Search Results (6,431)

Type 2 Diabetes Mellitus (T2DM) is a chronic metabolic disorder linked to gut microbiota dysbiosis and impaired inter-organ metabolic signalling. This study investigated the combined effects of the probiotic Lactiplantibacillus plantarum TJA7 and Mulberry Leaf extract (Morus alba) on cellular processes relevant to T2DM-related metabolic dysfunction. An advanced in vitro gut–pancreas–liver axis model, using Caco-2, EndoC-βH5, and HepG2 cells, was employed under hyperglycemic and oxidative stress conditions. The combined treatment consistently outperformed the individual components by improving intestinal barrier integrity, as indicated by increased transepithelial electrical resistance (TEER), and by enhancing butyrate translocation across the intestinal layer. Metabolites derived from the combination attenuated pancreatic β-cell dysfunction, reducing reactive oxygen species (ROS) levels and increased insulin secretion (1.7-fold compared with Mulberry Leaf extract alone). At the hepatic level, co-administration modulated key glucose metabolism pathways, including Insulin Receptor Substrate 1 (IRS1), Protein Kinase B (AKT), AMP-Activated Protein Kinase (AMPK), and Peroxisome Proliferator-Activated Receptor Gamma Coactivator 1 Alpha (PGC-1α), suggesting improved cellular glucose handling. Collectively, these findings support a positive dose-specific interaction under the tested conditions and provide a biologically plausible, hypothesis-generating framework for probiotic–phytochemical cooperation along the gut–pancreas–liver axis. Further in vivo and clinical studies are required to establish causality and translational relevance. Full article

Hormone-independent breast and prostate cancers represent highly aggressive malignancies characterized by profound metabolic reprogramming, elevated oxidative stress, and loss of sensitivity to endocrine therapies. Increasing evidence indicates that tumor progression and metabolic plasticity are sustained by interconnected signaling networks linking transcriptional regulation to energy metabolism. Among these, the STAT3–PKM2–HIF-1α signaling axis, functionally reinforced by reactive oxygen species (ROS), has been proposed as a central regulator of the Warburg phenotype and cellular adaptation to adverse microenvironmental conditions. Using androgen-independent prostate cancer (DU145) and triple-negative breast cancer (KPL-4) cell lines, we demonstrated constitutive activation and reciprocal regulation of STAT3, PKM2, and HIF-1α. Pharmacological inhibition of STAT3, stabilization of tetrameric PKM2 by L-serine, and ROS scavenging with N-acetylcysteine significantly reduced STAT3 phosphorylation, PKM2 nuclear translocation, and HIF-1α stabilization. These molecular effects were accompanied by decreased intracellular ROS levels, reduced lactate production, increased pyruvate levels, and a metabolic shift toward oxidative phosphorylation. Functionally, treated cells exhibited reduced Ki-67 expression and impaired clonogenic capacity. Our results identify the STAT3–PKM2–HIF-1α/ROS axis as a key determinant of metabolic and phenotypic plasticity in hormone-independent breast and prostate cancers, highlighting its potential as a molecular target for therapeutic modulation of cancer-associated metabolic phenotypes. Full article

Tubule-derived pro-fibrotic mediators are central for the development of kidney fibrosis. We previously showed that fibrotic stimuli activate and elevate GEF-H1 (ARHGEF2) in tubular cells, leading to RhoA-dependent fibrotic reprogramming. In search of new mechanisms of GEF-H1 regulation, here we used immunoprecipitation and proximity ligation assay to show interaction between GEF-H1 and Myotonic Dystrophy Kinase-related Cdc42-binding kinase (MRCK)α in tubular cells. MRCKα silencing elevated GEF-H1 activity, and induced GEF-H1-dependent RhoA activation, stress fibre formation and myosin light chain phosphorylation. MRCKα depletion also elevated phospho-cofilin levels in a RhoA-dependent manner. The fibrogenic cytokine TGFβ1 rapidly increased binding between GEF-H1 and MRCKα, while MRCKα silencing augmented TGFβ1-induced GEF-H1 activation, suggesting a negative feedback loop. An mRNA array detecting fibrogenic genes revealed increase in a subset of basal and TGFβ1-induced genes following MRCKα depletion. MRCKα silencing promoted nuclear translocation of the profibrotic transcriptional co-activator Myocardin-Related Transcription Factor (MRTF), and MRTF-A+B depletion prevented increase in ACTA2 (α-smooth muscle actin), a key marker of fibrotic reprogramming. Finally, total MRCKα mRNA was reduced in a murine kidney fibrosis model, and immunohistochemistry revealed a decrease in tubular MRCKα. Taken together, we identified MRCKα as a new suppressor of GEF-H1/RhoA/MRTF signaling. Reduced MRCKα expression in kidney fibrosis may promote tubular fibrotic gene expression. Full article

