Search Results (212)

Ungernia victoris and U. sewerzowii (Amaryllidaceae J.St.-Hil.) are rare medicinal species of Central Asia known as sources of biologically active alkaloids, including galantamine. In this study, antioxidant activity was comparatively evaluated across different types of plant material, including natural populations, botanical garden specimens, in vitro regenerants, callus cultures, in vitro obtained bulbs, and seeds. Micropropagation systems based on direct and indirect organogenesis were developed using Murasige and Skoog and Vollosovich et al. media with various plant growth regulator combinations. Antioxidant activity was determined with the use of DPPH and ABTS assays and expressed as IC₅₀ values. Significant variability was observed depending on population origin, type of biological material, and in vitro cultivation conditions. U. sewerzowii demonstrated higher antioxidant activity than U. victoris in natural populations. The highest activity was recorded in callus cultures, whereas in vitro-derived bulbs showed relatively low activity. A strong positive correlation between DPPH and ABTS assays confirmed the reliability of the results and indicated the contribution of multiple types of secondary metabolites. These findings highlight the potential of Ungernia callus cultures as a promising biotechnological platform for the production of antioxidant-active compounds and support sustainable utilization strategies. Full article

Elabela (ELA/APELA/Toddler) is an endogenous peptide ligand of the apelin receptor APLNR (also known as APJ) and, together with apelin, forms the apelinergic signalling system. Its role in embryonic development, the cardiovascular system, the kidneys and the endothelium is becoming increasingly well characterised, whilst its function in metabolic regulation remains unresolved. Elabela activates pathways essential for metabolic homeostasis—PI3K/Akt, AMPK-related pathways, redox regulation, inflammatory control and pro-survival cascades—but no study has shown that it directly regulates adipocyte lipid metabolism. This narrative review categorises the evidence at the receptor, organ, immunometabolic and intra-adipocyte levels, and also considers the adipose tissue microenvironment as a distinct level of potential relevance. The available data support a role for Elabela as a candidate mediator of lipid-related metabolic dysfunction—via anti-inflammatory, antioxidant and tissue-protective mechanisms—with macrophage lipid metabolism representing the most informative immunometabolic interface. Human studies remain scarce, heterogeneous and limited by a lack of standardisation in assay methods and the unresolved specificity of isoforms. Elabela should therefore be regarded as a candidate indirect modulator of metabolic homeostasis and a candidate biomarker of cardiometabolic stress or adaptation—not as a confirmed direct regulator of adipocyte lipid metabolism. Full article

Food spoilage from microbial contamination and oxidation drives the search for natural preservatives. Phenolic acids (PAs) and phenolamides are plant-sourced metabolites with broad-spectrum antimicrobial and antioxidant activities. This review comprehensively examines their sources, classification, structure–activity relationships, and multi-target mechanisms. PA antimicrobial action involves membrane disruption, intracellular acidification, and oxygen species generation, while antioxidant effects rely on hydrogen donation and metal chelation. For phenolamides, antimicrobial evidence is largely indirect, based on computational docking and one non-food nucleotide biosynthesis study, and direct validation of these mechanisms in food matrices against common foodborne pathogens is lacking. Delivery strategies (direct incorporation, encapsulation, edible coatings, active packaging) are critically evaluated, with emphasis on PA-grafted chitosan systems. Applications of PAs in fruits, vegetables, meat, aquatic products, and lipid-rich emulsions are summarized. Phenolamide applications are limited by low natural abundance, high purification costs, poor aqueous solubility, and a historical bias toward pharmacology. Safety assessments confirm favorable profiles for many PAs and select phenolamides, though chronic toxicity data for phenolamides remain limited. This review provides a theoretical framework for leveraging PAs and emerging phenolamides as natural preservatives and identifies critical knowledge gaps requiring future investigation. Full article

