Search Results (7,456)

There are no disease-modifying treatments available for Huntington’s disease (HD), a neurodegenerative disease caused by a genetic mutation in the Huntingtin gene. Previous research suggests that disruptions in the bioenergetics of the mitochondria and increased oxidative stress are potential inducers of HD. Therapies that enhance antioxidant pathways intend to target and attenuate the overproduction of reactive oxygen species associated with mitochondrial dysfunction. We have investigated the effect of Methylene Blue (MB) as a potential therapy for HD. MB is a small molecule demonstrated to exhibit neuroprotective effects in other neurodegenerative disease models, including Parkinson’s and Alzheimer’s, by attenuating the oxidative stress pathways implicated in their pathophysiology. We used an established striatal cell model of HD expressing wild-type (STHdh^Q7/Q7) or mutant (STHdh^Q111/Q111) HTT and a chemical inducer of HD, 3-Nitropropionic acid (3-NPA), to determine the HD-specific mechanisms regulated by 3 h of MB pre-treatment. Upon 24 h of exposure to 3-NPA, mutant HD cells exhibited a significant concentration-dependent decrease in cell survival and a concomitant increase in cell death compared to wild-type, confirming that 3-NPA exacerbates mutant HTT neurotoxicity. Examination of mitochondrial membrane potential and mitochondrial function in the striatal cells by JC-1 and ATP assays, respectively, revealed MB mediated neuroprotection against 3-NPA-induced reduction in mitochondrial activity. Immunoblotting analysis revealed that MB restores baseline expression of oxidative-stress-related proteins, including HO1 and p62, in both wild-type and mutant cells exposed to 3-NPA. Our findings establish a novel neuroprotective role of MB in both genetic and pharmacological models of HD, suggesting that MB might be a promising therapeutic candidate for altering the underlying pathophysiology of HD by improving mitochondrial function. Full article

A hypercaloric diet is associated with oxidative stress and the dysfunction of ATP-Binding Cassette transporter A1 (ABCA1), a key element in high-density lipoprotein (HDL) biogenesis and reverse cholesterol transport. Nicotinamide (NAM) presents antioxidant properties, which may contribute to maintaining lipid metabolism. Therefore, we aimed to evaluate the effect of NAM on HDL-cholesterol (HDL-C) level, oxidative stress markers, and the gene expression and protein levels of ABCA1 in Sprague-Dawley rats fed a hypercaloric diet. Forty male rats were divided into five groups: one group received a standard diet, and the remaining groups received a single high-fat, high-fructose diet (HFDF). Three of the HFDF groups received NAM treatment (5, 10, and 15 mM) in drinking water for 16 weeks (5 h/day). While HDL-C and oxidative stress were measured in serum samples, oxidative stress markers, and the gene expression and protein levels of ABCA1 were quantified in liver samples. The HDL-C level altered by the HFDF was improved by treatment with NAM. Furthermore, NAM reduces systemic lipid peroxidation levels and enhances the hepatic antioxidant response affected by the HFDF. In addition, NAM modulates the hepatic ABCA1 gene expression and protein level, altered by the HFDF. Our results suggest that NAM may modify the serum HDL-C level by an improvement of antioxidant response, and a possible modulation of the hepatic ABCA1 gene and protein expression. Further metabolic and molecular studies are needed to support the potential therapeutic role of NAM to prevent or treat lipid alterations promoted by a hypercaloric diet. Full article

