Search Results (12,266)

The uptake and accumulation of nanoplastics by plants have emerged as a major research focus. Exogenous selenium nanoparticles (SeNPs) are widely used to mitigate the toxicity of abiotic stresses, such as nanoplastics (NPs) and polyethylene (PE—NPs) nanoplastics, and represent a feasible strategy to enhance plant performance. However, the molecular mechanisms by which SeNPs alleviate the phytotoxicity of microplastics and nanoplastics remain poorly defined. To address this gap, we used Pistia stratiotes L. (P. stratiotes) as a model and silicon dioxide nanoparticles (SiO₂NPs) as a comparator, integrating physiological assays, ultrastructural observations, and proteomic analyses. We found that NP stress caused ultrastructural damage in root tips, exacerbated oxidative stress, and intensified membrane lipid peroxidation. SeNPs treatment significantly mitigated NP-induced oxidative injury and metabolic suppression. Compared to the NPs group, SeNPs increased T-AOC by 38.2% while reducing MDA and ·OH by 33.3% and 89.6%, respectively. Antioxidant enzymes were also elevated, with CAT and POD rising by 47.1% and 39.2%. SeNPs further enhanced the photosynthetic capacity and osmotic adjustment, reflected by increases in chlorophyll a, chlorophyll b, and soluble sugar by 49.7%, 43.8%, and 27.0%, respectively. In contrast, proline decreased by 17.4%, indicating stress alleviation rather than an osmotic compensation response. Overall, SeNPs outperformed SiO₂NPs. These results indicate that SeNPs broadly strengthen anti-oxidative defenses and metabolic regulation in P. stratiotes, effectively alleviating NP-induced oxidative damage. Proteomics further showed that SeNPs specifically activated the MAPK signaling cascade, phenylpropanoid biosynthesis, and energy metabolic pathways, enhancing cell-wall lignification to improve the mechanical barrier and limiting NPs translocation via a phytochelatin-mediated vacuolar sequestration mechanism. SiO₂NPs produced similar but weaker alleviative effects. Collectively, these findings elucidate the molecular basis by which SeNPs mitigate NPs’ phytotoxicity and provide a theoretical foundation and practical outlook for using nanomaterials to enhance phytoremediation in aquatic systems. Full article

Nemopilema nomurai is a species of common large toxic jellyfish in China seas, and its tentacle tissues contain various types of nematocysts. However, the correlation between the morphology and function of nematocysts still remains unclear. In this study, we first obtained two monomorphic nematocysts with high-purity from N. nomurai, namely Anisorhizas and O-isorhizas, by density gradient centrifugation: the Anisorhizas is small and rod-shaped and the O-isorhizas is larger and spherical. Upon deionized water stimulation, O-isorhizas exhibited a stronger discharge capability than Anisorhizas. The nematocyst contents of Anisorhizas (AnC) and O-isorhizas (OnC) were extracted separately, and their composition and bioactivities were analyzed simultaneously. The protein bands by SDS-PAGE revealed similar distributions in AnC and OnC, except that the protein band distribution in OnC was more extensive. OnC showed stronger cytotoxicity, hemolytic activity, metalloprotease activity, and serine protease activity than AnC. In contrast, AnC exhibited a higher antioxidant activity and significant proinflammatory activity. Both AnC and OnC exhibited antimicrobial activities against certain marine pathogenic Vibrios. These results suggest that O-isorhizas, with the larger capsule capability, stronger discharge ability and toxicity, likely plays a major role in inducing toxic effects and tissue damage, while Anisorhizas, being smaller and less toxic, may undertake preferentially other functions, such as synergistic predation, environmental stress adaptation, and energy balance maintenance. This study provides insights into the morpho-functional relationship between various types of nematocysts, and also lays a foundation for further exploration of the functional diversity of nematocysts and the mechanisms underlying jellyfish envenomation. Full article