Background: Prostate cancer is one of the most prevalent and deadly neoplasias in the male population. Despite the availability of therapies that increase the long-term survival of patients with localized tumors, metastatic prostate cancer is challenging to treat. A previous study revealed that the 2-aminopyridine derivative (named Neq0440) inhibited the PI3K-AKT-mTOR pathway and presented selective cytotoxicity toward the metastatic prostate cancer cell line PC-3. Methods: Here, we further analyzed the mechanism of action of these molecules by using cell-based colorimetric, fluorometric, epifluorescence microscopy, and Western blot assays. Results: Mitochondrial depolarization increased the AMPK level at 24 h inhibition with Neq0440, which led to the PI3K-AKT-mTOR pathway downregulation after 48 h. The phosphorylation was inhibited for AKT and the downstream quinases (S6RP and 4EBP1) from the PI3K-AKT-mTOR pathway, which can work together with the mitochondrial depolarization, lowering the pH of the medium, increasing ROS levels, and translocating the lysosomes toward the nucleus to trigger cell death. Conclusions: Therefore, Neq0440 can be used as a lead compound to obtain derivatives with a novel anticancer mechanism of action. Full article

Fluopyram is a widely used nematicide with a growing number of varieties registered both domestically and overseas. However, its absorption, transportation, and metabolism behaviors in plants have not been fully elucidated, thus hindering comprehensive assessment of the risks associated with its use. This study investigated the plant uptake, distribution, and metabolic behavior of fluopyram through 168 h hydroponic experiments. Fluopyram was easily absorbed by the roots of the tested crops, and almost 90.5% and 70.9% of fluopyram was transformed in cucumber and tomato, respectively, leading to the tentative identification of 16 metabolites using Quadrupole Time-of-Flight mass spectrometry. The metabolic reactions involved were hydroxylation, hydroxylation–dechlorination, dehydrogenation, dechlorination, and glucuronidation conjugation. Most metabolites were detected in leaves, suggesting that they have considerable potential to accumulate in the upper parts, even the edible parts. Model prediction indicated that fluopyram and high-toxicity metabolites (M430A, M412C) pose significant risks to aquatic ecosystems across trophic levels, while M574A and M574B showed reduced toxicity due to glucuronidation conjugation. These findings deepen our understanding of the behavioral characteristics of fluopyram within plants, and serve as an important reference for comprehensively assessing its risks. Full article

Liver cirrhosis represents the end stage of chronic liver disease arising from diverse etiologies and is characterized by persistent hepatic injury, architectural distortion, extensive fibrosis, and nodular regeneration. While decompensated cirrhosis is commonly associated with overt, life-threatening complications such as hepatic encephalopathy, hepatorenal syndrome and gastrointestinal bleeding, less apparent manifestations—including sarcopenia and metabolic disturbances—have emerged as major determinants of prognosis. Sarcopenia, defined by the progressive loss of skeletal muscle mass and function, is highly prevalent in cirrhotic patients and is closely linked to frailty, increased morbidity, mortality, and adverse liver transplantation outcomes. Increasing data support the role of gastrointestinal dysfunction in the pathogenesis of sarcopenia in liver cirrhosis. In chronic liver disease, intestinal dysfunction is exacerbated by portal hypertension, which promotes increased intestinal permeability and bacterial translocation. Furthermore, gut dysbiosis, a key feature of advanced liver disease, contributes to impaired digestion, malabsorption of macro- and micronutrients, increased intestinal permeability, malnutrition and systemic inflammation. These alterations promote negative energy balance, reduce muscle protein synthesis and enhance muscle catabolism, thereby accelerating muscle wasting. Despite increasing recognition of the individual roles of gut dysbiosis, malabsorption, and sarcopenia in cirrhosis, their complex interrelationship has not been comprehensively addressed. This narrative review synthesizes current evidence on the interplay between gut dysbiosis, malabsorption and sarcopenia in patients with liver cirrhosis. We discuss underlying pathophysiological mechanisms, clinical implications and potential therapeutic strategies, while highlighting existing knowledge gaps and future research directions. Improved understanding of the gut-liver-muscle axis may offer novel opportunities for early intervention and optimization of outcomes in this high-risk patient population. Full article

