Cadmium (Cd) contamination in soil poses a significant environmental threat, reducing crop yields and compromising food safety. This study investigates the potential of selenium nanoparticles (Se-NPs) synthesized using wheat extract to mitigate Cd toxicity, reduce Cd uptake and mobility, and recover grain nutrient composition in wheat (Triticum aestivum L.). A pot experiment was conducted following a completely randomized design (CRD) with three replications. Treatments included control, four Se-NPs concentrations (10, 25, 50, and 100 ppm), four Cd stress levels (25, 50, 75, and 100 ppm), and their combined interactions. Various physiological, biochemical, and agronomic parameters were analyzed to assess the mitigation potential of Se-NPs against Cd toxicity in wheat. Se-NPs (36.77 nm) were characterized using FTIR, confirming functional groups for stabilization, XRD verifying crystallinity and size via the Scherrer Equation, SEM revealing spherical morphology, and EDX confirming selenium as the predominant element with minor trace elements. Under 50 ppm Cd stress, Se-NPs at 25 ppm reduced days to anthesis by 8.16 % and mitigated a 45.13 % decrease in plant height. Grain yield, which declined by 90.86 % under Cd stress, was restored by 90.86 % with 10 ppm Se-NPs. Additionally, Se-NPs improved thousand kernel weight by 32.71 %, counteracting a 25.92 % reduction due to Cd stress. Antioxidant enzyme activities, including SOD and CAT, increased by up to 333.79 % in roots with Se-NP treatment, while oxidative stress markers decreased by 28 %. Moreover, Se-NPs effectively mitigated Cd uptake and reduced its mobility within the plant. Grain protein content improved by 16.89 %, and carbohydrate levels were maintained at 4.61 % despite Cd exposure. These findings indicate that Se-NPs enhance crop resilience, supporting sustainable food production in Cd-contaminated environments.

Lead (Pb) toxicity impairs the growth, yield, and biochemical traits of rice, making it essential to mitigate Pb stress in soil and restore its growth and production. This study investigated the potential of ascorbic acid-coated quantum dots (AsA-QDs) in alleviating Pb stress in two rice cultivars, Japonica (JP-5) and Indica (Super Basmati), grown in pots under Pb stress (50 mg/kg as lead chloride) with AsA-QD suspensions (50 ppm and 100 ppm) as treatments. The synthesized AsA-QDs were characterized by zeta potential (-14.4 mV), particle size (472.3 nm, PDI 0.745), UV-Vis absorption peak (240 nm), FT-IR analysis revealing functional groups (carboxylic acid and alkene), and TEM showing spherical morphology (average size 9.43 nm). Pb stress reduced key traits in JP-5, including tillers per plant (11.11 %), grain yield (18.22 %), kernel weight (18.22 %), protein (40.19 %), phenolic content (59.66 %), and antioxidant capacity (17.75 %), while 50 ppm AsA-QDs improved these by 33.33 %, 5.73 %, 2.03 %, and 13.19 %, respectively. Similarly, Pb stress reduced plant height, T/P, biomass yield (BY), GY, TKW, total sugars, reducing sugars, non-reducing sugars, starch, proteins, and TPC in Super Basmati by 19.76 %, 21.43 %, 11.01 %, 11.01 %, 7.52 %, 38.09 %, 7.24 %, 13.96 %, 11.97 %, and 40.39 %, respectively, while PbQD1 improved these traits by 14.29 %, 15.49 %, 9.25 %, 109.52 %, 8.31 %, 31.72 %, 25.91 %, and 7.075 %, respectively. The findings demonstrate that AsA-QDs effectively mitigate Pb toxicity by reducing oxidative stress, enhancing growth parameters, and restoring yield components, establishing them as a promising nanomaterial for sustainable crop resilience under Pb stress.