UVA radiation induces oxidative stress, mitochondrial dysfunction, and cell death in human dermal fibroblasts, contributing to skin aging and damage. In this study, we investigated the protective effects of polydatin, a natural polyphenol, against UVA-induced cell damage. Our results show that polydatin preserves cell viability and reduces intracellular reactive oxygen species (ROS) levels after UVA exposure. In addition, polydatin maintains mitochondrial integrity by preserving mitochondrial membrane potential and improving mitochondrial respiration. From a molecular perspective, polydatin regulates the expression of Nrf2, a key regulator of the cellular antioxidant response, thereby promoting cellular defense mechanisms. Additionally, polydatin attenuates UVA-induced mitochondrial fission, supporting a balanced mitochondrial dynamic profile. These results suggest that polydatin exerts a protective effect on UVA-irradiated fibroblasts, highlighting its potential for cosmetic and dermatological applications aimed at preventing photoaging and oxidative skin damage. Full article

This study investigates the mechanisms underlying osteocyte injury in a high glucose (HG) environment and explores potential therapeutic targets and diagnostic markers for diabetic osteoporosis, a common complication of type 2 diabetes mellitus (T2DM). Hyperglycemia induces oxidative stress through the reactive oxygen species (ROS) production, which impair osteocytes and accelerate bone loss. To examine these effects, MLO-Y4 cells and primary mouse osteocytes were cultured under normal glucose and HG conditions, with additional treatments using N-acetylcysteine (NAC, ROS scavenger) and rapamycin (autophagy promoter and mTOR inhibitor). Cell viability, ROS levels, and the autophagy and apoptosis markers expression (Beclin1, LC3, p62, Bax, Bcl2, cytochrome C, and caspase3) were assessed using CCK8/ATP level assay, flow cytometry, Western blot, qRT-PCR, immunofluorescence, and TUNEL staining. The results showed that HG inhibits cell proliferation, induces insulin resistance, generates ROS, alters antioxidant enzymes, and promotes oxidative stress, leading to mTOR activation, subsequent autophagy inhibition, and osteocyte apoptosis. NAC mitigated these effects, while rapamycin prevented HG-induced apoptosis by inhibiting mTOR activation and promoting autophagy. This suggests that ROS-induced mTOR activation impairs autophagy and hinders the clearance of damaged osteocytes, triggering apoptosis. This research provides foundational evidence and novel insights into diabetic osteoporosis pathogenesis and potential therapies. Full article

Melatonin (MT), an antioxidant and growth regulator, interacts with almost all phytohormones, but the molecular mechanisms of these interactions are poorly understood. Using mRNA sequencing (mRNA-seq) technology, we analysed the global regulation of MT-induced expression of genes involved in metabolism, signalling and responses to major phytohormones under prolonged high-intensity light (HL) stress. Plants respond to MT through the activation of auxin and brassinosteroid (BS) response genes, which were identified among the enriched categories of differentially expressed genes (DEGs) with increased expression, and the suppression of abscisic acid and ethylene signalling and response genes, which were among the enriched downregulated categories. MT also suppressed growth-inhibiting genes involved in jasmonic acid (JA) and salicylic acid (SA) signalling and response and activated genes encoding the growth-promoting hormones gibberellins and cytokinins (CKs), which is consistent with the role of MT in stress alleviation. However, the expression of some unique genes, which are positively or negatively modulated by stress, was reinforced by MT treatment, illustrating the extraordinary type of regulation that enhances the action of specific hormone-mediated mechanisms. The study of signal integration between MT and hormones with the involvement of signalling mutants revealed that some interactions are regulated at the transcriptional level and require the activity of relevant signalling pathways. Disruption of CAND2 completely abolished melatonin-dependent activation of the mitogen-activated protein kinases MAP3K17 and MKK7, suggesting that the MAP3K17-MKK7 module is an important player in the MT-triggered MAPK pathway, acting downstream of CAND2. Full article

Three-dimensional printing has emerged as a promising technology in endovascular surgery for the production of patient-specific stent-grafts. Thermoplastic polyurethane (TPU) is widely used for this purpose due to its favourable biocompatibility, hemocompatibility, and mechanical properties. However, its long-term stability under physiological conditions remains uncertain. This study evaluates the ageing behaviour of 3D-printed TPU stent-grafts under accelerated oxidative conditions (20% H₂O₂–0.1 M CoCl₂) over three months, corresponding to approximately 45 months in vivo, and during three months in hydrolytic (0.1 M NaOH) conditions. Mechanical, physicochemical, thermal, and surface properties were periodically analysed. Differential scanning calorimetry revealed a decrease in crystallisation enthalpy of 41% and a reduction in melting enthalpy of 29% after hydrolytic ageing, whereas no decrease was observed after oxidative ageing. Despite these chemical changes, size exclusion chromatography indicated minimal chain scission. However, spectroscopy and microscopy showed minor chain scission and additive migration (antioxidant and lubricant). Nevertheless, tensile testing highlighted that mechanical performance remained within clinically acceptable ranges. These findings demonstrate that 3D-printed TPU vascular implants retain essential properties under prolonged simulated ageing, supporting their safety and durability for vascular applications. Full article

