Search Results (279)

Endothelial dysfunction (ED) is an early event in cardiovascular and metabolic diseases, including atherosclerosis, diabetes, and hypertension. Emerging evidence highlights the interplay between chronic inflammation and oxidative stress, collectively termed OxInflammation, as a major driver of vascular injury and impaired tissue repair. Among the key mediators of this response is the Nod like receptor family pyrin domain containing 3 (NLRP3) inflammasome, a multiprotein complex that promotes the release of inflammatory cytokines, including Interleukin 1β (IL-1β) and Interleukin-18 (IL-18), and induces gasdermin D-mediated pyroptotic cell death. Activation of NLRP3 disrupts endothelial function, reduces nitric oxide availability, and accelerates vascular inflammation and injury. This review discusses current evidence on pharmacological strategies targeting NLRP3 inflammasome signaling using both natural and synthetic inhibitors. Studies have shown that inhibiting NLRP3 can reduce inflammation and oxidative stress, preserve endothelial integrity, improve vascular function, and support tissue repair. Several NLRP3-targeting compounds have advanced into early-phase clinical trials, showing encouraging safety profiles and efficacy in individuals with cardiovascular risk factors. By integrating the emerging concept of OxInflammation with endothelial dysfunction, this review critically evaluates the therapeutic and translational potential of NLRP3 inflammasome inhibition in cardiovascular and metabolic disorders. Collectively, the available evidence supports NLRP3 as a promising therapeutic target for restoring endothelial homeostasis and promoting vascular repair. However, further clinical studies are needed to establish long-term efficacy, optimal dosing strategies, and appropriate patient selection criteria. Full article

Fisetin is a bioactive flavanol with reported anticancer activity, although its mechanisms in leukaemia and potential for combination therapy remain incompletely understood. This study investigated the cytotoxic and mechanistic effects of fisetin, alone and combined with pinocembrin, in human leukaemia cells. Cell viability, apoptosis, and cell cycle progression were assessed by flow cytometry; protein expression in Jurkat cells was assessed by Western blotting; and molecular docking was used to evaluate interactions with the Fas receptor. Drug interactions were quantified using ZIP synergy analysis, and cytotoxicity and clonogenic survival were evaluated using soft-agar colony formation assays in K562 cells. Fisetin significantly reduced cell viability and induced apoptosis, accompanied by caspase-8 cleavage, p62 accumulation, and CDK4 downregulation, consistent with activation of extrinsic apoptosis, impaired autophagic flux, and cell cycle inhibition in Jurkat cells. Docking analysis supported a potential interaction with the Fas receptor, which was confirmed using the Fas receptor antagonist Met-12. Co-treatment with pinocembrin enhanced fisetin-mediated cytotoxicity and produced synergistic effects, particularly in Jurkat cells (ZIP score > 10), while synergistic interactions at specific sub-IC₅₀ concentrations were also observed in K562 cells. Combination treatment further enhanced caspase-8 activation, reduced CDK4 expression in Jurkat cells, and significantly suppressed clonogenic survival in K562 cells compared with single-agent treatments. These findings suggest that fisetin promotes caspase-8-dependent apoptosis, potentially involving Fas-associated signalling, and highlight fisetin–pinocembrin combination therapy as a promising strategy for leukaemia treatment. Full article

Plants must continuously balance the trade-offs between growth and defense, a constraint that is exacerbated by biotic and abiotic stresses, particularly when they occur together. Ethylene (ET) serves as a central, integrative regulatory node controlling this by linking developmental programs to stress-responsive signaling networks. Advances at the molecular and systems levels have revealed that ET mediates the redistribution of metabolic resources via coordinated regulation of its synthesis, perception, and downstream signaling. The ETR (Ethylene Receptor)-CTR1 (Constitutive Triple Response 1)-EIN2 (Ethylene Insensitive 2)-EIN3(Ethylene Insensitive 3) signaling module lies at the core of this network, integrating multiple hormonal pathways. Through dynamic crosstalk with jasmonic acid (JA), salicylic acid (SA), abscisic acid (ABA), auxin (AUX), and gibberellins (GA), ET enables the fine-tuned coordination of growth inhibition, immune activation, and stress acclimation in response to environmental fluctuations. Processes such as induced systemic resistance, programmed cell death, and architectural plasticity further reinforce this regulatory framework, with ethylene-responsive transcription factors, including ERFs (ethylene responsive factor gene family) and WRKYs, acting as critical convergence points. Emerging insights into ACC (1-aminocyclopropane-1-carboxylic acid)-dependent signaling, chromatin remodeling, and tissue-specific regulation expand the functional scope of ET beyond traditional hormone paradigms. At the same time, the ability of pathogens to manipulate ET signaling underscores its dual role in both promoting immunity and facilitating susceptibility. By integrating molecular, physiological, and ecological perspectives, this review highlights ET as a central coordinator of plant stress resilience and growth optimization, providing a unifying framework for understanding how plants adapt to complex and dynamic environments. Full article