Background/Objectives: Compartmentalized glucose metabolism in the brain contributes to neuro-metabolic stability and shapes hypothalamic control of glucose homeostasis. Glucose transporter-2 (GLUT2) is a plasma membrane glucose sensor that exerts sex-specific control of hypothalamic astrocyte glucose and glycogen metabolism. Aging causes counterregulatory dysfunction. Methods: The current research used Western blot and HPLC–electrospray ionization–mass spectrometry to investigate whether aging affects the GLUT2-dependent hypothalamic astrocyte metabolic sensor, glycogen enzyme protein expression, and glycogen mass according to sex. Results: The data document GLUT2-dependent upregulated glucokinase (GCK) protein in glucose-deprived old male and female astrocyte cultures, unlike GLUT2 inhibition of this protein in young astrocytes. Glucoprivation of old male and female astrocytes caused GLUT2-independent downregulation of 5′-AMP-activated protein kinase (AMPK) protein, indicating loss of GLUT2 stimulation of this protein with age. This metabolic stress also caused GLUT2-dependent suppression of phospho-AMPK profiles in each sex, differing from GLUT2-mediated glucoprivic enhancement of activated AMPK in young male astrocytes and phospho-AMPK insensitivity to glucoprivation in young female cultures. GS and GP isoform proteins were refractory to glucoprivation of old male cultures, contrary to downregulation of these proteins in young glucose-deprived male astrocytes. Aging elicited a shift from GLUT2 inhibition to stimulation of male astrocyte glycogen accumulation and caused gain of GLUT2 control of female astrocyte glycogen. Conclusions: The outcomes document sex-specific, aging-related alterations in GLUT2 control of hypothalamic astrocyte glucose and ATP monitoring and glycogen mass and metabolism. These results warrant future initiatives to assess how these adjustments in hypothalamic astrocyte function may affect neural operations that are shaped by astrocyte–neuron metabolic partnership. Full article

Background/Objectives: Muscle aging is a complex, dynamic process that impairs overall metabolism and physiological function. The molecular mechanisms underlying declines in muscle performance and metabolic efficiency remain poorly understood, largely due to the time and resource demands of traditional model organisms. The hawk moth Manduca sexta offers a promising alternative, with a short adult lifespan (~10 days) and notable similarities to vertebrate muscle systems, making it well-suited for time-course molecular dissection of muscle aging. Methods: In this study, we performed high-resolution temporal analysis of muscle tissues from aging M. sexta, spanning the physiomuscular aging process from middle age to advanced age. Results: We observed decreased expression of genes involved in fatty acid β-oxidation, ATP synthase subunits, superoxide dismutase, glutathione S-transferases, and heat shock proteins. In contrast, genes associated with proteolysis, catabolic processes, insulin signaling, akirin, titin, high-affinity choline transporters, and vesicular acetylcholine transporters were increased in expression. Conclusions: These changes suggest a shift toward increased proteolysis and protein catabolism with age. Our findings support the use of M. sexta as a complementary model for muscle aging research. However, it remains unclear whether the observed gene expression changes are driven by intrinsic, sex-specific age-related muscle aging or confounded by potential starvation effects in older males. Full article

Background: Point mutations in mitochondrial DNA (mtDNA) cause a range of neurometabolic disorders that currently have no curative treatments. The m.8993T>G mutation in the Homo sapiens MT-ATP6 gene leads to neurogenic muscle weakness, ataxia, and retinitis pigmentosa (NARP) when heteroplasmy exceeds approximately 70%. Methods: We engineered a split DddA-derived cytosine base editor (DdCBE), each half fused to programmable TALE DNA-binding domains and a mitochondrial targeting sequence, to correct the m.8993T>G mutation in patient-derived induced pluripotent stem cells (iPSCs). Seven days after plasmid delivery, deep amplicon sequencing showed 35 ± 3% on-target C•G→T•A conversion at position 8993, reducing mutant heteroplasmy from 80 ± 2% to 45 ± 3% with less than 0.5% editing at ten predicted off-target loci. Results: Edited cells exhibited a 25% increase in basal oxygen consumption rate, a 50% improvement in ATP-linked respiration, and a 2.3-fold restoration of ATP synthase activity. Directed neural differentiation yielded 85 ± 2% Nestin-positive progenitors compared to 60 ± 2% in unedited controls. Conclusions: Edits remained stable over 30 days in culture. These results establish mitochondrial base editing as a precise and durable strategy to ameliorate biochemical and cellular defects in NARP patient cells. Full article

