Search Results (4,769)

Cantaloupe melon seeds are a byproduct that can be upcycled for their nutritional value, generating added value, reducing food waste, and supporting food sustainability. This study evaluated the effects of melon seed flour on selected physicochemical and consumer acceptance of gluten-free cookies. Melon seeds were dehydrated at 60 °C for 12 h and ground. Then gluten-free cookies containing varying melon seed flour (20, 40, 60, 80, and 100%) were prepared by mixing the ingredients and baked at 177 °C for 18 min. Color, water activity, proximate composition, and mineral contents of the melon seed flour were measured. Color, water activity, spread factor, and hardness of the five cookie formulations were evaluated. Finally, a randomized block design was used for the consumer test with 90 consumers. Appearance, aroma, flavor, texture, grittiness, and overall liking were evaluated using a 9-point hedonic scale. Also, purchase intent was asked for before and after a sustainability claim. Data were analyzed using an ANOVA and the post hoc Tukey test (p < 0.05). The McNemar test was used to test whether there were significant differences in purchase intent before and after a sustainability claim. Melon seed flour had 21.4% protein, 34.93% crude fiber, 3% ash, 4% moisture, and 26.9% fat. Spread factor and a* (color redness) values increased with increasing melon seed flour. On the other hand, the more melon seed flour in cookies, the lower the L* value and water activity. The treatment with 40% melon seed flour had the highest liking score, 6.25. Finally, the sustainability claim significantly increased the positive purchase intent of the cookies. This study demonstrates the potential of cantaloupe melon seed flour as an ingredient in food, such as gluten-free cookies. This practice in the food industry can help increase value and reduce waste in cantaloupe processing. Full article

Zephyranthes tubispatha is an Amaryllidaceae species with high ornamental potential, whose seed dispersal coincides with periods of high temperatures (HTs) and long photoperiods. While supraoptimal temperatures (>28 °C) have been shown to induce thermoinhibition, the effect of light on germination dynamics has not yet been explored. The aim was to study the effect of different exposure times to white light (WL) and different light qualities, as well as the interaction with HT, on seed germination. Changes in the endogenous levels of several phytohormones, responses to pharmacological treatments, and O₂^.− production in the embryo were analyzed to gain an understanding of the underlying physiological mechanisms. Our results suggest the presence of a negative photoblastic response of the high-irradiance (HIR) type. Fluridone (an ABA synthesis inhibitor) restored germination in light-exposed seeds to levels close to the dark control, highlighting the importance of ABA content for photoinhibition. The preincubation period at HT (33 °C) significantly influenced germination behavior and photosensitivity at optimal temperature (20 °C). Thermoinhibition depends on changes in phytohormone balance and/or sensitivity, rather than on their absolute concentration. Unlike thermoinhibition, photoinhibition was not associated with the suppression of O₂^.− production in the embryonic root pole, confirming that these environmental signals utilize different regulatory pathways. Full article

Herbicide treatment for agricultural crops may cause dramatic damage to production amount and quality. The aim of the present investigation was to compare different silicon formulations to assess their efficiency in maintaining faba bean plant growth with the herbicide spray Dicameron. Soil pollution due to Dicameron caused an intensive oxidant stress, decreasing bean pods, seed number and weight, antioxidant activity (AOA) and polyphenol content (TP), leaf chlorophyll, and carotene, sharply increasing proline level, and creating pod and leaf anomalies. All the Si formulations, i.e., ionic Si forms in the presence of microelements (Siliplant) or terpenes (BioSi), Si nanoparticles, and organic silicon adjuvant siloxane polyalkylene oxide (Atomic), significantly restored bean antioxidant status and leaf photosynthetic pigment accumulation, enhancing plant defense, as indicated by the proline level decrease. Only the ionic form of Si in the Siliplant formulation, containing essential microelements, facilitated the recovery of pod form and seed weight, while nano-Si was the most effective treatment for bean AOA restoration, and Atomic was the best in rebalancing chlorophyll and the worst in decreasing proline content. A strong beneficial effect of ionic Si in the presence of terpenes (BioSi) was recorded only on the yield of the control plants which did not undergo herbicide spraying. The results indicate a moderate beneficial effect of siloxane adjuvant on plant performance and antioxidant defense level and the highest positive impact on broad bean protection in response to the ionic Si (Siliplant formulation) supply also containing Cu, Zn, Mo, Mn, Fe, and B. Full article

