Search Results (6,590)

Background and Clinical Significance: To our knowledge, there is a lack of electron microscopy studies in hematocornea since 1985, and more so for graft hematocornea after deep anterior lamellar keratoplasty (DALK). This study provides an ultrastructural characterization of hematocornea occurring in a DALK graft. Our study presents several limitations: single-case design and lack of control tissue. Case Presentation: The DALK graft with hematocornea was excised and introduced inside of the operating room in glutaraldehyde solution recipient. The graft was quickly cold-transported to light and transmission electron microscopy. Hematocornea in the DALK transplant graft resulted in features of stromal alteration and dysfunctional cellular clean-up response. The collagen lamellae ultrastructure was affected near electron-dense hem deposits. Two cellular aspects were observed: adaptation and degeneration. Electron-dense granules were found in keratocytes, which may exhibit cellular adaptations, such as vacuoles and phagosomes. Macropinocytosis may mechanistically explain ingestion of electron-dense granules, and dysfunctions in the macropinocytosis process may have led to cell degeneration. Cellular degeneration was marked by loss of organelle contour and loss of cellular membrane integrity (burst-cell aspect). Microscopic corneal alteration corresponded to macroscopic total loss of corneal transparency and elasticity. Conclusions: This study described lamellar ultrastructure alterations and dysfunctional cellular response in hematocornea of a DALK corneal transplant graft. Full article

The transcriptomic effects of hybridization and triploidization were investigated in diploid and triploid rainbow trout, diploid brook trout, as well as triploid hybrids of rainbow trout and brook trout. The examined fish were reared under identical conditions for about two and a half years after hatching. Expression of ten genes involved in cellular respiration (Atp5bp, Slc25a5), mitochondrial functioning (Mrpl28, Micu2), ribosome biogenesis (Rpl24, Rps24), proteasome-mediated protein turnover (Derl1, Psmc2), and protein chaperoning (Hsp90B1, Pdia4) was studied in liver and muscle tissues. Most of the analyzed genes (Atp5bp, Slc25a5, Mrpl28, Micu2, Rpl24, Rps24, Derl1, and Psmc2) displayed comparable expression levels in the liver tissue across the examined triploid hybrids and diploid parental species, with stabilization of genes that were both positively and negatively compensated in the triploid rainbow trout. In turn, significant upregulation of Slc25a5, Derl1, Rps24, and Rpl24 genes, together with downregulation of Micu2 gene, was observed in the triploid rainbow trout liver and muscle, respectively. On the other hand, triploid hybrids showed marked transcriptional upregulation of genes primarily associated with energy metabolism and protein synthesis (Atp5pb, Slc25a5, Rpl24, Rps24, and Pdia4) relative to all the fish groups examined. Although protein-synthesis- and energy-related genes were upregulated in the muscles of triploid hybrids, the recorded growth performance data did not indicate clear evidence of growth heterosis (MPH = −14.3% for body weight; MPH = −0.4% for body length), suggesting that potential benefits of increased heterozygosity in this cross may not be fully reflected in enhanced growth. Three- to four-fold downregulation of the heat shock protein (Hsp90B1) gene was also observed in both tissues of triploid hybrids compared with purebred diploid and triploid trout, which may reflect potential maladaptive genomic effects commonly observed in distant salmonid crosses, suggesting altered stress-response regulation in the examined triploid hybrids. Full article

Different components of the cytoskeleton are very important determinants of brain development. They orchestrate multiple cellular processes involved in all phases of cerebral cortex development. In this review, we summarize current knowledge on the components of the cytoskeleton—microtubules, actin filaments, and intermediate filaments—and their roles in cortical development. We provide a detailed analysis of how cytoskeleton molecules control neuronal progenitor proliferation, neuronal migration, polarization, axon and dendrite specification and outgrowth, and synaptogenesis. We further examine how pathogenic variants in genes encoding cytoskeletal proteins or their regulators disrupt particular steps of neurogenesis and contribute to major neurodevelopmental disorders (NDDs). Focusing on NDDs such as microcephaly, lissencephaly, corpus callosum agenesis, and synaptopathies, we discuss consequences of cytoskeletal dysfunctions causing altered cellular behavior and clinical phenotypes. By linking molecular defects to developmental and phenotypic consequences, this review highlights the cytoskeleton as a central element in neurodevelopmental pathologies and underscores its potential as a target for future therapeutic strategies. Full article

