Search Results (6,411)

Obesity increases susceptibility to ventricular arrhythmias due to an arrhythmogenic substrate by promoting oxidative stress and inflammation-driven cardiac remodeling. Klotho, an anti-aging protein that is reduced in obesity-related cardiovascular disease, protects against oxidative injury and inflammation. Berberine (BBR) has been demonstrated to have antiarrhythmic properties, but Klotho mediates these effects in obesity remains unclear. Here, high-fat diet (HFD)-induced obese rats were treated with BBR for 8 weeks. Surface electrocardiography showed BBR shortened prolonged QT, QTc, and Tp-Te intervals. Optical mapping of isolated hearts revealed that BBR eliminated arrhythmia susceptibility (60% to 0%) and stabilized cardiac electrophysiology by shortening action potential duration (APD₅₀/APD₉₀), reducing repolarization dispersion, normalizing conduction velocity, and improving abnormal intracellular Ca²⁺ handling. BBR also attenuated cardiac hypertrophy and fibrosis and increased expression of the potassium channel subunits Kv4.2, Kv4.3, and KChIP2. Furthermore, BBR suppressed oxidative stress and inflammation while upregulating circulating and tissue Klotho levels in obese rats. In ox-LDL-treated H9C2 cells, Klotho silencing abolished the antioxidative and anti-inflammatory effects of BBR, indicating that Klotho is required for its cardioprotective actions. These findings demonstrate that BBR stabilizes the arrhythmogenic substrate in obesity-related cardiac remodeling, at least partly through upregulation of Klotho expression and subsequent attenuation of oxidative stress and inflammation. Full article

Natural killer (NK) cells are crucial components of innate immunity and rapidly eliminate abnormal cells through ligand–receptor signaling without prior sensitization. Vitamin C is known to enhance NK cell function; however, its susceptibility to oxidation may limit its efficacy in NK cell activation. This study evaluated the efficacy of Aptamin C, a stabilized conjugate of vitamin C and an aptamer, in enhancing NK cell activation. In the in vivo randomized placebo-controlled study, 120 participants were randomized to receive either Aptamin C or placebo, and 109 participants were included in the final analysis. Participants received Aptamin C at a dose of 36.057 mg/day or placebo for 4 weeks. The results showed significant increases in NK cell cytotoxicity after 2 and 4 weeks in the Aptamin C group. Additionally, serum levels of cytokines and cytotoxic granules associated with NK cell activity peaked 4 weeks after Aptamin C intake. Subgroup analysis showed that the enhancing effect of Aptamin C on NK cell activity was mainly observed in participants older than 40 years, whereas no significant effects were detected in participants aged <40 years. In the in vitro study, NK-92 cells treated with Aptamin C were compared with NK-92 cells treated with vitamin C. Aptamin C treatment enhanced proliferation, survival, cytotoxicity, and cytotoxic granule production in NK-92 cells compared with vitamin C treatment. These findings indicate that Aptamin C may effectively promote NK cell activation, particularly in middle-aged and older adults, and suggest its potential as an immunomodulatory supplement for supporting NK cell function. Full article

The YABBY family consists of plant-specific transcription factors that regulate organ polarity and reproductive development. As a member of this family, CRABS CLAW (CRC) plays crucial roles, but its molecular mechanism in oilseed rape stigma development remains unclear. In this study, we identified YABBY genes in four Brassicaceae species. The results showed that CRC proteins are highly conserved in structure, but their cis-acting elements vary among species. To explore its function, we performed transcriptome sequencing on an oilseed rape CRC-deficient mutant (sd). The transcriptome data revealed multiple changes in the sd mutant. Specifically, brassinosteroid (BR) signaling factors were downregulated. Sugar transporters and auxin-related genes showed abnormal expression. Furthermore, pro-senescence and programmed cell death (PCD) genes were upregulated, whereas the classic senescence pathway remained unchanged. Based on these findings, we propose a potential mechanism. The loss of CRC disrupts BR signaling, sugar transport, and calcium homeostasis. This disruption triggers non-classic death of stigma papilla cells, which hinders pollen tube penetration and reduces seed set. Notably, increasing environmental humidity partially rescued the seed set, likely by delaying cell death. Although these transcriptomic insights warrant further experimental validation, this study provides valuable clues and genetic resources for future research on reproductive development in oilseed rape. Full article