Background: Renal ischemia–reperfusion (I/R) injury represents a principal etiologic factor in acute kidney injury (AKI), in which ferroptosis plays a critical role. Mulberrin (Mul), a prenylated flavonoid with antioxidative properties, has an as-yet undefined role in renal I/R injury. Methods: We established a mouse renal IRI model and an HK-2 H/R system. Renal function, histological injury, oxidative stress, ferroptosis markers, and mitochondrial function were assessed. The role of Sirtuin 3 (Sirt3) in Mul-mediated effects was further examined using siRNA knockdown in HK-2 cells. Results: The administration of Mul led to a marked improvement in renal function, lessened tubular injury, and reduced apoptosis in IRI mice. Mul also restored GSH levels, decreased MDA and Fe²⁺ accumulation, and normalized expression of ferroptosis-related proteins, thereby suppressing ferroptosis. In H/R-injured HK-2 cells, Mul restored mitochondrial membrane potential, increased ATP production, and reduced ROS accumulation. Mechanistically, Mul markedly upregulated Sirt3 expression, and silencing Sirt3 abolished its antioxidant and anti-ferroptosis effects, confirming the essential role of Sirt3 in Mul-mediated protection. Conclusions: Our findings underscore Mul’s therapeutic promise in acute kidney injury and provide a mechanistic foundation for interventions directed at the Sirt3–ferroptosis pathway to safeguard renal function. Full article

Early cellular alterations in abdominal aortic aneurysm (AAA) are scarcely investigated. Aortic remodeling inflammation-related suggested the CXCR2/CXCL1/IL-8 axis as a therapeutic target. This study investigates CXCR1/CXCR2 antagonism in primary human aortic endothelial (HAOEC) and smooth muscle cells (HAOSMC) conditioned with IL-8 or serum from patients with AAA (sPT). Ladarixin (10 μM Lad or 25 μM) served as an inhibitor. Readouts included RT-qPCR for CXCL1, CXCL8, CXCR2, MMP9, NFKB1, and VEGF-A; zymography for MMP9 activity confocal microscopy for F-actin and mitochondria; NADPH/NADH diaphorase histochemistry for redox activity; and ATP assay. In HAOEC, IL-8 downregulated CXCR2, increased MMP9 activity, and induced cytoskeletal and mitochondria disorganization without altering NADH/NADPH diaphorases but increasing ATP release. At concentration of 10 μM Lad rescued cell organization and gene expression. sPT upregulated CXCL8, CXCR2, and MMP9, decreased NADH/NADPH diaphorases, and altered cytoskeleton and mitochondria organization in HAOEC. At concentration of 10 μM Lad (partially) and 25 μM Lad reverted gene upregulation and mitochondria distribution; both doses increased diaphorase and released ATP. HAOSMC were scantily susceptible to IL-8 and weakly responsive to sPT, slightly upregulating CXCR2 and VEGF-A but increasing proMMP9 gelatinolysis. Ladarixin recovered proMMP9 activity and modulated CXCL1. AAA-like vascular cell alterations involve multiple inflammatory factors and are modulable by inhibition of IL-8 receptors. The results underline careful dose calibration. Full article

Oxidative stress-mediated dysfunction of granulosa cells (GCs) is recognized as a pivotal driver of prehierarchical follicular atresia in poultry, contributing substantially to the reduced egg production in aged laying hens. Here, we investigated the protective effects of the natural flavonol, fisetin, on aged chicken follicular GCs. A D-galactose (D-gal)-induced aging model of GCs was established to evaluate the protective role of fisetin against cellular senescence. Small yellow follicles (SYFs) from 580-day-old hens were cultured with fisetin for 72 h to verify its ameliorative effect on naturally aged follicles. Fisetin reduced the typical characteristic of senescence in D-gal-induced GCs, as reflected by decreased senescence-associated β-galactosidase (SA-β-gal) activity and increased expression of proliferation-related proteins, including cyclin D1 (CCND1), cyclin-dependent kinase 2 (CDK2), cyclin-dependent kinase 1 (CDK1), and Cyclin B1. Furthermore, fisetin enhanced the activity of antioxidant enzymes by activating the Nrf2/HO-1 signaling pathways, while attenuating mitochondrial dysfunction and promoting ATP production in senescent GCs. Additionally, fisetin significantly promoted nuclear translocation of β-catenin, and suppressed the expression of senescence marker proteins p53 and p21, thereby alleviating cell cycle arrest in D-gal-induced senescent GCs. Simultaneous inhibition of Nrf2/HO-1 and β-catenin signaling also abolished the beneficial effects of fisetin on oxidative stress and cell proliferation in naturally senescent follicles. These findings indicate that fisetin prevents follicular atresia by suppressing GCs oxidative damage and improving cell cycle arrest via activating the Nrf2/HO-1 and Wnt/β-catenin signaling pathways. Full article