The coexistence of microplastics (MPs) and heavy metals (Cd, Pb) in agricultural soils has become a global environmental and ecological risk. In this study, a pot experiment was conducted to investigate the effects of different concentrations of polyethylene (PE) microplastics and combined Cd/Pb contamination on the growth and development, heavy metal accumulation, and antioxidant system of tobacco (Nicotiana tabacum L. cv. Yunyan 87). The results showed that low-dose PE and low concentrations of heavy metals had minor impacts on tobacco growth and the antioxidant system; in contrast, high-dose PE and elevated heavy metal treatments markedly induced increases in malondialdehyde content (MDA) and enhanced the activities of superoxide dismutase (SOD), catalase (CAT), and peroxidase (POD). Under co-contaminated conditions, the addition of low-dose PE reduced the translocation capacity of heavy metals, alleviated heavy metal-induced oxidative stress responses, and promoted tobacco growth. Conversely, high-dose PE promoted the translocation of Cd into tobacco plants and increased Cd contents in tobacco leaves, leading to marked decreases in soluble protein and soluble sugar contents, and causing severe reductions in plant height, number of functional leaves, and biomass. Structural equation modeling (SEM) analysis revealed that the direct effect of PE on tobacco growth was not significant; instead, it primarily acted as a regulatory factor, exerting either promotional or inhibitory effects on tobacco growth at different doses. The impact of Cd/Pb on tobacco growth appeared to involve two potential pathways. On the one hand, Cd/Pb induced direct toxicity through their accumulation within tobacco tissues. On the other hand, they exerted indirect regulation primarily by modulating the activities of the tobacco antioxidant system. Full article

Background/Objectives: Rotenone (RT)-induced neurotoxicity is widely used to model Parkinsonism-like nigrostriatal injury and recapitulates several PD-relevant pathological features, including oxidative stress, mitochondrial dysfunction, neuroinflammation, and dopaminergic neurochemical disturbance. Loganin (LG), an iridoid glycoside isolated from Cornus officinalis, has been reported to possess antioxidant, anti-inflammatory, anti-apoptotic, and neuroprotective properties. However, its protective effects in a unilateral stereotaxic RT lesion model have not been fully elucidated. This study aimed to investigate the neuroprotective potential of LG against RT-induced Parkinsonism-like pathology in rats and to explore the possible involvement of antioxidant-related signaling mechanisms. Methods: Adult male Wistar rats were randomly assigned to twelve experimental groups (n = 8/group), including control, sham, RT, sham + LG, RT + LG, RT + trigonelline (TG) + LG, and RT + selegiline (SL). RT was stereotaxically injected once into the right substantia nigra pars compacta (SNpc) on Day 0 to induce unilateral nigrostriatal injury. LG was administered orally once daily from Day 1 to Day 21 at doses of 3, 10, and 30 mg/kg. TG was given intraperitoneally 30 min before LG treatment, while SL served as a reference antiparkinsonian drug. Behavioral assessments and biochemical analyses were conducted to evaluate motor dysfunction, oxidative and nitrosative stress, endogenous antioxidant status, mitochondrial dysfunction, inflammatory and apoptotic responses in the SNpc, and striatal catecholamine disturbances. Results: RT lesioning produced significant motor deficits, oxidative and nitrosative stress, depletion of endogenous antioxidant defenses, mitochondrial dysfunction, inflammatory and apoptotic activation in the SNpc, and abnormalities in striatal catecholamine levels. LG treatment significantly attenuated these pathological changes, with more pronounced protective effects observed at 10 and 30 mg/kg. Co-administration of TG partially weakened the beneficial effects of LG, suggesting the possible involvement of antioxidant defense-related signaling while not providing direct proof of a single pathway. SL also ameliorated RT-induced behavioral and biochemical abnormalities. Conclusions: These findings suggest that LG confers multi-target neuroprotective effects against RT-induced Parkinsonism-like features in rats. The protective actions of LG were associated with attenuation of oxidative stress, mitochondrial dysfunction, neuroinflammation, apoptosis, and catecholaminergic disturbances. Because the pathway analysis remains pharmacological and indirect, additional studies using direct molecular validation are warranted before LG can be considered a disease-modifying candidate for PD-related neurodegeneration. Full article

Using beneficial bacteria from the plant microbiome to combat pathogens is an environmentally friendly strategy for biological control. Although significant progress has been made in characterizing microorganisms with biocontrol potential, the optimal methods for applying such biological preparations to achieve maximum effectiveness against plant pathogens remain insufficiently defined. Our goal was to select rhizobacteria from the sugar beet microbiome and analyze their biocontrol capacity in both indirect and direct applications to protect the plant from Pseudomonas syringae pv. aptata P21. The methodological approach differed: indirect application involved seed priming with selected strains, Bacillus safensis MRh275, B. pseudomycoides JRh226, Stenotrophomonas maltophilia JRh266, or the T2 consortium (MRh275 and JRh266), while direct application involved simultaneous treatment of both the pathogen and the biocontrol strain. Although the direct approach resulted in a greater reduction in lesions and a lower concentration of H₂O₂, the indirect approach showed higher activity of peroxidase and superoxide dismutase as antioxidant enzymes, as well as phenylalanine ammonia-lyase, which is involved in the phenylpropanoid pathway and plant defense mechanisms. Infected plants showed higher expression of NPR1, MYC2, and LOX defense-related genes only under indirect biocontrol with all three strains, except in the T2 application. The T2 consortium performed best in direct biocontrol, where it most effectively reduced lesions. Since encounters between plants and pathogens cannot be accurately predicted, and the application of biological preparations should be easy and accessible for farmers, this study highlights the use of indirect biocontrol through seed priming to enhance the plant’s intrinsic defense capacity. Full article