Food allergies are increasing worldwide, yet the early epithelial mechanisms that initiate allergic sensitization remain incompletely defined. As the intestinal epithelium governs both allergen translocation and epithelial–immune crosstalk, it constitutes a critical but underutilized model for predicting allergenicity. In this study, we used Caco-2 and T84 intestinal epithelial monolayers cultured on Transwell^® inserts to compare barrier properties and responses to peanut protein extract. Phenotypic characterization included biomarker profiling, transepithelial electrical resistance (TEER) measurements, tight junction integrity assessment, and analysis of cytokine levels as well as oxidative and nitrosative stress. Peanut exposure caused moderate TEER reductions without overt tight junction disruption while allowing translocation of the major allergen, Arachis hypogaea allergen 1 (Ara h 1), likely via transcellular pathways. Peanut protein extracts also induced epithelial stress responses, characterized by increased reactive oxygen species and nitric oxide production, alongside time-dependent secretion of innate and type 2-associated mediators, including IL-1β, TSLP, IL-25, and IL-33, indicating epithelial activation in the absence of complete barrier breakdown. Notably, basolateral supernatants from peanut-exposed epithelial monolayers activated THP-1-derived macrophages and enhanced IL-6 secretion, demonstrating that limited allergen passage across an otherwise intact epithelial barrier is sufficient to elicit early innate immune responses. Collectively, these findings indicate that peanut extract induce subtle functional perturbations in the intestinal epithelium while promoting downstream immune activation, highlighting Caco-2 and T84 cells as complementary in vitro platforms for studying barrier-dependent mechanisms of allergic sensitization. Full article

Minimizing cadmium (Cd) contamination in rice grains is crucial for ensuring food security and promoting sustainable agriculture. Recent studies have investigated soil immobilization and foliar spraying for reduced cadmium accumulation in rice, yielding positive results. This study aimed to confirm the synergistic effects of the co-application of Ca-Mg soil immobilization and foliar spraying Si(OH)₄ on Cd uptake and transport in rice through field trials. The results indicated that Ca-Mg decreased the transfer of Cd from soil to root by 33.9% to 55.7%, Si(OH)₄ reduced the transfer of Cd from leaf to rachis by 43.8% to 69.7%, and the transfer of Cd from husk to brown rice was lowered by 33.4% to 61.2%. Compared with single application, co-application significantly decreased the bioconcentration factor (BCF)_{soil-brown rice} (p < 0.05), leading to brown rice Cd accumulation conforming to the National Food Safety Standard (<0.20 mg kg⁻¹),with an input–output ratio of 1.47–1.60. Furthermore, Ca-Mg + Si increased rice grain production. Comprehensive analyses using PLS-PM revealed that Ca-Mg and Si(OH)₄ directly or indirectly inhibited the translocation of Cd from stems to brown rice, with foliar-sprayed Si(OH)₄ significantly contributing to the reduction in Cd content in brown rice. Considering the economic cost and safety of production, Ca-Mg + Si(OH)₄ serves as a viable solution that promotes substantial rice growth and enhances yield while additionally inhibiting the accumulation and translocation of Cd in rice. Full article

Prime editing (PE) is a precise genome-editing technology that avoids double-strand breaks, holding great promise for clinical and agricultural applications. However, its genome-wide off-target effects are not fully understood, raising safety concerns. Here, we systematically compared the safety profiles of four prime editor variants (PE2max, PE3max, PE4max, and PE5max) using PEM-seq and RNA-seq. We further applied an ultra-sensitive method, Genome-wide Off-target analysis by Two-cell embryo Injection (GOTI), to assess PE5max. Our results show that PE5max did not produce detectable sgRNA-dependent off-target single-nucleotide variants (SNVs) in the GOTI assay and induced only limited large deletions and chromosomal translocations. Collectively, this side-by-side benchmarking under matched conditions demonstrates that PE5max achieves an improved specificity profile, with no detectable increase in genome-wide off-target SNVs, advancing its potential for safer therapeutic use. Full article

