Your search keyword '"NUTRIENT UPTAKE"' showing total 3,524 results

1. Zeoponic: A breakthrough plant growth media for horticulture and seedling of plantation

Author

Suwardi, Suryaningtyas, Dyah Tjahyandari, Oktariani, Putri, Widjaja, Hermanu, and Randrikasari, Octaviana

Published

2024

2. Effect of Ni and Fe Co-Application on the Soybean Crop Grown in Nickel and Iron Deficient Soils of Mirzapur District.

Author

Bahuguna, Ayush, Singh, Satish Kumar, Pandey, Astha, Sharma, Sachin, Pradhan, Surajyoti, Arvind, Shukla, Munesh Kumar, Bharteey, Prem Kumar, Mukherjee, Sayon, Tripathi, Sumit, and Singh, Pavan

Subjects

*IRON-nickel alloys, *SOIL science, *AGRICULTURE, *COPPER, *NUTRIENT uptake, *IRON fertilizers

Abstract

Considering the importance of nickel and iron nutrition for the soybean crop, their deficiency inhibits the yield drastically specially in the area where soybean crop is dominant. To encounter this problem, a pot experiment was conducted in glass house on low nickel and iron soil in Department of Soil Science and Agricultural Chemistry, Institute of Agricultural Sciences, Banaras Hindu University, Varanasi, during 2019–20 and 2021–22. The study was carried out to investigate the effect of Ni (nickel) and Fe (iron) on the post-harvest soil parameters, growth, yield, nutrient uptake and nutrient content of soybean crop. There were 10 treatments with two levels of Ni (5 and 10 mg kg −1) and Fe (10 and 20 mg kg−1) with recommended dosage of fertilizers nitrogen, phosphorus, potassium (8.93, 35.71, and 17.86 mg kg−1) applied to all treatments except control. The result of the experiment revealed that the co-application of nickel and iron@10 mg kg−1 and 20 mg kg−1 (RDF + Ni10Fe20), resulted in the increase in plant height, greeness index, no of seed per pod, no of pod per plant, seed yield, and stover yield. Similar, findings for the post- harvest soil parameter indicated that there was increase in pH, electrical conductivity, and organic carbon content of soil. DTPA (Diethylenetriaminepentaacetic acid) extractable Ni, Fe, Zn, and Cu, also found highest in treatment where nickel and iron@10 mg kg−1 and 20 mg kg−1 (RDF + Ni10Fe20) were applied in soil, but in case of DTPA extractable Mn, the highest amount was found in treatment where nickel and iron@10 mg kg−1 and 10 mg kg−1 (RDF + Ni10Fe10) was applied in soil. The soil microbial biomass carbon and urease activity was also found highest in the treatment where nickel and iron@10 and 20 mg kg−1 was applied in soil. The minimum plant height, greeness index, no of seed per pod, no of pod per plant, seed, and stover yield was recorded in treatment where only RDF(T1) was applied. Similar, result recorded for the post-harvest soil parameters. So, overall findings of the pot experiment revealed that the conjoint application of nickel and iron has resulted in better yield of soybean crop. [ABSTRACT FROM AUTHOR]

Published

2024

3. Influence of peat-derived humic acid on the growth of agarwood seedlings.

Author

Abdullah, Halimatul Sa'adiah, Kasim, Susilawati, Raguraj, Sriharan, Abdul Azim, Amir Affan, and Mohd Amin, Adibah

Subjects

*ALKALINE hydrolysis, *HUMIC acid, *PEAT soils, *SCANNING electron microscopes, *NUTRIENT uptake

Abstract

Humic acid (HA) is widely used in agriculture as a biostimulant to enhance plant growth and nutrient uptake. Studies on the early growth promotion of agarwood seedlings using plant biostimulants have not been explored. Therefore, the objective of this study was to extract and characterize peat-derived HA and to determine the optimum rate that would exert biostimulant action on the early growth of agarwood seedlings at the nursery stage. HA was extracted from peat soil using a modified rapid alkaline hydrolysis method. Produced peat humic acid (PHA) was compared with commercial humic acid (CHA) for its chemical and spectroscopic characteristics. One-month-old agarwood seedlings were treated with PHA at different rates (0, 20, 40, 80, 160 and 320 mg kg−1) before the commencement of the experiment. The study was conducted for four months. The C/N ratio of both PHA and CHA were 25.85 and 26.93, respectively. Scanning electron microscope (SEM) and fourier-transform infrared spectroscopy (FTIR) spectra observation reveals that PHA and CHA have similar surface morphology and functional groups respectively. Results revealed that agarwood seedlings treated with 80 mg kg−1 of PHA significantly increased the plant height, stem diameter, the number of leaves, leaf area, dry matter weight, N and P concentrations in plant tissues, and N, P and K uptakes. Based on the findings, incorporation of PHA at the rate of 80 mg kg−1 with planting medium could be used as an optimum rate to enhance the growth of agarwood seedlings in the nursery stage. [ABSTRACT FROM AUTHOR]

Published

2024

4. Optimizing nitrogen fertilization in maize: the impact of nitrification inhibitors, phosphorus application, and microbial interactions on enhancing nutrient efficiency and crop performance.

Author

Malakshahi Kurdestani, Ali, Francioli, Davide, Ruser, Reiner, Piccolo, Alessandro, Maywald, Niels Julian, Chen, Xinping, and Müller, Torsten

Abstract

Despite the essential role of nitrogen fertilizers in achieving high crop yields, current application practices often exhibit low efficiency. Optimizing nitrogen (N) fertilization in agriculture is, therefore, critical for enhancing crop productivity while ensuring sustainable food production. This study investigates the effects of nitrification inhibitors (Nis) such as Dimethyl Pyrazole Phosphate (DMPP) and Dimethyl Pyrazole Fulvic Acid (DMPFA), plant growth-promoting bacteria inoculation, and phosphorus (P) application on the soil-plant-microbe system in maize. DMPFA is an organic nitrification inhibitor that combines DMP and fulvic acid for the benefits of both compounds as a chelator. A comprehensive rhizobox experiment was conducted, employing varying levels of P, inoculant types, and Nis, to analyze the influence of these factors on various soil properties, maize fitness, and phenotypic traits, including root architecture and exudate profile. Additionally, the experiment examined the effects of treatments on the bacterial and fungal communities within the rhizosphere and maize roots. Our results showed that the use of Nis improved plant nutrition and biomass. For example, the use of DMPFA as a nitrification inhibitor significantly improved phosphorus use efficiency by up to 29%, increased P content to 37%, and raised P concentration in the shoot by 26%, compared to traditional ammonium treatments. The microbial communities inhabiting maize rhizosphere and roots were also highly influenced by the different treatments. Among them, the N treatment was the major driver in shaping bacterial and fungal communities in both plant compartments. Notably, Nis reduced significantly the abundance of bacterial groups involved in the nitrification process. Moreover, we observed that each experimental treatment employed in this investigation could select, promote, or reduce specific groups of beneficial or detrimental soil microorganisms. Overall, our results highlight the intricate interplay between soil amendments, microbial communities, and plant nutrient dynamics, suggesting that Nis, particularly DMPFA, could be pivotal in bolstering agricultural sustainability by optimizing nutrient utilization. [ABSTRACT FROM AUTHOR]

Published

2024

5. Effect of summer legume residue incorporation and fertilizer regimes on rice growth, yield, and nutrient uptake.

Author

Sunil Kumar, T., Virdia, H. M., Patel, K. G., Ragi, Shridhar, Chowdhury, Manojit, Kumar, Pradeep, Elbagory, Mohssen, Omara, Alaa El-Dein, Salem, Ali, Elbeltagi, Ahmed, and El-Shinawy, Doaa M.

Subjects

MUNG bean, FERTILIZER application, COWPEA, GRAIN yields, NUTRIENT uptake

Abstract

In a field trial at the College Farm, NAU, Navsari (Gujarat), evaluated four main plot treatments (T1: Green gram, T2: Cowpea, T3: Dhaincha, and T4: Fallow), which were grown during the summer with three replications following a randomized block design (RCBD). Green gram and cowpea were incorporated into the soil after harvest, but dhaincha was incorporated at 50% flowering. During Kharif, each main plot was split into six smaller plots with different treatments: W1 was 100% RDF, W2 was 75% RDF, W3 was 50% RDF, W4 was 75% RDF + 25% N from FYM, W5 was 50% RDF + 50% N from FYM, and W6 was no fertilizer. The results of all 24 treatment combinations were repeated three times in a split-plot design. The analysis showed significant growth, yield attributes, grain yield, and straw yield of rice in dhaincha-incorporated plots (T3), fb greengram (T1), and cowpea (T2) plots using 100% RDF, while fallow (T4) with no fertilizer application recorded significantly lower values. SPAD meter readings of rice were higher in W4 (75% RDF + 25% N from FYM), which was at par with W1 in dhaincha-incorporated plots (75% RDF + 25% N from FYM) (W4). However, applying no fertilizer (W6) resulted in lower values. The total uptake of nitrogen and phosphorus in rice was highest when it was grown in dhaincha incorporated (T3), followed by green gram (T1), cowpea (T2) incorporated plots with the usage of 100% RDF (W1) and 75% RDF + 25% N from FYM (W4), and lower values were recorded in fallow + no fertilizer treatment (T4W6). Our study revealed that incorporating summer legumes before planting rice significantly increased plant height, tillers, grain and straw yield, and total uptake. With dhaincha, inclusion has shown a greater advantage. [ABSTRACT FROM AUTHOR]

Published

2024

6. Effects of NH4+-N: NO3−-N ratio on growth, nutrient uptake and production of blueberry (Vaccinium spp.) under soilless culture.

Author

Anwar, Ali, Zheng, Junming, Chen, Chunfeng, Chen, Mengqing, Xue, Yanxu, Wang, Jinmiao, Su, Wei, Chen, Riyuan, and Song, Shiwei

Subjects

VACCINIUM corymbosum, HYDROPONICS, NUTRIENT uptake, RATE setting, VACCINIUM, BLUEBERRIES

Abstract

Blueberry (Vaccinium corymbosum) is a small pulp shrub, which prefers to grow on a soilless culture. For soilless culture, nutritional management remains typically vital for blueberry production. However, the effect of different nutritional treatments on blueberry growth and production is largely unknown. This study was designed to investigate to formulate a specific nutritional treatment for blueberry. The results showed that NH4+-N: NO3−-N ratios significantly affected the growth, nutrient uptake, physiological characteristics, and flowering, as well as the fruiting characteristics of blueberry plants. The number of shoots and top projection area was increased considerably by 25:75 treatment. In contrast, 50:50 treatment promotes plant height, shoot length, and stem thickness, increasing chlorophyll contents, photosynthetic capacity, and P, Ca, and Mg in leaves. In contrast, 50:50 treatment promotes the flowering fruiting rate and prolongs the blueberry flowering period. The maximum soluble sugar contents were noted in 25:75, while maximum starch contents were reported in the 50:50 treatment. The treatments 100:0 and 75:25 promote early flowering and accelerate fruit set. Notably, NH4+-N: NO3−-N ratios; 50:50 treatment significantly encourages plant growth, nutrient uptake, chlorophyll contents, photosynthetic capacity, and fruit setting rate in blueberry plants. These findings suggested that NH4+-N: NO3−-N ratios 50:50 is the most appropriate treatment that significantly promotes vegetative growth and enhances production in blueberry plants. This study provides valuable information for improved blueberry production under a controlled environment. [ABSTRACT FROM AUTHOR]

Published

2024

7. Topographic heterogeneity triggers complementary cascades that enhance ecosystem multifunctionality.

Author

Fairchild, Tom P., Walter, Bettina, Mutter, Joshua J., and Griffin, John N.

Subjects

*BIOTIC communities, *STRUCTURAL equation modeling, *NUTRIENT uptake, *COMMUNITY foundations, *HETEROGENEITY

Abstract

Topographic heterogeneity sets the stage for community assembly, but its effects on ecosystem functioning remain poorly understood. Here, we test the hypothesis that topographic heterogeneity underpins multiple cascading species interactions and functional pathways that indirectly control multifunctionality. To do so, we combined experimental manipulation of a form of topographic heterogeneity on rocky shores (holes of various sizes) with a comprehensive assessment of naturally assembled communities and multifunctionality. Structural equation modeling indicated that heterogeneity: (1) enhanced biodiversity by supporting filter feeder richness; (2) triggered a facilitation cascade via reef‐forming (polychaete) and biomass‐dominant (macroalga) foundation species, which in turn broadly supported functionally diverse epibiotic and understory assemblages; and (3) inhibited a key consumer (limpet). The model supported that these mechanisms exerted complementary positive effects on individual functions (e.g., water filtration, ecosystem metabolism, nutrient uptake) and, in turn, collectively enhanced multifunctionality. Topographic heterogeneity may therefore serve as a cornerstone physical attribute by initiating multiple cascades that propagate through ecological communities via foundation species, ultimately manifesting disproportionate effects on ecosystem multifunctionality. [ABSTRACT FROM AUTHOR]

Published

2024

8. Enhancing strawberry resilience to saline, alkaline, and combined stresses with light spectra: impacts on growth, enzymatic activity, nutrient uptake, and osmotic regulation.