Oxidative stress has been recognized as a repeatedly validated pathophysiological factor in schizophrenia, but its mechanistic role and translational relevance remain incompletely defined. Prior work has advanced redox dysregulation, neuroinflammation, and NMDA receptor hypofunction as a putative central hub in schizophrenia. This narrative review proposes an evidence-weighted redox–mitochondria–immune framework that integrates peripheral biomarkers, magnetic resonance spectroscopy, postmortem findings, and preclinical mechanisms while explicitly distinguishing established observations from candidate pathways. Existing studies support increased oxidative damage and altered antioxidant buffering in schizophrenia, particularly involving the glutathione system. However, these abnormalities are neither uniform across disease stages nor equally represented across patient subgroups, and may be markedly prominent only in certain biological subgroups. Mechanistically, redox imbalance may interact with mitochondrial bioenergetic deficits and innate immune signaling; however, pathway-specific links such as cGAS-STING activation, nitrosative/peroxynitrite stress, and GPx4-ferroptosis should currently be treated as testable extensions rather than validated human mechanisms in schizophrenia. Importantly, the pathological consequences of oxidative stress are unlikely to be cell-type neutral. Parvalbumin-positive interneurons and oligodendrocyte lineage cells are more vulnerable because of their high metabolic load, limited antioxidant buffering capacity, and lipid/iron-related susceptibility, thereby providing a mechanistic bridge to excitation–inhibition imbalance, myelin abnormalities, and reduced circuit synchrony. Microglial redox–inflammatory signaling may further exacerbate these processes. On the basis of this framework, we argue that the key for future research is not to continue demonstrating the universality of oxidative stress, but to improve the translational efficiency. Biomarker-guided stratification, stage-sensitive study designs, and cell-type-informed therapeutic strategies may therefore provide a more productive path toward redox-targeted interventions in schizophrenia. Full article

Centrosomal protein 152 (CEP152) is a key regulator of centriole architecture and function, essential for proper cell division and polarity. Pathogenic variants in CEP152 cause Seckel syndrome (SCKL), a systemic disorder characterized by microcephalic primordial dwarfism. However, the mechanisms underlying its multi-organ manifestations remain poorly understood. To investigate this, we utilized two mouse models harboring patient-derived CEP152 variants, Cep152^W105*/K897* and Cep152^Q32P/Q32P. While our previous work focused on neurodevelopmental defects, here we systematically analyzed extra-neuronal phenotypes. We identified impaired spermatogenesis, characterized by defective mitosis and increased apoptosis in spermatogonia, as well as hematological abnormalities indicative of macrocytic anemia. In addition, we found reduced expression of Opalin, a gene involved in oligodendrocyte differentiation, and decreased numbers of Olig2-positive oligodendrocytes, suggesting broader glial deficits beyond recently characterized neuronal abnormalities. Collectively, our results highlight the role of CEP152 dysfunction in multi-systemic abnormalities of SCKL and provide an integrative view of its impact on both neuronal and extra-neuronal development. Full article

