Numerous Processes Research Articles

Unraveling the Connection Between Ion Channels and Pancreatic Stellate Cell Activation.

Quiescent pancreatic stellate cells (PSCs) represent only a very low proportion of the pancreatic tissue, but their activation leads to stroma remodeling and fibrosis associated with pathologies such as chronic pancreatitis and pancreatic ductal adenocarcinoma (PDAC). PSC activation can be induced by various stresses, including acidosis, growth factors (PDGF, TGFβ), hypoxia, high pressure, or intercellular communication with pancreatic cancer cells. Activated PSC targeting represents a promising therapeutic strategy, but little is known regarding the molecular mechanisms underlying the activation of PSCs. Identification of new biomarkers of PSC activation associated with desmoplasia in chronic pancreatitis and PDAC could lead to new therapeutic targets for exocrine pancreatic disease treatments. Ion channels and transporters are transmembrane proteins involved in numerous physiological and pathological processes, including PDAC. They are well known to act as biosensors of the tissue microenvironment, and they can be easily accessible for drugs. However, their role in PSC activation is not fully understood. In this review, we briefly discuss the role of activated PSCs in pancreas inflammation and pathological fibrosis (associated with chronic pancreatitis and PDAC), and we describe the role of specific ion channels and transporters (Ca2+, K+, Na+ and Cl-) in these processes in the light of recent literature.

Gypsum heterogenous nucleation pathways regulated by surface functional groups and hydrophobicity

Gypsum (CaSO4·2H2O) plays a critical role in numerous natural and industrial processes. Nevertheless, the underlying mechanisms governing the formation of gypsum crystals on surfaces with diverse chemical properties remain poorly understood due to a lack of sufficient temporal-spatial resolution. Herein, we use in situ microscopy to investigate the real-time gypsum nucleation on self-assembled monolayers (SAMs) terminated with −CH3, −hybrid (a combination of NH2 and COOH), −COOH, −SO3, −NH3, and −OH functional groups. We report that the rate of gypsum formation is regulated by the surface functional groups and hydrophobicity, in the order of −CH3 > −hybrid > −COOH > −SO3 ≈ − NH3 > − OH. Results based on classical nucleation theory and molecular dynamics simulations reveal that nucleation pathways for hydrophilic surfaces involve surface-induced nucleation, with ion adsorption sites (i.e., functional groups) serving as anchors to facilitate the growth of vertically oriented clusters. Conversely, hydrophobic surfaces involve bulk nucleation with ions near the surface that coalesce into larger horizontal clusters. These findings provide new insights into the spatial and temporal characteristics of gypsum formation on various surfaces and highlight the significance of surface functional groups and hydrophobicity in governing gypsum formation mechanisms, while also acknowledging the possibility of alternative nucleation pathways due to the limitations of experimental techniques.

Quantitative analysis of the polar cod (Boreogadus saida) hepatic proteome highlights interconnected responses in cellular adaptation and defence mechanisms after dietary benzo[a]pyrene exposure.

Increased industrial offshore activities in northern waters raise the question of impact of polycyclic aromatic hydrocarbons (PAHs) on key Arctic marine species. One of these is the ecologically important polar cod (Boreogadus saida), which is the primary food source for Arctic marine mammals and seabirds. In the present work, we have conducted the first comprehensive proteomics study with this species by exploring the effects of dietary PAH exposure on the hepatic proteome, using benzo[a]pyrene (BaP) as a PAH model-compound. Functional annotation and pathway analyses of the proteins affected by BaP revealed a concerted cellular response for handling and adopting to its exposure, involving numerous interconnected signalling pathways and metabolic processes. In accordance with BaP being a strong aryl hydrocarbon receptor (Ahr) agonist, a prominent activation of the canonical Ahr signalling pathway was observed, including upregulation of Ahr target proteins like cytochrome P450 enzymes and microsomal glutathione transferase. Furthermore, cellular pathways for handling oxidative stress, protein misfolding and degradation, as well as endoplasmic reticulum stress and calcium homeostasis, were also activated by BaP, possibly as a result of the formation of harmful and redox reactive BaP metabolites via phase I metabolism. Activation of proteins that participate in the acute-phase response was also observed, suggesting prevalent tissue- and cellular damage that triggers the immune system and inflammatory responses. Our results at the protein level aligns well with previous analyses on the effects of BaP on the polar cod liver transcriptome and support that exposure to BaP and structural similar PAHs can cause adverse effects on polar cod physiology. Although more data is required for demonstrating how these molecular responses propagate to higher levels of biological organisation, increased knowledge about the initial cellular and molecular mechanisms that induce toxicity is a key-step towards a mechanistically informed impact assessment of PAH pollutants in the Arctic.