Plant-derived bioactive metabolites have emerged as promising modulators of oxidative stress and inflammation, two interconnected processes involved in the pathogenesis of numerous chronic diseases. Arid ecosystems, particularly the Sonoran Desert, constitute an underexplored source of structurally diverse phytochemicals with significant pharmacological potential. This review provides a comprehensive overview of major classes of plant-derived bioactives, including polyphenols, flavonoids, terpenoids, and alkaloids, with emphasis on their molecular mechanisms of antioxidant and anti-inflammatory action. These compounds exert cytoprotective effects through direct reactive oxygen species (ROS) scavenging and indirect regulation of endogenous defense systems, primarily via activation of the Nrf2/Keap1 pathway and suppression of NF-κB signaling. Additional pathways, including MAPK, PI3K/Akt, AMPK, and mitochondrial regulatory networks, are discussed as critical mediators of redox balance and inflammatory control. Particular attention is given to Sonoran Desert plant species such as Bucida buceras, Phoradendron californicum, Larrea tridentata, Opuntia spp., and Agave deserti, all of which demonstrate promising biological activities associated with enhanced adaptation to environmental stress. Experimental approaches used to evaluate phytochemical bioactivity, including chemical assays, cellular models, omics technologies, and translational strategies, are also examined. Furthermore, this review discusses current limitations related to bioavailability, phytochemical variability, and clinical validation, highlighting emerging nanodelivery systems and precision medicine approaches as potential solutions. Collectively, the evidence supports the therapeutic relevance of Sonoran Desert plant bioactives as multi-target agents for modulating oxidative stress, inflammation, and chronic disease progression. Full article

Mulberrofuran A (MFA), a natural product originally isolated from the root bark of Morus alba L. (Sang-Bai-Pi), is a structurally distinctive mulberry-derived 2-arylbenzofuran bearing a prenyl-related side chain. Although MFA has attracted attention because of its phytochemical uniqueness and reported biological relevance, the available evidence specific to MFA remains limited and fragmented. In addition, pharmacological interpretations are often complicated by the frequent use of indirect evidence derived from structurally related mulberrofuran analogues, other arylbenzofurans, or complex Morus extracts. This review critically summarizes current knowledge on the chemistry, occurrence, and biological relevance of MFA, while explicitly distinguishing direct MFA-specific evidence from indirect and contextual evidence. Available studies suggest that MFA may be associated with antimicrobial activity and modulation of arachidonic acid-related inflammatory pathways, whereas its putative roles in metabolic regulation, cardiovascular protection, antiviral activity, antioxidant effects, and anticancer relevance are currently supported mainly by structurally related compounds or broader mulberry literature rather than robust MFA-specific validation. We further discuss the limitations of the current evidence base, including methodological heterogeneity, incomplete statistical reporting, the lack of pharmacokinetic and toxicity data, and the absence of clinical validation. Rather than establishing MFA as a confirmed therapeutic agent, the available literature supports its consideration as an emerging natural product candidate that warrants rigorous chemical, pharmacological, and translational investigation. Full article

α-Crystallin, the predominant protein of the eye lens, possesses molecular chaperone activity and antioxidative properties, both of which are essential for maintaining lens transparency. Its chaperone function prevents the formation of light-scattering protein aggregates, while its antioxidative activity mitigates oxidative stress through both direct and indirect mechanisms. However, with aging, α-crystallin undergoes cumulative post-translational modifications and oxidative damage, leading to protein crosslinking and a decline in chaperone efficacy. Notably, α-crystallin exhibits free radical-scavenging activity comparable to that of serum albumin, a well-characterized antioxidant protein. In addition, its ability to bind redox-active metal ions and convert them into redox-inactive forms significantly reduces reactive oxygen species (ROS) generation in vivo. α-Crystallin also interacts with key proteins and signaling pathways involved in oxidative stress responses, further enhancing its multifunctional protective role. This review summarizes current evidence on the antioxidative properties of α-crystallin and their relationship to its chaperone function, highlighting its importance in lens homeostasis and age-related cataract formation. Full article