Water convolvulus (Ipomoea aquatica Forssk.) is a fast-growing leafy vegetable valued for its nutritional and antioxidant properties; however, suboptimal seed physiology can hinder its germination and early growth. Non-thermal plasma (NTP) treatment is an eco-friendly seed-priming method that enhances seed performance and crop quality without the use of chemical inputs. This study evaluated the effects of NTP exposure (0, 5, 10, and 20 min) using a dielectric barrier discharge (DBD) plasma with an air gas flow rate of 1.5 lpm on the germination, seedling growth, pigment and protein content, nitrogen assimilation, and antioxidant capacity of water convolvulus. Plasma treatment of seeds increased germination in a time-dependent manner. The surface hydrophilicity improved with increasing treatment time. Seedlings grown from seeds treated for 10 min exhibited longer shoots (+10.1%) and roots (+17.8%). The shoot nitrate content increased by 66.3%. At 10 min, the total phenolics and flavonoids increased by 26.5% and 37.2%, respectively, with an accompanying increase in antioxidant activity, as measured by DPPH, ABTS, and FRAP assays. These findings demonstrate that a 10 min NTP treatment of seeds improves germination, growth, nutrient assimilation, phytochemical accumulation, and antioxidant activity in water convolvulus seedlings, highlighting its potential as a sustainable and chemical-free seed-priming technology with considerable potential to enhance the productivity and nutritional quality of plant microgreens in modern agriculture. Full article

Background: Tree peony (Paeonia section Moutan DC.) seeds, renowned for their rich content of unsaturated fatty acids, hold significant medicinal and nutritional value. Despite their potential, their yield is relatively low, which constrains economic gains and health benefits. Brassinosteroids (BRs), emerging as potent plant growth regulators, have demonstrated efficacy in boosting plant productivity. Methods: This study employed Paeonia ostii ‘Fengdan’ and administered either water (control group, CKs) or 0.05 mg/L BRs through foliar application during the seed enrichment and conversion phase to assess the effects of BR treatment on seed yield. Results: The BR treatment notably enhanced the protein, starch, and sugar content and yield of P. ostii ‘Fengdan’ seeds, surpassing those of the CKs. Transcriptome profiling identified a plethora of differentially expressed genes in P. ostii ‘Fengdan’ in response to BR treatment, which are implicated in biological processes associated with nutrient reservoir activity. KEGG analysis highlighted the pivotal role of starch and sucrose metabolism in the BR treatment response. WGCNA revealed key gene expression modules that correlate with physiological traits in P. ostii ‘Fengdan’. Furthermore, the quantitative real-time PCR (qRT-PCR) validation of key genes in this pathway revealed that BR treatment enhances yield through a dual mechanism: accelerating the seed-filling process and optimizing developmental timing for earlier maturation. Conclusions: Collectively, these findings offer inaugural comprehensive genomic resources delineating the transcriptional regulatory mechanisms of BRs in P. ostii ‘Fengdan’ seeds. Full article

MicroRNAs (miRNAs) represent the most abundant class of small RNAs in plants, in which the miR159 family demonstrates a high degree of conservation across various plant species and plays a crucial role in regulating anther, silique, and seed development by targeting GAMYB-like. The members of the Fan-miR159 family in cultivated strawberry target not only GAMYB-like genes but also Auxin Response Factor (ARF) family members, which are annotated as “ARF23-like” in the genome. In this study, we firstly analyzed the structural features, evolutionary conservation, and expression patterns of the miR159 family in Fragaria × ananassa. Then, we reannotated the “ARF23-like” genes in cultivated strawberry and found that they actually belong to the “ARF2b” subfamily. Finally, we utilized RT-qPCR and co-transformation experiments to analyze and validate our observation. The results showed the suppression of FaARF2b-2 expression by fan-miR159n and fan-miR159r in both tobacco and strawberry. Moreover, two transcripts of the FaARF2b-2 gene were detected in cultivated strawberry, FaARF2b-2R and FaARF2b-2M. The expression levels of both FaARF2b-2M and FaARF2b-2R increased following the abscisic acid (ABA) treatment, indicating that they may be positively regulated by ABA. In addition, FaARF2b-2M exhibits significantly higher expression levels in the anther compared to FaARF2b-2R, which potentially plays an important role in the male reproductive development. Our findings enhance the understanding of the miR159 family in cultivated strawberry and expand the knowledge regarding its novel targets. Full article

