Search Results (587)

Chronic exposure to the cyanotoxin microcystin-LR is an emerging environmental driver of non-alcoholic fatty liver disease (NAFLD); however, the initiating molecular events at sub-lethal, environmentally relevant concentrations remain elusive. Current safety guidelines focus primarily on acute injury, potentially overlooking silent metabolic disruption. The present study investigates the early metabolic toxicity of chronic low-dose microcystin-LR (10 µg/L) in a 7-week rat model, specifically focusing on pre-symptomatic perturbations in lipid homeostasis. By integrating biochemical profiling with multivariate systems toxicology (LASSO and PLS-DA), we identified a specific phenotype of “Silent Hepatic Total Cholesterol Accumulation” (T-CHOL +16%, p = 0.01) occurring in the absence of systemic dyslipidemia or overt liver injury. Mechanistic analysis revealed a specific dual failure of cholesterol homeostasis, characterized by the paradoxical upregulation of the influx transporter Ldlr (LASSO coef +0.661) and the suppression of the efflux transporter Abcg1 (PLS1 loading −0.358). Crucially, Ldlr upregulation occurred despite the concomitant transcriptional downregulation of Srebp2 (Spearman ρ = −0.585), indicating a regulatory uncoupling mechanism. We propose that microcystin-LR-induced protein phosphatase 2A (PP2A) inhibition likely drives this uncoupling via a post-transcriptional override—possibly involving ERK/RSK-mediated Ldlr mRNA stabilization. Concurrently, this inhibition appears to block LXR-mediated Abcg1 expression through sustained AMPK hyperactivation resulting from the loss of dephosphorylation. These findings indicate liver-specific cholesterol accumulation as the critical first step of environmental NAFLD pathogenesis, suggesting that current WHO guidelines (1 µg/L) may require re-evaluation regarding metabolic safety. We propose the hepatic Ldlr/Abcg1 ratio as a potential early biomarker for revised risk assessment. Full article

Cancer stem cells (CSCs) represent a small but highly resilient tumor subpopulation responsible for sustained growth, metastasis, therapeutic resistance, and recurrence. Their survival is supported by aberrant activation of developmental and inflammatory pathways, including Wnt/β-catenin, Notch, Hedgehog, PI3K/Akt/mTOR, STAT3, and NF-κB, as well as epithelial–mesenchymal transition (EMT) programs and niche-driven cues. Increasing evidence shows that phytochemicals, naturally occurring bioactive compounds from medicinal plants, can disrupt these networks through multi-targeted mechanisms. This review synthesizes current findings on prominent phytochemicals such as curcumin, sulforaphane, resveratrol, EGCG, genistein, quercetin, parthenolide, berberine, and withaferin A. Collectively, these compounds suppress CSC self-renewal, reduce sphere-forming capacity, diminish ALDH⁺ and CD44⁺/CD24⁻ fractions, reverse EMT features, and interfere with key transcriptional regulators that maintain stemness. Many phytochemicals also sensitize CSCs to chemotherapeutic agents by downregulating drug-efflux transporters (e.g., ABCB1, ABCG2) and lowering survival thresholds, resulting in enhanced apoptosis and reduced tumor-initiating potential. This review further highlights the translational challenges associated with poor solubility, rapid metabolism, and limited bioavailability of free phytochemicals. Emerging nanotechnology-based delivery systems, including polymeric nanoparticles, lipid carriers, hybrid nanocapsules, and ligand-targeted formulations, show promise in improving stability, tumor accumulation, and CSC-specific targeting. These nanoformulations consistently enhance intracellular uptake and amplify anti-CSC effects in preclinical models. Overall, the consolidated evidence supports phytochemicals as potent modulators of CSC biology and underscores the need for optimized delivery strategies and evidence-based combination regimens to achieve meaningful clinical benefit. Full article

