Search Results (16,498)

The Arabidopsis thaliana Heat Shock Protein-Related (AtHSPR) gene participates in plant growth and abiotic stress tolerance, while its role in biotic stress resistance remains unclear. Here, we report that the athspr mutant is sensitive to Pseudomonas syringae pv. tomato (Pst) DC3000, whereas over-expression of AtHSPR enhances the defense of Arabidopsis against the pathogen. AtHSPR expression was induced by treatment with Pst DC3000, flg22, or salicylic acid (SA). Transcriptome analysis showed that mutation of AtHSPR changed the expression patterns of genes associated with defense response, oxidation–reduction, and SA responses, as well as transcription factors. The biochemical evidence revealed that AtHSPR interacted with Thimet Oligopeptidase 1 (TOP1), which modulated the SA-mediated immune response. Co-expression of AtHSPR and TOP1 showed that the TOP1 protein, normally located in the chloroplasts, gathered around the nucleus in response to a pathogen. After pathogen treatment, dynamic tubular projections (stromules) were present, extending from the chloroplasts toward the nucleus, and TOP1 was observed in the nucleus, together with AtHSPR. The top1athspr double mutant had lower SA levels and was more sensitive to pathogens than the top1 and athspr single mutants. Taken together, our results demonstrated that the interaction between AtHSPR and TOP1 plays a positive role in SA-mediated plant resistance against Pst DC3000. Full article

Background/Objectives: Cancer, a multifactorial disease with uncontrolled cell growth, oxidative stress, inflammation, genomic instability, and molecular signaling pathways, is a global health concern, leading to the ~20 million newly diagnosed cases annually. Although conventional therapy has been shown to enhance the survival rates of cancer patients, its clinical efficacy is limited by certain side effects that occur as a result of treatment, thus necessitating the exploration of plant-derived bioactive compounds for their potential as safer and alternative supportive therapeutic agents. Aloe vera, known as the plant of immortality, comprises phytochemicals, such as anthraquinones (aloe-emodin, emodin, and aloin), polysaccharides (acemannan), flavonoids, and phenolic acids, which contribute to the pharmacological effect of the compound. Methods: This review summarizes the anticancer potential of Aloe vera, and the data were retrieved from databases, such as PubMed, Google Scholar, ScienceDirect, Web of Science, and Wiley Online Library, during the time period of 2015 to 2025. Results: The literature revealed that Aloe vera and its bioactive compounds have dose-dependent cytotoxic and anti-proliferative properties against hepatocellular, cervical, colorectal, lung, breast, prostate, and hematological cancers, which are significantly mediated by apoptosis and pyroptosis induction, reactive oxygen species (ROS) production, mitochondrial dysfunction, inhibition of angiogenesis and metastasis, and the modulation of key signaling pathways, particularly PI3K/Akt, MAPK, NF-кB, p53, and Wnt/β-catenin. Furthermore, anthraquinones, including Aloe-emodin, demonstrate potent anticancer effects at micro-molar doses, and polysaccharides increase immune reactions and provide tumor immunity. Conclusions: Conclusively, Aloe vera is a promising multi-target natural compound, particularly efficient in the treatment of cancer. However, despite significant therapeutic potential, more research on pharmacokinetics, standard dose, and controlled clinical trials of Aloe vera is required to validate clinical applicability. Full article

Background/Objectives: Obesity-associated metabolic dysfunction involves oxidative stress, gut barrier impairment, and gut–liver axis disruption. This study evaluated whether enzymatically prepared Solenocera crassicornis peptides (SCPs) provide additional benefits during diet normalization in HFD-induced obese mice and examined associations with antioxidant, microbial, and barrier markers. Methods: SCPs were characterized using UPLC-Q-TOF-MS/MS and amino acid analysis. Peptides underwent bioactivity prediction and Keap1 docking. After 7 weeks of HFD feeding, obese male C57BL/6J mice were switched to a normal diet and administered vehicle, orlistat, or SCPs for 4 weeks. Adipose tissue mass, serum lipid profiles, liver histology, hepatic antioxidant status, barrier-associated histological and biochemical markers, and gut microbiota composition were assessed. A simulated digestion–fecal fermentation model was used to assess the effects of fermentation products generated in the presence of digested SCPs on H₂O₂-induced oxidative injury and MUC2 secretion in LS174T goblet-like cells. Results: SCPs reduced epididymal and perirenal fat, improved serum lipids, improved hepatic steatosis-related morphology and enhanced hepatic antioxidant status. SCPs were also associated with improved intestinal morphology, increased mucin-associated staining, decreased serum diamine oxidase levels and reduced hepatic lipopolysaccharide accumulation. 16S rRNA sequencing showed SCP-associated microbial shifts, with correlations linking taxa to metabolic and barrier markers. Fermentation products generated in the presence of digested SCPs improved oxidative-stress and MUC2-related readouts in LS174T cells. Conclusions: During diet normalization, SCPs were associated with additional improvements in adiposity, lipid profiles, hepatic antioxidant status, intestinal barrier readouts, and gut microbiota. These findings support further investigation of SCPs as standardized marine protein hydrolysates, but active components, causal mechanisms, long-term efficacy, safety, and human relevance remain to be established. Full article