Active Disturbance Rejection Control for an automotive suspension system based on parameter tuning using a fuzzy technique.

Road surface roughness is the cause of vehicle vibration, which is considered a system disturbance. Previous studies on suspension system control often ignore the influence of disturbances while designing the controller, leading to system performance degradation under severe vibration conditions. In this work, we propose a control method to improve active suspension performance that reduces vehicle vibration by eliminating the influence of road disturbances. The proposed method is formed based on the combination of an Active Disturbance Rejection Control (ADRC) technique with control coefficients tuned by a dynamic fuzzy technique formed based on special membership functions called Active Disturbance Rejection Control Based on Fuzzy (ADRCBF). An Extended State Observer (ESO) estimates state variables and disturbances. The performance of the proposed controller is evaluated through the numerical simulation process with three different cases. According to the calculation results, the acceleration and displacement of the sprung mass are significantly reduced when the suspension system is controlled by the proposed technique, compared with the passive suspension system and the active suspension system controlled by a Proportional-Integral-Derivative (PID) technique. In addition, the suspension travel follows the road disturbance with a small error. The error estimated by the ESO does not exceed 3.5% (for sinusoidal and random excitation). In general, system adaptation is ensured under many investigated conditions based on tuning the controller parameters by the soft computing method.

Urokinase Plasminogen Activation System Modulation in Transformed Cell Lines

The role of the plasminogen activation system is to regulate the activity of the extracellular protease plasmin. It comprises the urokinase plasminogen activator (uPA), a specific extracellular protease which activates plasminogen, its inhibitor PAI1, and the urokinase plasminogen activator receptor, uPAR, which localizes the urokinase activity. The plasminogen activation system is involved in tissue remodeling through extracellular matrix degradation, and therefore participates in numerous physiological and pathological processes, which make it a potential biomarker. To investigate the role of these molecules in the cellular processes, we cloned human uPA, PAI1, and uPAR and overexpressed them in two cell lines, the glioblastoma line A1235 and the transformed human embryonal kidney cells HEK 293. We analyzed the urokinase activity and the expression of plasminogen activation system elements on the protein and RNA level by Western blot analysis and RTqPCR. Cell proliferation was followed up by cell counting, cell migration and invasion by wound-healing and the transwell assays, respectively, and cell adhesion and dispersal by spheroid formation. The cells transfected with urokinase sequence had increased urokinase activity and uPA expression, while the PAI1-transfected cells decreased urokinase activity, increased PAI1 expression, and decreased cell migration. HEK 293 cells expressing PAI formed only small spheroids. The effects of the uPA system molecules depended on their interactions with each other and with other molecules in the microenvironment, as well as on the cell-type-specific signaling.

Identification of a global gene expression signature associated with the genetic risk of catastrophic fracture in iPSC-derived osteoblasts from Thoroughbred horses.