The ABCB subfamily, a subset transporter of the ATP-binding cassette (ABC) superfamily, is vital for various plant life processes, especially in the transport of polar auxin and brassinosteroids. Although ABCB transporters have been characterized in diverse plant species, their specific functions in wheat remain largely unexplored. In this study, we identified 99 TaABCB members in wheat and categorized them into four groups based on their conserved domains and phylogenetic relationships. These members were found to be unevenly distributed across all 21 wheat chromosomes. We conducted a comprehensive genome-wide analysis encompassing gene structure, protein motifs, gene duplication events, collinearity, and cis-acting elements. Transcriptome analysis revealed that different TaABCB members displayed distinct expression patterns under phosphate starvation stress. Notably, we discovered that TaABCB7 might play a role in regulating wheat’s phosphate starvation. Crucially, we pinpointed an elite haplotype, H001, of the candidate gene TaABCB7, which has been progressively selected and employed in wheat breeding improvement programs. Overall, this study enhances our comprehensive understanding of TaABCB members and offers a potential gene resource for molecular marker-assisted selection breeding in wheat. Full article

Cancer immunotherapy has redefined oncology’s goals, aiming for durable systemic immunity rather than mere cytoreduction. However, many solid tumors remain refractory due to immunosuppressive microenvironments and antigenic heterogeneity. Local tumor ablation techniques—including radiofrequency ablation (RFA), microwave ablation (MWA), cryoablation, irreversible electroporation (IRE), and high-intensity focused ultrasound (HIFU)—are being re-evaluated beyond their historic cytoreductive role. This comprehensive review synthesizes the paradigm of tumor ablation as an in situ vaccination strategy, a concept that leverages the tumor itself as a source of antigens and the ablation process to generate endogenous adjuvants. We detail the mechanistic underpinnings, highlighting how ablation induces immunogenic cell death (ICD), releasing damage-associated molecular patterns (DAMPs) such as calreticulin, ATP, HMGB1, and cytosolic DNA. These signals activate innate immunity via pathways like cGAS-STING, promote dendritic cell maturation, and facilitate epitope spreading. We critically examine the determinants of efficacy, including the critical impact of ablation modality on the “DAMP signature,” the necessity of complete ablation, and the pivotal role of the host’s immune contexture. Furthermore, we explore the induction of tertiary lymphoid structures (TLS) as a key anatomical site for sustained immune priming. Translational strategies are extensively discussed, focusing on optimizing procedural techniques, rationally combining ablation with immune checkpoint inhibitors (ICIs) and innate immune agonists, and developing a robust biomarker framework. By adopting the core principles of vaccinology—meticulous attention to antigen, adjuvant, route, and schedule—ablation can be engineered into a reproducible platform for systemic immunotherapy. This review concludes by addressing current limitations and outlining a roadmap for clinical translation, positioning interventional oncology as a central discipline in the future of immuno-oncology. Full article

