and environmental stresses. However, further research is needed to understand its long-term impacts and optimal applications fully.展开更多
基金Researchers Supporting Project No.(RSP2025R390),King Saud University,Riyadh,Saudi Arabia.
文摘Nickel(Ni)toxicity significantly impairs plant growth,photosynthesis,and metabolism by inducing oxidative stress.This study evaluates the potential of exogenous Alpha-Ketoglutarate(AKG)in mitigating Ni-induced stress in Peganum harmala L.Seedlings were exposed to 0,200,500,and 750μM NiCl2,with or without AKG supplementation.Under 750μM Ni stress,dry weight(DW)decreased by 33.7%,tissue water content(TWC)by 39.9%,and chlorophyll a and total chlorophyll levels were reduced by 17%and 15%,respectively.Ni exposure also significantly increased secondary metabolite production,with leaf anthocyanin content rising by 131%,and superoxide dismutase(SOD)and catalase(CAT)activities increasing by 228%and 53%,respectively,in roots at 500μM Ni.AKG treatment alleviated Ni toxicity by enhancing TWC by 39%and promoting root and shoot growth.Additionally,AKG treatment boosted the synthesis of phenolic compounds and flavonoids,contributing to improved tolerance against Ni stress.These findings demonstrate the potential of AKG in enhancing Ni tolerance in P.harmala,suggesting its promising role in bioremediation of metal-contaminated soils.This is the first study to report the beneficial effects of exogenous AKG in alleviating nickel toxicity in P.harmala L.,offering a new approach for improving plant resilience to heavy metal stress.
基金Deanship of Scientific Research(DSR)at King Faisal University,Saudi Arabia,under project number KFU241939.
文摘In recent years, the world has faced rising global temperatures, accumulative pollution, and energy crises, stimulating scientists worldwide to strive for eco-friendly and cost-effective solutions. Biochar has materialized as a favorable tool for environmental remediation, indicating efficacy as an efficient sorbent substance for both inorganic and organic pollutants in environmental field. These unique properties exclude improved surface functionality, porous morphology, large specific surface area (SSA), cation exchange capacity (CEC), robust adsorption capabilities, environmental stability, and embedded micronutrients. Biochar exhibited potential characteristics for environmental oversight, greenhouse gas (GHG) emission reduction, and soil fertility improvement. This review explores the impact of fundamental factors such as retention time, pyrolysis temperature, gas flow rate, and reactor design on biochar yield and properties. Collected data revealed the various applications of biochar, ranging from waste management and construction materials to the adsorptive removal of hydrocarbon lubricants from aqueous media, contaminant immobilization, and carbon sequestration. It has played mostly a significant share in climate change mitigation and an important role in soil amendments. Biochar improves soil improvement by increasing water retention (10%–30%), carbon sequestration, soil surface functionality, and providing high surface area with chemical stability. The assessment also reports the prospects and contests associated with biochar application uses in various agriculture cropping ecosystems. Inclusive, this review highlights the multifaceted characteristics of biochar as an adjustable on top of a sustainable solution addressing greenhouse gas emission, carbon sequestration, and environmental stresses. However, further research is needed to understand its long-term impacts and optimal applications fully.