In the context of global climate change, the co-occurrence of salt and heat stress represents a major constraint to rice production, resulting in greater yield penalties than either stress alone. This study aimed to assess the effects of salt and heat stress on oxidative homeostasis, photosynthetic performance, carbon (C)–nitrogen (N) metabolism, and rice yield. The experiment comprised four treatments, i.e., control (CK), salt (irrigation with 3.9 dS m⁻¹ NaCl solution), heat (exposure to 36 °C/30 °C day/night for 5 days at panicle initiation), and combined salt + heat stress. Results showed that combined stress enhanced reactive oxygen species (ROS) accumulation (i.e., H₂O₂ content and O₂⁻ contents were 1.3 and 1.5 times higher than CK), and the activities of superoxide dismutase (SOD), peroxidase (POD), and catalase (CAT) were increased by 64.6%, 69.5%, and 74.8% higher than CK. At the molecular level, salt + heat stress upregulated antioxidant defense-related genes, i.e., OsAPX2, OsSODCC1, and OsAPX1, while significantly downregulated ion homeostasis-related genes, i.e., OsSOSs, OsHKT1;3, OsHKT1;5, and OsNHX4, and photosynthesis-related genes, i.e., Ospsbo, OsRbcS2, and OsRbcS3, compared with CK. Furthermore, salt + heat stress reduced the activities of C-metabolism enzymes (sucrose phosphate synthase, sucrose synthase, and starch synthase) and N-metabolism enzymes (nitrate reductase, glutamine synthetase, and glutamate synthase), leading to 34.3% and 18.6% lower stem-sheath non-structural carbohydrate accumulation in stem sheath and its translocation rate, respectively, while total N accumulation decreased by 42.9%, as compared with CK. Ultimately, these cascading effects inhibited panicle development and reduced yield. The findings provide a theoretical basis for improving rice tolerance to combined abiotic stresses by targeting oxidative stress mitigation, photosynthetic protection, and key stress-responsive gene regulation. Full article

Background: Prostate cancer remains a leading cause of male cancer-related mortality, largely driven by the dysregulated activation of the androgen receptor (AR) signaling pathway. The emergence of resistance, particularly in castration-resistant prostate cancer (CRPC), necessitates the discovery of innovative therapeutic approaches. This systematic review aims to consolidate contemporary evidence regarding natural products as bioactive alternatives capable of targeting the AR signaling axis. Methods: Adhering to PRISMA guidelines, a systematic search was conducted across PubMed, Scopus, and ScienceDirect databases. The review identified and qualitatively analyzed 15 original research studies that investigated the efficacy and mechanisms of various natural compounds in modulating AR signaling. Results: The analysis reveals that natural products deactivate the AR signaling axis through diverse mechanisms. Neoisoliquiritin and α-terthienyl were found to suppress AR expression, activity, and nuclear translocation. Notably, α-mangostin facilitates the degradation of the AR-V7 splice variant, a key driver of treatment resistance. Manzamine A inhibits AR biosynthesis by targeting the transcription factor E2F8. Furthermore, alternative pathways are modulated through 5-α-reductase inhibition (Annona muricata compounds) and the activation of the non-classical membrane receptor ZIP9 by (-)-epicatechin to induce apoptosis. Conclusions: The emergence of resistance, particularly in castration-resistant prostate cancer (CRPC), necessitates the exploration of innovative therapeutic approaches. This systematic review consolidates contemporary evidence regarding natural products as potential bioactive alternatives for modulating the androgen receptor (AR) signaling axis. Rather than providing a definitive clinical roadmap, this work establishes a preclinical framework for identifying substances that may deactivate the receptor, break down its resistant forms, or prevent nuclear translocation. Full article