This study investigates the mechanisms underlying osteocyte injury in a high glucose (HG) environment and explores potential therapeutic targets and diagnostic markers for diabetic osteoporosis, a common complication of type 2 diabetes mellitus (T2DM). Hyperglycemia induces oxidative stress through the reactive oxygen species (ROS) production, which impair osteocytes and accelerate bone loss. To examine these effects, MLO-Y4 cells and primary mouse osteocytes were cultured under normal glucose and HG conditions, with additional treatments using N-acetylcysteine (NAC, ROS scavenger) and rapamycin (autophagy promoter and mTOR inhibitor). Cell viability, ROS levels, and the autophagy and apoptosis markers expression (Beclin1, LC3, p62, Bax, Bcl2, cytochrome C, and caspase3) were assessed using CCK8/ATP level assay, flow cytometry, Western blot, qRT-PCR, immunofluorescence, and TUNEL staining. The results showed that HG inhibits cell proliferation, induces insulin resistance, generates ROS, alters antioxidant enzymes, and promotes oxidative stress, leading to mTOR activation, subsequent autophagy inhibition, and osteocyte apoptosis. NAC mitigated these effects, while rapamycin prevented HG-induced apoptosis by inhibiting mTOR activation and promoting autophagy. This suggests that ROS-induced mTOR activation impairs autophagy and hinders the clearance of damaged osteocytes, triggering apoptosis. This research provides foundational evidence and novel insights into diabetic osteoporosis pathogenesis and potential therapies. Full article

Background: Thrushes (family Turdidae) are ecologically important passerine birds widely distributed across the Northern Hemisphere. However, the phylogenetic placement of several East Asian congeners, including Turdus pallidus, remains insufficiently resolved due to the limited resolution of partial mitochondrial or nuclear markers used in previous studies. Methods: In this work, we sequenced and annotated the complete mitochondrial genome of T. pallidus (16,739 bp) using high-throughput Illumina sequencing. The mitogenome exhibited the typical circular architecture and contained 37 genes (13 protein-coding genes, 22 tRNAs, and 2 rRNAs), with an overall GC content of 47.32%. Results: Most protein-coding genes initiated with the standard ATG codon, although lineage-specific deviations such as GTG in COX1 and ND2 were identified, and incomplete stop codons (T– or TA–) were observed, consistent with post-transcriptional polyadenylation. The 22 tRNA genes displayed typical cloverleaf secondary structures, except for trnS(AGN), which lacked a DHU arm, while rRNA genes were 977 bp (12S, 48.52% GC) and 1590 bp (16S, 44.65% GC), showing conserved stem regions but variable loop regions. Codon usage analysis revealed a strong bias toward A/T-ending codons, with a total of 3798 codons and an effective number of codons (ENC) of ~40, indicating moderate codon bias shaped by both mutational pressure and translational selection. Comparative analysis of evolutionary rates demonstrated that conserved genes such as COX1 and CYTB are suitable for resolving deeper relationships, whereas rapidly evolving genes like ATP8 provide resolution among closely related taxa. Conclusions: Phylogenetic reconstructions based on 13 mitochondrial protein-coding genes robustly supported the monophyly of Turdidae and recovered T. pallidus as most closely related to T. obscurus. Overall, this study provides a novel mitogenomic resource for T. pallidus, enhances phylogenetic resolution within Turdus, and underscores the value of complete mitochondrial genomes for molecular identification, conservation management, and avian evolutionary studies. Full article

Background/Objectives: Polygoni Cuspidati Rhizoma et Radix (PCRR) is an herb and a source of a resveratrol-containing dietary supplement. Breast cancer resistance protein (BCRP) is an ATP-binding cassette transporter involved in numerous drug-related pharmacokinetic interactions. This study used both in vivo and in vitro models to investigate the modulation effect of PCRR ingestion on BCRP. Methods: Three groups of rats were orally administered methotrexate (MTX), a probe substrate of BCRP, without and with PCRR at 1.0 g/kg and 2.0 g/kg in a parallel design, and the MTX pharmacokinetics were compared among three treatments. The modulation effects of PCRR and its serum metabolites (PCRRM) on BCRP were assayed by in vitro models. Results: PCRR at 1.0 g/kg and 2.0 g/kg significantly decreased the area under the serum level–time curve from 0 to 240 min (AUC_0-240) of MTX by 31% and 58%, respectively; 2.0 g/kg of PCRR markedly increased the area under the serum level–time curve from 240 to 2880 min (AUC_240-2880) and the mean residence time (MRT) of MTX by 39% and 74%, respectively. The results of in vitro assays indicated that PCRR enhanced the function of BCRP by 33~48%; on the contrary, PCRRM reduced the function of BCRP by 200~209%. Conclusions: PCRR activated BCRP, whereas PCRRM inhibited BCRP, thereby the coadministration of PCRR reduced both the absorption and excretion of MTX in rats. In clinical practice, the concurrent use of PCRR with critical BCRP substrate drugs should be avoided. Full article