Background/Objectives: Myocardial infarction (MI) remains a leading cause of death worldwide, primarily resulting from abrupt coronary occlusion that induces severe hypoxia and extensive cardiomyocyte loss. Hypoxia triggers mitochondrial dysfunction, oxidative stress, inflammation, and apoptosis, ultimately compromising cardiac function and promoting adverse cardiac remodeling. MicroRNAs (miRNAs) have emerged as critical regulators of cardiomyocyte survival and stress responses under ischemic conditions; however, the functional roles and molecular mechanisms of many hypoxia-responsive miRNAs remain insufficiently defined. Methods: In this study, we focused on miR-30c-1-3p, which is markedly downregulated during the early phase of MI, and investigated its functional role in hypoxia-induced cardiomyocyte injury. We identified trinucleotide repeat-containing 6A (Tnrc6a), a key component of the miRNA-induced silencing complex, as a potential downstream target. Using primary neonatal rat cardiomyocytes, we performed gain- and loss-of-function experiments, luciferase reporter assays, and Tnrc6a knockdown analyses to evaluate apoptosis, inflammatory cytokine secretion, and release of myocardial injury-related proteins. Results: Restoration of miR-30c-1-3p significantly attenuated hypoxia-induced pro-apoptotic signaling, reduced inflammatory cytokine release, and decreased myocardial injury markers. These protective effects were associated with regulation of the miR-30c-1-3p/Tnrc6a axis. Conclusions: Collectively, our findings identify a previously unappreciated functional role of the miR-30c-1-3p/Tnrc6a axis in hypoxia-induced cardiomyocyte injury and highlight its potential relevance in myocardial stress adaptation. Full article

Cannabinoids are potential anticancer agents for the add-on treatment of malignant tumors. Here, the effects of the previously less-explored non-psychoactive phytocannabinoids cannabigerol (CBG) and cannabichromene (CBC) on survival, apoptosis, and mitochondrial function were assessed in A549 and H460 lung cancer cells. CBG and CBC triggered concentration-dependent cell death, autophagy, and mitochondrial apoptosis in both cell lines, with apoptosis indicated by Annexin V staining, activation of caspase-8, -9, and -3/7, loss of mitochondrial membrane potential, and elevated cytosolic levels of mitochondrial cytochrome c. CBG also upregulated ATF4, a stress-responsive transcription factor involved in autophagy and apoptotic signaling, and enhanced PARP cleavage. Both cannabinoids increased mitochondrial superoxide formation and reduced the mitochondrial oxygen consumption rate, with CBG additionally decreasing NDUFB8, a subunit of respiratory chain complex I. Pharmacological receptor modulation showed that CBG- and CBC-induced cell death occurred independently of CB₁, CB₂, TRPV1, TRPM8, and PPARγ, whereas CBG-mediated cell death relied on PPARα, which also contributed to its apoptotic effects. In summary, CBG and CBC induce apoptosis and cell death in A549 and H460 cells, with PPARα mediating the effects of CBG, highlighting its potential as a therapeutic target. Full article

Toll-like receptor 3 (TLR3) is a double-stranded RNA sensor that plays a dual and context-dependent role in epithelial cancers, promoting either regulated cell death (RCD) or tumor-supportive programs. While TLR3 activation has been widely explored for its capacity to induce apoptosis or necroptosis and enhance antitumor immunity, accumulating evidence indicates that cancer cells can use TLR3 signaling to sustain proliferation, migration, stemness, and therapy resistance. In this review, we provide a comprehensive and mechanistic analysis of TLR3 signaling in epithelial cancers, encompassing canonical and non-canonical modules that regulate cancer cell fate. We examine how TLR3 activation engages interconnected RCD programs, including apoptosis, necroptosis, and immunogenic cell death, and contrast these with pathways driving tumor plasticity and progression. Importantly, we discuss the key determinants governing TLR3 signaling output, including signaling complex composition; ligand origin and delivery; TLR3 subcellular localization; and cancer cell-intrinsic factors such as genetic, epigenetic, and metabolic states. We propose an integrative framework in which TLR3 signaling influences cancer cell fate according to cellular and microenvironmental context. Full article