Exposure to fine particulate matter (PM2.5) poses a major threat to skin health, yet effective prevention strategies remain limited. Shikonin, a naphthoquinone derived from Lithospermum erythrorhizon, exhibits potent antioxidant and anti-inflammatory activities. However, its therapeutic application is limited by low bioavailability. To address this limitation, we developed shikonin-loaded nanoparticles (SH-NPs) using an emulsion solvent evaporation method and characterized their physicochemical properties. The protective effects of SH-NPs against PM2.5-induced skin damage were evaluated in a mouse model. The SH-NPs exhibited favorable characteristics, including a mean particle size of 209.03 ± 2.45 nm, a PDI of 0.064 ± 0.03, and a zeta potential of –17.69 ± 2.06 mV. The encapsulation efficiency is 88% and the drug loading capacity is 5.5%, respectively. In vitro, SH-NPs significantly enhanced cellular uptake in HaCaT cells. In vivo, treatment with SH-NPs significantly improved skin structural disorders, epidermal thickening, and collagen fiber reduction, while downregulating the expression of MMP-2 and MMP-9. Furthermore, SH-NPs increased the expression of SOD1 and SOD2, reduced MDA levels, and decreased the expression of TNF-α, IL-1β, and NO. In conclusion, SH-NPs attenuated PM2.5-induced skin toxicity via enhanced antioxidant, anti-inflammatory, and anti-degradation mechanisms, offering a novel strategy to boost shikonin bioavailability and prevent PM2.5-related skin damage. Full article

Background/Objectives: Traumatic brain injury (TBI) disrupts both the intestinal epithelium and blood–brain barrier (BBB), contributing to oxidative stress, neuroinflammation, and behavioral impairments. Vitis vinifera leaf (VVL) extract possesses antioxidant and anti-inflammatory properties, but its protective effects on the brain–gut axis following TBI remain unclear. This study aimed to evaluate whether VVL supplementation preserves barrier integrity and improves neurobehavioral outcomes after TBI. Methods: A murine model of TBI was used, with animals receiving daily oral supplementation of the VVL extract. Neurobehavioral performance was assessed through behavioral testing, while histopathological examinations, biochemical assays, and gene expression profiling were performed to evaluate neuronal and intestinal integrity, antioxidant defense, and inflammatory responses. Results: VVL supplementation significantly alleviated anxiety- and depression-like behaviors and preserved the structural integrity of neuronal and intestinal tissues. Antioxidant defense mechanisms were strengthened, as shown by increased catalase and superoxide dismutase activities, together with upregulation of Nrf2 and HO-1 expression. Tight junction proteins, including ZO-1 and occludin, were upregulated in both brain and gut tissues, reflecting improved barrier integrity. Furthermore, VVL markedly reduced pro-inflammatory cytokine expression. Conclusions: VVL extract confers dual protection of the gut and brain barriers after TBI by enhancing endogenous antioxidant defenses, maintaining tight junction integrity, and suppressing inflammation. These findings suggest that VVL may represent a natural therapeutic strategy to mitigate oxidative stress, neuroinflammation, and behavioral dysfunctions associated with TBI. Full article

Mangiferin (MF), a natural component widely found in fruits, vegetables, and herbs, has garnered increasing attention for its potent antioxidative properties and therapeutic potential. This bioactive xanthone compound plays a crucial role in mitigating oxidative stress, which is a key factor in the pathogenesis of various diseases, including liver diseases. As a powerful natural antioxidant, MF exhibits a wide range of hepatoprotective effects, making it a promising candidate for liver disease therapy. In this review, we systematically examine the source and chemical properties, synthetic pathways, pharmacokinetic characteristics, and bioavailability enhancement strategies of MF. Furthermore, we explore its mechanisms of action in treating liver diseases, with a focus on its antioxidative properties and their role in modulating liver disease progression. Given the growing burden of liver disease and the limitations of current therapies, this review aims to promote the clinical application of MF as a therapeutic candidate, paving the way for innovative therapeutic strategies for liver diseases. Full article