Background/Objectives: Pulmonary fibrosis (PF) is a progressive interstitial lung disease with limited therapeutic options. Lepidium sativum (cress seeds) possess recognized antioxidant and anti-inflammatory properties, yet its potential antifibrotic activity has not been investigated. This study evaluated the phytochemical composition and antifibrotic efficacy of cress seed extract (CSE) and examined whether its effects are associated with modulation of the ncNRFR/let-7d pathway in methotrexate (Mtx)-induced PF. Methods: Comprehensive metabolite profiling was performed using GC–MS, HPLC, and UPLC–T-TOF–MS/MS. Antioxidant capacity and antiproliferative effects were assessed in vitro. Network pharmacology was used to identify CSE-related PF targets and regulatory pathways. In vivo, PF was induced in adult male Wistar rats by Mtx, followed by oral CSE administration (50–150 mg/kg). Biochemical markers of inflammation, oxidative stress, extracellular matrix deposition, EMT, and ncRNA expression (ncNRFR and let-7d) were quantified alongside histopathology and immunohistochemistry. Results: CSE contained diverse terpenes, phenolics, flavonoids, glucosinolates, and amino acid derivatives. It exhibited potent antioxidant activity and antiproliferative effects against A549 and Hep2 lung cancer cells. Network analysis identified 997 overlapping CSE–PF targets and highlighted IL6 and MMP1 as relevant miR-let-7d–associated nodes. In vivo, Mtx-induced marked fibrosis characterized by increased ncNRFR, reduced let-7d, elevated IL6, HMGB1, TGF-β, MMP1, collagen, and hydroxyproline, and reduced antioxidant enzyme activity. CSE treatment dose-dependently mitigated these alterations, improved histoarchitecture, and reduced collagen deposition. Conclusions: CSE showed antifibrotic, antioxidant, and anti-inflammatory activity in MTX-induced PF in rats and modulated the reciprocal expression patterns of ncNRFR and let-7d. These findings support CSE as a potential source of bioactive constituents for PF management and identify the putative ncNRFR–let-7d regulatory relationship as a novel pathway in fibrotic lung disease, warranting further mechanistic investigation. Full article

Background: Preoperative localization of non-palpable breast lesions is critical for accurate resection and margin control in breast-conserving surgery. Traditional methods, such as wire or radioguided localization, have limitations in terms of logistics, patient comfort, and procedural flexibility. SCOUT^® is a wireless, radar-based alternative that may improve surgical precision and workflow. This study aimed to evaluate the clinical performance of the SCOUT^® in the localization of non-palpable breast and axillary lesions, including detection success, margin status, reoperation rates, and device-related events. Methods: We conducted a retrospective, single-centre observational study including 427 patients who underwent breast-conserving surgery after preoperative localization using the SCOUT^® between January 2023 and May 2024 at a tertiary academic hospital. Variables included lesion type, location, neoadjuvant treatment, device detection, seed deactivation, MRI interference, margin status, and reoperation rate. Results: The mean age was 58 ± 12.7 years, with malignant pathology in 88.5% of cases. SCOUT^® achieved a 100% detection rate in axillary localizations and 98.1% in breast lesions. Seed deactivation occurred in 1.2% of cases, all successfully managed intraoperatively. MRI artefacts were observed in 1.6% of patients, without diagnostic interference. Positive margins were reported in 8.3% of cases, representing an improvement compared with the institution’s historic 12% rate, with 5.9% requiring reoperation. Carcinoma in situ showed the highest rate of positive margins, at 26%. Conclusions: SCOUT^® was associated with high detection rates, a low incidence of device-related events, and favourable margin outcomes, supporting its reliability for the localization of non-palpable breast lesions. Full article

Priestia megaterium is a maize endophyte that may help the plant defend itself against bacterial and fungal pathogens. This study aimed to identify antimicrobials produced by two P. megaterium endophytes (FS10 and FS11) from maize and determine if seed coating with either strain could increase resistance to pathogens. Volatiles emitted by both isolates reduced the hyphal growth of fungi by 17–76%. Gas chromatography analysis found that each strain emitted isovaleric acid (IVA) and 3-methyl-1-butanol (3MB). Volatiles produced by each isolate inhibited bacterial growth, especially Clavibacter michiganensis ssp. michiganensis (Cmm). IVA killed all Cmm cells at 208 µL L⁻¹, while 3MB inhibited Cmm growth by 51% at 208 µL L⁻¹. Diluted cell-free extracts from FS10 and FS11 cultures stopped growth of Cmm, Erwinia amylovora and Ustilago maydis but did not arrest growth of Fusarium verticillioides. The treatment of corn seeds with FS10 or FS11 reduced leaf damage by 38–84% in young plants caused by Bipolaris maydis, Colletotrichum graminicola (Ces.) G.W. Wilson 1914, Exserohilum turcicum and Pythium sylvaticum. FS10 and FS11 isolates exuded volatile and soluble compounds that were more effective in slowing growth of bacteria than fungi. It is likely that corn seed treatment with FS10 and FS11 triggers induced systemic resistance, which mitigates leaf damage caused by maize pathogens. Full article