Background/Objectives: Cancer cells are subjected to various stress conditions and have stress adaptability strategies to survive. Various types of stresses lead to the aggregation of cytoplasmic RNA granules known as stress granules (SGs), seen in normal and tumor cells, and aid in cell survival by avoiding cell apoptosis. G3BP stress granule assembly factor 2 (G3BP2) encodes a multifunctional protein with known roles as a critical component of SGs and is also associated with chemoresistance in cancer, but its known roles in non-small cell cancer (NSCLC) are limited. Methods: We evaluated the expression of G3BP2 via qPCR and immunohistochemistry on a retrospective cohort of NSCLC isolated at surgery in St James’s Hospital, Dublin, Ireland. Expression levels were correlated with clinicopathological parameters. Survival analyses, including Kaplan–Meier analyses, were used to determine the prognostic value. Additional correlations with other available NSCLC datasets were explored. Results: In contrast to other studies, we did not observe upregulated expression of G3BP2. Furthermore, Kaplan–Meier analyses did not identify any prognostic value associated with G3BP2 expression in patient tissues in contrast to other published data. Bioinformatic analyses on these other datasets found strong correlations between G3BP2 and core stress granule genes in NSCLC. Additional analyses also identified correlations between G3BP2 expression and immune cell infiltration, immune cell exhaustion, and DNA Damage Response pathways. An examination of the available datasets did not find any overall prognostic value for altered DNA methylation and survival. However, two individual CpG residues were identified for which higher methylation was associated with worse overall survival. Finally, the effects of a G3BP2 inhibitor on cellular proliferation were assessed. Conclusions: In our analysis, G3BP2 was not associated with survival benefit. However, clear associations were observed between altered expression of this gene and a number of important pathways linked to cancer pathogenesis, and further studies are warranted to assess this gene (and/or) stress granules in cancer. Full article

Cholangiocarcinoma (CCA) is a rare malignancy of the biliary tree with increasing global incidence and mortality and limited therapeutic options. Intrahepatic cholangiocarcinoma (iCCA) metabolism exhibits enhanced glycolysis, oxidative phosphorylation, and glutamine utilization. In this study, we investigated the therapeutic potential of targeting glutaminolysis in iCCA, identifying glutamate dehydrogenase (GDH)—which converts glutamate to α-ketoglutarate—as a key metabolic hub. We evaluated the effects of pomegranate waste extract (PWE), a by-product of industrial pomegranate juice production, on cell viability, proliferation, migration, ATP production, and extracellular acidification in CCLP1 cells, an established iCCA model. Our results are consistent with an altered cellular energy metabolism. We further assessed GDH enzymatic activity, expression, and transcriptional regulation in the presence or absence of PWE and its major components, punicalagin and ellagic acid. GDH expression was downregulated by PWE in a dose-dependent manner through inhibition of NF-κB signaling, revealing a new mechanistic link between NF-κB and GDH. In addition, GDH enzymatic activity was dose-dependently inhibited by PWE, as well as punicalagin and ellagic acid. Notably, punicalagin was identified as a novel competitive inhibitor of GDH. Overall, these findings provide the first evidence that modulation of glutaminolysis through GDH targeting impairs iCCA cell growth and metabolism, supporting GDH as a promising metabolic target. This study highlights pomegranate-derived compounds as potential leads for the development of adjunctive or preventive strategies in intrahepatic cholangiocarcinoma. Full article