Improvement in the in vitro maturation (IVM) of oocyte quality is a gateway to enhancing the efficiency of in vitro embryo production. The anti-Müllerian hormone (AMH) is a crucial hormone secreted by granulosa cells that effectively suppresses primordial follicle recruitment and regulates follicular growth and development. This study was designed to investigate the role of AMH on the IVM of sheep oocytes. In this current study, oocytes in vitro were cultured in media supplemented with AMH. We comprehensively analyzed the impact of AMH on various developmental parameters of sheep oocytes, such as cellular activity, cortical granules (CGs) migration, cytoskeleton and mitochondrial function of oocytes. Furthermore, Smart-seq2 single-cell RNA sequencing (scRNA-seq) was employed to elucidate the oocytes’ development. The results showed that treatment with 100 ng/mL improved the maturation rate of the oocytes, the normal distribution rate of cortical granules and mitochondrial function, while reducing the rate of spindle abnormalities in oocytes. A total of 741 differentially expressed genes (DEGs) were observed between the FSH_12 h and AMH_12 h groups, and 746 DEGs were observed between the FSH_24 h and A+F groups. KEGG pathway analysis revealed that the FSH_12 h and AMH_12 h groups significant enrichment in DEGs were associated with p53, MAPK, PI3K-Akt and TGF-beta signaling pathways, and the FSH_12 h and AMH_24 h groups significant enrichment in DEGs were associated with cAMP, AMPK, Hedgehog and estrogen signaling pathways. These findings suggest that AMH may regulates oocytes IVM via several candidate signaling pathways. Our results provide preliminary clues for exploring the regulatory mechanism of sheep oocyte maturation and optimizing relevant culture systems. Full article

The gastric endocrine population comprises functionally distinct cell types that exhibit both neuronal and endocrine characteristics; however, their molecular markers remain incompletely defined. Here, we identify growth differentiation factor 9 (GDF9), nephrin (NPHS1), and rearranged during transfection (RET) as novel markers of gastric endocrine cells. A co-immunofluorescence (IF) analysis demonstrated that GDF9, NPHS1, and RET are co-expressed with chromogranin A (CHGA), a well-known marker of gastrointestinal endocrine cells. Further Co-IF analysis revealed that GDF9-expressing cells were negative for ghrelin and somatostatin, whereas NPHS1 was co-expressed with both hormones. A subpopulation of RET-positive cells co-expressed ghrelin but not somatostatin. Notably, GDF9- and RET-positive cells co-expressed dopamine decarboxylase (DDC), consistent with enrichment in enterochromaffin-like (ECL) cells. Revisitation of our previous mRNA-sequencing data revealed reduced transcript levels of Gdf9, Nphs1, and Ret in CA-PKA mice, which express constitutively active protein kinase A (PKA) and develop gastric preneoplastic lesions. Co-IF and cellular quantification showed a localized reduction in the density of GDF9 and CHGA-positive endocrine cells, together with altered abundance of NPHS1- and RET-expressing cells in CA-PKA stomachs. These changes occurred in the context of extensive hyperplasia of the surrounding epithelium, indicating that the observed alterations reflect localized reduction and non-cell-autonomous effects of epithelial expansion. Notably, we observed RET misexpression outside the endocrine compartment in CA-PKA mice, suggesting that aberrant RET signaling may contribute to lesions by promoting abnormal glandular branching. Together, these findings identify GDF9, NPHS1, and RET as novel markers of gastric endocrine cells and their potential role in gastric homeostasis. Full article