The use of antioxidants has become a fundamental approach in food preservation to mitigate the adverse effects of oxidative deterioration, such as lipid rancidity and protein degradation. As a result, chlorogenic acids (CGAs), natural phenolic compounds, have attracted considerable attention due to their potent antioxidant and antibacterial activity as well as their diverse bioactivities, which are primarily achieved through the direct scavenging of free radicals and indirect inhibition of signaling pathways. Based on this, this review introduces the various derivatives of CGAs and their numerous health benefits, such as hypotensive and hypoglycemic effects, anti-obesity activity, and gastrointestinal flora regulation, and discusses innovative added forms involving novel encapsulation methods such as microcapsules, nanocapsules, and hydrogels. Moreover, this paper also provides a comprehensive summary of the preservation effects and sensory evaluation of CGAs in the food field, which have been proven to significantly extend the shelf life and enhance antioxidant capability in seafood products, meat, and baked goods. Finally, it also highlights the practical limitations of CGAs, including their poor liposolubility, chemical instability, and high thermal sensitivity, as well as the need for their application in a wider range of foods and further research on their influence on sensory evaluation, in order to broaden their application as antioxidants in the future. Full article

Methylglyoxal (MG) is a reactive dicarbonyl compound generated mainly as a byproduct of glycolysis. Excess accumulation of MG can promote protein glycation and the formation of advanced glycation end-products (AGEs), which have been associated with oxidative stress, inflammation, mitochondrial dysfunction, and cellular damage. These processes are implicated in the development of several chronic conditions, including diabetes, neurodegenerative disorders, cardiovascular disease, and age-related decline. The glyoxalase system, comprising Glyoxalase I (Glo1) and Glyoxalase II (Glo2), serves as a key cellular defense mechanism that detoxifies MG and helps maintain dicarbonyl homeostasis. Among these enzymes, Glo1 catalyzes the conversion of MG into less reactive intermediates in a glutathione (GSH)-dependent manner. A range of natural compounds and dietary phytochemicals, including sulforaphane, resveratrol, α-lipoic acid, selenium, vitamin D3, and N-acetylcysteine, have been reported to modulate Glo1 activity through transcriptional regulation, antioxidant effects, or support of intracellular GSH levels. Evidence from preclinical and limited human studies suggests that these compounds may help reduce MG burden and AGE formation, although their effects are often indirect and context-dependent. However, several challenges remain, including variable bioavailability, dose-dependent responses, disease-specific differences in Glo1 regulation, and the lack of standardized biomarkers and adequate clinical validation. This review examines the MG–Glo1 axis as a mechanistic framework linking metabolic stress to disease and evaluates natural compounds as context-dependent modulators of this pathway. By integrating mechanistic insights with emerging in vivo and clinical evidence, this work highlights the potential, while acknowledging the limitations, of targeting Glo1 as a translational strategy for managing glycation-associated disorders. Full article

Annona muricata (soursop) is a tropical medicinal plant widely used in traditional medicine across Africa, the Caribbean, and parts of South America. While its ethnomedicinal applications span a range of conditions, including infections, inflammation, and anemia-related symptoms, its potential relevance to hematopoiesis has not been systematically examined. This narrative review synthesizes ethnomedicinal knowledge, phytochemical composition, and experimental evidence to explore the biological plausibility by which A. muricata may indirectly influence hematopoietic processes. Bioactive constituents of A. muricata, including flavonoids, polyphenols, and acetogenins, have demonstrated antioxidant, anti-inflammatory, and immunomodulatory properties in preclinical models. These effects are particularly relevant given the established roles of oxidative stress and chronic inflammation in disrupting hematopoietic stem and progenitor cell function and bone marrow homeostasis. Rather than proposing direct erythropoietic activity, this review emphasizes indirect, marrow-supportive mechanisms through which A. muricata may contribute to the preservation of hematopoietic function under conditions of physiological or inflammatory stress. The limitations of the current evidence base, including the predominance of in vitro and animal studies and the absence of direct hematopoietic endpoints in humans, are critically discussed. Overall, this review provides a cautious, integrative framework linking A. muricata bioactivity to hematopoietic regulation and highlights key gaps that must be addressed before any translational or clinical relevance can be established. Full article