In today’s world, unhealthy living habits have contributed to the rise in metabolic disorders like hyperlipidemia. Recognized as a popular edible and medicinal mushroom in China and various eastern nations, Ganoderma lucidum is a promising high-value functional and medicinal food with multiple biological activities. Our earlier research has demonstrated that G. lucidum polysaccharides (GLP) showed distinct lipid-lowering abilities by enhancing the response to oxidative stress and inflammation, adjusting bile acid production and lipid regulation factors, and facilitating reverse cholesterol transport through Nrf2-Keap1, NF-κB, LXRα-ABCA1/ABCG1, CYP7A1-CYP27A1, and FXR-FGF15 pathways, hence we delved deeper into the effects of GLP on hyperlipidemia, focusing on its structural characterization, gut microbiota, and fecal metabolites. Our findings showed that GLP changed the composition and structure of gut microbiota, and 10 key biomarker strains screened by LEfSe analysis markedly increased the abundance of energy metabolism, and cell growth and death pathways which were found by PICRUSt2. In addition, GLP intervention significantly altered the fecal metabolites, which enriched in amino acid metabolism and lipid metabolism pathways. The results of structural characterization showed that GLP, with the molecular weight of 12.53 kDa, consisted of pyranose rings and was linked by α-type and β-type glycosidic bonds, and its overall morphology appeared as an irregular flaky structure with some flecks and holes in the surface. Collectively, our study highlighted that the protective effects of GLP were closely associated with the modification of gut microbiota and the regulation of metabolites profiles, thus ameliorating dyslipidemia. Full article

Background: The ATP-binding cassette (ABC) G subfamily, a key member of the ABC protein family, mediates plant stress responses by transporting metabolites across membranes, but its mechanism of action in tomato (Solanum lycopersicum L.) remains poorly understood. Methods: We systematically analyzed the evolutionary relationships, structural characteristics, stress-responsive expression patterns, and functional roles in response to saline-alkali stress of the SlABCG gene family in tomato, using a combination of approaches including phylogenetic analysis (MEGA), gene structure and motif analysis (GSDS, MEME), cis-acting element prediction, homology analysis, transcriptome analysis, protein-protein interaction prediction, and qRT-PCR validation. Results: We identified a total of 41 SlABCG genes from the tomato genome. These genes, together with 43 ABCG genes from Arabidopsis thaliana, were clustered into five distinct clades. There are 35 collinear gene pairs between the SlABCG gene family in tomato and the ABCG gene family in Arabidopsis, while 39 collinear gene pairs exist among ABCG genes within the tomato genome itself.The promoter regions of SlABCG genes contain cis-acting elements associated with responses to salicylic acid, low temperature, and gibberellin stresses. Transcriptome sequencing revealed that six SlABCG genes responded to saline-alkali stress. Gene regulatory network prediction revealed that multiple genes related to saline-alkali stress were regulated. Expression profile analysis of the 25 upregulated genes revealed that all of them were significantly upregulated during the saline-alkali stress treatment. Conclusions: In summary, our results provide deep insights into the characteristics of the SlABCG subfamily, facilitate the design of effective analysis strategies, and offer data support for exploring the roles of ABCG transporters under different stress conditions. Full article