Background: Multiparameter flow cytometry is widely used in the diagnosis of acute leukemia, allowing for rapid identification of leukemic cells based on their immunophenotype. The EuroFlow Acute Leukemia Orientation Tube was designed as a standardized screening tool to support early diagnostic orientation and guide further, more targeted testing. In this study, we assessed the diagnostic performance of the ALOT panel in pediatric patients with suspected acute leukemia. Methods: A total of 254 pediatric patients (0–18 years) with suspected acute leukemia were analyzed. Bone marrow samples were assessed using multiparameter flow cytometry with the EuroFlow ALOT panel, comprising eight markers (MPO, cyCD79a, CD34, CD19, CD3, cyCD3, CD7, and CD45). Final diagnoses were established using extended immunophenotypic panels and additional diagnostic methods when required. Samples were processed according to EuroFlow standard operating procedures and acquired on FACSCanto II and FACSCanto 10-color flow cytometers (BD Biosciences). Diagnostic performance was assessed by calculating sensitivity, specificity, precision, accuracy, and negative predictive value. Results: Among 254 patients, 234 were diagnosed with hematologic disorders, while 20 had normal bone marrow findings. The ALOT panel correctly identified all pathological samples and did not misclassify any normal sample, resulting in 100% sensitivity, specificity, positive predictive value, negative predictive value, and accuracy for discrimination between abnormal and normal samples. In terms of exact diagnostic orientation, ALOT correctly classified 244 of 254 cases (96.1%) using a single-tube approach. The remaining 10 cases (3.9%), including rare entities such as Burkitt leukemia, chronic myeloid leukemia, and transient myeloproliferative syndrome, required extended immunophenotypic evaluation. Importantly, these cases were not false negative results, as all were correctly identified as abnormal. Conclusions: The EuroFlow ALOT panel is a reliable screening tool for rapid diagnostic orientation in pediatric acute leukemia. Its implementation facilitates targeted selection of extended immunophenotypic panels, improving the efficiency and cost-effectiveness of diagnostic workflows. Full article

Pituitary apoplexy is an uncommon but clinically urgent complication that often involves intrasellar hemorrhage and tissue necrosis. The mechanisms linking acute tissue injury to the inflammatory tumor microenvironment remain incompletely defined. Here, we characterized the apoplexy-associated microenvironment and examined whether macrophage mechanosensitive signaling contributes to inflammatory amplification and tissue damage in pituitary neuroendocrine tumors (PitNETs). We combined single-cell RNA sequencing (scRNA-seq), histological validation, clinical stratification, and in vitro functional assays using apoplectic and non-apoplectic human PitNET specimens. Macrophage state transitions, intercellular communication, and transcriptional regulatory programs were analyzed, followed by an experimental assessment of the PIEZO1–Ca²⁺ axis and macrophage-conditioned medium-induced tumor cell death. Histological validation confirmed macrophage accumulation in apoplectic PitNETs, including a 1.67-fold increase in IBA-1-positive cells (p < 0.001). CellChat-inferred interaction metrics increased descriptively in apoplectic samples. Apoplectic tissues showed higher TNF-α expression (3.00-fold; p < 0.0001) and higher PIEZO1 fluorescence in IBA-1-positive regions (1.39-fold; p = 0.001). Yoda1 increased Calcium 520 fluorescence in macrophages (1.72-fold; p = 0.002), whereas Piezo1 knockdown reduced the Yoda1-associated response (p = 0.003). Conditioned medium from activated macrophages increased total Annexin V/PI-positive death in AtT-20 cells (0.53 ± 0.53% to 32.48 ± 1.14%; p < 0.001) and GH3 cells (0.82 ± 0.50% to 30.92 ± 1.11%; p < 0.001); Piezo1 knockdown or TNF-α neutralization attenuated this effect. Clinically, pathological necrosis was associated with higher symptom frequencies and a greater adjusted likelihood of two or more clinical symptoms. Together, these findings indicate that PIEZO1-related macrophage signaling may participate in TNF-α-associated tumor cell necroptosis in pituitary apoplexy. Pathological necrosis was linked to greater acute symptom burden and perioperative hormonal abnormalities, suggesting that it may identify a clinically severe apoplexy subtype. Full article