Author

Malekzadeh, Mohammad Reza, Roosta, Hamid Reza, and Kalaji, Hazem M.

Subjects

*OSMOREGULATION, *PLANT physiology, *PLANT growth, *COPPER, *NUTRIENT uptake, *STRAWBERRIES

Abstract

Background: This study examines the effects of various complementary light spectra on the growth, development, antioxidant activity, and nutrient absorption in strawberry plants under stress conditions. Light-emitting diodes (LEDs) were used to provide specific wavelengths, including monochromatic blue (460 nm), monochromatic red (660 nm), a dichromatic mix of blue and red (1:3 ratio), full-spectrum white light (400–700 nm), and ambient light as a control (no LED treatment). The stress treatments applied were: control (no stress), salinity (80 mM NaCl), alkalinity (40 mM NaHCO₃), and a combined salinity/alkalinity condition. Results: Our results indicated that complementary light spectra, especially red and blue/red, helped mitigate the adverse effects of stress on plant growth and development. These spectra improved plant tolerance by enhancing the activity of polyphenol oxidase and peroxidase enzymes and increasing starch accumulation in the leaves. Furthermore, under stress conditions, red and blue-red light significantly boosted fruit anthocyanin levels. Although stress elevated antioxidant activity, supplementary light reduced this activity by alleviating stress compared to ambient light. While stress led to increased Na and Cl ion concentrations in leaves, treatments with blue, red, and blue-red light minimized these harmful effects and promoted the absorption of beneficial ions such as K, Mg, Fe, and Cu. Conclusions: Adjusting light quality significantly influences the morphology and physiology of strawberry plants, underscoring the role of specific light spectra in promoting optimal growth under stress conditions. Clinical trial number: Not applicable [ABSTRACT FROM AUTHOR]

Published

2024

9. Epithelial metabolism as a rheostat for intestinal inflammation and malignancy.

Author

Schwärzler, Julian, Mayr, Lisa, Grabherr, Felix, Tilg, Herbert, and Adolph, Timon E.

Subjects

*INFLAMMATORY bowel diseases, *INTESTINAL mucosa, *NEURAL circuitry, *NUTRIENT uptake, *CELL physiology

Abstract

The intestinal epithelium comprises a dynamic single cell layer in the gut that allows segregation of luminal content from the host while executing nutrient absorption, barrier maintenance, and danger signaling. Epithelial metabolism of nutrients allows for the maintenance of epithelial cell functions and host–microbe commensalism. Dietary cues, microbes and metabolites, immune cross-talk, endocrine signals, and neuronal networks control and regulate the execution of intestinal epithelial metabolism. Rewiring of epithelial metabolism constitutes a hallmark of inflammatory and malignant diseases in the gut. Extrinsic or intrinsic perturbation of intestinal epithelial metabolism promotes experimental gut inflammation and tumorigenesis. The gut epithelium protects the host from a potentially hostile environment while allowing nutrient uptake that is vital for the organism. To maintain this delicate task, the gut epithelium has evolved multilayered cellular functions ranging from mucus production to hormone release and orchestration of mucosal immunity. Here, we review the execution of intestinal epithelial metabolism in health and illustrate how perturbation of epithelial metabolism affects experimental gut inflammation and tumorigenesis. We also discuss the impact of environmental factors and host–microbe interactions on epithelial metabolism in the context of inflammatory bowel disease and colorectal cancer. Insights into epithelial metabolism hold promise to unravel mechanisms of organismal health that may be therapeutically exploited in humans in the future. [ABSTRACT FROM AUTHOR]

Published

2024

10. The use of nanotechnology in genetic modification: a recent promising technology for enhancing crop productivity.

Author

Mmbando, Gideon Sadikiel

Subjects

*SUSTAINABLE agriculture, *TRANSGENIC plants, *AGRICULTURE, *NUTRIENT uptake, *GENOME editing

Abstract

From targeted gene insertion techniques to gene editing tool delivery systems, nanotechnology presents a promising path for improving many aspects of crop modification. However, little is known about the current application of nanotechnology and genetic engineering (GE) to improve agricultural yield. This review explores the potential applications of nanotechnology and GE to enhance sustainable agricultural systems. Most of the research indicates that by carefully guiding the delivery of nutrients to plants, nanomaterials and nanoscale methods like nanofertilizers and nanocarriers maximize plant nutrient uptake efficiency and increase the efficacy of agriculture's utilization of resources. Studies reveal that the application of nanoencapsulated pesticides as well as antimicrobial agents ensures precise delivery to plant tissues, maximizing effectiveness and reducing chemical usage. Nanotechnology also offers more precise control over genetic modifications and produces crops with desired traits like enhanced nutrient content, boosted resistance to pests and diseases, and raised yield. This fusion of GE and nanotechnology is an example of a modern approach to sustainable agriculture that maximizes resource use while reducing environmental impact. This review clarifies the promise of nanotechnology as a clean technology for transforming the production of genetically modified crops, improving nutrient utilization, and thus contributing to worldwide food security and environmentally-friendly agriculture. [ABSTRACT FROM AUTHOR]

Published

2024

11. Synergistic effects of microbial inoculation, different forms of iron application, and phosphorus on wheat growth and nutrient uptake in alkaline soil.

Author

Fiuzi, Amirhassan, Hassanzadehdelouei, Mojtaba, and Madani, Ahad

Subjects

*VESICULAR-arbuscular mycorrhizas, *FOLIAR feeding, *SODIC soils, *SOIL fertility, *NUTRIENT uptake

Abstract

Iron and phosphorus deficiencies in alkaline soils threaten wheat by limiting nutrient availability due to their antagonistic relationship. This study tested if combining microbial incubation with foliar iron could synergistically improve wheat productivity and nutrition and mitigate deficiencies. A field experiment using a split plot design tested different iron and phosphate fertilization techniques. The main plots consisted of three iron application methods: foliar-applied iron (FL) at 2.5 kg ha−1, soil-applied iron (FS) at 5 kg ha−1, and no iron (F0). The subplots comprised four phosphate fertilizers: PSB + TSP (inoculation with phosphate-solubilizing bacteria + 100 kg ha−1 of triple superphosphate fertilizer), AMF + TSP (inoculation with arbuscular mycorrhizal fungi + triple superphosphate), TSP alone, and no phosphorus (P0). Foliar iron application with AMF + TSP increased seed potassium and root length density by 16.3-17.9% and 22.1-25.8% more than PSB + TSP, respectively. Under FS conditions, AMF + TSP exhibited 28.5-29.1% lower magnesium and 23.9-28.4% higher zinc seed concentrations compared to PSB + TSP, as well as higher levels of soluble proteins and lower concentrations of chlorophyll. There was no difference in grain yield between PSB + TSP and AMF + TSP for any of the iron treatments. Combining AMF + TSP and foliar iron application resulted in the highest grain yield, desirable seed nutrient content (particularly zinc, iron (>100 mg kg−1), and magnesium (>18 mg kg−1), improved root biomass, chlorophyll, and soluble proteins compared to PSB + TSP and TSP alone. This combination of microbial inoculation with foliar iron application is an effective strategy for mitigating the antagonism between iron and phosphorus and improving both crop productivity and nutrition. [ABSTRACT FROM AUTHOR]

Published

2024

12. Biomass Accumulation, Soil Fertility and Energy Use in Seed Crop Systems of Velvet Bean (Mucuna Pruriens L.).

Author

Sujatha, S., Tanuja, S. P., Hima Bindu, K., and Kalaivanan, D.

Subjects

*GROWING season, *POWER resources, *SEED crops, *ENERGY consumption, *BIOMASS production

Abstract

Seed crop production systems of velvet bean (Mucuna pruriens L.) were assessed in two field studies for ecosystem services. At flowering stage, long duration genotype Arka Shubra was significantly superior in biomass accumulation (14.61 t ha−1), while 100% recommended NPK + 15 t FYM ha−1 registered significantly higher biomass production (11.74 t ha−1). Biomass availability at harvest was higher in long duration genotypes (7.48–7.75 t ha−1) and the average biomass availability of 6.45 t ha−1 at harvest gives scope for including velvet bean as component crop in cropping systems/fallows. The average soil carbon stocks were estimated at 22.8 t ha−1 at the end of 2 yrs and 12.4 t ha−1 at the end of one crop season. Soil nutrient availability was optimum except for soil test P in pre-, standing and post crop growth periods. Highly significant relations (R2 = 0.949) were observed between nodule number and available N at harvest. The N availability was more in long duration genotypes (209–215 kg N ha−1) over pre-experimental status. Nutrient addition improved the available N status by 40–185 kg ha−1 over pre-experimental status and control. The nutrient uptake was 4–10% higher in Arka Shubra over other long duration genotypes and 100–200% higher over medium/short duration genotypes at flowering. The recyclable biomass and uptake of NPK are more in long duration genotypes implying huge nutrient recycling potential of the system. Overall, seed crop systems of velvet bean are efficient in resource use and energy use (>2.5 EUE) and ideal components for sustainable land management. [ABSTRACT FROM AUTHOR]

Published

2024

13. A Kinetic Approach for Employing Two Duckweed Species, Lemna minor, and Spirodela polyrhiza, in the Sustainable Aquaculture Wastewater Treatment and Fish Feed Production.

Author

Rifai, Ridwan Muhamad, Yulistyorini, Anie, Siswahyudi, Dwi, Pratiwi, Jenvia Rista, Fauzi, Ichsan Achmad, and Rachminiwati, Nina

Subjects

*SUSTAINABLE aquaculture, *LEMNA minor, *WASTEWATER treatment, *FISH feeds, *PORTULACA oleracea, *NUTRIENT uptake

Abstract

Duckweed, a widely used natural fish feed, has also become more popular as the phytoremediation agent for wastewater, including one sourced from aquaculture. These two features indicate that duckweed can be utilized in a sustainable aquaculture system by treating and reclaiming nutrients from wastewater and then harvesting them for fish feed production. Hence, this study attempted to assess the approach of the two most known duckweed species, i.e., Lemna minor and Spirodela polyrhiza, in depleting NH4 and PO4 from synthetic controlled aquaculture wastewater as well as to understand their yield based on the N:P ratio. Cultivation in synthetic aquaculture wastewater media was carried out, followed by nutrient uptake and growth analysis. According to statistical analysis, both L. minor and S. polyrhiza could remove NH4 and PO4 with a relatively equal rate (p-val > 0.050). Nonetheless, both duckweed species absorb nitrogen more easily than phosphorous (p-val < 0.050). Considering the yield based on nutrient uptake, NH4 drove a more efficient yield for L. minor to S. polyrhiza at 16.70 g dry biomass/g NH4 and 14.14 g dry biomass/g NH4, respectively. Meanwhile, a higher yield was observed on S. polyrhiza than on L. minor regarding PO4 concentration, at 19.31 g dry biomass/g PO4 and 9.10 g dry biomass/g PO4, respectively. Therefore, a strategy to remove nutrients and produce biomass for fish feed can be formulated based on the N:P concentration ratio, where L. minor tends to produce biomass more rapidly in a higher N:P ratio, whereas S. polyrhiza works in the opposite. [ABSTRACT FROM AUTHOR]

Published

2024

14. The rootstock genotype shapes the diversity of pecan (Carya illinoinensis) rhizosphere microbial community.

Author

Wei Ren, Lu Zhang, Tondre, Braden, Xinwang Wang, and Tingying Xu

Subjects

PECAN, ECTOMYCORRHIZAL fungi, MYCORRHIZAL fungi, FARMERS, NUTRIENT uptake

Abstract

Pecans (Carya illinoinensis), one of the most valuable native North American nut crops, are commonly propagated through grafting to preserve the desired characteristics from parent trees. Since successful cultivation of pecan trees relies on the interplay among scion varieties, rootstocks, and soil conditions, this study investigated the microbial change to communities in the soils and roots of southern (87MX5-1.7) and northern (Peruque) rootstocks in a rootstock test orchard. Both grafted with the 'Pawnee' scion cultivar. Bacterial 16S ribosomal RNA and fungal ITS were amplified from both roots and rhizosphere soils of the two 10-yeargrafted trees, then sequenced and annotated into trophic and nutrient-related groups to characterize the rhizosphere microbiota. The Peruque roots had a higher relative abundance of saprotroph fungi, while 87MX5-1.7 exhibited higher levels of symbiotroph fungi and nitrogen fixation-related bacteria. Among them, the presence of symbiotroph fungi, particularly ectomycorrhizal fungi, notably differed between these two rootstocks, with a significantly higher presence observed in the root of 87MX5-1.7 compared to Peruque. This variation likely leads to divergent pathways of nutrient translocation: Peruque was in favor of multiple fungi (Russula and Inocybe) to gain nutrition, while 87MX5-1.7 preferred a specific domain of fungi (Tuber) and nitrogen fixation-related bacteria (Bradyrhizobia) to form beneficial symbiosis. Moreover, the presence of pathogens suggested a potential risk of Fusarium patch and snow molds in 87MX5-1.7, while canker and black foot disease pose threats in Peruque. The findings of this study suggest that rootstocks from different origins shape rhizosphere microbes differently, potentially affecting nutrient uptake and nut yield. Exploring rootstock-microbe combinations could provide insights into optimizing scion growth and ultimately increasing nut yield. By understanding how different rootstock-microbe interactions influence pecan tree development, growers can strategically select combinations that promote beneficial symbiotic relationships, enhancing nutrient uptake, disease resistance, and overall tree vigor. [ABSTRACT FROM AUTHOR]

Published

2024

15. Synergistic mitigation of cadmium stress in rice (Oryzasativa L.) through combined selenium, calcium, and magnesium supplementation.