Bone fractures are a significant problem in Thoroughbred racehorses. The risk of fracture is influenced by both genetic and environmental factors. To determine the biological processes that are affected in genetically susceptible horses, we utilised polygenic risk scoring to establish induced pluripotent stem cells (iPSCs) from horses at high and low genetic risk. RNA-sequencing on iPSC-derived osteoblasts revealed 112 genes that were significantly differentially expressed. Forty-three of these genes have known roles in bone, 27 are not yet annotated in the equine genome and 42 currently have no described role in bone. However, many of the proteins encoded by the known and unknown genes have reported interactions. Functional enrichment analyses revealed that the differentially expressed genes were overrepresented in processes regulating the extracellular matrix and pathways known to be involved in bone remodelling and bone diseases. Gene set enrichment analysis also detected numerous biological processes and pathways involved in glycolysis with the associated genes having a higher expression in the iPSC-osteoblasts from horses with low polygenic risk scores for fracture. Therefore, the differentially expressed genes may be relevant for maintaining bone homeostasis and contribute to fracture risk. A deeper understanding of the consequences of mis-regulation of these genes and the identification of the DNA variants which underpin their differential expression may reveal more about the molecular mechanisms which are involved in equine bone health and fracture risk.

RNA-binding proteins as versatile metabolic regulators

Metabolic shifts are a hallmark of numerous biological processes, including the differentiation of stem cells along a specific lineage and the activation of diverse cell types, such as immune cells. This review examines the intricate energy metabolic alterations that occur in diverse biological settings, from embryonic development to adult tissue homoeostasis and disease states. In particular, we emphasise the regulatory function of RNA-binding proteins (RBPs) in coordinating these metabolic shifts and examine how they modulate key pathways, such as glycolysis and oxidative phosphorylation, to meet the dynamic cellular energy demands. This review highlights the various mechanisms by which RBPs regulate these changes, ranging from active involvement in the post-transcriptional regulation of metabolically relevant genes to alteration of an RBP’s function by specific RNAs, metabolites or growth factors. Finally, we consider how ageing and disease affect the function of RBPs and how RBPs can disrupt the delicate balance of metabolic regulation. Taken together, this review provides a comprehensive overview of the critical interplay between RBPs and metabolism and offers insights into potential therapeutic targets for regenerative medicine and age-related diseases.

Density prediction for selective laser melting fabricated of CuCrZr alloy using hybrid Gaussian boosted regression

Selective laser melting (SLM), an emerging technology, constructs components through layer-by-layer material deposition and has gained popularity in the industry due to its advantages such as shorter lead time, higher flexibility, lower material wastage, and the capability to fabricate complex geometries. However, the development of process databases for new materials is often time-consuming and laborious because SLM involves multiple physical fields and multiple process steps with numerous process parameters. Recently, machine learning is renowned for its excellent capabilities in tasks such as classification, regression, and clustering. In this study, hybrid Gaussian boosted regression that combines Gaussian process regression with gradient boosting machine was used to obtain a process database for CuCrZr alloy, optimizing for density with laser power and scanning speed as characteristic parameters, under limited samples. A machine learning model was developed using fivefold cross-training on 36 datasets. With a determination coefficient (R2) of 0.96587, the model demonstrated a high level of fit. Next, by extending the prediction range, we achieved process parameters for the highest five densities of samples. Finally, the model’s precision was confirmed with experiments on the five predicted maximum densities, with all predictions falling within a ±0.09% error margin from the experimental values. This research precisely predicted the densities of SLM-formed CuCrZr parts, created a comprehensive process parameter database, and substantiated both theoretical and practical backing for the 3D printing of CuCrZr parts.

Genome- and Transcriptome-Wide Characterization and Expression Analyses of bHLH Transcription Factor Family Reveal Their Relevance to Salt Stress Response in Tomato