Background: Pharmacogenetic markers associated with the need to switch patients from methotrexate (MTX) to biologic agents in moderate-to-severe psoriasis remain insufficiently studied. The pharmacokinetics of MTX depend on the individual characteristics of the patient, as well as on the function of specific transporters and enzymes involved in its absorption, distribution, metabolism, and elimination; therefore, polymorphisms in genes encoding these proteins may be considered pharmacogenetic predictors of MTX intolerance or insufficient efficacy. This study aimed to investigate genetic variants associated with MTX intolerance or insufficient efficacy leading to therapy switch. Methods: A total of 80 patients with moderate-to-severe psoriasis were included: 43 who required switching from MTX to biologics and 37 who continued MTX therapy. Twelve polymorphisms in transporter and metabolism-related genes (ABCB1 (rs1045642), MTHFR (rs1801133), ABCB1 (rs1128503), ABCC2 (rs3740066), ABCC2 (rs717620), ABCG2 (rs2231137), GSTP1 (rs1695), SLC19A1 (rs1051266), COL18A1 (rs9977268), SLCO1B1 (rs2306283), SLCO1B1 (rs4149056), and ABCB1 (rs2229109)) were analyzed using next-generation sequencing. Results: Significant differences in genotype frequencies were observed for SLC19A1 rs1051266 (p = 0.03) and COL18A1 rs9977268 (p = 0.02). Carriers of the T allele in both genes were more frequent among patients requiring biologic therapy, suggesting a possible association with MTX intolerance or reduced efficacy. Conclusions: The study revealed an association between polymorphisms in the SLC19A1 rs1051266 and COL18A1 rs9977268 genes and the need to switch from MTX to biologic therapy in patients with moderate-to-severe psoriasis. These findings suggest that carriers of the C allele in these genes may have an increased risk of methotrexate intolerance. Full article

The ATP-binding cassette (ABC) transporter family is one of the oldest conserved protein families and is widely present in animal and plant cells. However, few studies have investigated the role of ABC in the forest musk deer (FMD; Moschus berezovskii). In this study, we employed bioinformatics methods to identify and analyze the ABC transporter genes in M. berezovskii to elucidate the potential function of ABC genes in musk secretion. A total of 51 members of the MbABC gene family were identified. The analysis encompassed various aspects including physical and chemical properties, phylogenetic tree, structure prediction, conserved motifs, gene structures, chromosome localization, collinearity analysis, and KEGG and GO enrichment. Collinearity analysis revealed that the ABC transporter gene family is conserved in FMD, Cervidae, and five Bovinae species. MbABCB6, MbABCD4, MbABCF3, and MbABCG5 are key genes in protein–protein interaction networks, which are primarily involved in the transport of vitamins, lipids, and proteins. Tissue expression analysis showed that MbABCs were expressed at different stages. The RT-qPCR analysis revealed that 12 MbABC genes were up-regulated in musk gland cells during the non-secretion phase and stimulation phase, particularly MbABCC4d and MbABCC3. This study provides comprehensive information on the ABC gene family in FMD which can be further used for their functional validation. Full article

Ochratoxin A (OTA), Zearalenone (ZEA), and Fumonisins (FB) are common contaminants of poultry feed associated with oxidative damage and potentially dangerous residues in products from exposed animals. We investigated the molecular effects in broilers of a short-term (10 days) dietary exposure to OTA (0.26 mg/kg), ZEA (2.9 mg/kg), or FB (60 mg/kg) on cytochrome P450 enzymes (CYP), drug transporters (DT) and the antioxidant defence system. OTA markedly decreased serum antioxidant capacity, while all mycotoxins depressed reduced glutathione content and increased lipid peroxidation in the liver, indicating a hepatic pro-oxidant effect. All the tested mycotoxins also reduced both the activities and the gene expression of selected antioxidant enzymes in the liver and duodenum as a result of the modulation of the Nrf2/Keap1 pathway. Moreover, mycotoxins differentially altered the hepatic and intestinal gene expression of CYP enzymes (i.e., CYP2A6, CYP2C45, CYP3A4, and CYP1A isoforms). Finally, the transcription of selected DT (i.e., ABCB1, ABCC2 and ABCG2) was generally enhanced in both the liver and duodenum. In conclusion, short-term exposure to OTA, ZEA, or FB at dietary concentrations higher than those recommended in the EU, but occurring in third countries, not only disrupt the antioxidant defence but also affect the expression of CYP and DT, which might potentially alter the kinetics of drugs and toxicants. Our results provide new insights into mycotoxin adverse effects in the light to assess the effectiveness of new mitigation strategies that contribute to food and feed safety. Full article