Author

Arinzechi, Chukwuma, Dong, Chunhua, Huang, Peicheng, Zhao, Pengwei, Liao, Qi, Li, Qingzhu, and Yang, Zhihui

Subjects

SOIL pollution, NUTRIENT uptake, MAGNESIUM, CADMIUM, STATISTICAL correlation, SELENIUM

Abstract

Rice is susceptible to cadmium (Cd) accumulation, which poses a threat to human health. Traditional methods for mitigating moderately contaminated soils can be impractical or prohibitively expensive, necessitating innovative approaches to reduce Cd uptake in rice. Nutrient management has emerged as a promising solution by leveraging the antagonistic interactions between nutrients and cadmium. However, the research on the synergistic effects of multiple nutrients on Cd toxicity in rice is limited. To address this limitation, pot experiments was utilized to investigate the combined effects of selenium (Se), calcium (Ca), and magnesium (Mg) denoted as (SeCM) on Cd uptake and translocation in rice. The synergistic application of SeCM reduced grain Cd levels by 55.0%, surpassing the individual effects of Se (42.1%) and CM (40.5%), and bringing Cd content below the safe consumption limits. SeCM treatment exhibited multiple beneficial effects: it decreased malondialdehyde (MDA) levels, enhanced catalase (CAT), peroxidase (POD) and glutathione (GSH) enzyme activities, limited Cd translocation from roots to shoots, promoted iron plaque formation, and reduced Cd transfer from soil to iron plaque and subsequently to rice grains. Correlation analysis revealed strong negative relationships between rice Cd content, Cd translocation factors, and the translocation factors of selenium, calcium, and magnesium. These findings suggest that selenium, calcium, and magnesium collaboratively mitigate Cd toxicity through antagonistic and competitive interactions. These nutrients enhance the uptake of beneficial elements, while competitively inhibiting the translocation and accumulation of Cd in rice plants. SeCM application offers a promising strategy for producing nutrient-rich, and Cd-safe rice in contaminated soils. [ABSTRACT FROM AUTHOR]

Published

2024

16. Influence of N, P, and Fe availability on Braarudosphaera bigelowii, Trichodesmium, Crocosphaera, and noncyanobacterial diazotrophs: a review.

Author

Wenhui Cao, Qunhui Yang, Fuwu Ji, and Cheng Liu

Subjects

TECHNOLOGICAL innovations, TRICHODESMIUM, OCEAN, PHOSPHORUS, NITROGEN, NUTRIENT uptake

Abstract

Marine biological nitrogen fixation (BNF) is crucial for introducing "new nitrogen" into the oceans. Over the past 30 years, numerous laboratory and on-board culture experiments have been conducted studying the effects of nutrients such as total dissolved nitrogen (TDN), total dissolved phosphorus (TDP), and dissolved iron (DFe) on marine diazotrophs such as Braarudosphaera bigelowii (B. bigelowii), Trichodesmium, Crocosphaera and noncyanobacterial diazotrophs (NCDs). Most studies concluded that elevated dissolved inorganic nitrogen levels inhibit nitrogen fixation in Trichodesmium, promote its growth, and have minimal effect on B. bigelowii. The impact on NCDs is unclear. Moreover, elevated dissolved inorganic phosphorus (DIP) levels can promote individual growth, population growth, and nitrogen fixation in most diazotrophs in P-limited marine environments. Dissolved organic phosphorus is a potential phosphorous source for diazotrophs in low-DIP environments. Elevated DFe can promote population growth and nitrogen fixation in diazotrophs in Fe-limited marine environments. At present, most diazotrophs have yet to achieve pure culture. Moreover, the effect of nutrients on diazotrophs is mainly limited to the study of a single nutrient, which cannot accurately reflect the actual Marine environment where diazotrophs live. As a result, our understanding of the effect of nutrients on diazotrophs is still insufficient. Future research focusing on the issues above and the development of innovative technologies and methodologies to investigate the impact of marine BNF is highly recommended, which will allow for a more precise assessment of the impact of marine BNF on global primary productivity while providing a scientific foundation for rational evaluation of ocean CO2 uptake and emissions. [ABSTRACT FROM AUTHOR]

Published

2024

17. Integration of organic amendments and phosphate-solubilizing bacteria improves wheat growth and yield by modulating phosphorus availability and physiological reponses.

Author

Ahmed, Ahmed Fathy, Dahdouh, Salah M., Abu-hashim, Mohamed, and Merwad, Abdel-Rahman M.

Subjects

*PHOSPHATE fertilizers, *CALCAREOUS soils, *BIOAVAILABILITY, *PHOSPHATE rock, *SOIL salinity, *WHEAT straw

Abstract

AbstractSaline calcareous soil presents significant challenges for crop production due to its poor nutrient availability and adverse effects on plant growth. Hence this study aimed to investigates the impact of integrating organic amendments—specifically Moringa seed residues, biogas manure, and vermicompost (Ver)—with and without phosphate-solubilizing bacteria (PSB), alongside two types of phosphatic fertilizers, ordinary super phosphate (OSP) and rock phosphate (RP), on the growth, yield, and nutrient uptake of wheat plants in saline calcareous soil conditions. The results indicate that the combined application of Ver + PSB, particularly when paired with OSP, consistently yields superior outcomes across all measured parameters, followed by Ver + PSB with RP. Notably, the Ver + PSB with OSP treatment exhibits the highest values across several key parameters: chlorophyll levels (chlorophyll a at 1.8, chlorophyll b at 0.84, and carotenoids at 0.72 mg g−1f wt), proline at 38.5 μg g−1 DW, relative water content at 80.76%, membrane stability index at 67.62%, as well as net photosynthetic rate (Pn), transpiration rate (Tr), and stomatal conductance (gs). Furthermore, this treatment showcases the highest antioxidant enzyme activities (Superoxide dismutase, SOD at 9.27 A564 min−1 g−1 protein, Catalase, CAT at 78.53 A564 min−1 g−1 protein, Peroxihdase, POX at 1.86 A564 min−1 g−1 protein), as well as NPK content and uptake in wheat straw and grains. Additionally, it leads to significant increases in wheat growth parameters, including plant height, straw weight, grain weight, 1000 grain weight, and protein content. However, it also results in a notable decrease in other parameters such as total soluble sugars and nonenzymatic antioxidants (Ascorbate, AsA; Total glutathione, GsH; and α-Tocopherol, α-TOC). [ABSTRACT FROM AUTHOR]

Published

2024

18. Bacterial endophyte Pseudomonas mosselii PR5 improves growth, nutrient accumulation, and yield of rice (Oryza sativa L.) through various application methods.

Author

Sultana, Razia, Jashim, Asif Iqbal Ibne, Islam, Shah Mohammad Naimul, Rahman, Md. Habibur, and Haque, Mohammad Mahbubul

Subjects

*RICE blast disease, *NUTRIENT uptake, *RICE, *ENDOPHYTIC bacteria, *GRAIN yields

Abstract

Background: Pseudomonas spp. have drawn considerable attention due to their rhizospheric abundance and exceptional plant growth-promoting attributes. However, more research is needed on the optimal application methods of Pseudomonas mosselii for rice growth, nutrient accumulation, and yield improvement. This research explored the application of the endophytic bacterium P. mosselii PR5 on rice cultivar BRRI dhan29 with four treatments: control, seedling priming, root drenching, and bacterial cell-free culture (CFC) foliar application. Results: PR5 led to better rice growth, improved nutrient acquisition, and higher yields compared to the control, regardless of the application method used. The highest results in fresh weight of root (146.93 g/pot), shoot (758.98 g/pot), and flag leaf (7.88 g/pot), dry weight of root (42.16 g/pot), shoot (97.32 g/pot), and flag leaf (2.69 g/pot), and grains/panicle (224.67), were obtained from seedling priming treatment, whereas root drenching resulted in maximum plant height (105.67 cm), root length (49.0 cm), tillers/pot (23.7), and panicles/pot (17.67). In all three application methods, rice grain yield per pot was higher in PR5 inoculated treatments, compared to the control. The amount of P, Mg and Zn in the shoot and N, P, Ca, Mg and Si content in the flag leaf was significantly increased along with effective suppression of naturally occurring blast disease in bacterial CFC foliar application, validated by multivariate analysis. Conclusion: Our results indicated that rice seedlings priming with PR5 improved rice growth, yield and nutrient uptake, whereas CFC foliar application significantly increased the concentration of most nutrients in the rice plant and suppressed the naturally occurring rice blast disease. This research highlights the significant potential of P. mosselii PR5 in enhancing rice growth, yield, and nutrient uptake, particularly through seedling priming and CFC foliar application methods. Highlights: Pseudomonas mosselii PR5 significantly improved the growth and yield of rice. Inoculation of PR5 changed the root structure of rice plant. PR5 boosted the N, P, Mg, S, Fe and Zn content in rice plant. Seedling priming enhanced plant growth most and bacterial cell free culture (CFC) foliar treatment enriched most nutrients. Bacterial CFC foliar application suppressed naturally occurred rice blast disease. [ABSTRACT FROM AUTHOR]

Published

2024

19. Sugars, Lipids and More: New Insights Into Plant Carbon Sources During Plant–Microbe Interactions.

Author

Zhang, Qiang, Wang, Zongqi, Gao, Runjie, and Jiang, Yina

Subjects

*PLANT diseases, *PHYTOPATHOGENIC microorganisms, *NUTRIENT uptake, *PLANT lipids, *SIGNAL processing

Abstract

ABSTRACT Heterotrophic microbes rely on host‐derived carbon sources for their growth and survival. Depriving pathogens of plant carbon is therefore a promising strategy for protecting plants from disease and reducing yield losses. Importantly, this carbon starvation‐mediated resistance is expected to be more broad‐spectrum and durable than race‐specific R‐gene‐mediated resistance. Although sugars are well characterized as major carbon sources for bacteria, emerging evidence suggests that plant‐derived lipids are likely to be an essential carbon source for some fungal microbes, particularly biotrophs. Here, we comprehensively discuss the dual roles of carbon sources (mainly sugars and lipids) and their transport processes in immune signalling and microbial nutrition. We summarize recent findings revealing the crucial roles of lipids as susceptibility factors at all stages of pathogen infection. In particular, we discuss the potential pathways by which lipids and other plant carbon sources are delivered to biotrophs, including protein‐mediated transport, vesicle trafficking and autophagy. Finally, we highlight knowledge gaps and offer suggestions for clarifying the mechanisms that underlie nutrient uptake by biotrophs, providing guidance for future research on the application of carbon starvation–mediated resistance. [ABSTRACT FROM AUTHOR]

Published

2024

20. Shifting interactions between ectomycorrhizae, plants and insect herbivores in a CO2‐enriched world.

Author

Zehr, Luke N., Prada, Cecilia M., and Taylor, Benton N.