The bHLH (basic helix–loop–helix) transcription factors function as crucial regulators in numerous biological processes including abiotic stress responses and plant development. According to our RNA-seq analysis of tomato seedlings under salt stress, we found that, although the bHLH gene family in tomato has been studied, there are still so many tomato bHLH genes that have not been identified and named, which will hinder the later study of SlbHLHs. In total, 195 SlbHLHs that were unevenly distributed onto 12 chromosomes were identified from the tomato genome and were classified into 27 subfamilies based on their molecular features. The collinearity between SlbHLHs and interrelated orthologs from 10 plants further revealed evolutionary insights into SlbHLHs. Cis-element investigations of SlbHLHs promotors further suggested the potential roles of SlbHLHs in tomato development and stress responses. A total of 30 SlbHLHs were defined as the differentially expressed genes in response to salt stress by RNA-seq. The expression profiles of selected SlbHLHs were varyingly and markedly induced by multiple abiotic stresses and hormone treatments. These results provide valuable information to further understand the significance and intricacy of the bHLH transcription factor family, and lay a foundation for further exploring functions and possible regulatory mechanisms of SlbHLH members in abiotic stress tolerance, which will be significant for the study of tomato stress resistance and agricultural productivity.

An Alternative Mode of GPCR Transactivation: Activation of GPCRs by Adhesion GPCRs

G protein-coupled receptors (GPCRs), critical for cellular communication and signaling, represent the largest cell surface protein family and play important roles in numerous pathophysiological processes. Consequently, GPCRs have become a primary focus in drug discovery efforts. Beyond their traditional G protein-dependent signaling pathways, GPCRs are also capable of activating alternative signaling mechanisms, including G protein-independent signaling, biased signaling, and signaling crosstalk. A particularly novel signaling mode employed by these receptors is GPCR transactivation, which enables cross-communication between GPCRs and other receptor types. Intriguingly, GPCR transactivation by distinct GPCRs has also been identified. In this review, I provide an overview of the known GPCR transactivation mechanisms and explore recently uncovered GPCR transactivation mediated by adhesion-class GPCRs (aGPCRs). These aGPCR-GPCR transactivation processes regulate unique cell type-specific functions, offering an exciting opportunity to develop therapies that precisely modulate specific GPCR-mediated biological effects.

Association analysis of genetic polymorphisms of METTL3 with clinical outcomes in a Chinese pediatric population with primary brain tumors.

Methyltransferase-like 3 (METTL3) regulates numerous biological processes and diverse cancers. To explore the frequency distribution of METTL3 rs1061026, rs1139130, and rs1263801 polymorphisms, and their potential impacts on clinical outcomes and chemotherapy-induced toxicities in a cohort of Chinese pediatric patients diagnosed with primary brain tumors (PBTs). Genotyping for three investigated SNPs was performed in 107 pediatric patients with PBTs using the Sequenom MassARRAY iPLEX platform. Serum METTL3 levels were determined by Enzyme-Linked Immunosorbent Assay. Serum methotrexate (MTX) concentrations were quantified utilizing fluorescence polarization immunoassay. The three investigated SNPs were not significantly associated with the risks of relapse and metastasis after adjusting all confounders. Compared to individuals with the rs1139130 GG genotype, GA genotype carriers exhibited a significantly higher risk of oral mucositis (adjusted OR: 7.504; 95 % CI, 1.931-29.436; P = 0.004). The rs1139130 GA (adjusted OR: 5.091; 95 % CI, 1.351-19.176; P = 0.016) and AA (adjusted OR: 9.588; 95 % CI, 1.769-51.949; P = 0.009) genotype carriers exhibited a significantly lower risk of fever than GG genotype carriers. The median dose-normalized MTX concentrations at 42 h were lower with borderline significance in children with rs1061026 GT and GG genotypes (0.004 μmol/L per g/m2) than the TT genotype carriers (0.006 μmol/L per g/m2, P = 0.048). Patients with the rs1139130 GA genotype had significantly higher median serum METTL3 protein levels (59.91 ng/mL) than GG genotype carriers (44.57 ng/mL, P = 0.015). This study demonstrated the association of the rs1139130 polymorphism with the development of oral mucositis and fever and the rs1061026 polymorphism with MTX exposure.

Nuclear Waste Tank Emission Contributions to Particle Size Distribution.