Pollution with heavy metals, such as cadmium (Cd), can significantly affect insect growth, development, and behavior. The midgut is an essential organ for stress response. Chitin synthase-2 (CHS-2) is closely associated with forming the peritrophic membrane (PM). The fourth-instar larvae of Aedes albopictus were exposed to varying concentrations of Cd. The results showed that Cd inhibited chitin synthesis and metabolism-related genes, but thickened the midgut PM, indicating that the larvae could respond to Cd stress through the midgut PM. Silencing CHS-2 by RNA interference resulted more severe vacuolization and malformation of midgut epithelial cells without midgut PM protection. Additionally, there was an intensified redox reaction, upregulated expression of metallothionein (MT) and heat shock proteins 70 (HSP70), and increased activity of antioxidant enzymes at some scattered time points. This study confirms that CHS-2 is involved in oxidative stress induced by Cd exposure by regulating PM formation. This study also contributes to further understanding the resistance mechanism of Ae. albopictus under Cd stress, thereby establishing a theoretical foundation for the future studies of them, which is concerned with the possibility of Ae. albopictus as a water environment detection and the control of Ae. albopictus based on resistance mechanism. Full article

Background: Metabolic Syndrome (MetS) is a multifactorial condition characterized by insulin resistance, dyslipidemia, hypertension, and abdominal obesity, which collectively increase the risk of type 2 diabetes mellitus and cardiovascular diseases. Lifestyle modification represents the first-line strategy in its management, whereas pharmacological interventions are complex and typically require long-term polypharmacotherapy. In this context, natural bioactive compounds with pleiotropic effects are gaining increasing attention. Among these, S-allyl cysteine (SAC), the major sulfur-containing compound derived from black garlic, has been identified as a promising candidate due to its well-documented antioxidant and anti-inflammatory properties. Methods: This narrative review examines the pathophysiological mechanisms underlying MetS and summarizes current evidence on the protective role of SAC against key pathological features of this condition, including oxidative stress, inflammation, glucose and lipid dysmetabolism, endothelial dysfunction, and gut microbiota alterations. Results: Preclinical studies indicate that SAC counteracts lipid accumulation, insulin resistance, endothelial dysfunction, and gut dysbiosis through multiple mechanisms, including hydrogen sulfide release, reactive oxygen species scavenging, inhibition of advanced glycation end products, and modulation of metabolic pathways. Conclusions: SAC emerges as a promising nutraceutical for the prevention and management of MetS and its complications. This underscores the broader relevance of nutraceuticals as promising tools in mitigating metabolic dysfunctions and reducing the burden of cardiometabolic diseases. Full article

Ochratoxin A (OTA) is a major mycotoxin contaminant in grapes and their products, and Aspergillus carbonarius is its main producer. Controlling the growth of A. carbonarius is therefore critical for mitigating OTA contamination. Plant-derived perillaldehyde, with good antifungal activity and safety, has garnered growing attention. However, current understanding of how perillaldehyde affects A. carbonarius growth and OTA production remains poorly characterized. In this study, we systematically investigated the antifungal and antimycotoxigenic effects of perillaldehyde against A. carbonarius and explored the underlying mechanisms. The results showed that perillaldehyde could alter the mycelial morphology and damage the cell integrity of A. carbonarius. Additionally, perillaldehyde could diminish the total antioxidant capacity and impair the energy metabolism of A. carbonarius. Transcriptome analysis showed that the expressions of all the known conserved OTA biosynthetic genes and two OTA transport-related genes were significantly down-regulated, indicating that perillaldehyde could directly inhibit their expression. In conclusion, perillaldehyde can significantly inhibit OTA production by directly disrupting OTA biosynthesis and transport and inhibiting the growth of A. carbonarius. Thus, perillaldehyde has the potential to be used as a natural fungicide or alternative food preservative in grapes and their products, owing to its strong antifungal and antimycotoxigenic effects on A. carbonarius. Full article