The physical and mechanical properties of soybean seeds are of fundamental importance for their practical use, as they determine the quality of seed material and the efficiency of technological processes in the food, feed, and oil industries, as well as the seeds’ ability to withstand transport, storage, and processing. Modern agriculture strives to increase productivity sustainably, and plant biostimulants are an innovative solution aiming to support plant development and to improve plant resistance. The purpose of this study was to determine how the form of an application of a biostimulant influences the geometrical and mechanical properties of soybean seeds. Two biostimulants (Asahi SL and Kelpak SL), both applied in three ways (universal spray nozzle, injector spray nozzle, and spray hoses), were tested in conjunction with three levels of moisture (6%, 8%, and 10%) on soybean seeds of the cultivar Abelina. The results demonstrated that the biostimulants did not have a significant effect on the sphericity of seeds, which remained at an average level: 0.74. Lower moisture of seeds resulted in their weaker tolerance to mechanical damage and a higher compression resistance factor. Seeds with a moisture content of 6% treated with Asahi SL using universal nozzle 12004C showed the highest cracking resistance (719.4 N∙mm⁻¹) and ultimate force (245.1 N) compared with untreated seeds (672.4 N∙mm⁻¹ and 216.4 N). The Asahi SL biostimulator increased the compression work up to the maximum force by 12% relative to the control, regardless of the spray application method, while the ceramic universal spray nozzle caused an almost 10% increase in maximum force compared with the control, irrespective of the type of biostimulator used. The findings indicate that biostimulants have a positive effect on the physical quality of seeds, with the choice of spray parameters playing a key role. The results provide practical guidelines for optimising agrotechnical treatments to produce seeds with improved quality parameters. They are also crucial for making an appropriate selection of sowing and seed-processing equipment, minimising seed loss and improving the efficiency of soybean production. Full article

High-temperature (HT) stress during flowering significantly impairs anther development and pollen fertility, leading to substantial yield loss in wheat. A key aspect of plant adaptation to temperature stress concerns remodeling of lipid metabolism. In this study, heat-tolerant and heat-sensitive wheat cultivars were employed to investigate the biochemical alterations in lipid metabolism in response to high-temperature (HT) stress during anthesis. Pollen viability and SEM demonstrated that, under high temperature, the heat-tolerant cultivar maintained a more stable pollen structure and exhibited higher pollen fertility compared to the sensitive cultivar. Fatty acid analysis showed that HT led to a decrease in the unsaturated fatty acid 18:3 and an increase in the saturated fatty acid 16:0, thereby reducing the double bond index in both cultivars. Lipidomic profiling revealed that HT caused a shift toward higher levels of saturated acyl chains, reducing unsaturation in both phospholipids and galactolipids. Notably, the levels of saturated lipids such as PC (34:0) and PA (36:0) increased markedly upon heat exposure in the heat-tolerant cultivar, whereas only minor changes were observed in the heat-sensitive cultivar. Furthermore, analysis of cuticular lipids showed a reduction in polyunsaturated cutin components under high temperature in wheat anthers. Heat treatment caused a substantial reduction in fertile spikelet rate in both cultivars, while the heat-tolerant cultivar maintained a better seed setting and higher yield. These findings provide biochemical insights into lipid metabolic adjustments that underlie thermotolerance during anthesis in wheat. Full article

Seed germination and early seedling development represent critical stages for turfgrass establishment under increasingly frequent drought and salinity constraints. This study evaluated the germination performance of three cultivars of Lolium perenne L. and three cultivars of Poa pratensis L. exposed to iso-osmotic drought stress simulated with polyethylene glycol (PEG) and salt stress induced by NaCl. Germination percentage, mean germination time, germination index, seedling vigor index, and radicle and plumule elongation were quantified, and post-stress recovery tests assessed the reversibility of stress effects. Osmotic restriction imposed by PEG caused stronger inhibition of germination and seedling growth than NaCl at equivalent water potentials. L. perenne showed higher overall tolerance, maintaining faster emergence and greater seedling vigor across treatments, while P. pratensis was more sensitive but exhibited substantial germination recovery after stress removal. Cultivar-dependent variation was evident in both species, and multivariate analyses consistently differentiated tolerant and sensitive genotypes. The contrasting germination strategies, with rapid activation in L. perenne and delayed, recovery-oriented germination in P. pratensis, highlight species-specific adaptive responses to water and salt stress. These findings provide a physiological basis for selecting resilient turfgrass cultivars suited to drought- and salinity-prone environments, contributing to sustainable turfgrass establishment and management. Full article