Neurodegenerative disorders, including Alzheimer’s disease (AD), Parkinson’s disease (PD), Huntington’s disease (HD), and amyotrophic lateral sclerosis (ALS), arise from highly interconnected molecular and cellular abnormalities that progressively lead to neuronal dysfunction, synaptic failure, and cell death. This review provides a unified framework to understand the interrelated molecular mechanisms driving these diseases, with a focus on identifying key disease-specific intervention nodes. Core contributors include oxidative stress, mitochondrial dysfunction, protein aggregation, neuroinflammation, and emerging roles of peroxisomal dysfunction in redox imbalance, lipid dysregulation, and inflammatory amplification. Single-target therapies often show limited efficacy due to the complex, interconnected nature of these pathways. In contrast, polypharmacology, which targets multiple disease-relevant mechanisms simultaneously, offers a more promising therapeutic strategy. This review critically examines how pathway crosstalk drives neurodegenerative progression, with particular emphasis on mitochondrial–ROS–inflammatory signaling, aggregation–proteostasis failure, synaptic–neuroimmune dysfunction, and gut–brain communication. It evaluates various multi-node intervention strategies, including multi-target-directed ligands (MTDLs), molecular hybrids, natural products, drug repurposing, and nanocarrier-based delivery systems. Advances in network pharmacology, artificial intelligence (AI), bioinformatics, and multi-omics have enhanced the identification of actionable therapeutic nodes, candidate compounds, and brain-targeted delivery platforms. Notably, the NOD-like receptor pyrin domain-containing protein 3 (NLRP3) inflammasome and cyclic GMP–AMP synthase (cGAS)—stimulator of interferon genes (STING) pathways—play distinct roles in neuroinflammation, amplifying neuronal damage by releasing inflammatory cytokines and inducing mitochondrial dysfunction. However, successful translation into clinical practice remains constrained by challenges such as blood–brain barrier penetration, patient heterogeneity, and biomarker limitations. The review advocates for a shift towards mechanism-informed, patient-stratified polypharmacological strategies to better address the network pathology of neurodegeneration, despite significant translational hurdles. Full article

Algae rarely occur as solitary phototrophs in nature or engineering; instead, they are embedded in complex bacterial consortia that control their physiology, productivity and ecological performance. The phycosphere, a microscale niche rich in algal exudates, promotes extensive metabolic exchange and chemical signaling, defining these associations. Bacteria capitalize on the dissolved organic carbon released by algae, providing growth supporting molecules such as vitamins, trace metals, and siderophores, as well as regenerated inorganic nutrients. Bidirectional beneficial interactions range from obligate mutualism to facultative commensalism and antagonism, depending on environmental context and community membership. Bacterial partners can stimulate algal growth, morphogenesis, and stress tolerance, as well as modulating defense and programmed cell death during the decline and bloom succession of algae resulting from algicidal taxa. Metabolic cooperation, QS signaling, extracellular enzyme activity, and chemically induced gene expression produce the exometabolome in the phycosphere, which in turn reprograms gene expression in all partners. Recent advances in multi-omics toolboxes, single-cell isotopic analyses, and microfluidics have greatly enhanced our understanding of the functional and spatiotemporal orientation of algal microbiomes. Ecologically, algal–bacterial interactions manage the phytoplankton community structure, control HABs, and modulate carbon and nutrient fluxes in both marine and freshwater realms. Biotechnologically, engineered algal–bacterial consortia are a promising tool for enhancing biomass production, stabilizing large-scale cultivation, improving wastewater treatment, and upgrading biofuels and fine chemicals. Despite these notable research advances, the context- and species-dependent complexity of multispecies interactions remains a major obstacle to their practical modeling and scalable implementation. Integrative research frameworks that combine molecular, ecological, and bioengineering approaches are urgently needed to unlock the full potential of sustainable applications in the future. Full article

Plant–pathogen interactions are shaped by dynamic regulatory processes that control immune signaling. Among these, post-translational modifications (PTMs) play central roles in modulating protein activity, stability, and interaction networks. Increasing evidence indicates that Phytophthora effectors target PTM-dependent regulatory systems to suppress host immunity and promote infection. Here, we synthesize current knowledge on how Phytophthora virulence factors manipulate post-translational regulation through two mechanistically distinct strategies: (i) canonical mechanisms, involving direct enzymatic modification of host proteins or the recruitment of host PTM-modifying enzymes, and (ii) non-canonical mechanisms, in which effectors alter the activity, organization, or localization of PTM-associated regulatory systems without directly inducing covalent modification. These processes frequently involve protein–protein interactions and oligomerization-dependent regulation that reshape signaling complexes and enzymatic accessibility. By distinguishing effector-mediated PTM induction from regulatory interference, we provide a mechanistic framework for interpreting how diverse virulence strategies converge on the control of immune signaling pathways, including those governing reactive oxygen species production, transcriptional regulation, hormone signaling, and cell death. We further highlight current limitations in mechanistic understanding and emphasize the need for integrative approaches combining structural biology and proteomics to resolve how effectors reprogram host signaling systems. Full article