Melanoma is a highly malignant neoplasm of the skin with early metastatic spread and increasing incidence worldwide. Although there are significant therapeutic advances in immunotherapy, especially with the checkpoint inhibitors targeting PD-1 and CTLA-4, challenges such as treatment-related toxicities, a heterogeneous response to therapy, and drug resistance continue to exist. There are unmet needs for novel therapeutic strategies and/or approaches to complement the existing treatment options. Potential targets for future melanoma treatment are the gap junction proteins, connexins, which show an altered pattern of regulation during melanoma progression. In this review, we highlight the regulation of gap junctions during melanoma progression and the characterization of gap junctions as tumor suppressors during early-stage tumor development and then the reversion to enhancers of tumor metastasis during late-stage melanoma progression. We provide a comprehensive overview of gap junctions in the skin and how the connexin proteins, which comprise gap junctions, are alternatively regulated in melanoma progression. Connexins are protein channels in the human body that consist of 21 isoforms. These isoforms form gap junctions that provide important intercellular signaling and permeability channels. Each connexin protein consists of four transmembrane domains and a C-terminal tail, which is an important part of its function and regulation. Permeants of gap junctions include signaling molecules such as cyclic AMP and inositol triphosphate which are linked to key cellular behaviors such as proliferation and migration, making them essential for several tumor-related processes. At least ten connexin isoforms are found in normal skin. Connexin 43 (Cx43) is classified as the most prevalent isoform while Connexin 26 (Cx26) has been reported to be more specialized with restricted expression patterns. Cx43 and Cx26 regulate the growth, differentiation, and repair of the epidermis after injury. Evidence suggests that connexins have a stage-related function in melanoma. Loss of connexin expression and gap junctional intercellular communication is linked to tumor suppression and loss of differentiation in early-stage melanoma, while re-expression or overexpression of specific connexins, notably Cx43, may promote metastasis through enhanced tumor–stromal interactions and increased motility in late-stage melanoma. Such opposing actions of connexins support their candidacy as biomarkers and therapeutic targets. Understanding the dual-stage related functions of connexins in melanoma development and progression may lead to less cytotoxic and more efficient future therapeutic approaches. Full article

Cognitive dysfunction and neurodegenerative disorders represent an increasing clinical challenge in aging dogs and cats, while objective and minimally invasive biomarkers for early detection and disease monitoring remain limited. Tear film is a biologically active fluid reflecting both local and systemic processes and offers a practical, non-invasive source of potential biomarkers in geriatric veterinary patients. Proteomic analyses of canine and feline tear film have revealed a complex protein composition, including molecules involved in inflammation, oxidative stress, immune regulation, and cellular homeostasis—processes implicated in neurodegeneration. However, growing evidence from human and veterinary research emphasizes the importance of CNS-specific and mechanistically informative biomarkers, such as markers of axonal injury, synaptic degeneration, and glial activation, which may provide a more precise framework for interpreting peripheral proteomic alterations. This review summarizes current knowledge on tear film proteomics in dogs and cats and discusses its potential relevance to cognitive dysfunction and neurodegenerative processes. Particular attention is given to the integration of tear-derived proteins with validated blood and cerebrospinal fluid biomarkers, as well as to methodological challenges and future research priorities. With appropriate standardization and clinical validation, tear film proteomics may contribute to the development of novel diagnostic and monitoring strategies for neurodegenerative disorders in companion animals. Full article