Seed priming with Pulsed Electric Fields (PEF) is a promising strategy to enhance early plant development and crop quality. This study evaluated PEF priming effects on Beetroot (Beta vulgaris L.), Arugula (Eruca vesicaria), and Basil (Ocimum basilicum L.) microgreens by assessing the effects of three distinct monopolar PEF protocols (PEFA: 2 kV/cm; PEFB: 3 kV/cm; PEFC: 4 kV/cm). PEFB and PEFC treatments significantly influenced imbibition. Germination Indexes (DGI, CGI, and SVI) were positively and significantly affected, with radicle length increasing up to 33% and DGI improving from 40 to 66 on the 1st day (Beetroot, PEFC). Chlorophylls and the Total Carotenoid concentration increased in Basil but decreased in Beetroot and Arugula. Fat and Protein increased in Beetroot (Fat: +41%; Protein: +34%) and Arugula (Fat: +91%; Protein: +11%) treated with PEFC. PEFB led to an increase in Starch in all species. Crude Fibre and Neutral Detergent Fibre decreased amongst all species. Methionine rose by 100% in Beetroot treated with PEFC. Sensory analysis showed slight increases in Sweet (Beetroot) and Aroma Intensity (Basil and Arugula), although these changes were not statistically significant. Species-specific responses to different PEF protocols were observed: optimal protocols seem to be PEFC for Beetroot, PEFB for Arugula, and PEFA/B for Basil. Full article

We evaluated the effects of suspensions of magnetite–maghemite nanocomposites functionalized with quaternized chitosan and phosphate groups on morpho-anatomical and physiological traits of yellow maize (Zea mays) and chili pepper (Capsicum annuum) seeds. A phytotoxicity assay was first conducted by applying aqueous suspensions of these nanocomposites to maize seeds at iron concentrations up to 100 ppm, using deionized water as the control under humid chamber conditions. After incubation, seeds treated with concentrations above 100 ppm exhibited reductions in biomass and root length compared with the control, suggesting phytotoxicity at high levels. Based on these results, suspensions containing 25, 35, and 45 ppm of iron, with corresponding phosphorus concentrations of 2.9, 4.0, and 5.2 ppm, were selected for a second in vitro assay using both maize and chili seeds. No statistically significant differences between treatments and control were detected for the variables measured. Germinated seeds from this assay were further evaluated under greenhouse conditions, where measured parameters also showed no significant differences between treatments and control in either crop. Overall, the findings indicate that aqueous suspensions of magnetite–maghemite nanocomposites with iron concentrations below 100 ppm do not produce phytotoxic effects on seed germination or morpho-anatomical and physiological traits measured. Full article

Drought is a major abiotic stress that compromises seed germination, seedling establishment, and subsequent crop productivity, thereby threatening agricultural sustainability and food security. Developing effective seed-based strategies is therefore essential to enhance drought resilience. In this study, we investigated the efficacy of green-synthesized silver nanoparticles (AgNPs), produced using Azadirachta indica (neem) flower extract as a seed priming agent, to improve drought tolerance and early growth in wheat (Triticum aestivum). Seeds were primed with AgNPs (25–100 mg L⁻¹), PEG 6000 (−0.6, −0.8, and −1.0 MPa), and their combination (AgNPs + PEG 6000). AgNP priming enhanced germination by 72%, 86%, and 100% at 25, 50, and 75 mg L⁻¹, respectively, compared with the control, with 75 mg L⁻¹ identified as the optimal concentration. This treatment increased total chlorophyll and carotenoid contents by 14% and 6%, and elevated phenolic and flavonoid accumulation by 58% and 97%, respectively. Antioxidant enzyme activities were also substantially increased—catalase (CAT) by 44%, superoxide dismutase (SOD) by 23%, peroxidase (POX) by 11%, and glutathione reductase (GR) by 58%. Under drought stress, AgNP priming at 75 mg L⁻¹ improved germination by up to 80%, indicating enhanced drought tolerance. Elevated protein and antioxidant enzyme levels, along with reduced malondialdehyde (MDA), proline, and total soluble sugar levels, further confirmed mitigation of oxidative stress. Collectively, these results demonstrate that neem-mediated green-synthesized AgNPs could serve as an effective seed-priming agent, promoting wheat seedling establishment and enhancing drought resilience under water-deficit conditions. Full article