Mycorrhizal associations play a crucial role in afforestation efforts, as they enhance the acquisition of nutrients and water, thereby supporting seedling establishment. However, the influence of nitrogen (N) forms in the soil, particularly the organic N, on the formation of mycorrhizal associations and their subsequent effects on seedling morpho-physiology remains poorly understood. In this study, we examine the mycorrhizal colonization, along with morpho-physiological and functional traits, in Pinus cooperi seedlings following fertilization with organic N in controlled nursery conditions. A factorial experiment was performed with Pinus cooperi C. E. Blanco seedlings using two N sources: organic N (amino acids) and inorganic N (NH4NO3) and two N doses: low and high (60 vs 200 mg N seedling-1). Seedlings were inoculated with a mixture of native fungi, but the phylogenetic analysis showed that Suillus placidus (Bonord.) Singer was the only species colonizing roots. Organic N promoted similar morphology and nutritional status as inorganic N, though at a low N rate, it improved root growth and mycorrhizal colonization. High N fertilization improved seedling growth and nutritional status but reduced mycorrhizal colonization. Mycorrhizal colonization improved needle P concentration, delayed plant desiccation, and reduced root cellular damage when seedlings were subjected to desiccation, though it decreased plant growth and needle N concentration. We conclude that organic N fertilization improves mycorrhization of P. cooperi with S. placidus, but the fertilization dose should be adjusted to meet species-specific requirements in order to optimize plant quality and promote afforestation success.

Environmental stresses, particularly drought and salinity, significantly impair plant growth and productivity. This study explores the novel synergistic interaction between biochar and arbuscular mycorrhizal fungi (AMF) in enhancing the resilience of sweet pepper plants subjected to the individual or combined stresses of drought and salinity. The impact of these biostimulants on growth parameters, photosynthetic efficiency, and biochemical traits was assessed. Sweet pepper plants were subjected to drought stress (35 and 75% of field capacity (FC)), salinity (0 and 150 mM NaCl), and their combined effects (150 mM NaCl +35% of FC), with treatments including biochar (2.5 g/kg soil), AMF, and their combination. Under drought stress, the dual application of biochar and AMF notably improved plant growth indicators such as shoot fresh weight, shoot height, and number of leaves by 50, 14, and 3%, respectively compared to the control plants. Under drought and salinity combined, this combination also enhanced photosynthetic pigments content by 144% for Chl a, 316% for Chl b, 212% for Chl T and 302% for carotenoids content respectively compared to the control plants. Additionally, AMF and Biochar combined reduced the oxidative effect of malondialdehyde (MDA) by 37% and hydrogen peroxide (H2O2) by 43%, indicating a reduction in oxidative damage. Furthermore, a significant increase in antioxidant enzyme activities was observed, with peroxidase activity (POX) rising by 33% and polyphenol oxidase activity (PPO) increasing by 212%, indicating enhanced stress tolerance. This study underscores the efficacy of using biochar and AMF together to bolster sweet pepper plant resilience, offering a viable strategy for improving plant performance under challenging environmental conditions.

Soil salinization threatens global agriculture, reducing crop productivity and food security. Developing strategies to improve salt tolerance is crucial for sustainable agriculture. This study examines the role of organic fertilizer in mitigating salt stress in rice (Oryza sativa L.) by integrating NDVI and metabolomics. Using salt-sensitive (19X) and salt-tolerant (HHZ) cultivars, we aimed to (1) evaluate changes in NDVI and metabolite content under salt stress, (2) assess the regulatory effects of organic fertilizer, and (3) identify key metabolites involved in stress response and fertilizer-induced regulation. Under salt stress, survival rate of the 19X plants dropped to 6%, while HHZ maintained 38%, with organic fertilizer increasing survival rate to 25% in 19X and 66% in HHZ. NDVI values declined sharply in 19X (from 0.56 to <0.25) but remained stable in HHZ (similar to 0.56), showing a strong correlation with survival rate (R-2 = 0.87, p < 0.01). NDVI provided a dynamic, non-destructive assessment of rice health, offering a faster and more precise evaluation of salt tolerance than survival rate analysis. Metabolomic analysis identified 12 key salt-tolerant metabolites, including citric acid, which is well recognized for regulating salt tolerance. HTPA, pipecolic acid, maleamic acid, and myristoleic acid have previously been reported but require further study. Additionally, seven novel salt-tolerant metabolites-tridecylic acid, propentofylline, octadeca penten-3-one, 14,16-dihydroxy-benzoxacyclotetradecine-dione, cyclopentadecanolide, HpODE, and (+/-)8,9-DiHETE-were discovered, warranting further investigation. Organic fertilizer alleviated salt stress through distinct metabolic mechanisms in each cultivar. In 19X, it enhanced antioxidant defenses and energy metabolism, mitigating oxidative damage and improving fatty acid metabolism. In contrast, HHZ primarily benefitted from improved membrane stability and ion homeostasis, reducing lipid peroxidation and oxidative stress. These findings primarily support the identification and screening of salt-tolerant rice cultivars while also highlighting the need for cultivar-specific fertilization strategies to optimize stress resilience and crop performance. Based on the correlation analysis, 26 out of 53 differential metabolites were significantly correlated with NDVI, confirming a strong association between NDVI shifts and key metabolic changes in response to salt stress and organic fertilizer application. By integrating NDVI and metabolomics, this study provides a refined method for evaluating salt stress responses, capturing early NDVI changes and key salinity stress biomarkers. This approach may prove valuable for application in salt-tolerant variety screening, precision agriculture, and sustainable farming, contributing to scientific strategies for future crop improvement and agricultural resilience.