Subjects

*CARBON sequestration, *INSECT-plant relationships, *NUTRIENT uptake, *MYCORRHIZAS, *ECTOMYCORRHIZAS, *HERBIVORES

Abstract

Increasing atmospheric CO2 concentrations are changing how plants interact with their biotic mutualists and antagonists, but few syntheses consider how the three‐way interactions between mycorrhizae, plants and herbivores will shift under rising CO2. We summarise the mechanisms by which ectomycorrhizal (EcM)‐associated plants, their mycorrhizae and insect herbivores interact with each other under current conditions and evaluate a set of expectations for how these interactions might shift under higher CO2. We then outline priorities for future work on EcM–plant–herbivore interactions as atmospheric CO2 continues to rise. EcM colonisation has variable but often positive effects on herbivory, while herbivory has consistently negative impacts on EcM colonisation. Mechanistic evidence suggests that the positive EcM effect on herbivory will strengthen and the negative impact of herbivory on EcM will be ameliorated under higher CO2. Synthesis: While more empirical evidence on fungal–plant–herbivore interactions is needed in EcM systems, our synthesis suggests that EcM associations may play an under‐recognised role in dictating future terrestrial carbon capture by mediating herbivory and the ability of plants to compensate for herbivory as atmospheric CO2 continues to rise. [ABSTRACT FROM AUTHOR]

Published

2024

21. Substrate pH mediates growth promotion and resilience to water stress of Tilia tomentosa seedlings after Ectomycorrhizal inoculation.

Author

Serafim, Cindy, Ramos, Miguel A., Yilmaz, Tugce, Sousa, Nadine R., Yu, Kang, Van Geel, Maarten, Ceulemans, Tobias, Saudreau, Marc, Somers, Ben, Améglio, Thierry, Honnay, Olivier, and Castro, Paula M. L.

Subjects

*ECTOMYCORRHIZAL fungi, *SUBSTRATES (Materials science), *URBAN trees, *NUTRIENT uptake, *ROOT formation

Abstract

Highlights: Urban trees in urban environments are commonly exposed to stresses, contributing to their health decline; Ectomycorrhizal fungi improve the vigour and resilience of Tilia seedlings, but their performance is dependent on soil pH. Inoculation promotes growth in height, biomass production, mycorrhization status, nutrient uptake, and proline accumulation, and these effects dependent on fungi species and soil pH; Inoculation with EcM can be a strategy to produce healthier saplings that when transplanted to the urban environment will have a better performance. Colonization by Ectomycorrhizal (EcM) fungi is key for the health and performance of plants under different stress scenarios, such as those faced by trees in urban environments. Because urban environments can be lacking EcM fungi, we here assessed the benefits of inoculating Tilia tomentosa seedlings in a pre-transplantation nursery context with the EcM fungi Lactarius deliciosus and Paxillus involutus, using substrates of different pH and facing water-stress. P. involutus had a more evident positive effect in T. tomentosa seedlings and had a good performance in both acidic and alkaline substrate. In acidic substrate the fungus increased the plant height by 0.91-fold, increased the mycorrhization rate by 3.23-fold, expansion rate by 5.03-fold and formation of secondary roots by 0.46-fold, compared to the non-inoculated control. This species also improved the phosphorus content of leaves, which revealed a promotion of nutrient uptake. In alkaline substrate P. involutus increased root dry weight by 3.92-fold and the mycorrhization parameters. In contrast, L. deliciosus only had a positive effect in the improvement of mycorrhization and expansion rates and phosphorus content in the root, effects visible only in alkaline substrate. When exposed to water-stress the increase of proline content was visible in acidic substrate for both fungi, L. deliciosus and P. involutus, and in alkaline substrate for the fungus P. involutus, a response indicative of the enhancement of defenses in stressing scenarios such as water scarcity. We conclude that fungal inoculation improves the vigour and resilience of Tilia seedlings and that it is of utmost importance to select a suitable EcM fungus and to consider the soil pH of the transplanting site. The inoculation approach can be a valuable tool to produce robust seedlings which may have a better performance when transplanted to the challenging urban environment. [ABSTRACT FROM AUTHOR]

Published

2024

22. Enhancement of Productivity of Late Sown Rapeseed (Brassica campestris var toria) Through Sulfur and Boron Application Under Rice-Fallow System of Assam.

Author

Pegu, Rekhankona, Ojha, Nayan Jyoti, Begum, Mahima, Pathak, Kalyan, Ahmed, Perves, and Saikia, Hemanta

Subjects

*LEAF area index, *SEED yield, *NUTRIENT uptake, *PEARSON correlation (Statistics), *TURNIPS

Abstract

The neglected use of micronutrient greatly hampered the productivity of oilseed crop. Thus, to determine the optimal dose of S and B on toria under rice-fallow system, an experiment was carried out with five doses of S i.e. 0, 10, 20, 30 and 40 kg/ha and 3 doses of B i.e. 0, 1 and 2 kg/ha for two consecutive years (2018–19 and 2019–20). The plant growth parameters, i.e. plant height, dry matter accumulation, leaf area index and crop growth rate, and yield attributing parameters, i.e. siliqua/plant and seeds/siliqua, were greatly enhanced through application of S @ 30 kg/ha as well as B@ 2 kg/ha. The higher seed yield (10.11q/ha), stover yield (22.00q/ha) and oil yield (3.86 q/ha) were registered with the application of S @ 30 kg/ha + B @ 2 kg/ha, but it was at par with S@ 30 kg/ha + B @ 1 kg/ha. The combined application of S@ 30 kg/ha + B @ 2 kg/ha also noted higher plant nutrient uptake of N, P, K including S and B closely followed by S@ 30 kg/ha + B @ 1 kg/ha. But in terms of economics, conjugate application of S@ 30 kg/ha + B @1 kg/ha showed maximum monetary benefit with highest B:C (2.24). The pearson correlation indicated strong and positive correlation of seed yield with growth and yield parameters as well as nutrient uptake by plants. Regression analysis revealed that each one unit increase in plant dry matter accumulation showed an increase in seed yield by 4.56 unit and each one increase uptake in N, P, K, S and B showed an increase in seed yield by 0.19, 0.63,0.40,0.55 and 0.05, respectively. Henceforth, considering all the factors the combination of S@ 30 kg/ha and B@1 kg/ha may be recommended under the late sown toria in rice-fallow system. [ABSTRACT FROM AUTHOR]

Published

2024

23. Effects of Individual and Combined Applications of Seaweed Extracts and Plant Growth-Promoting Rhizobacteria (PGPR) on Plant Growth and Physio-Biochemical Properties of Soft Wheat and Faba Bean.

Author

El Jazouli, Mouna, Sammama, Hasnaa, Zehhar, Naima, Hsissou, Driss, El Kaoua, Mimoun, and Alfeddy, Mohamed Najib

Subjects

*PLANT growth-promoting rhizobacteria, *SUSTAINABLE agriculture, *DURUM wheat, *CARBON-based materials, *NITRATE reductase, *FAVA bean

Abstract

The research on carbon materials and plants primarily focuses on their use in soil, showing variable effects. However, significant gaps exist regarding their impact under stress conditions (such as drought, salinity, etc.) and their interactions with plant physiological processes. Long-term effects on plant health and ecosystems are understudied, as are their interactions with other biofertilizers like algae extracts and plant growth-promoting rhizobacteria (PGPR). The aim of the present study was to evaluate the effects of seaweed extracts and PGPR on plant growth and some physio-biochemical properties of soft wheat (Triticum aestivum L.) and faba bean (Vicia faba L.). Two concentrations of aqueous extract from two seaweeds, Fucus spiralis (F) and Ulva rigida (U), and the PGPR bacillus strain solution S48 (S48S) were used either individually or in combination. All treatments were applied as foliar sprays. The findings showed that the combined application of Fucus spiralis extract [25%] (F), Ulva rigida extract [50%] (U), along with the PGPR S48 bacillus strain solution (S48S) promoted plant growth (50.93 cm for faba bean) and root development (17.90 cm for wheat). This treatment also resulted in increased chlorophyll content (3.25 mg/g Fresh Weight (FW) in soft wheat and 3.93 mg/g FW in faba bean), proteins (14.66 µg/mg FW in soft wheat and 23.79 µg/mg FW in faba bean), amino acids (0.46 mg/g FW in soft wheat and 0.56 mg/g FW in faba bean), and total carbohydrates (529.8 µg/ml in soft wheat and 340.7 µg/ml in faba bean) as compared to controls. On the other hand, the nitrate reductase activity was enhanced by seaweed extract application in both crops. Phosphorus (P) uptake by soft wheat and faba bean was significantly improved following the application of Ulva rigida extract [50%] (U), the PGPR S48 bacillus strain solution (S48S), and the co-treatment of Fucus spiralis extract [25%] (F) with the PGPR S48 bacillus strain solution (S48S). The findings suggest that the combined application of Fucus spiralis extract (F) and Ulva rigida extract (U) with the PGPR S48 bacillus strain solution (S48S) can significantly improve plant growth and nutrient absorption in durum wheat and faba bean. This offers a sustainable alternative to chemical fertilizers, reducing pollution and promoting healthier ecosystems. Furthermore, these biological treatments enhance plant resilience to abiotic stresses, potentially increasing yields in challenging conditions. By reducing reliance on chemical fertilizers, these practices can save money for farmers and advance sustainable agriculture. [ABSTRACT FROM AUTHOR]

Published

2024

24. Legacy effect of 25 years reduced atmospheric sulphur deposition on spruce tree nutrition.

Author

Zethof, Jeroen H. T., Julich, Stefan, Feger, Karl‐Heinz, and Julich, Dorit

Subjects

*NORWAY spruce, *NUTRITIONAL status, *LIME (Fruit), *ATMOSPHERIC deposition, *NUTRIENT uptake

Abstract

Background Aims Methods Results Conclusions Since the mid‐1990s, sulphur (S) pollution was drastically reduced in Central Europe. Over time, this has led to a distinct reduction in S availability for Norway spruce (Picea abies Karst.), which is still the most important timber species in Central European forestries.Determination of the Norway spruce nutritional status of former strongly affected areas by S pollution (Saxony) with different degrees of liming by assessing their foliar element contents and comparing them to regions remote from historical high S deposition.Sites were selected based on levels of S deposition in the 1970–1990s with historical high deposition in Saxony (NE Germany), low deposition at Schluchsee (SW Germany) and Davos (Switzerland) as a clean air reference. Needles were sampled in late autumn 2019/2020 and elemental contents determined. Additional historical data on foliar S contents were available.Historical data showed a clear decrease in foliar S contents in the Saxonian sites over the last 25 years, independent of liming. No difference between all study sites was found in the most recent sampling, whereas S together with other macronutrients strongly indicates deficiencies for forest growth and health.After 25 years of reduced S deposition, S nutrition became low for Norway spruce trees in Saxony, whereas soil parent material determines the overall tree nutritional status with respect to other nutrients. As such, no difference between sites with historical high, low or no S deposition was found. Further studies should focus on the mineralization of organic S in the topsoil to understand if S is effectively recycled within the forest ecosystem and on the effect of other diminishing nutrients such as Mg and P. [ABSTRACT FROM AUTHOR]

Published

2024

25. On the structure of species-function participation in multilayer ecological networks.

Author

Hervías-Parejo, Sandra, Cuevas-Blanco, Mar, Lacasa, Lucas, Traveset, Anna, Donoso, Isabel, Heleno, Ruben, Nogales, Manuel, Rodríguez-Echeverría, Susana, Melián, Carlos J., and Eguíluz, Victor M.

Subjects

PLANT species, SEED dispersal, ECOLOGICAL assessment, NUTRIENT uptake, PLANT anatomy

Abstract

Understanding how biotic interactions shape ecosystems and impact their functioning, resilience and biodiversity has been a sustained research priority in ecology. Yet, traditional assessments of ecological complexity typically focus on species-species interactions that mediate a particular function (e.g., pollination), overlooking both the synergistic effect that multiple functions might develop as well as the resulting species-function participation patterns that emerge in ecosystems that harbor multiple ecological functions. Here we propose a mathematical framework that integrates various types of biotic interactions observed between different species. Its application to recently collected data of an islet ecosystem—reporting 1537 interactions between 691 plants, animals and fungi across six different functions (pollination, herbivory, seed dispersal, decomposition, nutrient uptake, and fungal pathogenicity)—unveils a non-random, nested structure in the way plant species participate across different functions. The framework further allows us to identify a ranking of species and functions, where woody shrubs and fungal decomposition emerge as keystone actors whose removal have a larger-than-random effect on secondary extinctions. The dual insight—from species and functional perspectives—offered by the framework opens the door to a richer quantification of ecosystem complexity and to better calibrate the influence of multifunctionality on ecosystem functioning and biodiversity. Studies of species interactions tend to focus on single ecological functions. Here, the authors show that plant species tend to participate across different ecological functions in a non-random, nested structure, and some species and functions emerge as unexpected keystone actors of the multifunctional ecosystem. [ABSTRACT FROM AUTHOR]

Published

2024

26. Soil- and Foliar-Applied Silicon and Nitrogen Supply Affect Nutrient Uptake, Allocation, and Stoichiometry in Arabica Coffee Plants.