Young barley, derived from the early vegetative stage of Hordeum vulgare L., constitutes a plant-based functional ingredient whose phytochemical profile differs markedly from that of mature grain. Two principal commercial forms exist—dried grass powder and juice-derived products—differing in matrix composition and bioactive compound concentration. This narrative review critically evaluates the current knowledge on the phytochemical composition, biological activity, and translational relevance of young barley preparations considered as a functional plant food. The phytochemical spectrum is dominated by C-glycosyl flavones, particularly saponarin and lutonarin, alongside phenolic acids, chlorophylls, enzymatic antioxidants, vitamins, and minerals. Experimental evidence implicates the modulation of redox homeostasis, inflammatory signaling, and metabolic regulators as the primary biological mechanisms. In vitro studies additionally demonstrate antiproliferative activity in human cancer cell lines and immunomodulatory properties mediated by polysaccharide-rich fractions, extending the biological profile of young barley beyond classical antioxidant activity. Although preclinical models consistently demonstrate antioxidant and metabolic effects, high experimental doses and limited preparation standardization restrict the direct extrapolation to human supplementation contexts. Available clinical trials suggest modest improvements in selected lipid, glycemic, and oxidative stress markers; yet, most are small in scale and brief in duration. Agronomic variables including fertilization strategy and soil composition represent additional, underappreciated sources of phytochemical variability and safety concern. Overall, the current evidence supports the biological plausibility of young barley as a functional plant food; yet, the clinical data remain preliminary. Future research should prioritize preparation standardization, dose–response characterization, and agronomic transparency to strengthen translational reliability. In conclusion, young barley preparations represent a biologically plausible functional plant food ingredient with preliminary clinical support, pending confirmation from adequately powered, standardised randomised controlled trials. Full article

This study aims to elucidate the mechanism by which exogenous guanosine monophosphate (GMP) enhances the stress tolerance of Lactiplantibacillus plantarum Y12. Phenotypic assays demonstrated that GMP supplementation significantly improved biofilm formation, adhesion index, and auto-aggregation ability. The survival ability of Y12 in simulated gastric juice, intestinal juice, and freeze-drying stress was also significantly increased. Transcriptomic results revealed that GMP increased the intracellular content of the second messengers C-di-AMP and C-di-GMP by reducing phosphodiesterase (PDE, RS04640). This, together with the upregulated expression of luxR and rpoN, synergistically promoted biofilm formation. Furthermore, GMP enhanced acid tolerance by increasing glutamate decarboxylase activity (GAD, RS05235). It also significantly elevated the levels of extracellular proteins, exopolysaccharides, membrane polysaccharides, and membrane fatty acids by modulating genes related to proteins (yidC, yajC), polysaccharides (agaB, agaC), and membrane fatty acid synthesis (RS02005, plsY), which was also demonstrated by quantitative determination. Collectively, these regulatory mechanisms substantially improve the stress tolerance of L. plantarum Y12, providing a theoretical basis for its application. Full article