Hepatocellular carcinoma is challenging to detect at an early stage, and its severity increases over time. Recently, the incidence of hepatocellular carcinoma has increased, partly due to lifestyle-related factors such as excessive alcohol intake, sedentary behavior, and diets high in fat, which contribute to the growing prevalence of fatty liver and hepatitis. Various therapeutic strategies are being explored for hepatocellular carcinoma, among which therapies targeting deubiquitinating enzymes (DUBs) have attracted growing attention. Ubiquitination acts as a crucial modulator in the regulation of intracellular signaling across many diseases. E3 ligase recognizes the target protein and transfers ubiquitin, received from the E2 enzyme, to the lysine residues of the substrate, thereby conferring specificity to the ubiquitination process. Once a ubiquitin chain is attached to a target protein by an E3 ligase, the protein is directed to the ubiquitin–proteasome system (UPS) for degradation. In this process, the 26S proteasome complex recognizes the ubiquitin chain and degrades the target protein, thereby serving as a major mechanism for maintaining protein homeostasis. Through this pathway, cells regulate signal transduction, eliminate abnormal proteins, and perform various essential functions. On the other hand, deubiquitinating enzymes (DUBs) recognize the ubiquitin chains on target proteins and remove them by hydrolyzing the isopeptide bonds of ubiquitin, thereby enabling the target proteins to evade degradation by the proteasome system. Furthermore, deubiquitinating enzymes independently remove ubiquitin from proteins and can serve as central regulators in signaling pathways related to hepatocellular carcinoma. Full article

Background and Objectives: Uterine metastasis from breast carcinoma is rare but poses substantial diagnostic and therapeutic challenges. Invasive lobular carcinoma (ILC) demonstrates a documented predilection for unusual metastatic patterns including the female genital tract, while tamoxifen-associated endometrial pathology may complicate diagnosis in breast cancer survivors. Materials and Methods: We performed a structured PubMed/MEDLINE and Google Scholar search (1980–2025) for cases with histologically confirmed breast primary and uterine involvement; a pooled analysis of demographic, histological, molecular, and clinical variables was performed. Results: 105 individual cases were identified. ILC accounted for 58.0% of histologically classified cases despite representing only 10–15% of breast cancers. Endometrial involvement was present in 68.6%, myometrial in 25.7%, and cervical in 26.7%. Tamoxifen exposure was strongly associated with polyp-substrate metastasis (29.3% vs. 4.7%; Fisher’s exact p = 0.0009; OR 8.41, 95% CI 2.20–32.14). Abnormal uterine bleeding was the dominant presentation (68.1%); 19.8% were asymptomatic. Median latency was 36 months (range from 24 months before to 360 months after the breast cancer diagnosis). Conclusions: Uterine metastasis from breast carcinoma is dominated by invasive lobular histology and frequently involves tamoxifen-associated polyps. A combined immunohistochemical panel (GATA3, TRPS1, E-cadherin, hormone receptors, PAX8) is essential for distinguishing metastatic disease from primary uterine pathology. Endometrial sampling should be considered with a low threshold in breast cancer survivors with abnormal uterine bleeding, and breast imaging is warranted when discohesive cells are encountered without a known breast primary. These proportions describe the published case literature rather than population-based prevalence; because the evidence is limited to case reports and small series, they should not be read as the true frequency of uterine involvement among women with breast cancer. Full article

Flow cytometry is an essential diagnostic method in hematology, and one of its main applications is the assessment of the clonality of mature B cells. We present a case report of a patient referred for the investigation of absolute lymphocytosis. The flow cytometry study revealed an increased percentage of B cells, but it could not establish B-cell clonality, based on the study of surface light chains in combination with the pattern of expression of mature B-cell markers. The diagnosis of Persistent Polyclonal B-cell Lymphocytosis (PPBL) was considered in the differential diagnosis as the mature B cells were found to be immunophenotypically memory B cells. However, due to the markedly elevated count of B cells, molecular testing with Polymerase Chain Reaction (PCR) for B-cell clonality based on IGH (Immunoglobulin Heavy Chain) gene rearrangements was performed, and it revealed the presence of two clones of B cells. Approximately one year later, the same work-up was repeated in the patient’s bone marrow aspirate. By flow cytometry, a distinct clonal B-cell population was isolated, while the molecular testing with PCR for B cell clonality based on IGH heavy-chain gene rearrangements revealed the presence of three clones of B cells. In addition, evaluation of the sample with high-dimensional mass cytometry showed the presence of four major immunophenotypically abnormal B-cell subsets. Full article