Author

Parecido, Renan J., Soratto, Rogério P., Perdoná, Marcos J., and Gitari, Harun I.

Subjects

*COFFEE, *NUTRIENT uptake, *BIOMASS production, *COFFEE growing, *MINERALS in nutrition, *NITROGEN, *SILICON

Abstract

Silicon (Si) application may affect the plant response to nitrogen (N), possibly by changing the uptake, concentration, and partitioning of nutrients in plant tissues; however, this has not yet been proven in Arabica coffee plants. The effects of Si application methods [no Si, soil-applied soluble Si (168 mg Si L−1), and foliar-applied soluble Si (two application of 2 mg Si plant−1)] and N levels (0 and 80 mg N L−1) on biomass production and partitioning and uptake, partitioning, and stoichiometry of nutrients and Si in young Arabica coffee plants grown under greenhouse conditions were evaluated. Nitrogen fertilization increased the biomass production and uptake of all nutrients; however, reduced the concentrations of K, Ca, Mg, S, Mn, and Si in the leaves, Si in the stems, and K, Mg, and S in the roots of coffee plants as a dilution effect. In the presence of N, soil-applied Si increased the concentrations of Zn in the leaves and Ca and Si in the stems, the uptake of K, S, and Si, and the Si:N ratio. Foliar-applied Si increased the concentrations of N, P, K, and Zn in the leaves and Ca and Si in the stems, as well as the total uptake of K and Si and the Si:N ratio in coffee plants, being more evident in the N fertilization presence. This study unraveled that, especially when it was soil-applied, Si altered the nutrient uptake, allocation, and stoichiometric ratios with N, with a consequent increase in biomass production of young coffee plants fertilized with N. [ABSTRACT FROM AUTHOR]

Published

2024

27. Investigating the effect of changing the K:Ca ratio in nutrient solution on the quantitative and qualitative yield of <italic>Lilium spp</italic>. in hydroponic cultivation.

Author

Ranjbar Sheykhani, Reyhaneh

Subjects

*PLANT nutrition, *PLANT performance, *NUTRIENT uptake, *PERLITE, *BLOCK designs

Abstract

AbstractNowadays, hydroponics is an advanced method for plant production in agriculture. The optimal balance of nutrients in the nutrient solution is crucial to enhance plant performance in this method. To investigate the effect of potassium to calcium (K:Ca) ratio change in nutrient solution on quantitative and qualitative yield of lilies in hydroponic culture, a randomized complete block design with nine treatments and three replications was designed and carried out in 30% perlite and 70% sand. The treatments included different concentrations of calcium (Ca) at three levels of 0, 3, and 6 mM and different concentrations of potassium (K) at three levels of 0, 3, and 6 mM in the Hoagland nutrient solution, with K:Ca ratios of 0:0, 0:3, 0:6, 3:0, 3:3, 3:6, 6:0, 6:3, and 6:6. Results showed that the presence of different levels of potassium and calcium was found to enhance the quality of lilies by influencing nutrient uptake. The results indicated that nutrient solutions containing different ratios of K:Ca had a significant effect on reproductive height, the number of aborted buds, stem diameter at the 5% level and the number of flowers, the number of leaves, the fresh weight of shoots, the dry weight of shoots, and the longevity at the 1% level. The highest yield in terms of longevity (17 days), the number of flowers, the number of leaves, and absorption of potassium and calcium were observed in the nutrient solution with a 3:3 K:Ca ratio. [ABSTRACT FROM AUTHOR]

Published

2024

28. Integrated use of phosphorus sources, phosphate solubilizing bacteria, and rhizobium enhanced growth, nitrogen, and phosphorus uptake in chickpea.

Author

Alamzeb, Madeeha, Iqbal, Asif, Inamullah, Iqbal, Mazhar, and Ullah, Inam

Subjects

*PHOSPHATE fertilizers, *PHOSPHATE rock, *SEED proteins, *NUTRIENT uptake, *RHIZOBIUM, *CHICKPEA

Abstract

Expensive phosphatic fertilizers and limited phosphorus (P) availability hamper chickpea production in calcareous soils. Using cheaper P sources could reduce production costs. A field experiment assessed the combined effect of single superphosphate (SSP) and rock phosphate (RP) ratios (RP: SSP; 0:100, 25:75, 50:50, 75:25, and 100:0), phosphate solubilizing bacteria (PSB; with and without), and rhizobium (with and without) on chickpea growth and N and P uptake. RP:SSP ratios of 0:100 and 25:75 yielded higher plant height, growth rate, branch number, N concentration in straw and seeds, crude protein content, and P concentration and uptake in both straw and seeds compared to the 100:0 ratio. PSB application significantly improved chickpea growth, seed and straw N concentration, seed crude protein, and P uptake. Rhizobium-inoculated seeds also enhanced growth, N and P concentration in straw and seed, and P uptake. PSB enhanced rhizobium efficiency by promoting chickpea growth and increasing N and P concentration and uptake through solubilizing low-availability P from RP and SSP. Using RP:SSP (25:75) with PSB and rhizobium is recommended for enhanced chickpea growth and nutrient uptake in calcareous soils. [ABSTRACT FROM AUTHOR]

Published

2024

29. Root growth dynamics, nutrient uptake and use efficiency of Grevillea robusta grown under nitrogen and phosphorus deficiency.

Author

Senevirathna, A. G. U. N., Wickramasinghe, K. G. G. M., Dissanayaka, D. M. S. B., and De Silva, S. H. N. P.

Subjects

*NITROGEN deficiency, *ROOT formation, *BIOMASS, *PROTEACEAE, *MORPHOLOGY, *NUTRIENT uptake

Abstract

Root growth, nutrient uptake, and nutrient use efficiency of a plant is influenced by the nutrient availability in its growing environment. The aim of this study was to investigate the root morphology, nutrient uptake and use efficiency of Grevillea robusta grown in nitrogen (N)- and phosphorus (P)-limited conditions. A hydroponic experiment was conducted for three months in a glasshouse with four nutrient treatments; (i) N-deficient, (ii) P-deficient, (iii) N/P-deficient (co-limitation of N and P), and (iv) control (sufficient amounts of N, P, and other nutrients in the growth medium). The composition and the concentration of each nutrient in the control solution were custom-made based on the growth requirement of G. robusta. N and P concentration in nutrient-deficient media were maintained at 2 ppm. The impact of N- or P-deficiency and their co-limitation on cluster root formation, organ-specific dry matter and nutrient accumulation, N and P uptake and their use efficiencies were measured. P-deficient conditions produced the highest number of cluster roots (24 ± 4) which was comparatively lower than those of N- and N/P-deficient conditions indicating that P-deficiency is the primary factor influencing the formation of cluster roots in G. robusta. The use efficiency of N and P in biomass formation was significantly (p < 0.05) enhanced when their uptake was reduced in response to N- and P-limitation. The efficient internal use of P by G. robusta under N- and N/P-deficiency is indicated by the significant increase in P-remobilization efficiency under these nutrient-deficient conditions. [ABSTRACT FROM AUTHOR]

Published

2024

30. Foliar Application of Silicon Influences Crop Productivity, Dry Matter Accumulation, Water Use Efficiency, Lodging Score, and Aphid Density in Wheat (Triticum aestivum L.).

Author

Jhorar, Pooja, Choudhary, Roshan, Jinger, Dinesh, Samal, Ipsita, Paramesh, Venkatesh, Kumar, Deepak, Nepali, Anamika, Kumawat, Raveena, Jat, Ram A., Kumar Bhoi, Tanmaya, and Singh, Satyapriya

Subjects

*WATER efficiency, *LEAF area index, *GREENBUG, *CROP yields, *GRAIN yields

Abstract

Silicon (Si) is a versatile nutrient that plays an instrumental role in mitigating biotic and abiotic stresses besides improving growth and yield of graminaceous crops. We hypothesized that application Si would significantly improve productivity and resilience of wheat. Hence, the objectives were a) to assess the impact of Si application on wheat growth, productivity, nutrient uptake, water use efficiency, and b) to determine the potentiality of Si in mitigating lodging and aphid density. Therefore, we conducted a field experiment with five levels of Si (0, 2, 4, 6, and 8 g Si liter−1) at three growth stages (crown root initiation, tillering, and jointing stage) using a factorial randomized block design replicated three times. The results showed that increasing Si doses positively influenced plant height, dry matter accumulation (DMA), leaf area index (LAI), yield, and nutrient uptake. The highest grain and straw yield were observed with 8 g Si liter−1, followed by 6 g Si liter−1, while the control had the lowest yields. With 8 g Si liter−1, grain yield, straw yield, and Si uptake increased by 10.5%, 13.5%, and 26.3%, respectively, compared to the control. Additionally, Si application at 8 g Si liter−1 significantly reduced the density of S. avenae (aphids) by 81.4% and lodging by 75.1% compared to the control. Overall, the study demonstrated that increasing Si doses enhanced various growth and yield parameters, with 8 g Si liter−1 and 6 g Si liter−1 showing superior results. Among the growth stages, foliar application of Si during the tillering stage exhibited better performance in terms of growth, yield, and nutrient uptake in wheat. Therefore, the study concludes that Si fertilization at a rate of 8 g Si liter−1 during the tillering stage can effectively improve growth, productivity, and nutrient uptake in wheat in the southern region of Rajasthan. [ABSTRACT FROM AUTHOR]

Published

2024

31. Fluid Nourishment: Unveiling the Secrets of Water-Soluble Fertilizers in Agriculture.

Author

Florence, J. Jency, Devi, A. Renuka, Kaleeswari, R. K., Gnanachitra, M., and Kalpana, R.

Subjects

*CROP quality, *FERTILIZER application, *NUTRIENT uptake, *AGRICULTURAL productivity, *FERTILIZERS

Abstract

Water-soluble fertilizers provide a very effective and adaptable method of managing nutrients, which has completely changed contemporary agriculture methods. These fertilizers allow for exact control over the distribution of nutrients to crops because they are made to dissolve easily in water. This trait improves crop quality and production by facilitating better nutrient uptake. Farmers now have an easier time fertilizing their fields since water-soluble fertilizers are easy to apply and can adapt to a variety of irrigation schemes. They are a sustainable option in modern agriculture because of their decreased negative effects on the environment and less fertilizer waste. The increasing worldwide need for food has made the planned application of water-soluble fertilizers an indispensable instrument for attaining maximum agricultural productivity and guaranteeing food security amidst population growth. [ABSTRACT FROM AUTHOR]

Published

2024

32. Nutrient Use Efficiency and Cucumber Productivity as a Function of the Nitrogen Fertilization Rate and the Wood Fiber Content in Growing Media.

Author

Čepulienė, Rita, Butkevičienė, Lina Marija, and Steponavičienė, Vaida

Subjects

WOOD, NITROGEN fertilizers, PLANT fibers, CUCUMBER growing, NUTRIENT uptake, CUCUMBERS

Abstract

A peat substrate is made from peat from drained peatlands, which is a limited resource. A realistic estimate is that 50% of the world's wetlands have been lost. Peat is used in horticulture, especially for the cultivation of vegetables in greenhouses. The consequences of peatland exploitation are an increase in the greenhouse effect and a decrease in carbon stocks. Wood fiber can be used as an alternative to peat. The chemical properties of growing media interact and change continuously due to the small volume of growing media, which is limited by the growing container. This study aims to gain new knowledge on the impact of nutrient changes in the microbial degradation of carbon compounds in wood fiber and mixtures with a peat substrate on the content and uptake of nutrients required by plants. The cucumber (Cucumis sativus L.) variety 'Dirigent H' developed in the Netherlands was cultivated in growing media of a peat substrate and wood fiber: (1) peat substrate (PS); (2) wood fiber (WF); (3) wood fiber and peat substrate 50/50 v/v (WF/PS 50/50); (4) wood fiber and peat substrate 25/75 v/v (WF/PS 25/75). The rates of fertilization were the following: (1) conventional fertilization (CF); (2) 13 g N per plant (N13); (3) 23 g N per plant (N23); (4) 30 g N per plant (N30). The experiment was carried out with three replications. As the amount of wood fiber increased, the humidity and pH of the growing media increased. The fertilization of the cucumbers with different quantities of nitrogen influenced the nutrient uptake. The plants grown in the 50/50 and 25/75 growing media had the best Cu uptake when fertilized with N23. When the plants grown in the wood fiber media and the 50/50 media were fertilized with N13, N23, and N30, the Mn content in the growing media at the end of the growing season was significantly lower than the Mn content in the media with conventional fertilization. Thus, nitrogen improved the uptake of Mn by the plants grown not only in the wood fiber, but also in the combinations with a peat substrate. Growing plants in wood fiber and fertilizing them with N13 can result in the optimum uptake of micronutrients. The number and biomass of cucumber fruits per plant were influenced by the amount of wood fiber in the growing media and the application of nitrogen fertilizer. The highest number of fruits and biomass of fruits per plant obtained were significantly higher when the cucumbers were grown in WF/PS 50/50 growing media with additional N13 fertilization. [ABSTRACT FROM AUTHOR]

Published

2024

33. Exploring rice tolerance to salinity and drought stresses through Piriformospora indica inoculation: understanding physiological and metabolic adaptations.

