Search Results (236)

Reactive oxygen species (ROS) play a dual role as both essential signaling molecules and harmful mediators of damage. Imbalances in the redox state of the liver can overwhelm antioxidant defenses and promote mitochondrial dysfunction, oxidative damage, and inflammation. Complex feedback loops between ROS and immune signaling pathways are a hallmark of pathological liver conditions, such as hepatic ischemia–reperfusion injury (IRI). This is a major cause of liver transplant failure and is of increasing significance due to the increased use of marginally discarded livers for transplantation. This review outlines the major enzymatic and metabolic sources of ROS in hepatic IRI, including mitochondrial reverse electron transport, NADPH oxidases, cytochrome P450 enzymes, and endoplasmic reticulum stress. Hepatocyte injury activates redox feedback loops that initiate immune cascades through DAMP release, toll-like receptor signaling, and cytokine production. Emerging regulatory mechanisms, such as succinate accumulation and cytosolic calcium–CAMKII signaling, further shape oxidative dynamics. Pharmacological therapies and the use of antioxidant and immunomodulatory approaches, including nanoparticles and redox-sensitive therapeutics, are discussed as protective strategies. A deeper understanding of how redox and immune feedback loops interact is an exciting and active area of research that warrants further clinical investigation. Full article

This study details how 3-(naphthalen-2-yl)-1-phenylprop-2-en-1-one (3NPEO) behaves in terms of photophysics when exposed to different solvents. The solvatochromic effect study reveals significant polarity shifts in the excited states of the 3NPEO compound, likely due to an intramolecular proton transfer mechanism. Measurements of dipole moments provide insight into their resonance structures in both ground and excited states. Electrochemical analysis revealed a reversible redox process, indicating a favorable charge transport potential. HOMO and LUMO energies of the compound were computed via oxidation and reduction potential standards. 3NPEO exhibits optimal one-photon and two-photon absorption characteristics, validating its suitability for visible wavelength laser applications in photonic devices. Furthermore, molecular docking and dynamics simulations demonstrated strong interactions between 3NPEO and the progesterone receptor enzyme, supported by structure–activity relationship (SAR) analyses. In vitro cytotoxicity assays on the MDAMB-231 breast cancer cell line showed moderate tumor cell inhibitory activity. Apoptosis studies confirmed the induction of both early and late apoptosis. These findings suggest that 3NPEO holds promise as a potential anticancer agent targeting the progesterone receptor in breast cancer cells. Overall, the findings highlight the substantial influence of solvent polarity on the photophysical properties and the design of more effective and stable therapeutic agents. Full article

Estrogens are considered the most important risk factor for the development of breast cancer. Therefore, attempts are being made to reduce their level through diminished synthesis on one hand and to protect against the formation of DNA-damaging estrogen metabolites on the other. Cytochromes P450 (CYPs) play key roles in estrogen synthesis and catabolism, leading to potentially carcinogenic metabolites. CYP19 (aromatase) catalyzes the conversion of androgens to estrogens. The estrogen receptor-dependent pathway induces cell growth. CYP1 family enzymes, particularly CYP1B1, are involved in the redox cycling of estrogen metabolites and the subsequent estrogen–DNA adducts formation. Naturally occurring phytochemicals of different classes were shown to modulate the CYP expression and activity in cell-free systems or breast cancer cells. One of the most promising CYP19 inhibitors is chrysin (flavone), while stilbenes seem to be the most effective CYP1B1 inhibitors. In most cases, their effect is not specific. Therefore, different approaches are made to find the best candidate for the drug prototype of a new therapeutic or chemopreventive agent and to improve its pharmacokinetic parameters. This review presents and discusses the possible effects on major CYPs involved in estrogen metabolism by phytochemicals from the most investigated classes, namely flavonoids, stilbenes, and glucosinolates breakdown products. Full article