Co-contamination of biphenyl and heavy metals is widespread in industrial environments, but systematic studies on the simultaneous treatment of both pollutants using a single microbial strategy remain limited. In this study, we characterized the biphenyl degradation performance, metabolic pathway, transcriptomic response, and Cr(VI) tolerance of Rhodococcus sp. TG-1, and developed an alkali-modified biochar immobilization system to enhance its degradation efficiency for biphenyl under Cr(VI) stress. Degradation experiments were carried out under optimal conditions (30 °C, pH 7.0), and it was found that strain TG-1 degraded 76.84% of 300 mg/L biphenyl within 3 days. Intermediate metabolites were identified by LC-MS, and five key intermediates were detected, confirming that TG-1 metabolizes biphenyl via the classical 2,3-dihydroxybiphenyl dioxygenase pathway, with subsequent entry into the tricarboxylic acid cycle. Transcriptomic analysis was performed to profile gene expression, revealing 845 differentially expressed genes under biphenyl stress, including 672 upregulated genes significantly enriched in aromatic degradation pathways. Seven complete bph gene clusters responsible for biphenyl catabolism were also identified. Strain TG-1 exhibited high tolerance to Cr(VI), with a minimum inhibitory concentration (MIC) of 500 mg/L. However, its biphenyl degradation efficiency dropped to 51.32% in the presence of 200 mg/L Cr(VI). After immobilization using alkali-modified straw biochar (JBC), heavy metal toxicity was alleviated, and the biphenyl removal rate increased to 99.30% under co-contamination conditions. Scanning electron microscopy (SEM) and Fourier transform infrared spectroscopy (FTIR) analyses confirmed that TG-1 was stably loaded onto the biochar surface through hydrogen bonding and electrostatic interactions. Altogether, this study provides a promising bacterial strain and a green immobilization strategy for enhancing biphenyl removal in the presence of Cr(VI), offering a practical approach for the treatment of environments co-contaminated with aromatic compounds and heavy metals. Full article

Background/Objectives: Anemia and iron dysregulation are common in chronic heart failure (CHF), but additional metabolic mechanisms may contribute to these alterations. This study aimed to evaluate purine metabolism and oxidative stress markers in patients with CHF and to explore their potential relationship with anemia. Methods: In this cross-sectional study, 176 patients with CHF and 29 control individuals were included. CHF phenotypes were classified according to left ventricular ejection fraction (HFpEF, HFmrEF, HFrEF). Purine metabolites (guanine, hypoxanthine, adenine, xanthine, and uric acid) were measured using high-performance liquid chromatography, while lipid peroxidation (LPO) and advanced oxidation protein products (AOPPs) were assessed spectrophotometrically. Non-parametric statistical tests with correction for multiple comparisons were applied. Results: Anemia was present in 40.3% of patients with CHF. Serum iron and platelet counts were significantly lower in CHF compared with controls (p = 0.001). Among purine metabolites, adenine levels were higher in CHF (nominal p = 0.009), whereas other metabolites did not differ significantly between groups. LPO levels were lower and AOPP levels were higher in CHF (p = 0.021 and p = 0.008, respectively). No statistically significant associations were observed between hemoglobin levels and purine metabolites. Conclusions: CHF is associated with alterations in iron status and oxidative stress markers, as well as changes in purine metabolism. However, no significant associations between purine metabolites and anemia were identified in this cohort, and these findings should be interpreted cautiously given the exploratory design and sample size limitations. Full article

Objectives: This study investigated the interplay between pre- and post-match physiological responses and subsequent emotional changes in male water polo players competing in the Italian Serie C league (third national level, sub-elite), focusing on differences between official championship (competitive) and non-competitive (training) settings. Methods: Sixteen male Italian Serie C water polo players participated. Salivary biomarkers (cortisol, immunoglobulin A (IgA), and uric acid) were measured, alongside psychological assessments of cognitive anxiety, somatic anxiety, and self-confidence. Measurements were taken before and after both training and competition matches. Results: A significant anticipatory rise in salivary cortisol was observed before competition matches compared to training, highlighting the psychological stress associated with competitive events. Post-match, cortisol levels remained elevated to a greater extent after competition. Salivary IgA levels decreased significantly following both training and competition, with a more pronounced reduction after official matches, and exhibited a negative correlation with cortisol. Salivary uric acid, a marker of oxidative stress, increased post-exercise and was significantly higher after competition. Players reported higher somatic and cognitive anxiety and lower self-confidence before competition compared to training, and pre-competition cortisol levels were positively correlated with both anxiety measures and negatively correlated with self-confidence. Conclusions: These findings highlight the distinct physiological and psychological responses elicited by competitive versus non-competitive settings in water polo, emphasizing the importance of considering the emotional context when monitoring athletes’ stress and recovery. The social meaning of competitive contexts may be embodied, impacting stress and immune responses. Full article