Pollutants from anthropogenic activities including industrial processes are ubiquitous to the environment. To understand the impact from industrial aerosol on climate and human health, industrial aerosol needs to be better characterized. In this study, particle number concentrations were used as a proxy for atmospheric pollutants, which include both particles and gases. Particle concentration and size distribution were measured using a scanning mobility particle sizer (SMPS) approximately 4.5 km from primary industrial areas at the Savannah River Site in Aiken, SC. Industrial areas include numerous nuclear waste storage and processing tanks. The SMPS data were divided into two groups depending on the wind direction measured onsite to categorize transport from the industrial area or from elsewhere. Industrial contributions were found to have a higher concentration of particles with sizes less than 200 nm, 859 ± 564 cm-3, in comparison to non-industrial attributed particles, 733 ± 495 cm-3 on average from March-July 2021. For sizes larger than 200 nm, industrial and non-industrial particles have a similar concentration, 89 ± 59 cm-3 and 99 ± 61 cm-3, with non-industrial concentrations being slightly larger. To confirm that industrial particles could travel to the sampling location, air dispersion modeling was completed for specific case studies during the sampling period. The atmospheric dispersion modeling results confirmed that particles released at the industrial areas reached the sampling location when the wind direction was favorable for transport from the industrial areas. The greater concentration of smaller-sized particles in industrial emissions has implications for typical particulate measurements (PM2.5), heath impacts, and climatological influences.

Probing Single-Cell Adhesion Kinetics and Nanomechanical Force with Surface Plasmon Resonance Imaging.

Single cell adhesion plays a significant role in numerous physiological and pathological processes. Real-time imaging and quantification of single cell adhesion kinetics and corresponding cell-substrate mechanical interaction forces are crucial for elucidating the cellular mechanisms involved in tissue formation, immune responses, and cancer metastasis. Here, we present the development of a plasmonic-based nanomechanical sensing and imaging system (PNMSi) for the real-time measurement of single cell adhesion kinetics and associated nanomechanical forces with plasmonic tracking and monitoring of cell-substrate interactions and the accompanying nanoscale fluctuations. Both the slow binding and dynamic nanomechanical interaction processes were tracked and analyzed with a thermodynamic model to determine the adhesion kinetic parameters and quantity the mechanical forces. To demonstrate the capabilities of the PNMSi platform, we examined single cell binding interactions across four different surface modifications, and obvious alterations in binding kinetics and corresponding nanomechanical forces were observed, influenced by surface charges and interfacial hydrophilicity. Additionally, we investigated changes in mechanical interaction forces of single cells during cytoskeleton modification, revealing the cross-linking-induced cell adhesion changes. Furthermore, to demonstrate the application capability of the system, the adhesion profiling of primary tumor and metastatic tumor cells was explored, and obvious alterations were observed in the kinetic forces of single cell-substrate interaction. The PNMSi platform facilitates high-throughput single cell adhesion imaging and the quantification of adhesion interaction kinetics and nanomechanical forces with high sensitivity and serves as a promising platform for identifying biomarkers for tumor metastasis and for screening potential therapeutic agents.

Membrane Treatment to Improve Water Recycling in an Italian Textile District

The textile district of Prato (Italy) has developed a wastewater recycling system of considerable scale. The reclaimed wastewater is characterized by high levels of hardness (32 °F on average), which precludes its direct reuse in numerous wet textile processes (e.g., textile dyeing). Consequently, these companies utilize ion exchange resins for water softening. However, the regeneration of the resins results in an increased concentration of chlorides in the reclaimed wastewater that exceeds the limit set by Italian regulations for the reuse of water for irrigation purposes. The objective of this study is to investigate the potential of membrane filtration as an alternative method for removing hardness from water. Therefore, an industrial-scale ultrafiltration-nanofiltration (UF-NF) pilot plant was installed to test the rejection of hardness from the reclaimed wastewater. The experiment employed two types of NF membranes and three permeate fluxes (27, 35, and 38 L·m−2·h−1) for testing. The results demonstrated that the system could remove hardness with efficiencies exceeding 98% under all conditions tested. The experimental findings indicate that the UF-NF system has the potential to be employed as a post-treatment step to render the reclaimed wastewater suitable for all textile finishing processes and to expand the scope for reuse.