Oxidative stress overwhelms cellular antioxidant defenses, causing DNA damage and pro-tumorigenic signaling that accelerate cancer initiation and progression. Electron shuttles (ESs) from phytocompounds offer precise redox control but lack quantitative benchmarks. This study aims to give a clearer definition to electron shuttles by characterizing mulberry’s electrochemical capabilities via the three defined ES criteria and deciphering its mechanism against oxidative stress-related cancer. Using double-chambered microbial-fuel-cell power metrics, cyclic voltammetry, and compartmental fermentation modeling, we show that anthocyanin shows a significant difference (p < 0.05) in power density at ≥500 µg/mL (maximum of 2.06-fold power-density increase) and reversible redox cycling (ratio = 1.65), retaining >90% activity over four fermentation cycles. Molecular docking implicates meta-dihydroxyl motifs within the core scaffold in receptor binding, overturning the view that only ortho- and para-substituents participate in bioactivity. In vitro, anthocyanins both inhibit nitric oxide release and reduce DU-145 cell viability dose-dependently. Overall, our findings establish mulberry anthocyanins as robust electron shuttles with potential for integration into large-scale bio-electrochemical platforms and targeted redox-based cancer therapies. Full article

Cancer is hallmarked by uncontrolled cell proliferation and enhanced cell survival, driven by a complex interplay of factors—including genetic and epigenetic changes—that disrupt metabolic and signaling pathways and impair organelle function. While the roles of mitochondria and the endoplasmic reticulum in cancer are widely recognized, emerging research is now drawing attention to the involvement of peroxisomes in tumor biology. Peroxisomes are essential for lipid metabolism, including fatty acid α- and β-oxidation, the synthesis of docosahexaenoic acid, bile acids, and ether lipids, as well as maintaining redox balance. Despite their critical functions, the role of peroxisomes in oncogenesis remains inadequately explored. Prostate cancer (PCa), the second most common cancer in men worldwide, exhibits a unique metabolic profile compared to other solid tumors. In contrast to the glycolysis-driven Warburg effect, primary PCa relies primarily on lipogenesis and oxidative phosphorylation. Peroxisomes are intricately involved in the metabolic adaptations of PCa, influencing both disease progression and therapy resistance. Key alterations in peroxisomal activity in PCa include the increased oxidation of branched-chain fatty acids, upregulation of α-methylacyl coenzyme A racemase (a prominent PCa biomarker), and downregulation of 1-alkyl-glycerone-3-phosphate synthase and catalase. This review critically examines the role of peroxisomes in PCa metabolism, progression, and therapeutic response, exploring their potential as biomarkers and targets for therapy. We also consider their relationship with androgen receptor signaling. A deeper understanding of peroxisome biology in PCa could pave the way for new therapies to improve patient outcomes. Full article

Plasma non-transferrin-bound iron (NTBI) comprises multiple subspecies, classified by their composition, chemical reactivity, and susceptibility to chelation. The redox-active and chelatable fraction of NTBI is referred to as labile plasma iron (LPI). The pathophysiological significance of NTBI and LPI lies in their ability to enter cells via alternative transport pathways that are not regulated by the transferrin receptor system or by cellular iron levels. Several mechanisms have been proposed for their cellular entry, including the hijacking of divalent metal transporters and passive diffusion. This unregulated uptake can lead to iron accumulation in vulnerable tissues such as the liver and the heart. NTBI and LPI bypassing normal cellular control mechanisms can rapidly exceed the cell’s capacity to safely store excess iron, leading to toxicity. Both NTBI and LPI contribute to oxidative stress by participating in free-radical-generating reactions. However, LPI concentration in the bloodstream may be differentially affected by the mode and extent of iron overload, the presence of residual serum iron-binding activity, and the antioxidant capacity of individual sera. In summary, both NTBI and LPI contribute to iron-mediated toxicity but differ in terms of reactivity, availability, and pathogenic potential depending on the pathophysiological conditions that influence the degree of toxicity. Full article

In this study, we investigated the potential of a three-mushroom complex extract (GMK) to inhibit neuronal cell death induced by the activation of AMPA and NMDA receptors following glutamate treatment in NGF-differentiated PC12 neuronal cells. GMK significantly mitigated glutamate-induced excitotoxic neuronal apoptosis by reducing the elevated expression of BAX, a critical regulator of apoptosis, and restoring BCL2 levels. These neuroprotective effects were associated with redox regulation, as evidenced by the upregulation of SOD, CAT, and GSH levels, and the downregulation of MDA levels. Mechanistic studies further revealed that GMK effectively scavenged ROS by downregulating NOX1, NOX2, and NOX4, while upregulating NRF1, P62, NRF2, HO1, and NQO1. Additionally, in the same model, GMK treatment increased acetylcholine, choline acetyltransferase, and GABA levels while reducing acetylcholinesterase activity. These effects were also attributed to the regulation of redox balance. Furthermore, we investigated the antioxidant and anti-inflammatory mechanisms of GMK in LPS-stimulated BV2 microglia. GMK inhibited the activation of IκB and MAPK pathways, positively regulated the BCL2/BAX ratio, suppressed TXNIP activity, and upregulated NQO1 and NOX1. In conclusion, GMK improved neuronal excitotoxicity and microglial inflammation through the positive modulation of the redox regulatory system, demonstrating its potential as a natural resource for pharmaceutical applications and functional health foods. Full article