Abiotic stresses, including drought, salinity, alkalinity, temperature extremes, flooding, heavy metals, and emerging pollutants, challenge plant growth and productivity by disturbing water relations, ion balance, redox homeostasis, membrane stability, energy metabolism, and developmental progression. Although substantial progress has been made in the identification of stress-responsive hormones, second messengers, kinases, transcription factors, transporters, and metabolic regulators, plant stress adaptation cannot be fully explained by linear signaling cascades or single tolerance genes. A major unresolved question is how early molecular events are reorganized into coordinated physiological and developmental outputs that support survival, recovery, and productivity. In this review, we propose an intermolecular interaction-driven adaptive remodeling framework for plant abiotic stress responses. This framework emphasizes that stress tolerance emerges from dynamic changes in receptor–ligand recognition, protein–protein interactions, calcium decoding, redox-sensitive modification, phosphorylation networks, transcriptional regulation, chromatin-associated control, and metabolite-mediated feedback. We further emphasize ROS as integrative redox switches that connect stress sensing, defense activation, senescence-related transitions, and recovery, and chromatin-associated mechanisms as regulators that may stabilize primed or memory-like adaptive states. We discuss how these interaction networks converge on core signaling hubs, including abscisic acid, reactive oxygen species, Ca²⁺, and kinase/phosphatase systems, and how they remodel stomatal behavior, root architecture, ion and pH homeostasis, redox buffering, metabolism, development, and reproductive resilience. We further highlight how natural variation, multi-omics, genome editing, high-throughput phenotyping, and field validation can translate interaction-centered stress biology into crop resilience. This perspective provides a conceptual bridge between molecular stress perception, network behavior, physiological adaptation, and climate-resilient agriculture. Full article

Diabetes mellitus (DM) is a complex metabolic disorder characterized by chronic hyperglycemia and represents a major global public health concern due to its rapidly increasing prevalence. Although current pharmacological therapies effectively achieve glycemic control, their long-term use is limited by adverse effects, high costs, patient compliance issues, and increasing interest in safer, multi-targeted therapeutic strategies. In this context, plant-derived bioactive compounds have gained attention as complementary or alternative approaches to metabolic disease management. Gymnema sylvestre (Retz.) R.Br. ex Sm (GS), traditionally known as “gurmar” (“sugar destroyer”), is one of the most extensively studied medicinal plants with significant antidiabetic potential. This review evaluates the antidiabetic effects of G. sylvestre, focusing on its phytochemical composition, molecular mechanisms, and impact on diabetes-related complications. Major bioactive constituents, including triterpenoid saponins (gymnemic acids), gurmarin-like peptides, flavonoids, and sterols, regulate glucose homeostasis, inhibit intestinal glucose absorption, preserve pancreatic β-cell function, stimulate insulin secretion, modulate lipid metabolism, and suppress inflammatory signaling pathways. Experimental and clinical evidence indicates that G. sylvestre modulates oxidative stress and inflammation associated with complications such as nephropathy, neuropathy, retinopathy, vascular dysfunction, and dyslipidemia. This review adopts a mechanism-oriented framework integrating phytochemical structure–molecular target–metabolic outcome relationships and discusses emerging strategies, including nanotechnology-based delivery systems, molecular docking, and multi-component phytotherapy. Overall, G. sylvestre represents a promising multi-target phytotherapeutic agent, highlighting directions for future mechanistic and clinical research. Full article