The growing popularity of electronic cigarettes (e-cigarettes) necessitates a better understanding of their biological effects. In this study, we aimed to evaluate the effects of e-cigarette aerosol condensates generated from either e-cigarette carrier liquid alone or with e-cigarette liquid with nicotine and flavor on bronchial epithelial cells. BEAS-2B cells were exposed to e-cigarettes for 24 h, and transcriptional and proteomic profiling, including assessment of protein modifications, was performed. Additionally, cell-based assays were used to evaluate mitochondrial function, rate of protein synthesis, lysosomal signal, lipid droplet quantity and actin formation. Our findings reveal that short-term exposure to both types of aerosol condensates altered transcriptome and proteome profiles, disrupting cellular homeostasis in BEAS-2B cells through impaired proteostasis and mitochondrial function in response to both types of condensates. Changes in lipid and lysosome content, as well as a reduction in polymerized actin, were observed with nicotine- and flavor-containing condensate. E-cigarette exposure also induced irreversible protein modifications, including different chemical derivatives (25 out of 49 in nicotine/flavor condensate; 20 out of 48 in nicotine/flavor-free condensate; 4 out of 35 in control), suggesting their particularly harmful effect. Together, these findings point to early-onset cellular stress and impaired lung epithelial fitness caused by acute e-cigarette exposure. Full article

Immunosenescence is characterized by an age-associated decline in immune function, particularly involving T-cell dysfunction, which increases susceptibility to infections and chronic diseases. This study investigated the anti-aging and immunomodulatory effects of American ginseng extract (G1899) using in vitro and in vivo models of aging. Cellular senescence was induced in HepG2 cells by D-galactose treatment, followed by exposure to G1899 (20 and 100 μg/mL). Senescence-associated markers were assessed to evaluate cellular aging. An aging mouse model was established in male C57BL/6 mice through intraperitoneal administration of D-galactose (500 mg/kg) and tert-butyl hydroperoxide (0.4 mmol/kg), and G1899 was orally administered at 400 mg/kg. Thymic immune cell subsets and aging-related protein expression were analyzed using flow cytometry and Western blotting. G1899 significantly reduced p21 expression and senescence-associated β-galactosidase activity in senescent HepG2 cells. In aging-induced mice, G1899 restored CD4⁺ and CD8⁺ T-cell populations, normalized naïve T-cell levels, and reduced anergic CD28-negative T cells. Furthermore, G1899 regulated the expression of key aging-related proteins, including FOXO1, Sirt1, p53, and CD38. These findings demonstrate that G1899 attenuates age-related immune alterations by restoring thymic T-cell homeostasis and regulating aging-associated molecular pathways. Full article

Background and Objectives: Mitogen-activated protein kinases (p38, JNK, ERK1/2) regulate key cellular processes essential for kidney development. Disruptions in these signaling pathways can lead to congenital anomalies of the kidney and urinary tract (CAKUT), a major cause of pediatric kidney disease. This study investigates and compares the expression of these molecules in normal fetal kidneys and CAKUT-affected tissues. Materials and Methods: Forty-three human fetal kidney samples, including controls and specimens with horseshoe, hypoplastic, and dysplastic kidneys, were analyzed across developmental phases 2–4 using immunofluorescence. Quantitative image analysis and statistical comparisons were performed between developmental stages and phenotypes. Results: ERK1/2 expression increased during late development in control kidneys but was significantly reduced in hypoplastic kidneys. p38 showed phase-dependent alterations, with early upregulation in dysplastic kidneys and late elevation in horseshoe kidneys. JNK exhibited significant phase-dependent upregulation in horseshoe kidneys. P38 displayed dynamic expression associated with nephron maturation. Conclusions: MAPK pathways show distinct developmental and phenotype-specific expression patterns in human fetal kidneys. These differences reflect divergent pathogenic mechanisms in CAKUT and may support improved molecular characterization of congenital renal anomalies. Full article