Gut microbiota, through both its species composition and its metabolites, impacts expression and activity of intestinal drug transporters. This phenomenon directly affects absorption process of orally administered drugs and contributes to the observed inter-individual variability in pharmacotherapeutic responses. This review summarizes mechanistic evidence from in vitro and animal studies and integrates clinical observations in which alterations in gut microbiota are associated with changes in oral drug exposure, consistent with potential regulation of key intestinal drug transporters—such as P-glycoprotein (P-gp, ABCB1), Breast Cancer Resistance Protein (BCRP, ABCG2), MRP2/3 proteins (ABCC2/3), and selected Organic Anion-Transporting Polypeptides (OATPs, e.g., SLCO1A2, SLCO2B1)—by major bacterial metabolites including short-chain fatty acids (SCFAs), secondary bile acids, and tryptophan-derived indoles. The molecular mechanisms involved include activation of nuclear and membrane receptors (PXR, FXR, AhR, TGR5), modulation of transcriptional and stress-response pathways (Nrf2, AP-1) with simultaneous suppression of pro-inflammatory pathways (NF-κB), and post-translational modifications (e.g., direct inhibition of P-gp ATPase activity by Eggerthella lenta metabolites). The review also highlights the pharmacokinetic implications of, e.g., tacrolimus, digoxin, and metformin. In conclusion, the significance of “drug–transporter–microbiome” interactions for personalized medicine is discussed. Potential therapeutic interventions are also covered (diet, pre-/probiotics, fecal microbiota transplantation, modulation of PXR/FXR/AhR pathways). Considering the microbiota as a “second genome” enables more accurate prediction of drug exposure, reduction in toxicity, and optimization of dosing for orally administered preparations. Full article

Background/Objectives: The ABCG2 transporter actively effluxes anticancer drugs, reducing their efficacy and promoting multidrug resistance (MDR). Developing oral formulations of poorly soluble ABCG2 inhibitors remains challenging due to their low solubility and intestinal permeability. This study aimed to formulate and evaluate an ABCG2 inhibitor using micro- and nanoscale drug delivery systems. Methods: To address the poor solubility and bioavailability of the corresponding active ingredient, a self-nanoemulsifying drug delivery system (SNEDDS) was developed. The SNEDDS was encapsulated into microcapsules using sodium alginate crosslinked with calcium chloride. Five microcapsule formulations were developed, varying in the inclusion of polyvinylpyrrolidone (PVP), Transcutol^® HP and SNEDDS. The effects of the excipients on encapsulation efficiency, swelling capacity, enzymatic stability, dissolution, cytocompatibility, and permeability were systematically evaluated. Results: The SNEDDS exhibited monodisperse particle sizes and efficient drug entrapment. Results revealed that formulations incorporating PVP and SNEDDS improved encapsulation efficiency and bioavailability. SNEDDS-containing formulations demonstrated superior enzymatic stability in simulated gastric and intestinal fluids and provided the highest cumulative drug release in vitro. Cytotoxicity studies conducted on Caco-2 and MCF-7 cells demonstrated that our formulations were well tolerated, indicating favorable biocompatibility. Conclusions: Our findings demonstrate that SNEDDS-loaded alginate microcapsules offer an efficient platform for oral delivery of dimeric ABCG2 inhibitors, combining enhanced solubility, stability, and controlled release. The optimized formulation can be regarded as a promising strategy to enhance the oral bioavailability of efflux pump inhibitors and other poorly soluble drugs. Full article