Cardiac hypertrophy represents a central manifestation of hypertension-mediated organ damage (HMOD), which consists of structural and functional changes as a response to sustained pressure overload. Oxidative stress and inflammation play central roles in the development of cardiac hypertrophy, contributing to myocardial remodeling in association with mechanical stress and neurohormonal activation. The imbalance between the production of reactive oxygen species and antioxidant defense mechanisms is associated with the activation of signaling pathways and the expression of genes involved in the development and progression of cardiac fibrosis and hypertrophy. Oxidative stress is also related to mitochondrial dysfunction, redox-sensitive transcription factors, post-translational modifications, and epigenetic modulation. Novel therapeutic strategies can target these molecular pathways, reducing the impact of hypertension on HMOD. Type-2 sodium glucose transporter inhibitors were shown to restore mitochondrial bioenergetics, reducing oxidative stress, and suppressing inflammation. Also, glucagon-like peptide-1 receptor agonists reduce ROS generation and stabilize mitochondrial structure and function. In addition, vericiguat, which represents an approach targeted to restore nitric oxide-soluble guanylate cyclase signaling, might represent a valuable therapeutic approach, working to prevent and slow the progression of cardiac hypertrophy before the development of heart failure. In this review we will describe the pathophysiological mechanisms associated with cardiac hypertrophy and discuss the recent innovative therapeutic strategies with potential implications for prevention and management. Full article

Heart failure represents the terminal stage in the development of many cardiovascular diseases, and its pathological mechanisms are closely related to disturbances in energy metabolism and mitochondrial dysfunction in cardiomyocytes. In recent years, nicotinamide adenine dinucleotide (NAD⁺), a core coenzyme involved in cellular energy metabolism and redox homeostasis, has been shown to potentially ameliorate heart failure through the regulation of mitochondrial function. This review systematically investigates four core mechanisms of mitochondrial dysfunction in heart failure: imbalance of mitochondrial dynamics, excessive accumulation of reactive oxygen species (ROS) leading to oxidative stress injury, dysfunction of mitochondrial autophagy, and disturbance of Ca²⁺ homeostasis. These abnormalities collectively exacerbate the progression of heart failure by disrupting ATP production and inducing apoptosis and myocardial fibrosis. NAD⁺ has been shown to regulate mitochondrial biosynthesis and antioxidant defences through the activation of the deacetylase family (e.g., silent information regulator 2 homolog 1 (SIRT1) and SIRT3) and to increase mitochondrial autophagy to remove damaged mitochondria, thus restoring energy metabolism and redox balance in cardiomyocytes. In addition, the inhibition of NAD⁺-degrading enzymes (e.g., poly ADP-ribose polymerase (PARP), cluster of differentiation 38 (CD38), and selective androgen receptor modulators (SARMs)) increases the tissue intracellular NAD⁺ content, and supplementation with NAD⁺ precursors (e.g., β-nicotinamide mononucleotide (NMN), nicotinamide riboside, etc.) also significantly elevates myocardial NAD⁺ levels to ameliorate heart failure. This study provides a theoretical basis for understanding the central role of NAD⁺ in mitochondrial homeostasis and for the development of targeted therapies for heart failure. Full article

Despite improvements in therapeutic approaches like immunotherapy and gene therapy, cancer still remains a serious threat to world health due to its high incidence and mortality rates. Limitations of conventional therapy include suboptimal targeting, multidrug resistance, and systemic toxicity. A major challenge in current oncology therapies is the development of new delivery methods for antineoplastic drugs that act directly on target. One approach involves the complexation of antitumor drugs with cyclodextrins (CDs) and chitosan (CS) as an attempt to counteract their primary limitations: low water solubility and bioavailability, diminished in vitro and in vivo stability, and high dose-dependent toxicity. All those drawbacks may potentially exclude some therapeutic candidates from clinical trials, thus their integration into smart delivery systems or drug-targeting technologies must be implemented. We intended to overview new drug delivery systems based on chitosan or cyclodextrins with regard to the current diagnosis and cancer management. This narrative review encompasses full-length articles published in English between 2019 and 2025 (including online ahead of print versions) in PubMed-indexed journals, focusing on recent research on the encapsulation of diverse antitumor drugs within those nanosystems that exhibit responsiveness to various stimuli such as pH, redox potential, and folate receptor levels, thereby enhancing the release of bioactive compounds at tumor sites. The majority of the cited references focus on the most notable research, studies of novel applications, and scientific advancements in the field of nanostructures and functional materials employed in oncological therapies over the last six years. Certainly, there are additional stimuli with research potential that can facilitate the drug’s release upon activation, such as reactive oxygen species (ROS), various enzymes, ATP level, or hypoxia; however, our review exclusively addresses the aforementioned stimuli presented in a comprehensive manner. Full article