Vibrio alginolyticus is a foodborne pathogen commonly found in seafood and freshwater products, causing human illness through the consumption of tainted seafood. Small non-coding RNAs (sRNAs) take effect on the stability and translation of their target mRNAs by base-pairing, thereby quickly altering bacterial physiology and pathogenicity at the post-transcriptional level. This work constructed a label-free in-frame deletion mutant and a complement strain of micX, a cell-density-associated sRNA in V. alginolyticus. The ΔmicX mutant exhibited reduced growth and a reduction in the synthesis of exopolysaccharides, biofilm, and alkaline serine protease. A TMT-based quantitative proteomic analysis comparing ΔmicX with the wild-type strain identified 900 differentially expressed proteins, comprising 376 that were upregulated and 524 that were downregulated. The upregulated proteins are primarily associated with porin activity, transmembrane signaling receptor function, and the two-component system. The downregulated proteins are mainly engaged in processes including biofilm formation, cellular communication, and transmembrane transport activity. Of note, the expression levels of proteins involved in the type VI secretion system, exopolysaccharide synthesis, mannose-sensitive hemagglutinin type IV pili (MSHA), and biofilm formation were significantly reduced in the absence of micX. Furthermore, the expression levels of proteins associated with quorum sensing (particularly LuxR and AphA) changed significantly in the ΔmicX vs. WT comparison. These findings strengthened comprehension of the novel sRNA regulatory network and established a theoretical foundation for additional investigations into the virulence of V. alginolyticus. Full article

Background: Alzheimer’s disease (AD) represents a significant therapeutic challenge, largely attributed to the complex interplay of genetic and non-genetic mechanisms. Among the latter, metabolic dysregulation has emerged as a critical factor influencing disease progression. This study proposes a paradigm shift in our understanding of the role of phosphoglycerate dehydrogenase (PHGDH), a key metabolic enzyme, which, under pathological conditions associated with AD, transitions from a protective role to a pathogenic influence through alterations in its cellular localization and function. Methods: To elucidate the impact of exercise on PHGDH dynamics, a narrative review methodology was employed. We conducted comprehensive searches across bibliographic databases, including PubMed, Scopus, and Web of Science, focusing on peer-reviewed articles that detail the relationship between exercise, PHGDH activity, and AD-related neuroinflammation. The review was structured around specific inclusion criteria, which prioritized studies elucidating the mechanisms underlying PHGDH’s dual role in AD pathology and the influence of exercise on this process. Results: Our findings reveal that under AD-associated stress, PHGDH translocates to the nucleus, facilitating the activation of pro-inflammatory genes such as IKKα and HMGB1, while simultaneously suppressing autophagy and enhancing amyloid beta (Aβ) deposition. However, exercise induces the release of the myokine irisin, which inhibits PHGDH nuclear translocation through AMPK/PGC-1α signaling pathways. Additionally, peripheral effects of exercise are observed in hepatic Kupffer cells, where exercise attenuates PHGDH activity, leading to reduced systemic IL-1β release and neuroinflammation. Conclusions: This study underscores the potential of exercise as a precision intervention in AD management, highlighting its capacity to modulate PHGDH activity and mitigate neuroinflammatory processes. The therapeutic implications of these findings are profound, paving the way for novel diagnostic tools, such as PET probes for assessing PHGDH compartmentalization, and promoting a synergistic approach to “exercise–pharmacotherapy” in the treatment of Alzheimer’s disease. Future research should aim to further delineate the mechanisms by which exercise influences metabolic pathways in the context of neurodegeneration. Full article

Adipose tissue serves as a critical metabolic and endocrine organ, essential for maintaining systemic energy homeostasis and inter-organ communication. During the aging process, it undergoes significant structural remodeling and functional decline, characterized by dysregulated lipid metabolism, chronic low-grade inflammation, reduced insulin sensitivity, and adipokine imbalance. These alterations not only compromise the physiological integrity of adipose tissue but also contribute to the progression of various age-associated metabolic disorders, including type 2 diabetes, atherosclerosis, and nonalcoholic fatty liver disease. In recent years, natural products have emerged as a focal point in anti-aging research, owing to their broad accessibility, high biological safety, and capacity for multi-target regulation. Polyphenolic and polysaccharide, in particular, have demonstrated robust antioxidant, anti-inflammatory, autophagy-modulating, and mitochondrial-protective effects in cellular and animal models, indicating their promise in attenuating adipose tissue aging. Although the anti-aging effects of these natural compounds are well documented in the neural, hepatic, and cardiovascular systems, their specific mechanisms in adipose depots—especially differential regulatory patterns between white and brown adipose tissues, which may inform depot-specific therapies—and the development of targeted delivery approaches remain inadequately explored. This review, grounded in the three primary hallmarks of adipose tissue aging (oxidative stress, chronic inflammation, and dysregulated lipid metabolism), systematically elucidates the molecular mechanisms and recent advancements in the application of polyphenols and polysaccharides as natural modulators. This review establishes a cohesive theoretical foundation and delivers innovative perspectives to guide the advancement of natural product-based nutritional and therapeutic strategies for combating adipose tissue aging. Full article