Author

Vanani, Ali Raeisi, Shahrivar, Fatemeh Sheikhi, Nouri, Amin, and Sepehri, Mozhgan

Subjects

CLIMATE extremes, NUTRIENT uptake, PHYSIOLOGICAL adaptation, GERMINATION, SALT, PLANT growth, DROUGHT tolerance

Abstract

Drought and salinity are significant challenges to global food security. This study investigated the interactive impacts of Piriformospora indica inoculation with salinity and drought stresses on rice. Two greenhouse experiments were conducted. The first experiment evaluated two P. indica inoculation levels and three salinity levels (0-, 50-, and 100-mM sodium chloride), while the subsequent experiment assessed two inoculation levels under three drought intensities (25%, 50%, and 100% of available water content). P. indica spores were inoculated following optimized seed disinfection and germination processes. The shoot and root biomass under salinity stress were consistently higher in inoculated plants compared to controls. Sodium concentrations in shoots and roots exhibited an overall upward trend, with the trend being less pronounced in inoculated plants due to increased potassium uptake. Under salinity stress, nitrogen, magnesium, and calcium concentrations significantly increased in inoculated plants. With increasing salinity, there was a significant increase in catalase enzyme activity and soluble carbohydrate concentrations across all treatments, with a greater increase in inoculated plants. Plants under drought stress experienced reduced root and shoot biomass, but inoculated plants maintained higher biomass. Increasing drought stress led to decreased nitrogen, magnesium, and calcium concentrations in all treatments, with the reduction being less severe in inoculated plants. Catalase enzyme activity and carbohydrate increased with rising drought stress, with the increase being more pronounced in inoculated plants compared to non-inoculated ones. By promoting plant growth, nutrient uptake, and stress tolerance, P. indica inoculation has a significant potential to enhance crop productivity in extreme climate conditions. [ABSTRACT FROM AUTHOR]

Published

2024

34. Cyanophage-encoded auxiliary metabolic genes in modulating cyanobacterial metabolism and algal bloom dynamics.

Author

Qurat ul Ain, Wu, Kevin, Xuan Wu, Qing Bai, Qiong Li, Cong-Zhao Zhou, and Qingfa Wu

Subjects

WATER management, ALGAL blooms, ECOSYSTEM dynamics, BIOLOGICAL pest control agents, NUTRIENT uptake

Abstract

Cyanophages play a pivotal role in controlling cyanobacterial populations in aquatic environments. These dsDNA viruses harbor auxiliary metabolic genes (AMGs) that modulate the key metabolic processes of their cyanobacterial hosts, such as Photosynthesis, nutrient uptake for the optimization of viral replication. Recently, pan1~pan5 and pam1~pam5 cyanophages have been isolated from the fifth largest water resource in China; Lake Chaohu. Detailed genomic analysis of these phages revealed that these isolated cyanophages especially Pan1, Pam2 and Pam3 possess unique AMGs that significantly enhance the metabolic activities of their hosts, potentially leading to the suppression of bloom formation and stabilization of the ecological dynamics of Lake Chaohu. Our findings provide concrete evidence that cyanophages encoding AMGs could serve as effective biocontrol agents against harmful algal blooms, offering a targeted approach to manage these environmental threats. The integration of cyanophage-based management therapies with traditional methods could advance the efficiency and sustainability of controlling cyanobacterial outbreaks, paving the way for novel applications in water resource management. This review emphasizes the importance and critical need for further exploration of phage-host dynamics to fully harness the potential of cyanophages in ecosystem regulation. [ABSTRACT FROM AUTHOR]

Published

2024

35. Optimizing nitrogen fertilization in maize: the impact of nitrification inhibitors, phosphorus application, and microbial interactions on enhancing nutrient efficiency and crop performance.

Author

Kurdestani, Ali Malakshahi, Francioli, Davide, Ruser, Reiner, Piccolo, Alessandro, Maywald, Niels Julian, Xinping Chen, and Müller, Torsten

Subjects

SUSTAINABLE agriculture, NITRIFICATION inhibitors, PHOSPHAMIDON, SUSTAINABILITY, PLANT exudates

Abstract

Despite the essential role of nitrogen fertilizers in achieving high crop yields, current application practices often exhibit low efficiency. Optimizing nitrogen (N) fertilization in agriculture is, therefore, critical for enhancing crop productivity while ensuring sustainable food production. This study investigates the effects of nitrification inhibitors (Nis) such as Dimethyl Pyrazole Phosphate (DMPP) and Dimethyl Pyrazole Fulvic Acid (DMPFA), plant growth-promoting bacteria inoculation, and phosphorus (P) application on the soil-plant-microbe system in maize. DMPFA is an organic nitrification inhibitor that combines DMP and fulvic acid for the benefits of both compounds as a chelator. A comprehensive rhizobox experiment was conducted, employing varying levels of P, inoculant types, and Nis, to analyze the influence of these factors on various soil properties, maize fitness, and phenotypic traits, including root architecture and exudate profile. Additionally, the experiment examined the effects of treatments on the bacterial and fungal communities within the rhizosphere and maize roots. Our results showed that the use of Nis improved plant nutrition and biomass. For example, the use of DMPFA as a nitrification inhibitor significantly improved phosphorus use efficiency by up to 29%, increased P content to 37%, and raised P concentration in the shoot by 26%, compared to traditional ammonium treatments. The microbial communities inhabiting maize rhizosphere and roots were also highly influenced by the different treatments. Among them, the N treatment was the major driver in shaping bacterial and fungal communities in both plant compartments. Notably, Nis reduced significantly the abundance of bacterial groups involved in the nitrification process. Moreover, we observed that each experimental treatment employed in this investigation could select, promote, or reduce specific groups of beneficial or detrimental soil microorganisms. Overall, our results highlight the intricate interplay between soil amendments, microbial communities, and plant nutrient dynamics, suggesting that Nis, particularly DMPFA, could be pivotal in bolstering agricultural sustainability by optimizing nutrient utilization. [ABSTRACT FROM AUTHOR]

Published

2024

36. Multidimensional role of <italic>Pseudomonas</italic>: from biofertilizers to bioremediation and soil ecology to sustainable agriculture.

Author

Khoshru, Bahman, Fallah Nosratabad, Alireza, Mahjenabadi, Vahid Alah Jahandideh, Knežević, Magdalena, Hinojosa, Antonio Castellano, Fadiji, Ayomide Emmanuel, Enagbonma, Ben Jesuorsemwen, Qaderi, Sirvan, Patel, Margi, Baktash, Eisa Mollaiy, Dawood, Mona Fathi AbdEl-mowla, and Mitra, Debasis

Abstract

AbstractPseudomonas species are a versatile group of gram-negative bacteria that thrive in diverse ecological niches including soil, water, and plant environments. Their remarkable metabolic flexibility arises from their ability to utilize a plethora of compounds as carbon or energy sources, a feature that has attracted extensive scientific research. These microbial powerhouses are equipped to degrade various pollutants and toxins, thereby positioning them as valuable allies for bioremediation. This detoxification process is not only claim for ecological fame. Pseudomonas also exhibits potent biocontrol capabilities, and acts as a guard against plant pathogens. Their control strategies includes a suite of antimicrobial substances, along with an innate ability to outcompete other microbes for nutrients and stimulate plant defense. By harnessing these natural defenders, a range of Pseudomonas-based biocontrol agents have been formulated for agriculture. This approach is of growing interest for leveraging Pseudomonas strains as biofertilizers to support sustainable farming practices. These bacterial promoters enhance plant growth by boosting nutrient assimilation and by promoting robust root systems. New-generation biofertilizers can support crop yields and fortify soil vitality, thereby offering resilience to abiotic stress. This offers dual benefit of improving agricultural productivity while attenuating the harmful environmental problems caused by chemical fertilizers. Overall, the versatility of Pseudomonas species makes them a promising resource, spanning from agricultural enhancement to environmental remediation. As research accelerates, the ambition is to unlock and refine the myriad applications of these extraordinary bacteria. [ABSTRACT FROM AUTHOR]

Published

2024

37. Influence of drought and salt stress on almond nutrition.

Author

Kucukyumuk, Zeliha, Suarez, Donald L., and Kucukyumuk, Cenk

Subjects

*STRESS concentration, *MINERALS in nutrition, *NUTRIENT uptake, *ARID regions, *SALINITY, *ALMOND

Abstract

AbstractIncreased drought and salinity is a threat to agriculture in arid and semiarid zone worldwide. Almond is nutritious, rich in minerals protein and fiber with increasing world demand and production. The objective was to determine the effect of drought and salinity stress on nutrient concentrations in almond trees. Almond is known as sensitive to salt stress compared to other trees. There are limited studies on almond nutrition uptake under salt and drought stress conditions. This study had three drought and four salinity levels, and combined applications for a total of 12 treatments each with three replications. Drought increased K, Mg, Ca, Na and Cl concentrations in leaves, yet, decreased B concentrations. Similarly under salinity, almond leaves increased in K, Mg and Ca concentrations (as well as in Na and Cl). This study showed that the nutrient uptake varies under drought and salt stress conditions. Mineral nutrition should be taken into consideration, fertilization needs to account for stress factors. [ABSTRACT FROM AUTHOR]

Published

2024

38. Differential responses of two local and commercial guar cultivars for nutrient uptake and yield components under drought and biochar application.

Author

Soltani-Gerdefaramarzi, Somayeh, Hoseinollahi, Mansoureh, Meftahizadeh, Heidar, Bovand, Fatemeh, and Hatami, Mehrnaz

Subjects

*PEARSON correlation (Statistics), *SEED yield, *GUAR, *WATER efficiency, *SOIL amendments, *NUTRIENT uptake, *PLANT nutrients

Abstract

Drought is one of the abiotic stresses that can reduce crop yields. It has a major impact on crop yield reduction. For crops under stress, organic modifiers such as biochar can be useful. Guar (Cyamopsis tetragonoloba L.), an annual legume from the Fabaceae Family, is highly adaptable to arid and semi-arid regions, with many applications in various industries. Field experiments were carried out in a randomized complete block design with three replications using a split-split plots arrangement. The aim was to evaluate the influence of irrigation levels (Ir1 = 10, Ir2 = 14, and Ir3 = 17 days irrigation cycle) and biochar (B1 = 0, B2 = 5, and B3 = 10 tons ha−1) application on physiological traits [(chlorophyll a and b, chlorophyll index (SPAD), relative leaf water content (RWC), electrolyte leakage (EL), canopy temperature, leaf area, water use efficiency (WUE)], morphological parameters (length and diameter of the stem, pod length, fresh weight of root and plant, root length), yield components (seed yield, number of branch plant−1, number of clusters plant−1, pod plant−1, seed pod−1, seed plant−1, 1000-seed weight, and gum contents), and leaf nutrient uptake (Ca, Mg, P, Na, and K) of two commercial and local cultivars (cv1 = RGC-936 and cv2 = Saravan) of the guar plant. It was observed that the Ir3 irrigation treatment produced the highest seed yield (1921.8 kg ha−1) in terms of water stress. However, the maximum pod plant−1 (75.5), seed plant−1 (454.2), seed yield (1871.1 kg ha−1), leaf area (861.8 mm2), SPAD (92.2), Mg (49.8 mg g−1), Na (43.3 mg g−1) and P (0.49 mg g−1) were observed in RGC-936. The results also revealed that biochar was more effective than cultivars in terms of morphological traits. While yield and yield components were affected by cultivar, irrigation at different levels also had a significant effect on functional traits, physiology, and morphology. The addition of biochar appeared to have a positive effect on water stress alleviation and guar growth and leaf nutrient uptake. According to Pearson's correlation analysis, plant weight and length, root weight and length, stem diameter, seed pod−1, branches plant−1, and 1000-seed weight are moderately correlated with seed yield, while pod plant−1 and seed plant−1 are strongly associated with seed yield. On the other hand, the pod length, branches plant−1, and gum content showed a positive but not significant relationship. [ABSTRACT FROM AUTHOR]

Published

2024

39. Impacts of Bacillus amyloliquefaciens and Trichoderma spp. on Pac Choi (Brassica rapa var. chinensis) grown in different hydroponic systems.