Purinergic signaling plays a critical role in several inflammatory diseases, including acute lung injury, inflammatory bowel disease, coronary artery diseases, and various cancers. Purine and its derivatives, specifically adenosine and ATP, exhibit a critical regulatory axis that bridges platelet activation, vascular thrombosis, and sterile inflammation. Myocardial infarction (MI) initiates a complex pathophysiological cascade characterized by profound hypoxia, inflammation response, reduced coronary blood flow, and increased oxidative stress, which leads to myocardial cell death and apoptosis. Reperfusion therapy remains a primary strategy for restoring coronary blood flow and maximally limiting infarct size; increased infarct size further exacerbates ischemic injury, making it myocardial ischemic/reperfusion injury (MIRI). In this review, we delineate the mechanistic “triad axis”, comprising adenosine signaling, hypoxia-inducible factor (HIF) stabilization, and reactive oxygen species (ROS) homeostasis; this axis serves as a pivotal determinant of cardiomyocyte death during MIRI. We further examine the cell-specific roles of adenosine signaling in modulating immune cell infiltration and function within the ischemic milieu. Finally, we highlight the emerging role of mitochondrial ROS (mtROS) and HIF-dependent signaling in circadian regulation, suggesting that the chronotherapeutic approaches targeting these pathways may offer transformative opportunities for the treatment of ischemic heart disease (IHD). Full article

Kv11.1 (hERG1) channels, encoded by KCNH2, mediate the rapid delayed rectifier potassium current (I_Kr) crucial for cardiac repolarization. Disruptions, via mutations or antiarrhythmic drugs like dofetilide cause severe arrhythmogenic disorders, including Long QT Syndrome Type 2 (LQT2), Brugada Syndrome (BrS), and Torsades de Pointes (TdP). While Kv11.1’s role in channelopathies and drug-induced arrhythmias is established, understanding its complex regulation and therapeutic targeting remains a challenge. This review synthesizes the structural, functional, and regulatory aspects of Kv11.1 channels and their clinical implications. Recent studies using iPSC-derived cardiomyocytes highlight regulation by PI3K/Akt, PKC, and PKA signaling via phosphorylation (Ser283, Ser890) and interactions with proteins like 14-3-3. Beyond electrophysiology, Kv11.1 influences pathological hypertrophy and non-cardiac functions including insulin secretion. Pharmacological efforts focus on activators to shorten action potential duration and suppress TdP, and blockers with overdose risks. Mutation heterogeneity, exemplified by trafficking impairment (G785D) in LQT2 and gain-of-function (R397C) in BrS, complicates precision therapy. Clinically, systematic risk stratification using electrocardiographic parameters and genotype-specific approaches enables personalized management. Beta-blockers remain first-line therapy for LQTS2, while rigorous avoidance of QT-prolonging medications and electrolyte monitoring form the cornerstones of preventive care. Advancing Kv11.1-targeted therapies with approaches like CRISPR-Cas9 and pharmacological chaperones (e.g., lumacaftor) holds promise for personalized treatments, ultimately reducing arrhythmic events and sudden cardiac death. Full article

Plants are sessile organisms that use molecular oxygen to perform basic metabolic functions. However, when oxygen availability decreases to 1–5% (hypoxic stress), the plant responds transcriptionally to adjust its metabolism and survive the stress. It has been observed that during hypoxia, adenosine triphosphate (ATP) levels decrease drastically, which could trigger plant death. However, despite experiencing an energy deficit, it has been observed that during hypoxia, plants induce defense mechanisms against pathogens. Plants manage to evade pathogenic microorganisms during an energy deficit by using complex signaling networks and different levels of regulation (transcriptional, post-translational, physiological, metabolomic, etc.) that converge to respond to both types of stress (biotic and abiotic). Understanding this phenomenon would have potential applications for agriculture and crop improvement. Therefore, this review details the main mechanisms of plant response to hypoxia and how this affects immunity mechanisms, highlighting the participation of ERF-VII transcription factors as oxygen sensors and their ability to bind to the GCC-box present in promoter regions of defense genes, MAPK signaling pathways, hormonal pathways, ROS, and Ca²⁺. Full article