Parthanatos represents an alternative form of regulated cell death (RCD) mediated by poly (ADP-ribose) polymerase-1 (PARP-1). However, the underlying mechanisms and physiological significance of parthanatos are poorly understood. In this study, we investigated molecular mechanisms of parthanatos in human fibrosarcoma HT1080 cells using biochemical and cellular experiments, and found that parthanatos induced by the alkylating agent N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) is mediated by two alternative pathways that depend on pro-death Bcl-2 family proteins BAX/BAK or Bcl-2-interacting mediator of cell death (Bim). Moreover, we found that MNNG activates AMP-activated protein kinase (AMPK) through PARP-1-dependent ATP depletion, and then AMPK selectively downregulates MNNG-induced parthanatos mediated by Bim but not BAX/BAK. Under unstimulated conditions, expression levels of Bim were below the detection limit. Interestingly, MNNG strongly upregulated the protein expression levels of Bim, but only when the activation of AMPK was inhibited. These observations suggest that the AMPK signaling pathways activated by PARP-1-dependent ATP depletion limit parthanatos by blocking the Bim upregulation triggering Bim-mediated parthanatos. Thus, our results demonstrate a novel relationship between AMPK and parthanatos, which may provide insights into the physiological roles of parthanatos. Full article

The inner mitochondrial membrane proteins ATP/ADP carrier protein 1 (AAC1) and Uncoupling protein 1 (UCP1) belong to the SLC25 mitochondrial carrier family. AAC1 is responsible for ATP/ADP exchange, while UCP1-dependent proton transport, which also requires small molecules known as activators, is the basis of brown fat thermogenesis. Arachidonic acid (AA) is an endogenous activator capable of inducing proton transport in both proteins. As such, both AAC1- and UCP1-dependent proton transport are potential targets of weight loss drugs. While AAC1 structures have long been available, only recently have structures of UCP1 been determined. Unfortunately, no AA-bound structure of either protein is available. To explore their interactions with AA, we performed molecular dynamics (MD) simulations of both proteins. Six parallel simulations of each protein were run with an average length of just over 6 μs, for a total of 75 μs of aggregate simulation across both proteins. AA bound deeply between transmembrane helix (TM) helices or in the central cavity of AAC1 in 14 events and between TM helices of UCP1 in 6 events. All AA involved in these deep binding events came from the intermembrane space-facing (C) leaflet. In AAC1, AA most often bound between TM1/TM2 and TM5/TM6. In four cases the fatty acid bound at the bottom of the central cavity rather than in an interhelical groove. In UCP1, all but one deeply bound AA sat between TM5 and TM6. No AA fully entered the cavity as observed in AAC1. In addition to entering the proteins, AAs were enriched around them in the surrounding membrane adjacent to the TM helices. While both protein structures exhibit hydrophobic stretches separating the intermembrane space (IMS) from the matrix, water wires formed through both AAC1 and UCP1, connecting the bulk water in both regions. Grotthuss shuttling along water wires has been proposed as a possible mechanism of AAC1/UCP1-dependent proton transport, but water wires are not present in experimental structures and have not previously been reported in MD simulations. Calculations of electric potentials along these water wires find a large 0.75–1 V electrostatic barrier along water wires through AAC1 and a substantially smaller such barrier of ~0.5 V through UCP1. Full article