Modern botanical gardens are essential for conservation, research, education, and recreation. However, recreating habitats with extreme edaphic conditions, such as the Iberian gypsum steppes (priority habitat 1520), poses a significant challenge due to the severe physicochemical constraints of gypsisols. This work aimed to present and evaluate a biomimetic protocol for establishing two gypsum botanical gardens in the southeast Iberian Peninsula, one on a university campus and one at a mining concession, to fulfil all four prototypical functions. The design was biomimetic, replicating the floristic (Gypsophiletalia scrublands) and edaphic characteristics of natural gypsum areas. Crucially, gypsum-milling waste (fines) from the mining operation was repurposed as the main substrate to create the artificial gypsisols. Physicochemical analyses confirmed this strategy effectively replicated the key chemical properties of natural gypsisols, including high CaSO₄ concentration, pH, and electrical conductivity, although the artificial soils displayed the low carbon and nitrogen content typical of disturbed gypsum soils. The gardens successfully fulfilled their conservation role by maintaining populations of endemic and threatened gypsophilous species, which flowered and set fruit. The industrial garden validated a research function by serving as a platform for the successful translocation of threatened Narcissus tortifolius bulbs. This project validates a replicable, biomimetic technical protocol that transforms a mining residue into a functional substrate for conservation. The dual model (academic/industrial) maximizes the botanical garden’s functions, offering an effective and highly visible strategy for conserving gypsum biodiversity and countering the social undervaluation of these extreme ecosystems. Full article

In addition to binding to and regulating over 400 different proteins, calmodulin (CaM) also binds to lipids. Binding occurs to the prenylated tails of various small GTPases, to specific lipids in biological membranes and to free lipids in the cytoplasm. Here, CaM binding to Rac1, RalA, and KRAS4b is covered, emphasizing its importance in protein translocation from the cell membrane to the cytosol and its resultant impact on cell signaling. Binding phosphatidylserine and phosphatidylethanolamine in membranes not only leads to the tethering of CaM, but also to the disruption of lipid bilayers. Binding to sphingolipids also occurs, an event that acts as a competitive inhibitor of CaM function. The mechanism through which CaM binds to lipids is also examined. In total, the current state of affairs regarding calcium-dependent CaM–lipid binding is reviewed, including potential therapeutic uses, setting the stage for future work on this important biological event. Full article

Background/Objectives: Drug development and delivery remain critical areas of research for addressing modern bioanalytical challenges. Understanding drug biodistribution, stability, and metabolism within biological systems is essential for optimising therapeutic efficacy. This study focuses on synthesising and characterising a novel fluorescent conjugate derived from commercially available rapid-acting insulin glulisine (Apidra^®) and fluorescein isothiocyanate (FITC). The objective was to produce a mono-labelled FITC-insulin glulisine conjugate without employing complex protective group strategies or multi-step processes. Methods: The conjugation was optimised by varying molar ratios (1:1 to 3:1) and reaction times (18–24 h) at pH 7. Results: The desired B1 mono-labelled conjugate was successfully achieved at a 2:1 molar ratio, pH 7, and 18 h reaction time. MALDI-TOF mass spectrometry confirmed the molecular weight and conjugation site, with fragmentation analysis identifying FITC attachment at phenylalanine (B1) on the β-chain (m/z = 537.11). Western blots performed on C2C12 skeletal cell lysates stimulated with the FITC–insulin glulisine conjugate showed Akt and IRS-1 activity similar to that of cells treated with native commercial insulin glulisine. Confocal imaging also demonstrated translocation of GLUT4 in FITC–insulin glulisine conjugate-treated C2C12 cells similar to that of commercial native insulin glulisine. Octanol-water partitioning studies assessed the physicochemical properties of the conjugate. Conclusions: This approach demonstrates an efficient method for fluorescent labelling of insulin analogues, enabling future applications in imaging, biodistribution studies, and pharmacokinetic profiling. Full article

Elevated plasma lactate is a significant risk factor in pulmonary hypertension (PH), and endothelial-mesenchymal transition (EndoMT) is a major contributor to this pathological process, yet its specific role in driving endothelial-mesenchymal transition (EndoMT) remains unclear. Using in vivo and in vitro models, we demonstrate that modulating lactate levels critically influences PH progression. In a hypoxic PH mouse model, inhibition of lactate production ameliorated hemodynamic and vascular remodeling, whereas exogenous lactate exacerbated these pathologies. In human pulmonary arterial endothelial cells under hypoxia, lactate promoted a pro-remodeling phenotype, enhancing migration, proliferation, and EndoMT. Mechanistically, lactate induced Twist1 lactylation via enhanced association with p300/CBP, promoting its nuclear translocation. This upregulated TGFB1 transcription and activated the Smad2 pathway, thereby driving EndoMT—an effect abolished by Twist1 knockdown. Our findings reveal a previously unrecognized lactate-Twist1 lactylation-TGFB1 axis that promotes vascular remodeling in PH, identifying novel therapeutic targets. Full article