Author

Plocek, Gretchen, Kunz, Dario Rueda, and Simpson, Catherine

Subjects

BOK choy, SUSTAINABILITY, NUTRIENT uptake, PLANT physiology, PLANT nutrients

Abstract

Soilless production systems (i.e hydroponics, aeroponics, aquaponics) have become commonplace in urban settings and controlled environments. They are efficient nutrient recyclers, space savers, and water conservers. However, they lack high levels of biological richness in the root microbiome when compared to soil production systems, which may affect plant health and nutrient uptake. To address this issue and incorporate more sustainable practices, beneficial microorganisms (i.e. Trichoderma spp., Bacillus sp.) can be added in the form of biofertilizers. However, many factors affect impacts of microorganisms and their interactions with plants. In this experiment, Black Summer Pac Choi (Brassica rapa var. Chinensis) was grown for two trials in a Deep-Water system (DWS) or a Nutrient Film Technique system (NFT) with commercial biofertilizers containing Trichoderma spp., Bacillus amyloliquefaciens, a combination of both, and a control. Plant physiology, nutrient composition, and nutrient uptake efficiency (NUE) were generally negatively affected by Trichoderma spp. both growing systems, indicating that Trichoderma may not be recommended for hydroponic production. However, Bacillus amyloliquefaciens showed promise as an effective biofertilizer in the NFT systems and had a positive influence on NUE in DWS. [ABSTRACT FROM AUTHOR]

Published

2024

40. Summer primary production of Arctic kelp communities is more affected by duration than magnitude of simulated marine heatwaves.

Author

Miller, Cale A., Gazeau, Frédéric, Lebrun, Anaïs, Alliouane, Samir, Urrutti, Pierre, Schlegel, Robert W., Gattuso, Jean‐Pierre, and Comeau, Steeve

Subjects

*MARINE heatwaves, *HEAT waves (Meteorology), *NUTRIENT uptake, *BIOGEOCHEMICAL cycles, *KELPS

Abstract

Fjord systems in the Norwegian Arctic are experiencing an increasing frequency and magnitude of marine heatwaves. These episodic heat stress events can have varying degrees of acute impacts on primary production and nutrient uptake of mixed kelp communities, as well as modifying the biogeochemical cycling in nearshore systems where vast areas of kelp create structural habitat. To assess the impact of future marine heatwaves on kelp communities, we conducted a 23 day mesocosm experiment exposing mixed kelp communities to warming and heatwave scenarios projected for the year 2100. Three treatments were considered: a constant warming (+1.8°C from the control), a medium magnitude and long duration heatwave event (+2.8°C from the control for 13 days), and two short‐term, more intense, heatwaves(5 day long scenarios with temperature peaks at +3.9°C from the control). The results show that both marine heatwave treatments reduced net community production, whereas the constant warm temperature treatment displayed no difference from the control. The long marine heatwave scenario resulted in reduced accumulated net community production, indicating that prolonged exposure had a greater severity than two high magnitude, short‐term heatwave events. We estimated an 11°C temperature threshold at which negative effects to primary production appeared present. We highlight that marine heatwaves can induce sublethal effects on kelp communities by depressing net community production. These results are placed in the context of potential physiological resilience of kelp communities and implications of reduced net community production to future Arctic fjord environmental conditions. [ABSTRACT FROM AUTHOR]

Published

2024

41. Milk‐derived exosomes in the regulation of nutritional and immune functions.

Author

Yang, Hui, Wuren, Tana, Zhai, Bin‐tao, Liu, Yang, and Er, Demtu

Subjects

*INTERGENERATIONAL communication, *EXTRACELLULAR vesicles, *IMMUNOREGULATION, *NUTRIENT uptake, *EXOSOMES

Abstract

Milk‐derived exosomes (MDEs), being a component of milk, have the potential to support immune system maturation in offspring and enhance immune cell proliferation. Through the transport and transmission of essential signaling molecules, MDEs contribute to the regulation of intergenerational and intraspecies communication, thereby impacting nutrient uptake and metabolic functions. A comprehensive comprehension of MDE functionalities is imperative for enhancing the quality of the dairy industry. A systematic search of the databases PubMed/Medline, Web of Science, and Scopus utilizing predetermined keywords resulted in the identification of 418 articles, of which 67 were chosen for inclusion in this review, which specifically explores the intersection of immune response and nutrition. This article provides a critical analysis of the classification of extracellular vesicles, the mechanisms underlying the biosynthesis of microvesicular dietary exosomes (MDEs), the components of MDEs, and their relevance in the contexts of nutrition and immune modulation. The primary aim of this review was to offer valuable scholarly insights to support the advancement and practical application of MDEs. [ABSTRACT FROM AUTHOR]

Published

2024

42. Growth, Productivity and Nutrient Uptake Rates of Ulva lactuca and Devaleraea mollis Co-Cultured with Atractoscion nobilis in a Land-Based Seawater Flow-Through Cascade IMTA System.

Author

Huo, Yuanzi, Elliott, Matthew S., and Drawbridge, Mark

Subjects

*NUTRIENT uptake, *FOOD of animal origin, *FOREIGN exchange rates, *LIGHT intensity, *WATER quality

Abstract

To advance environmentally friendly technologies in the aquaculture of Atractoscion nobilis, and simultaneously to diversify seafood production, a 79-day trial was conducted to assess the performance of Ulva lactuca and Devaleraea mollis cultured in the effluent from A. nobilis in a land-based integrated multi-trophic aquaculture (IMTA) system in southern California, USA. Water quality and performance of macroalgae were measured weekly. The impacted factors on the growth of macroalgae and nutrient uptake rate of macroalgae were assessed. The specific growth rate of juvenile A. nobilis was 0.47–0.52%/d. Total ammonia nitrogen in effluents of A. nobilis tanks ranged from 0.03 to 0.19 mg/L. Ulva lactuca and D. mollis achieved an average productivity of 24.53 and 14.40 g dry weight (DW)/m2/d. The average nitrogen content was 3.48 and 4.89% DW, and accordingly, the average nitrogen uptake rate was 0.88 and 0.71 g/m2/d, respectively. Temperature and nutrient concentration were key factors impacting macroalgae growth, and light intensity also impacted the growth of D. mollis. The high protein content of U. lactuca and D. mollis would make them good for use as human or animal food, or for use in other industries. Research on the interaction effects between seawater exchange rates and aeration rates on the performance and nutrient uptake rates of macroalgae will be conducted in future studies. [ABSTRACT FROM AUTHOR]

Published

2024

43. Long-Term Manuring and Fertilization Influence on Soil Properties and Wheat Productivity in Semi-Arid Regions.

Author

Kumari, Manju, Prakash, Dhram, Sheoran, Sunita, Yadav, Parmod Kumar, Ankit, Yadav, Harendra Kumar, Apurva, Gupta, Rajeev Kumar, El-Hendawy, Salah, and Mattar, Mohamed A.

Subjects

*CROPPING systems, *FARM manure, *SOIL fertility management, *SOIL fertility, *POULTRY manure

Abstract

Information on the long-term effects of the addition of organics and fertilizers to wheat under the pearl millet–wheat cropping system with semi-arid conditions in north-western India is still lacking. The present research was conducted in an ongoing field experiment initiated during Rabi 1995 at the Research Farm of Chaudhary Charan Singh at Haryana Agricultural University, Hisar. After 25 years, the impacts of nutrient management practices on soil fertility and wheat productivity were evaluated. The experiment comprised a total of eight treatment combinations viz. half and full doses of recommended fertilizers (N and P), organic manures (FYM: farmyard manure, POM: poultry manure, and PRM: press mud) alone and in combination with NP fertilizers. The conjoint application of organic manure and chemical fertilizers resulted in a positive influx of nutrients via increasing total organic carbon (TOC), available N, P, K, and S, which ranged from 0.46 to 1.42%, 122.70 to 194.70, 15.66 to 74.92, 340.5 to 761.2, and 15.26 to 54.63 kg ha−1 in surface soil (0–15 cm), respectively. Carbon fractions and crop yield were significantly improved by adopting integrated nutrient management (INM). The TOC showed a positive and significant correlation with C fractions (r > 0.92) and with soil-available N, P, K, and S (r > 0.77) content. The data also revealed a strong relationship between TOC and soil-available (0–15 cm) nutrients i.e., available N (R2= 0.769), available P (R2 = 0.881), available K (R2 = 0.758), and available S (R2 = 0.914), respectively. Thus, practices that increased TOC were also beneficial in enhancing the availability of the nutrients in the soil. A positive and highly significant correlation was also found among wheat yield, nutrient (NPKS) content, and uptake. A polynomial relationship between grain yield and grain N (R2 = 0.962), P (R2 = 0.946), and K (R2 = 0.967) content, and between straw yield and straw N (R2 = 0.830), P (R2 = 0.541) and K (R2 = 0.976) content was obtained. Integrated use of PRM7.5 followed by FYM15 and POM5 coupled with NP fertilizers proved best, which could be beneficial for obtaining nutritious and highest wheat yield (grain: 6.01 t ha−1 and straw: 7.70 t ha−1) coupled with improved fertility within a sustained manner under the pearl millet–wheat sequence in prevailing semi-arid conditions of the North Indian state of Haryana. [ABSTRACT FROM AUTHOR]

Published

2024

44. NIN-LIKE PROTEIN3.2 inhibits repressor Aux/IAA14 expression and enhances root biomass in maize seedlings under low nitrogen.

Author

Wang, Ruifeng, Zhong, Yanting, Han, Jienan, Huang, Liangliang, Wang, Yongqi, Shi, Xionggao, Li, Mengfei, Zhuang, Yao, Ren, Wei, Liu, Xiaoting, Cao, Huairong, Xin, Beibei, Lai, Jinsheng, Chen, Limei, Chen, Fanjun, Yuan, Lixing, Wang, Yi, and Li, Xuexian

Subjects

*GENOME-wide association studies, *GENE expression, *ROOT growth, *TRANSGENIC plants, *NUTRIENT uptake

Abstract

Plants generally enhance their root growth in the form of greater biomass and/or root length to boost nutrient uptake in response to short-term low nitrogen (LN). However, the underlying mechanisms of short-term LN-mediated root growth remain largely elusive. Our genome-wide association study, haplotype analysis, and phenotyping of transgenic plants showed that the crucial nitrate signaling component NIN-LIKE PROTEIN3.2 (ZmNLP3.2), a positive regulator of root biomass, is associated with natural variations in root biomass of maize (Zea mays L.) seedlings under LN. The monocot-specific gene AUXIN/INDOLE-3-ACETIC ACID14 (ZmAux/IAA14) exhibited opposite expression patterns to ZmNLP3.2 in ZmNLP3.2 knockout and overexpression lines, suggesting that ZmNLP3.2 hampers ZmAux/IAA14 transcription. Importantly, ZmAux/IAA14 knockout seedlings showed a greater root dry weight (RDW), whereas ZmAux/IAA14 overexpression reduced RDW under LN compared with wild-type plants, indicating that ZmAux/IAA14 negatively regulates the RDW of LN-grown seedlings. Moreover, in vitro and vivo assays indicated that AUXIN RESPONSE FACTOR19 (ZmARF19) binds to and transcriptionally activates ZmAux/IAA14, which was weakened by the ZmNLP3.2–ZmARF19 interaction. The zmnlp3.2 ZmAux/IAA14-OE seedlings exhibited further reduced RDW compared with ZmAux/IAA14 overexpression lines when subjected to LN treatment, corroborating the ZmNLP3.2–ZmAux/IAA14 interaction. Thus, our study reveals a ZmNLP3.2–ZmARF19–ZmAux/IAA14 module regulating root biomass in response to nitrogen limitation in maize. In nitrogen-limited growth conditions, the levels of a nitrate signaling component rise in maize seedlings, triggering the inhibition of a root growth repressor, and increased root biomass. [ABSTRACT FROM AUTHOR]

Published

2024

45. Zinc and silicon fertilizers in conventional and nano‐forms: Mitigating salinity effects in maize (Zea mays L.).

Author

Shoukat, Abbas, Pitann, Britta, Hossain, Md. Sazzad, Saqib, Zulfiqar Ahmad, Nawaz, Allah, and Mühling, Karl Hermann