Drought stress significantly impacts potato (Solanum tuberosum) yield and quality, necessitating the identification of molecular regulators involved in stress response. This study presents a systems-level, integrative in silico strategy to characterize StABCG25 transporter homologs, key players in abscisic acid (ABA) export in Arabidopsis, to evaluate their potential role in drought adaptation. We performed a genome-wide scan of the potato genome and identified four StABCG25 isoforms. A comprehensive computational framework was applied, including transcriptomic profiling, Weighted Gene Co-expression Network Analysis (WGCNA), AlphaFold2-based 3D modeling, docking, and long-timescale Molecular Dynamics (MD) simulations. Expression analyses revealed the coordinated upregulation of StABCG25-2 and -4 in the drought-tolerant FB clone, contrasted by suppression or instability in sensitive cultivars. WGCNA placed StABCG25-2 as a hub gene in ABA-enriched stress response modules, while StABCG25-4 was associated with plastid-related pathways, suggesting functional divergence. Structurally, StABCG25-2 and -6 exhibited high conformational stability in MD simulations, supported by consistent RMSD/RMSF profiles and MM/PBSA-based binding energy estimates. In contrast, StABCG25-5B, despite favorable docking scores, demonstrated poor dynamic stability and unreliable binding affinity. Overall, this study highlights the critical role of transcriptional coordination and structural robustness in the functional specialization of StABCG25 isoforms under drought stress. Our findings underscore the value of combining WGCNA and molecular dynamics simulations to identify structurally and functionally relevant ABA transporters for future crop improvement strategies. Full article

To identify key genes involved in drought stress response among Chinese cabbage materials with different drought resistance, a pair of waxy near-isogenic lines (NILs) of Chinese cabbage were used as materials, and a 10% polyethylene glycol (PEG) 6000 solution was employed to simulate drought stress. A comparative analysis of phenotypes, physiology, and transcriptomes under drought stress was conducted in this study. Compared with the non-waxy material T065-2, the waxy material T065-1 exhibited 5068, 5512, 5210, and 5875 significantly differentially expressed genes (DEGs) at 0, 6, 12, and 24 h under drought stress, respectively. These DEGs were primarily enriched in “response to oxygen levels” and “secondary metabolite biosynthesis” biological processes and “biosynthesis of secondary metabolites” and “glucosinolate biosynthesis” pathways. Combined with gene function annotation, 26 genes related to the abscisic acid (ABA) signaling pathway (e.g., PYL2, PYL6, SnRK2.5, and SnRK2.10), 63 genes associated with wax synthesis and transport (e.g., MAH1, CER3a, ABCG25, and LTPG1), and 84 transcription factor genes (e.g., ERF, WRKY, and MYB) were identified, all of which showed significant differential expression in the waxy NILs of Chinese cabbage, potentially participating in drought stress response. The reliability of the transcriptomic analysis was validated using qRT-PCR. These findings provide a crucial theoretical foundation for exploring drought-resistant molecular markers and editing targets in Chinese cabbage, significantly accelerating the breeding of superior drought-resistant varieties. Full article

The assessment of donor corneas is currently based solely on central endothelial cell (EC) density, which potentially overlooks the transition zone (TZ) regenerative potential. Therefore, the present study characterizes TZ using multimodal imaging techniques to understand its regenerative potential and refine the assessment of donor tissue. Ex vivo donor corneas (n = 41) were examined using phase-contrast microscopy for EC counting and reflectance confocal microscopy (HRTII/RCM) for non-invasive visualization of the TZ. A subset of eight of these corneas underwent ultrastructural analysis using field-emission scanning electron microscopy (SEM) and immunostaining analysis using confocal microscopy. We observed a significant decrease in central EC density (p < 0.001) with increasing storage duration and donor age, while TZ width and TZ surface cell count remained stable. HRTII/RCM and SEM revealed distinct morphological differences (small, polygonal cells, irregular arrangement) in the TZ compared to the peripheral endothelium (PE). Immunostaining revealed elevated expression of progenitor markers (Nestin, ABCG2, SOX2, Lgr5, Vimentin) and reduced expression of endothelial markers (ZO1 and Na/K-ATPase) in the TZ compared to the PE, indicating the presence of a stem cell-like population. These findings suggest that TZ may contribute to endothelial cell regeneration, and HRTII/RCM could serve as a novel tool for TZ evaluation in low EC count donor corneas. Full article