The accumulation of polylactic acid nano-plastics (PLA-NPs) in saline–alkali soils poses a potential threat to crop growth; however, the underlying toxicological mechanisms remain poorly understood. We conducted a hydroponic experiment to investigate the effects of polylactic acid (PLA) NPs (100 and 500 mg L⁻¹) under conditions both in the presence (50 mmol L⁻¹ NaCl) and absence of salt stress on maize seed germination, seedling growth, physiological characteristics, and transcriptomic responses. The results showed that exposure to PLA-NPs, particularly at a high concentration (500 mg L⁻¹), significantly inhibited seed germination and seedling growth. Compared to the low concentration (100 mg L⁻¹) of PLA-NPs, the high concentrations (500 mg L⁻¹) reduced the germination percentage by 25.0% and fresh weight by 25.8% and increased root MDA (6.7%), SOD (30.0%), POD (6.3%), ASA (13.4%), and GSH (13.1%). Under the same concentration of the PLA, PLA + NaCl treatments exerted stronger inhibitory effects than PLA-NPs alone, with the seed germination percentage and fresh weight reduced by an average of 52.7% and 6.6%, respectively. Notably, the inhibitory effects and integrated biomarker response (IBR) index of the PLA 500 + NaCl treatment were the highest. The presence of PLA-NPs in roots was confirmed using confocal laser scanning microscopy. GO enrichment analysis showed that pathways related to nutrient reservoir activity, oxidoreductase activity, hydrogen peroxide catabolic process, and hydrogen peroxide metabolic process were enriched under PLA-NP and PLA + NaCl treatments. KEGG analysis further indicated enrichment in phenylpropanoid biosynthesis, ABC transporters, and alpha-linolenic acid metabolism. The PLA-NP and PLA + NaCl treatments upregulated genes associated with oxidoreductase activity (Zm00001eb238800, Zm00001eb128620, and Zm00001eb020790). These findings suggest that synergistic toxicity of PLA-NPs and salinity stress in maize is primarily driven by the internalization of PLA-NPs and Na⁺ within maize roots, which negatively impacts maize seed germination and seedling growth by disrupting redox homeostasis and metabolic balance, thereby forcing plants to reallocate resources from growth toward oxidative stress defense. This study provides critical insights into the environmental risks of biodegradable nano-plastics in saline–alkali soil environments. Full article

Cacti thrive in arid and coastal environments partly through associations with beneficial endophytic and rhizosphere bacteria; however, current knowledge remains limited. This study aimed to assess the diversity of cultivable bacteria associated with Opuntia dillenii and evaluate their potential as Plant Growth-Promoting (PGP) agents. Endophytic bacteria were isolated from cladodes and roots, while rhizobacteria were recovered from rhizosphere soil. Bacterial isolates were identified using morphological characteristics and 16S rRNA/gyrB sequencing, followed by screening for PGP traits, pH and temperature tolerance. A total of 31 isolates were obtained, including 23 endophytes and 8 rhizobacteria, mainly affiliated with Firmicutes, Actinobacteria, and Proteobacteria. Bacillus (35.48%) and Priestia (32.25%) predominated, with Priestia flexa as the most prevalent species. The most frequent PGP traits were phosphate solubilization (80.65%), proteolytic activity (70.97%), siderophore production (67.74%), and nitrogenase activity (64.52%). The highest phosphate solubilization indices were observed for strain R3 (3.41), R6 (3.39) and S6 (3.21), whilst the highest indole-3-acetic acid yields were recorded for C9 (172.88 µg/mL), R11 (96.22 µg/mL) and C3 (90.94 µg/mL), and the strongest siderophore production for C3 (30.37 mm), C7 (27.96 mm) and S7 (27.88 mm). These findings highlight O. dilleniid-associated coastal bacteria as promising resources for plant growth and plant stress resilience. Full article

Background/Objectives: Gallic acid (GA) is a naturally occurring polyphenol with reported antioxidant and anticancer properties. This study investigated whether GA enhances carboplatin (CARB)-associated anticancer activity in HeLa cervical cancer cells through mechanisms related to oxidative stress, mitochondrial dysfunction, apoptosis, and cell cycle dysregulation, while comparatively evaluating cytotoxicity in HaCaT cells. Methods: The effects of GA and CARB, individually and in combination, were evaluated using cell viability assays, apoptosis and cell cycle analyses, intracellular reactive oxygen species (ROS) measurements, N-acetylcysteine (NAC)-mediated rescue experiments, mitochondrial membrane potential assessment, reverse transcription–quantitative polymerase chain reaction (RT-qPCR), immunocytochemistry, and three-dimensional (3D) tumor spheroid models. Bioinformatic analyses were performed to explore pathways associated with the observed molecular responses. Results: The GA + CARB combination demonstrated enhanced cytotoxicity and apoptotic activity in HeLa cells compared with either monotherapy, while exhibiting comparatively lower toxicity in HaCaT cells. Combination treatment increased intracellular ROS levels, whereas NAC pretreatment partially reversed ROS accumulation and cytotoxicity, supporting a contributory role of oxidative stress in treatment-associated responses. The combination also induced mitochondrial membrane depolarization, increased G2/M arrest and SubG1 accumulation, and modulated apoptosis- and cell cycle-related gene expression. In 3D spheroid models, GA + CARB reduced spheroid growth and viability and disrupted spheroid integrity more effectively than single-agent treatments. Bioinformatic analyses identified interconnected pathways associated with oxidative stress, apoptosis, and cell cycle regulation. Conclusions: GA may enhance CARB-associated anticancer activity through mechanisms linked to oxidative stress, mitochondrial dysfunction, apoptosis, and cell cycle dysregulation. The incorporation of ROS/NAC rescue experiments and 3D spheroid validation further supports the biological relevance of the observed effects. Nevertheless, these findings remain preliminary and require confirmation in advanced in vivo and translational cervical cancer models. Full article