Radiation exposure from environmental sources, medical procedures, or space exploration poses considerable risks to human health, with profound effects on immune function and inflammatory responses. Radiotherapy (RT) is a cornerstone of modern cancer treatment, leveraging ionizing radiation to induce DNA damage and tumor cell death. However, its biological effects extend beyond direct cytotoxicity, exerting complex and context-dependent influences on both innate and adaptive immunity. Ionizing radiation can enhance antitumor immune responses by promoting tumor antigen release, activating dendritic cells, and augmenting cytotoxic T-cell priming. Conversely, it can also induce immunosuppressive mechanisms, including lymphocyte depletion, regulatory T-cell expansion, immune checkpoint upregulation, and chronic inflammatory signaling, which may limit therapeutic efficacy. These immune effects are critical for optimizing RT protocols, particularly in the era of immunotherapy, where immune modulation plays a pivotal role in treatment efficacy. This review summarizes the current knowledge concerning how radiation induces immune and inflammatory responses in cells and tissues; focuses on key molecular pathways such as the DNA damage response, cGAS–STING signaling, and immune checkpoint modulation; and discusses their clinical implications. These findings provide potential therapeutic strategies for cancer treatment by harnessing the immunomodulatory potential of radiation while reducing adverse effects and for the prevention and treatment of radiation-related diseases. Full article

Myocardial ischemia–reperfusion injury remains a major unresolved challenge in cardiovascular medicine. Although timely restoration of blood flow is essential to limit ischemic damage, reperfusion triggers a complex network of maladaptive biological responses, including oxidative stress, calcium overload, mitochondrial dysfunction, metabolic impairment, and sterile inflammation. These processes converge on cardiomyocyte death, adverse ventricular remodeling, and long-term functional deterioration. Mesenchymal stem cells have been widely investigated as cardioprotective agents; however, accumulating evidence indicates that their beneficial effects are predominantly mediated by paracrine mechanisms. Among these, extracellular vesicles released by mesenchymal stem cells have emerged as key biological effectors. Experimental studies demonstrate that mesenchymal stem cell–derived extracellular vesicles modulate multiple signaling pathways involved in ischemia–reperfusion injury, including activation of the phosphoinositide 3-kinase (PI3K) and protein kinase B (PKB) axis, regulation of signal transducer and activator of transcription 3 (STAT3) signaling in a cell-specific manner, suppression of nuclear factor kappa B (NF-κB)-driven inflammatory responses, and stabilization of hypoxia-inducible factor-1α (HIF-1α)–dependent adaptive programs. At the subcellular level, these vesicles preserve mitochondrial structure and function, support energy metabolism, regulate mitophagy, and limit oxidative damage. Their molecular cargo, comprising regulatory microRNAs, metabolic enzymes, and stress-response proteins, enables coordinated modulation of survival, inflammatory, and reparative pathways rather than single-target effects. This review synthesizes current experimental evidence on the mechanistic basis of mesenchymal stem cell–derived extracellular vesicle–mediated cardioprotection and discusses their potential as cell-free, mechanism-based therapeutic strategies to limit myocardial ischemia–reperfusion injury. Full article

Phloem-restricted poleroviruses cause substantial yield losses in crops. Co-infection of the polerovirus brassica yellows virus (BrYV) with the umbravirus pea enation mosaic virus 2 (PEMV 2) results in synergistic interactions that enable BrYV to overcome phloem limitation in Nicotiana benthamiana, yet the associated host transcriptional responses remain poorly understood. At 7 days post inoculation (dpi), BrYV RNA accumulation was increased in plants co-infected with BrYV and PEMV 2, although no visible symptoms or detectable cell death were observed. By 14 dpi, extensive cell death was induced in upper leaves infected with BrYV and PEMV 2. Transcriptome analysis at 14 dpi identified 45, 188, and 1962 differentially expressed genes (DEGs) in leaves infected with BrYV, PEMV 2, and co-infected with BrYV and PEMV 2, respectively, compared with mock-inoculated plants. A large number of DEGs, Gene Ontology terms, and KEGG pathways were predominantly observed in co-infected plants. Notably, expression changes were observed in genes related to plasmodesmata-associated processes, RNA silencing, photosynthesis, cell death, and ethylene biosynthesis and signaling during co-infection. These results provide a transcriptome-based overview of host responses during the late stage of BrYV and PEMV 2 co-infection and highlight the complexity of viral synergism between phloem-limited and taxonomically distinct plant viruses. Full article