Global warming-induced abiotic stresses, such as waterlogging, significantly threaten crop yields. Increased rainfall intensity in recent years has exacerbated waterlogging severity, especially in lowlands and heavy soils. Its intensity is projected to increase by 14-35% in the future, posing a serious risk to crop production and the achievement of sustainable development goals. Soybean, a major global commercial crop cultivated across diverse climates, is highly sensitive to waterlogging, with yield losses of up to 83% due to impaired root morphology and growth. Therefore, understanding the stage-specific response of soybean to varying intensities of waterlogging under different climate regimes is crucial to mitigate the impact of climate change. This study evaluated two climate regimes (Summer: C-S and Rainy: C-R), four growth stages (S-15: 15 days after emergence, S-30, S-45, and S-60), and five waterlogging durations (D-2: 2 days, D-4, D-6, D-8, and D-10) using a randomized complete block design (RCBD) with seven replications in 2023. Results revealed that waterlogging adversely affected soybean root morphology (reducing root volume by 8.6% and dry weight by 5.3%) and growth (decreasing leaf area by similar to 6% and dry matter by 48.2%), with more severe effects observed during the summer compared to the rainy season. Among growth stages, soybean was most sensitive at S-45, showing greater reductions in growth attributes and seed yield (similar to 64.9%) across climate regimes. Prolonged waterlogging (2-10 days) had a pronounced negative impact on root and shoot parameters, resulting in yield reductions of 25.4-47.8% during summer and 47.0-68.2% during the rainy season, compared to the control. Yield stability was highest at D-2 (yield stability index: 0.53) with minimal yield reductions, while D-10 caused the greatest yield loss (similar to 58%). Interestingly, the summer climate regime, characterized by bright sunshine hours and higher temperatures, supported better post-stress recovery, leading to higher grain yields. In conclusion, waterlogging during C-R x S-45 x D-10 caused the most substantial yield reduction (similar to 91%).

Microorganisms play a vital role in restoring soil multifunctionality and rejuvenating degraded meadows. The availability of microbial resources, such as carbon, nitrogen, and phosphorus, often hinders this process. However, there is limited information on whether grass restoration can alleviate microbial resource limitations in damaged slopes of high-altitude regions. This study focused on alpine bare land impacted by engineering activities, with the goal of using grass seeds to improve soil resource availability and multifunctionality. High- throughput sequencing and enzyme stoichiometry (vector analyses) were employed to analyze microbial community composition and assess resource limitations. Our findings suggested that soil carbon, nitrogen, and phosphorus contents were low, ranging from 7.67 to 12.6 g kg- 1 for carbon, 0.61 to 0.98 g kg-1,for nitrogen, and 0.65 to 0.78 g kg-1for phosphorus. Nevertheless, the standardized scores for high yield and resource acquisition strategies remained at 0.26 and 1.36 in the four groups, which were lower than those of the stress tolerance strategy. Microorganisms primarily employed the stress tolerance strategy, focusing on repairing injured cells rather than promoting cell growth, which suggests that microbial growth and metabolism were only marginally enhanced. Because of this strategy's limited impact on enhancing microbial community diversity and fostering a co-occurrence network, the resultant levels remained comparable to those observed in degraded meadows. In this case, microbial resource limitations persisted, with phosphorus remaining a constraint. Consequently, grass restoration alone offered limited relief for microbial resource limitations in alpine meadows, underscoring the challenges of solely relying on grass seeds to recover damaged alpine ecosystems.