Selenium is an essential micronutrient for humans, underscoring its importance in enhancing the nutritional and physiological attributes of agricultural and horticultural crops through exogenous application. At low doses, selenium improves growth and development, and increases crop yield and quality, particularly under stress conditions. It is believed that abscisic acid and sucrose work together to regulate strawberry (Fragaria × ananassa Duch.) fruit ripening. This study aimed to provide comprehensive biochemical and molecular insights into the selenium mediated effects on ripening and quality changes in ‘Camarosa’ strawberry fruits. Selenium treatment increased chlorophyll levels in leaves, suggesting a positive impact on overall plant health. Foliar application of 1 mM selenium significantly accelerated ripening. Treated fruits exhibited higher levels of total soluble solids, along with a decrease in titratable acidity. About lipid peroxidation indices, foliar application of 1 mM selenium decreases hydrogen peroxide and malondialdehyde. Consistently, flavonoids, phenolic compounds, anthocyanins, ascorbic acid, and antioxidant capacity, as well as the activity of the enzymes SOD, CAT, APX and PAL, were increased by selenium treatment. Interestingly, the ABA content in strawberry fruits also increased with selenium treatment. The selenium treatment upregulated genes involved in abscisic acid biosynthesis, phenolic compound biosynthesis, and anthocyanin production, namely, FaNCED1, FaG2BD, FaCHS, FaPAL, and FaSUT1. This study highlights the potential of selenium as a biostimulant and quality-enhancing agent in strawberries, improving fruit biochemical composition and ripening dynamics while contributing to better nutritional value and market appeal. Full article

Zinc deficiency is increasingly recognized as a risk factor for neurodegenerative diseases, yet the underlying molecular mechanisms remain incompletely understood. In this study, we investigated the impact of intracellular zinc depletion on oxidative stress and inflammasome activation in microglial (SIM-A9) and neuronal (SH-SY5Y) cell models, and evaluated the protective effects of polyphenolic compounds. Intracellular zinc chelation with the membrane-permeable chelator TPEN markedly increased reactive oxygen species (ROS) production, reduced cell viability, and upregulated the mRNA expression of NLRP3 inflammasome-related genes and pro-inflammatory cytokines. In contrast, extracellular zinc chelation had no effect, highlighting the critical role of intracellular zinc homeostasis in maintaining redox balance. Zinc supplementation significantly attenuated these responses. Among 32 polyphenols screened by DPPH radical scavenging assay, caffeic acid derivatives—chicoric acid (ChA), rosmarinic acid (RA), and caffeic acid phenethyl ester (CAPE)—exhibited the most potent antioxidant activity, surpassing that of edaravone. These compounds suppressed ROS production and differentially protected against zinc deficiency-induced cellular damage. ChA showed the strongest ROS inhibitory activity (IC50: 1.9 µM in SIM-A9), RA provided robust cytoprotection even at low concentrations, and CAPE most effectively suppressed inflammasome-related gene expression and inhibited aggregation of both Aβ1–42 and the highly neurotoxic pyroglutamate-modified variant pEAβ3–42. These findings demonstrate that intracellular zinc deficiency drives ROS-dependent upregulation of NLRP3 inflammasome-related genes, and suggest that caffeic acid derivative polyphenols may serve as complementary agents for mitigating neuroinflammatory and amyloidogenic processes relevant to Alzheimer’s disease. Full article