Traumatic brain injury (TBI) can lead to persistent adverse outcomes, including cognitive and emotional dysfunction, with recent estimates indicating that up to 50% of individuals with mild TBI experience long-term symptoms. Growing evidence suggests that biological sex influences TBI outcomes and recovery trajectories; however, the molecular underpinnings driving these sex-specific differences remain poorly understood. In this study, a preclinical TBI model was used to directly compare chronic glutamatergic alterations in adult male and female Sprague Dawley rats. To define frontocortical molecular signatures associated with sex-specific glutamatergic dysfunction, proteomic analyses were conducted. Proteomic data revealed dysregulation of key pathways, cellular processes, and molecular regulators involved in excitatory signaling and synaptic function in both sexes. Biomarker profiling identified a single common biomarker between males and females, along with multiple biomarkers unique to each sex. Furthermore, two key brain regions highly susceptible to TBI, the prefrontal cortex and hippocampal subregions, were examined for chronic alterations in key glutamatergic signaling proteins, including N-methyl-D-aspartate (NMDA) receptors and the excitatory synaptic marker postsynaptic density protein 95 (PSD95). Immunofluorescence analyses revealed both sex- and region-specific alterations in the expression of NMDA receptor subunits, as well as in PSD95. Notably, many of these changes were concentrated within the hippocampal subregions, suggesting long-term dysregulation of hippocampal glutamatergic circuitry following injury. Together, these findings indicate the emergence of chronic sex-specific pathophysiology in glutamate signaling after TBI and highlight the importance of incorporating sex as a biological variable in the development of precision medicine-based therapeutic strategies for TBI. Full article

Diabetes is a pivotal risk factor for cardiovascular disease as well as microvascular complications, including retinopathy and nephropathy. Chronic hyperglycemia is a key player in linking diabetes with endothelial dysfunction which, in turn, contributes to cardiovascular disease. Indeed, hyperglycemia acts as a trigger for endothelial dysfunction, promoting a shift in the endothelium from a protective, anti-inflammatory state to a dysfunctional, injury-prone phenotype. A hyperglycemic environment triggers several pathogenetic mechanisms, including alterations in bioenergetics, production of advanced glycation end products, oxidative stress and mitochondrial dysfunction, all contributing to endothelial dysfunction. The activation of these pathophysiological mechanisms by hyperglycemia culminates in reduced nitric oxide production, as well as the induction of oxidative stress and inflammation, all of which are pivotal in impairing endothelial homeostasis and promoting cellular damage. Besides these classical mechanisms, there is growing attention on novel pathogenetic factors linking diabetic hyperglycemia with endothelial dysfunction, such as the ACE2 protein. The latter is emergeing for its potential to counter hyperglycemia-induced cellular damage through its vasoprotective and anti-inflammatory actions, making it a promising therapeutic target for tackling endothelial dysfunction. This review provides an overview of classical as well as emerging mechanisms underpinning the deleterious effects of diabetic hyperglycemia on endothelial dysfunction. In turn, understanding the molecular interconnections between hyperglycemia and endothelial dysfunction is crucial for developing novel strategies to restore endothelial homeostasis and mitigate diabetic vascular complications. Full article