Corneoscleral-ring-derived extracellular vesicles represent a potential therapeutic strategy for promoting in vitro corneal wound healing. In this study, we successfully isolated and characterized extracellular vesicles from human corneolimbal tissue obtained from 42 donors, with a mean age of 51.62 ± 15.56 years. Donor-related factors such as age, corneal endothelial cell density, and underlying systemic conditions did not confound extracellular vesicle size and concentration with mean peak size of 99.52 ± 13.00 nm by nanoparticle tracking analysis. Western blotting analysis revealed positive Alix, stable expression of CD9 and CD81, and variable expression of CD63. Limbal stem cell (LSC)-associated markers, i.e., ABCG2, p63, Notch-1, and Integrin α9 were positively detected in the isolated extracellular vesicles. Notably, Integrin α9 showed stable and relatively strong expression in all samples serving a specific marker of LSC-derived extracellular vesicles. Functional assays demonstrated that LSC-derived extracellular vesicles exhibited better wound healing potency compared to extracellular vesicles derived from mesenchymal stem cells (MSCs). These findings suggest that corneoscleral-ring-derived extracellular vesicles express distinct LSC markers, including Integrin α9, and hold significant potential for application in corneal wound healing and ocular surface regeneration. Full article

Background/Objectives: Dolutegravir (DTG) is recommended as first-line treatment for Thai people living with HIV (PLWH). Real-world studies show high plasma concentration variability, which may increase neuropsychiatric adverse effects. This variability can be influenced by both genetic and nongenetic factors, but data for the Thai population are insufficient. We investigated factors associated with DTG pharmacokinetics in Thai PLWH. Methods: A cross-sectional analysis was conducted in Thai PLWH receiving a 50 mg DTG-based regimen. Intensive blood sampling was performed to determine DTG pharmacokinetic parameters using a non-compartmental analysis. Genotyping for UGT1A1, ABCG2, and NR1I2 was performed. Univariable and multivariable linear regression analyses were used to identify factors associated with DTG pharmacokinetics. Results: A total of 104 Thai PLWH were included. Multivariable analysis demonstrated that both the UGT1A1 poor metabolizer phenotype and body weight were independently associated with DTG exposure. After adjusting for body weight, the UGT1A1 poor metabolizer phenotype was associated with increases of 5.18% in AUC_0–24 and 20.59% in C_trough. No significant association was found between the ABCG2 421 C>A polymorphism and DTG pharmacokinetic parameters. Conclusions: Body weight and the UGT1A1 poor metabolizer phenotype significantly impacted DTG exposure in Thai PLWH. Those with the UGT1A1 poor metabolizer, particularly with lower body weight, had significantly increased DTG exposures. These findings highlight that dose optimization may be worth exploring in selected individuals in this population. Full article

The progression of atherosclerosis (AS) is strongly linked to lipid crystals accumulation caused by cholesterol metabolism disorders and the worsening of the inflammatory microenvironment. Cyclodextrin (CD), characterized by their unique hydrophobic cavity structure, effectively solubilize cholesterol crystals (CCs) through host–guest recognition and act as a multifunctional nanocarrier core, facilitating synergistic therapy that combines pharmaceutical and adjuvant properties. CD-based nano drug delivery systems (CD-NDDS) enable precise targeting of atherosclerotic plaques. By employing synergistic functions (e.g., CCs solubilization, cholesterol efflux promotion via ABCA1/ABCG1 pathways, inflammasome inhibition, and inflammatory microenvironment alleviation), this system provides an effective strategy for AS therapy. Furthermore, CD-NDDS bestows additional pharmaceutical attributes, including enhanced solubility, controlled release, and responsive stimulation. This review begins by elucidating the intrinsic relationship between cholesterol and AS, followed by an examination of the structure-activity relationship governing CD’s cholesterol adsorption. It then explores the construction strategies, structural characteristics, and targeting mechanisms of CD nanodelivery systems in detail. The work systematically assesses CD’s formulation and pharmacological properties in targeted nanodelivery systems for combating AS, integrating drugs and adjuvants. Finally, future research directions are outlined, addressing biocompatibility optimization, targeting efficiency enhancement, and clinical translation challenges to provide a theoretical foundation and technical guidance for precise AS treatment. Full article