Featured Application The Middle European ecotype of Cd hyperaccumulator Solanum nigrum L. ssp. nigrum was found to show extraordinarily strong tolerance to high contents of Cd in soil (over 50 mg kg-1 Cd) and high Cd accumulation capacity at this concentration range. Its adapted A50 variety obtained from the seeds of first-generation plants grown in soil with 50 mg kg-1 Cd appeared to display further considerable enhancement of resistance to Cd stress, accumulation capacity, and healthy state. This makes the Middle European ecotype and its adapted variety A50 particularly useful to sustainable decontamination of heavily polluted hot spots in degraded post-industrial areas.Abstract The Cd hyperaccumulator Solanum nigrum L. exhibits a cosmopolitan character and proven high and differentiated efficiency. This suggests the possibility of optimizing its Cd phytoremediation capacity and applicability through searching among remote ecotypes/genotypes. However, the extensive studies on this hyperaccumulator have been limited to Far East (Asian) regions. Pioneer pot experiments on the Middle European ecotype of S. nigrum within a concentration range of 0-50 mg kg-1 Cd in soil revealed its Cd phytoremediation capacity to be comparable to Asian ecotypes but with a fundamentally different Cd tolerance threshold. While biomass of the Asian ecotypes declined sharply at Csoil approximate to 10 mg kg-1 Cd, in the Middle European ecotype, a gradual mild biomass decrease occurred within the whole Csoil approximate to 0-50 mg kg-1 Cd range with no toxic symptoms. Its adapted A50 variety was obtained from the seeds of first-generation plants grown in soil with Csoil approximate to 50 mg kg-1 Cd. In this variety, Cd tolerance, accumulation performance, and all physiological parameters (chlorophyll, carotenoids, RuBisCO, and first- and second-line defense anti-oxidant activity) were significantly enhanced, while cell damage by ROS was considerably lesser. This makes the Middle European ecotype and its adapted variety A50 particularly useful to sustainable decontamination of heavily polluted hot spots in degraded post-industrial areas.

Endophytes generally increase antioxidant contents of plants subjected to environmental stresses. However, the mechanisms by which endophytes alter the accumulation of antioxidants in plant tissues are not entirely clear. We hypothesized that, in stress situations, endophytes would simultaneously reduce oxidative damage and increase antioxidant contents of plants and that the accumulation of antioxidants would be a consequence of the endophyte ability to regulate the expression of plant antioxidant genes. We investigated the effects of the fungal endophyte Epichlo & euml; gansuensis (C.J. Li & Nan) on oxidative damage, antioxidant contents, and expression of representative genes associated with antioxidant pathways in Achnatherum inebrians (Hance) Keng plants subjected to low (15%) and high (60%) soil moisture conditions. Gene expression levels were measured using RNA-seq. As expected, the endophyte reduced the oxidative damage by 17.55% and increased the antioxidant contents by 53.14% (on average) in plants subjected to low soil moisture. In line with the accumulation of antioxidants in plant tissues, the endophyte increased the expression of most plant genes associated with the biosynthesis of antioxidants (e.g., MIOX, crtB, gpx) while it reduced the expression of plant genes related to the metabolization of antioxidants (e.g., GST, PRODH, ALDH). Our findings suggest that endophyte ability of increasing antioxidant contents in plants may reduce the oxidative damage caused by stresses and that the fungal regulation of plant antioxidants would partly explain the accumulation of these compounds in plant tissues.

Plant growth and productivity are continually being challenged by a diverse array of abiotic stresses, including: water scarcity, extreme temperatures, heavy metal exposure, and soil salinity. A common theme in these stresses is the overproduction of reactive oxygen species (ROS), which disrupts cellular redox homeostasis causing oxidative damage. Ascorbic acid (AsA), commonly known as vitamin C, is an essential nutrient for humans, and also plays a crucial role in the plant kingdom. AsA is synthesized by plants through the d-mannose/l-galactose pathway that functions as a powerful antioxidant and protects plant cells from ROS generated during photosynthesis. AsA controls several key physiological processes, including: photosynthesis, respiration, and carbohydrate metabolism, either by acting as a co-factor for metabolic enzymes or by regulating cellular redox-status. AsA's multi-functionality uniquely positions it to integrate and recalibrate redox-responsive transcriptional/metabolic circuits and essential biological processes, in accordance to developmental and environmental cues. In recognition of this, we present a systematic overview of current evidence highlighting AsA as a central metabolite-switch in plants. Further, a comprehensive overview of genetic manipulation of genes involved in AsA metabolism has been provided along with the bottlenecks and future research directions, that could serve as a framework for designing stress-smart crops in future.