Fine particulate matter (PM_2.5) exposure increases the risk of neurodevelopmental abnormalities by disrupting neural stem cell (NSC) proliferation and cell cycle homeostasis, which are critical for normal neurodevelopment. This study investigated the impact of fine particulate matter (PM_2.5) on NSC proliferation and cell cycle using a three-dimensional (3D) graphene oxide (GO) scaffold that mimics the NSC microenvironment. PM_2.5 exposure led to concentration-dependent decreases in NSC viability and induced G0/G1 phase arrest via the marked downregulation of Cyclin D1-Cdk4 and Cyclin E-Cdk2, which critically impact G1/S transition. NSCs in 3D GO scaffolds maintained higher expression of key cell cycle regulators (Cyclin A, Cdk1/Cdk2, APC, and Cdc20) and superior cell viability when suffering PM_2.5 exposure, demonstrating the 3D culture environment was beneficial for NSC proliferation. We speculate that the 3D culture environment is more favorable and protective for cell proliferation. Therefore, these findings highlight the utility of the 3D GO scaffold for studying PM_2.5 effects on growing neural stem cells. This work provides a physiologically relevant in vitro platform that captures microenvironment-dependent neurotoxic responses, consequently offering valuable mechanistic insights into PM_2.5-induced developmental neurotoxicity. Full article

The Popeye domain-containing protein 1 (Popdc1), also known as Bves, plays a crucial role in maintaining skeletal muscle homeostasis, with its variants leading to limb–girdle muscular dystrophy type R25. Skeletal muscles of patients with the homozygous missense variant of Bves exhibit impaired membrane trafficking, while skeletal muscle fibers in bves^S191F homozygous mutant zebrafish are significantly reduced and disorganized. However, the mechanism by which the absence of bves induces skeletal muscle atrophy remains unclear. In this study, we discovered a novel mechanism whereby bves deficiency drives skeletal muscle atrophy by disrupting mitochondrial structure and function. Our findings indicate that bves knockout leads to a significant decrease in zebrafish’s ability to swim, atrophy of skeletal muscle tissue, loss of cell membrane localization signals, and abnormalities in mitochondrial structure and function. After an 8-week intervention of regular aerobic exercise, the symptoms of skeletal muscle atrophy in bves knockout zebrafish were significantly alleviated, and the expression levels of genes and proteins related to mitochondrial were effectively rescued. These findings establish a connection between bves deficiency-induced disruption of mitochondrial structure and function and the onset and progression of skeletal muscle tissue atrophy symptoms, thereby laying a molecular foundation for exercise rehabilitation strategies in atrophic myopathy. Full article

The skin serves as the body’s first line of defense against environmental threats, acting as a barrier between external aggressors and internal systems. Current evidence regarding the roles of sulfur dioxide (SO₂) in biology and medicine is limited. Environmental pollutants, including SO₂, can increase the production of reactive oxygen species in the skin, leading to oxidative damage that may worsen various dermatological conditions. Endogenous SO₂, proposed as the fourth member of the gasotransmitter family, functions as a biological signaling molecule. It is generated in various human skin cells, including vascular smooth muscle cells, endothelial cells, mast cells, keratinocytes, macrophages, adipocytes, fibroblasts, dermal immune cell population, etc, where it performs multiple functions at physiologically relevant concentrations. Endogenous SO₂ plays a crucial role in regulating cell signaling and maintaining skin homeostasis through its antioxidant, anti-inflammatory, and cytoprotective effects. Abnormal generation and metabolism of SO₂ are linked to several critical processes in the skin, including vascular biology, immune response, cell proliferation, pigmentation, malignancy, protective barriers, senescence, and resistance to stress. This paper provides a narrative review of the significant roles of SO₂ in skin health and disease. A comprehensive understanding of the complex molecular effects and mechanisms mediated by SO₂ in human skin, along with the development of gas therapy, will be essential for translating fundamental research into clinical applications. Full article