As a moonlighting protein with multiple enzymatic activities, peroxiredoxin 6 (PRDX6) maintains redox homeostasis, regulates phospholipid metabolism, and mediates intra- and inter-cellular signaling transduction. Its expression and activity can be regulated by diverse stressors. However, the roles and relevant mechanisms of these regulators in various conditions have yet to be comprehensively reviewed. In this study, these stressors were systematically reviewed both in vivo and in vitro and classified into chemical, physical, and biological categories. We found that the regulatory effects of these stressors on PRDX6 expression were primarily mediated via key transcriptional factors (e.g., NRF2, HIF-1α, SP1, and NF-κB), micro-RNAs, and receptor- or kinase-dependent signaling pathways. Additionally, certain stressors, including reactive oxygen species, pH fluctuations, and post-translational modifications, induced the structure-based functional switches in the PRDX6 enzyme. We further reviewed the altered expression of PRDX6 under various disease conditions, with a particular focus on neuropsychiatric disorders and cancers, and proposed the concept of PRDX6-related disorders (PRD), which refers to a spectrum of diseases mediated by or associated with dysregulated PRDX6 expression. Finally, we found that an exogenous supplementation of PRDX6 protein provided preventive and therapeutic potentials for oxidative stress-related injuries in both in vivo and in vitro models. Taken together, this review underscores the critical role of PRDX6 as a cellular orchestrator in response to various stressors, highlighting its clinical potential for disease monitoring and the development of therapeutic strategies. Full article

Superoxide dismutase (SOD), a key antioxidant enzyme, plays a crucial role in neutralizing reactive oxygen species (ROS) and maintaining redox balance. However, SOD is highly susceptible to glycation, a non-enzymatic modification induced by reducing sugars and reactive carbonyl species such as methylglyoxal. This review aims to provide a comprehensive analysis of SOD glycation, examining its biochemical mechanisms, its impact on enzymatic function, and its role in the progression of oxidative stress-related diseases. Additionally, it explores potential therapeutic strategies to prevent SOD glycation and restore its activity, highlighting translational applications for disease management. The review examines research on SOD glycation and its pathological consequences in diabetes complications, neurodegenerative disorders, and cardiovascular diseases. Key therapeutic interventions, including advanced glycation end-product (AGE) inhibitors (aminoguanidine, pyridoxamine), antioxidants (N-acetylcysteine, alpha-lipoic acid), SOD mimetics (MnTBAP, Tempol), enzyme stabilizers (thymoquinone, alliin), and receptor for advanced glycation end-products (RAGE) blockade, are analyzed for their efficacy in mitigating oxidative stress. SOD glycation reduces enzymatic activity, leading to elevated ROS levels and inflammation. Glycated SOD interacts with RAGE, increasing oxidative stress biomarkers. AGE inhibitors reduce carbonyl stress, whereas antioxidants lower ROS levels. SOD mimetics restore up to 85% of enzymatic activity, and enzyme stabilizers protect SOD from structural degradation. Additionally, monoclonal antibodies targeting RAGE have been shown to reduce inflammatory cytokines and improve mitochondrial function. SOD glycation is a major contributor to oxidative stress-related diseases. Preventing glycation and restoring SOD function through a multifaceted therapeutic approach is crucial for mitigating disease progression. By elucidating the role of SOD in disease pathogenesis, this review contributes to the advancement of targeted therapies for oxidative stress-related conditions, including diabetes, neurodegeneration, and cardiovascular diseases. Full article