Fish allergy, mainly caused by Parvalbumin (PV), is a worldwide health issue with few effective mitigation options. This study investigated Maillard conjugation using chitosan (CS) and various saccharides to modify the structural, functional, and allergenic properties of turbot (Scophthalmus maximus) PV. Structural analyses, including SDS-PAGE, Western blotting, FTIR spectroscopy, and Circular dichroism, confirmed successful conjugation and significant changes in secondary structure, including decreases in α-helical content and increases in β-sheet and random-coil fractions. Glycation significantly boosted antioxidant activity, with total phenolic content (TPC) increasing up to 10.3 times and DPPH radical scavenging reaching 74.5% in the CS–xylose–PV conjugate (CXTPV). Indirect ELISA revealed notable (p < 0.05), sugar-dependent reductions in IgE-binding capacity, with reductions of up to approximately 72% for CXTPV. RBL-2H3 cell assays showed decreased β-hexosaminidase release (about 75% reduction), lowered IL-6 secretion, and strong inhibition of IL-4 production, indicating reduced allergenic potential and immune regulation. CXTPV demonstrated the best overall performance. These findings suggest that CS–saccharide Maillard conjugation is an effective approach for creating hypoallergenic marine ingredients with improved bioactive properties. Full article

Microplastic pollution has become a major environmental challenge for terrestrial ecosystems; however, the mechanisms by which it affects the growth of medicinal plants and their rhizosphere microecology remain unclear. This study selected the important medicinal herb P. capitata as the research subject. A pot experiment was conducted to investigate the effects of different concentrations (0%, 1%, 4%, and 8% w/w) of polyethylene microplastics (PE-MPs) on its growth performance, physiological responses, and rhizosphere bacterial communities. The main findings are as follows: (1) PE-MPs exhibited a hormetic effect on the biomass of P. capitata. A low concentration (1%) slightly promoted total biomass (44.78 g) compared to the control (40.94 g), whereas higher concentrations caused significant inhibition. Total biomass decreased by 28.5% and 53.5% under the 4% and 8% treatments, respectively, indicating that the transition from stimulation to inhibition occurred between the 1% and 4% PE-MPs. (2) Chlorophyll a was more sensitive to stress, with its content significantly increasing under the 1% treatment but declining at higher concentrations. (3) Regarding the antioxidant system, POD activity was significantly inhibited at low and medium concentrations, while MDA content increased significantly only under the 8% treatment (by 72%). SOD and CAT showed no significant changes, indicating that POD and MDA were more sensitive indicators of oxidative damage. (4) PE-MPs significantly reduced rhizosphere bacterial community richness (Chao1 index), and the loss of microbial diversity was highly coupled with the decline in plant biomass and the exacerbation of oxidative damage. In conclusion, this study confirms a threshold effect in the toxicity of PE-MPs to P. capitata, with the transition from hormetic stimulation to toxic inhibition occurring between 1% and 4% (w/w). Furthermore, rhizosphere microecological imbalance is identified as a key indirect mechanism underlying phytotoxicity. These findings provide a new theoretical basis for understanding the potential impacts of microplastic pollution on medicinal plants and agroecosystems. Full article

Multiple myeloma (MM) is an incurable plasma cell malignancy characterized by high metabolic activity, chronic endoplasmic reticulum stress, and persistent redox imbalance. Excessive immunoglobulin synthesis and adaptation to the hypoxic bone marrow microenvironment lead to sustained production of reactive oxygen species (ROS). Their excessive accumulation promotes genomic instability, disease progression, osteolytic bone disease, and resistance to therapy. Paradoxically, MM cells adapt to oxidative stress by activating antioxidant and metabolic defense mechanisms, including Nuclear factor erythroid 2-related factor 2 (NRF2)- and Heme Oxygenase 1 (HMOX1)-dependent pathways, metabolic reprogramming, and overexpression of ROS-scavenging enzymes such as peroxiredoxin 6 (PRDX6), allowing survival at the threshold of oxidative toxicity. Evidence indicates that biomarkers of oxidative stress—such as lipid and protein oxidation products, antioxidant enzyme activity, and the Oxidative Stress Score—correlate with disease stage, prognosis, and treatment response. Redox-modulating therapeutic strategies, including pharmacological ROS induction, inhibition of antioxidant defenses, and the use of natural pro-oxidant compounds, are emerging as promising adjuncts to standard MM therapies. Recent studies also highlight the gut microbiota as an indirect regulator of oxidative balance, immune modulation, and metabolic homeostasis in MM. This review summarizes current knowledge on oxidative stress in multiple myeloma, emphasizing its role in pathogenesis, drug resistance, biomarker development, and emerging therapeutic and supportive strategies. Full article