Inflammatory bowel disease (IBD) is a multifactorial and complex condition of the gastrointestinal tract shaped by host genetics, immune dysregulation, gut microbiota and environmental determinants, with a steadily rising global prevalence. Although the etiology of IBD remains incompletely understood, chronic inflammation accompanied by oxidative stress, immune dysregulation, and gut dysbiosis is widely recognized as a hallmark of the condition. Given the frequent occurrence of undernutrition in IBD patients, the role of vitamins and micronutrients in modulating disease activity has been recently explored. Selenium (Se) is universally recognized as an essential trace element due to its diverse physiological functions, including potent antioxidant activity, anti-inflammatory effects, immunomodulatory properties, and the ability to influence gut microbial composition and diversity. This comprehensive review examines current evidence on the relationship between Se status and IBD, integrating epidemiological and experimental findings, elucidating the underlying biological mechanisms, and introducing Se nanoparticles, a viable therapeutic option using Se in IBD management. Full article

Ahuehuete (Taxodium mucronatum Ten.) is a riparian tree species of significant ecological, cultural, and economic importance, demonstrating remarkable tolerance to prolonged flooding. However, the underlying mechanism of waterlogging adaptation remains unknown. In this study, we determined the physiological traits of the Ahuehuete leaves at 0, 15, 30, and 60 d under waterlogging conditions. The results showed that no significant difference in MDA content occurred between the Ahuehuete leaves subjected to waterlogging and those under well-watered (CK) conditions. In contrast, the contents of osmoprotectants (soluble sugar, soluble protein, and proline) and the activities of antioxidant enzymes (SOD, POD, and CAT) exhibited similar change trends under both waterlogging and CK conditions, despite minor quantitative differences between the two groups. Subsequent comparative transcriptome analysis was performed to investigate the transcriptional characteristics. A total of 3687 DEGs were expressed in all comparisons throughout the waterlogging process, while 2873, 4617, and 2710 DEGs were comparison group specific. KEGG enrichment analysis revealed that DEGs were enriched in various metabolic pathways, such as Plant hormone signal transduction (ko04075), MAPK signaling pathway-plant (ko04016), ABC transporter (ko02010), and Nitrogen metabolism (ko00910). WGCNA also identified key modules associated with physiological traits, simultaneously emphasizing the importance of plant hormone signal transduction and MAPK signal cascade. Overall, our findings revealed physiological and transcriptomic characteristics of the Ahuehuete under waterlogging conditions, and provided new insights to waterlogging adaptation in woody gymnosperm species. Full article

The retention of polyphenols in thermally processed noodles is constrained by interactions with starch and glutenin, critically impacting functional properties (antioxidant activity, starch digestibility modulation) and quality attributes. Current understanding lacks quantitative links between initial pomace particle size, polyphenol behavior throughout processing, and the resulting noodle properties. This study systematically investigated how Rosa roxburghii pomace particle size (0.1–250 μm), fractionated into five ranges, governs polyphenol extractability, retention in fresh/boiled noodles, and their functional and quality outcomes. Mathematical modeling established quantitative particle size–property relationships. The results indicated that polyphenol release was maximized at the 1–10 μm particle size. Total phenolic retention in boiled noodles was highest with 0.1–1 μm pomace, while the retention of specific phenolics peaked with 60–80 μm pomace. Fresh noodle hardness and gumminess decreased significantly, particularly with extracts from 1 to 40 μm pomace, whereas boiled noodles showed increased chewiness/adhesiveness. All polyphenol-enriched noodles exhibited suppressed starch digestibility and enhanced antioxidant capacity. Robust quadratic regression models predicted key properties based on particle size. Molecular interactions (hydrogen bonding, hydrophobic contacts, π–cation stacking, salt bridges) between key phenolics (EGCG, hydroxybenzoic acid, gallic acid, quercetin, and isoquercitrin) and the gluten–starch matrix, critically involving residues Arg-86 and Arg-649, were identified as the underlying mechanism. These results demonstrate that precise control of pomace particle size regulates extract composition and molecular binding dynamics, providing a strategic approach to optimize functional noodle design. Full article