Estrogen receptor β (ERβ) is the most highly expressed subtype in the colon epithelium and mediates the protective effect of estrogen against the development of colon cancer. Indeed, the expression of this receptor is inversely related to colorectal cancer progression. Structurally estrogen-like compounds, including vitamin E components, affect cell growth by binding to ERs. In the present study, cell proliferation was measured by cell counting in a Bürker hemocytometer, and ERβ expression was measured by Real-Time qPCR and immunoenzymatic methods. The results obtained show that natural δ-tocopherol (δ-Toc) and two of its semi-synthetic derivatives, bis-δ-tocopheryl sulfide (δ-Toc)₂S and bis-δ-tocopheryl disulfide (δ-Toc)₂S₂, play an antiproliferative role and upregulate ERβ expression, similar to 17-β-estradiol (17β-E2), in human colon adenocarcinoma HCT8 cells engineered to overexpress ERβ protein (HCT8-β8). These events are not present in HCT8-pSV2neo and in HCT8-β8 pretreated with ICI 182,780, suggesting that they are mediated by the binding of compounds to ERβ, as also boosted by an in silico assay. The antiproliferative effect is independent of the intracellular redox state and (δ-Toc)₂S and (δ-Toc)₂S₂ reduce cell proliferation at concentrations lower than that of δ-Toc and all tested compounds are also able to upregulate ERβ expression. Taken together, the data indicate that, through the involvement of ERβ activity and expression, δ-Toc, (δ-Toc)₂S, and (δ-Toc)₂S₂ may provide potential therapeutic support against colorectal cancer. Full article

The response of ryanodine receptor (RyR) channels to increases in free cytoplasmic calcium concentration ([Ca²⁺]) is tuned by several mechanisms, including redox signaling. Three different responses to [Ca²⁺] have been described in RyR channels, low, moderate and high activity responses, which depend on the RyR channel protein oxidation state. Thus, reduced RyR channels display the low activity response, whereas partially oxidized channels display the moderate response and more oxidized channels, the high activity response. As described here, RyR channels from rat brain cortices or hippocampi displayed aged-related marked changes in the distribution of these channel responses; RyR channels from aged rats displayed reduced fraction of low activity channels and increased fraction of high activity channels, which would favor Ca²⁺-induced Ca²⁺ release. In addition, compared with young rats, aged rats displayed learning and memory defects, with lower hit rates when tested in the Oasis maze, a dry version of the Morris water maze. Previous oral administration of N-acetylcysteine for 3 weeks prevented both the age-dependent effects on RyR channel activation by [Ca²⁺], and the learning and memory defects. Based on these results, it is proposed that redox-sensitive neuronal RyR channels partake in the mechanism underlying the learning and memory disruptions displayed by aged rats. Full article

The interplay between oxidative stress and adipogenesis is a critical factor in the development of obesity and its associated metabolic disorders. Excessive reactive oxygen species (ROS) disrupt key transcription factors such as peroxisome proliferator-activated receptor gamma (PPARγ) and CCAAT/enhancer-binding protein alpha (C/EBPα), impairing lipid metabolism, promoting adipocyte dysfunction, and exacerbating inflammation and insulin resistance. Antioxidants, classified as endogenous (e.g., glutathione, superoxide dismutase, and catalase) and exogenous (e.g., polyphenols, flavonoids, and vitamins C and E), are pivotal in mitigating these effects by restoring redox balance and preserving adipocyte functionality. Endogenous antioxidants neutralize ROS and safeguard cellular structures; however, under heightened oxidative stress, these defenses are often insufficient, necessitating dietary supplementation. Exogenous antioxidants derived from plant-based sources, such as polyphenols and vitamins, act through direct ROS scavenging, upregulation of endogenous antioxidant enzymes, and modulation of key signaling pathways like nuclear factor kappa B (NF-κB) and PPARγ, reducing lipid peroxidation, inflammation, and adipocyte dysfunction. Furthermore, they influence epigenetic regulation and transcriptional networks to restore adipocyte differentiation and limit lipid accumulation. Antioxidant-rich diets, including the Mediterranean diet, are strongly associated with improved metabolic health, reduced obesity rates, and enhanced insulin sensitivity. Advances in personalized antioxidant therapies, guided by biomarkers of oxidative stress and supported by novel delivery systems, present promising avenues for optimizing therapeutic interventions. This review, “Crosstalk Between Antioxidants and Adipogenesis: Mechanistic Pathways and Their Role in Metabolic Health”, highlights the mechanistic pathways by which antioxidants regulate oxidative stress and adipogenesis to enhance metabolic health. Full article