Subjects

*ZINC fertilizers, *AGRICULTURAL productivity, *PLANTING, *NUTRIENT uptake, *SALINITY, *PLANT nutrients

Abstract

Background: Salinity stress, an escalating concern in the realm of agriculture, significantly hampers crop productivity worldwide. In recent years, nano‐fertilizers have been identified as an innovative and promising avenue for improving nutrient use efficiency and mitigating salt stress in plants. Aims: This study delves into the comparative efficacy of nano‐fertilizers (Zn and Si) and their conventional sources in bolstering maize's resilience against salt stress. Methods: The hydroponic experiment was conducted to test maize plants under salt stress along with Zn and Si nanoparticles (NPs) application. The analysis extends to their impacts on ionic homeostasis, specifically focusing on potassium and sodium concentrations, K/Na ratio, stomatal conductance, chlorophyll content, and the osmotic potential (OP) within the shoots and roots of maize. Results: Nanoparticles relatively helped plants better under stress, compared to their respective bulk mode of applications. Nano‐Zn treatment considerably boosts the K+ concentration and enhanced K/Na ratio, as a key physiological trait in salt‐resistant species, while nano‐Si demonstrates a prominent role in modulating OP and limiting Na+ accumulation along with higher Zn and Si accumulation in plants. The salt tolerance index confirmed the contribution of these ionic and osmotic adjustments in helping maize plant against salt stress. Conclusions: Our findings confirm that the application of nutrients as nano‐fertilizers, particularly nano‐Zn, enhanced K/Na ratio and improved nutrient availability and uptake of the plant. Si nanoparticles are also attributed to better osmotic adjustment and facilitating water movement, thus highlighting the potential of nano‐fertilizers in improving overall agricultural productivity and related environmental issues. [ABSTRACT FROM AUTHOR]

Published

2024

46. How nano‐iron chelate and arbuscular mycorrhizal fungi mitigate water stress in Lallemantia species: A growth and physio‐biochemical properties.

Author

Paravar, Arezoo, Maleki Farahani, Saeideh, Rezazadeh, Alireza, and Keshavarz Afshar, Reza

Subjects

*PLANT colonization, *WATER efficiency, *VESICULAR-arbuscular mycorrhizas, *NUTRIENT uptake, *MYCORRHIZAL fungi

Abstract

Background: Water deficit can seriously affect the growth, yield, and biochemical properties of plants; however, the application of nano‐iron chelate and arbuscular mycorrhizal fertilizers in water deficit has been considered one of the most promising methods to improve plant growth and enhance drought tolerance. Aims: This study aimed to investigate the effects of nano‐iron chelated (nFe) fertilizer and arbuscular mycorrhizal fungi (AMFs) on the growth, yield, root colonization, mycorrhizal dependency, water use efficiency (WUE), physio‐biochemical properties, and seed biochemical properties of Lallemantia iberica and Lallemantia royleana species under drought stress. Methods: A split‐factorial experiment was conducted using a randomized complete block design with three replications. The main plot consisted of three drought stress levels (according to the depletion of soil available water) of 30% (I1; without stress), 60% (I2; mild stress), and 90% (I3; severe stress). The subplots were the factorial combination of fertilizers (F) (without fertilizer, nano‐iron chelate [nFe], and AMFs) and plant species (S) of Lallemantia (L. iberica and L. royleana). Results: A decrease in the irrigation regime caused a reduction in growth, seed yield, WUE, chlorophyll content, nutrient uptake, seed oil, and mucilage content, as well as an increase in lipid peroxidation and hydrogen peroxide. Compared with nFe, AMF significantly increased root colonization by mycorrhizal fungi in both species across irrigation regimes. Furthermore, AMF inoculation enhanced nutrient uptake, mucilage, oil, and fatty acids by increasing the WUE. Higher mycorrhizal dependency in inoculated plants played an important role in increasing proline and antioxidant activities in the leaves of the host plant. The water stress and fertilization treatments resulted in the highest root colonization, mycorrhizal dependency, proline content, and antioxidant enzyme activities in L. royleana, as well as the highest WUE, accumulation of fatty acids, and nutrient uptake was observed in L. iberica. Interestingly, the mycorrhization potential of Lallemantia sp. is clearly defined. Conclusions: The results highlighted that AMFs can promote Lallemantia to increase seed mucilage and oil under water stress. Overall, we found that both Lallemantia species responded well to AMF inoculation under water deficit conditions, where nFe was found to be less effective. [ABSTRACT FROM AUTHOR]

Published

2024

47. Effect of potassium application on maize to sandy soil under deficit irrigation conditions.

Author

Rusan, Munir J., Al-Masri, Ayat, and Lubani, Rashid

Subjects

*SANDY loam soils, *DEFICIT irrigation, *SOIL moisture, *NUTRIENT uptake, *PLANT growth

Abstract

Maize is widely growth in arid and semi-arid region where, drought is common and a limiting factor for crop production. Potassium plays a key role in enhancing plant growth under drought condition. The objective of this study is to determine the effect of K fertilization with and without NP on maize growth grown in sandy loam soil under adequate and deficit irrigation conditions. The following treatments were investigated in pot experiment: (1) control with no fertilizer application (C); (2) 128 kg N + 328 kg P2O5 ha-1 (NPK0); (3) 128 kg N + 328 kg P2O5 ha-1 + 152.5 kg K2O ha1 (NPK1); (4) 128 kg N + 328 kg P2O5 ha-1 + 305 kg K2O ha-1 (NPK2); and 128 kg N + 328 kg P2O5 ha-1 + 457.5 kg K2O ha-1 (NPK3). Treatments were investigated under adequate and deficit soil moisture content. Each pot filled with 3.5 kg air-dry soil and seeded with maize and pots were watered according to the treatments. The results indicated that plant growth and nutrient uptake were significantly reduced under water stress condition. The application of NP increased plant growth and nutrient uptake and further were increased with K application. K application also enhanced plant tolerance to deficit soil moisture condition. In addition, K enhanced nutrient uptake and leaf chlorophyll content. Based on the results, it can be concluded that application of NP for maize was not adequate to achieve the highest plant growth, unless it is combined with K application. In addition, K application enhances plant tolerance to water stress. [ABSTRACT FROM AUTHOR]

Published

2024

48. Spectral data augmentation for leaf nutrient uptake quantification.

Author

Martins, R.C., Queirós, C., Silva, F.M., Santos, F., Barroso, T.G., Tosin, R., Cunha, M., Leão, M., Damásio, M., Martins, P., and Silvestre, J.

Subjects

*DATA augmentation, *NUTRIENT uptake, *COPPER, *PEARSON correlation (Statistics), *COMPOSITION of leaves, *INDUCTIVELY coupled plasma atomic emission spectrometry, *TRACE elements

Abstract

Data scarcity is a hurdle for physiology-based precision agriculture. Measuring nutrient uptake by visible-near infrared spectroscopy implies collecting spectral and compositional data from low-throughput, such as inductively coupled plasma optical emission spectroscopy. This paper introduces data augmentation in spectroscopy by hybridisation for expanding real-world data into synthetic datasets statistically representative of the real data, allowing the quantification of macronutrients (N, P, K, Ca, Mg, and S) and micronutrients (Fe, Mn, Zn, Cu, and B). Partial least squares (PLS), local partial least squares (LocPLS), and self-learning artificial intelligence (SLAI) were used to determine the capacity to expand the knowledge base. PLS using only real-world data (RWD) cannot quantify some nutrients (N and Cu in grapevine leaves and K, Ca, Mg, S, and Cu in apple tree leaves). The synthetic dataset of the study allowed predicting real-world leaf composition of macronutrients (N, P, K, Ca, Mg and S) (Pearson coefficient correlation (R) ∼ 0.61–0.94 and standard error (SE) ∼ 0.04–0.05%) and micro-nutrients (Fe, Mn, Zn, Cu and B) (R ∼ 0.66–0.91 and SE ∼ 0.88–3.98 ppm) in grapevine leaves using LocPLS and SLAI. The synthetic dataset loses significance if the real-world counterpart has low representativity, resulting in poor quantifications of macronutrients (R ∼ 0.51–0.72 and SE ∼ 0.02–0.13%) and micronutrients (R ∼ 0.53–0.76 and SE ∼ 8.89–37.89 ppm), and not allowing S quantification (R = 0.37, SE = 0.01) in apple tree leaves. Representative real-world sampling makes data augmentation in spectroscopy very efficient in expanding the knowledge base and nutrient quantifications. [Display omitted] • Data hybridisation expands the information of the original dataset. • Synthetic data reproduces spectral and compositional information of the samples. • Hybridisation creates samples that could have been physically sampled. • Representativity of real-world data is essential for information expansion. • Data augmentation as a diagnostic tool of knowledge base representativity. [ABSTRACT FROM AUTHOR]

Published

2024

49. Residual effect of micronutrients and sulfur enriched phyto-biochars soil applied to fodder maize on yields, tissue concentration and uptake of nutrients by rice and post-harvest soil properties.

Author

Srivastava, Prakash Chandra, Pachauri, Satya Pratap, Pathak, Anand, Labanya, Rini, Shukla, Arvind Kumar, Shrivastava, Manoj, and Srivastava, Prashant

Subjects

*ANIMAL feeds, *PINE needles, *FODDER crops, *MICRONUTRIENTS, *RICE, *WHEAT straw, *NUTRIENT uptake, *CORN

Abstract

The residual effect of low doses of lantana, pine needles and wheat straw phyto-biochars pyrolyzed at 300 °C and 450 °C and enriched with 0, 50, 75 and 100% of recommended doses of fertilizers (RDF) of micronutrients and S was studied on the yields, nutrient concentration and uptake of second crop, i.e. rice (Oryza sativa L.) after fodder maize to validate their nutrient slow-release characteristics. The residual effect of phyto-biochars averaged over different RDF increased rice grain yield significantly under lantana and pine needles phyto-biochars pyrolyzed at 300 °C, but decreased with pine needles biochar pyrolyzed at 450 °C as compared to the control. The highest grain yield (9.43 g pot−1) was under pine needles phyto-biochar pyrolyzed at 300 °C and enriched initially with 75% of RDF, which was 7.8 per cent higher than that with 75% of RDF applied through conventional fertilizer sources. The residual effect of some treatments significantly increased the readily oxidizable C and extractable Zn, Cu, Fe, Mn, B and S in the soil after rice harvest. For fodder maize + rice crops together, pine needles phyto-biochar pyrolyzed at 300 °C or lantana phyto-biochar pyrolyzed at 450 °C with enrichment of 75% RDF of micronutrients and S gave the higher apparent per cent utilization of Zn, Fe, Mn, and S, but numerically closer per cent utilization values for Cu and B in comparison to the conventional chemical fertilizer sources. [ABSTRACT FROM AUTHOR]

Published

2024

50. Allantoin regulated oxidative defense, secondary metabolism and ions homeostasis in maize (Zea mays L.) under heat stress.

Author

Yasmeen, Humaira, Rasheed, Rizwan, Ashraf, Muhammad Arslan, Zafar, Sadia, and Ali, Shafaqat

Abstract

Understanding how maize responds to temperature stress is crucial for improving its resilience and productivity under changing climate conditions. Previous studies have shown that exogenous allantoin (ALA) regulates various physiological processes in plants under cadmium and salinity stress. The existing body of literature provides limited insight into the specific mechanisms that govern the impact of ALA on the physiological and biochemical responses of maize plants under heat stress. This study aims to investigate the role of ALA in regulating oxidative defense, secondary metabolism, and ion homeostasis in maize under heat stress, with the ultimate goal of improving maize resilience and productivity. The current investigation displayed visible depression in growth, chlorophyll content, and nutrient uptake in maize cultivars (tolerant cv. Pearl and sensitive cv. Pak-afgoi) under heat stress. Heat stress raised MDA and H2O2 levels in plants, indicating hampered ROS detoxification that might have impeded nutrient acquisition in plants more profoundly in heat-sensitive cv. Pak afgoi. ALA (150 and 300 mg L−1) promoted plant heat stress tolerance. ALA (300 mg L−1) increased enzymatic antioxidant activities and antioxidant molecule buildup, which diminished cell ROS levels. ALA increased osmolyte accumulation, raised chlorophyll and nutrient uptake, and mitigated oxidative damage in maize under heat stress. After 72 h of recovery from heat stress, ALA significantly enhanced biomass, photosynthetic pigments, ROS detoxification, and nutrient uptake while minimizing oxidative damage, aiding rapid plant recovery from heat stress. [ABSTRACT FROM AUTHOR]

Published

2024