Targeting p97/Valosin-Containing Protein Promotes Hepatic Stellate Cell Senescence and Mitigates Liver Fibrosis.

Liver fibrosis, one of the main histological determinants of various chronic liver diseases, currently lacks effective treatment. Hepatic stellate cells (HSCs) are pivotal in the production of extracellular matrix and amplify the fibrogenic response. Inhibiting the activation of HSCs or promoting the senescence of activated HSCs is crucial for the regression of liver fibrosis. The ATPase p97, also known as valosin-containing protein (VCP), is a central component of the ubiquitin-proteasome system, and it regulates numerous cellular processes by influencing protein homeostasis. In this study, we observed an upregulation of p97 expression around regions exhibiting fibrosis in a diet- and chemical-induced nonalcoholic steatohepatitis and fibrosis murine model. Intervention with the p97 antagonist CB-5083 or the knockdown of p97 reduced the expression of alpha-smooth muscle actin and collagen-I in both mouse or human HSCs. The administration of CB-5083 induced HSC senescence and resulted in the upregulation of senescence markers, including p21, p53, GPX4, and senescence-associated β-galactosidase. Furthermore, CB-5083 treatment also inhibited the expression of Yes-associated protein (YAP), which is also a senescence-related regulatory protein and has a profibrotic function. We used CB-5083 to treat fibrotic mice and found that the activation of HSCs was inhibited, and the liver fibrosis was attenuated. In addition, invivo experiments confirmed that CB-5083 facilitated HSC senescence and reduced YAP expression. These findings underscore the potential of pharmacological targeting p97/VCP to induce HSC senescence and alleviate liver fibrosis.

Cellular and organismal function of choline metabolism.

Choline is an essential micronutrient critical for cellular and organismal homeostasis. As a core component of phospholipids and sphingolipids, it is indispensable for membrane architecture and function. Additionally, choline is a precursor for acetylcholine, a key neurotransmitter, and betaine, a methyl donor important for epigenetic regulation. Consistent with its pleiotropic role in cellular physiology, choline metabolism contributes to numerous developmental and physiological processes in the brain, liver, kidney, lung and immune system, and both choline deficiency and excess are implicated in human disease. Mutations in the genes encoding choline metabolism proteins lead to inborn errors of metabolism, which manifest in diverse clinical pathologies. While the identities of many enzymes involved in choline metabolism were identified decades ago, only recently has the field begun to understand the diverse mechanisms by which choline availability is regulated and fuelled via metabolite transport/recycling and nutrient acquisition. This review provides a comprehensive overview of choline metabolism, emphasizing emerging concepts and their implications for human health and disease.

Heterogeneity of late endosome/lysosomes shown by multiplexed DNA-PAINT imaging.

Late endosomes/lysosomes (LELs) are crucial for numerous physiological processes and their dysfunction is linked to many diseases. Proteomic analyses have identified hundreds of LEL proteins; however, whether these proteins are uniformly present on each LEL, or if there are cell-type-dependent LEL subpopulations with unique protein compositions is unclear. We employed quantitative, multiplexed DNA-PAINT super-resolution imaging to examine the distribution of seven key LEL proteins (LAMP1, LAMP2, CD63, Cathepsin D, TMEM192, NPC1, and LAMTOR4). While LAMP1, LAMP2, and Cathepsin D were abundant across LELs, marking a common population, most analyzed proteins were associated with specific LEL subpopulations. Our multiplexed imaging approach identified up to eight different LEL subpopulations based on their unique membrane protein composition. Additionally, our analysis of the spatial relationships between these subpopulations and mitochondria revealed a cell-type-specific tendency for NPC1-positive LELs to be closely positioned to mitochondria. Our approach will be broadly applicable to determining organelle heterogeneity with single organelle resolution in many biological contexts.

Additive CHARMM Force Field for Pterins and Folates.

Folates comprise a crucial class of biologically active compounds related to folic acid, playing a vital role in numerous enzymatic reactions. One-carbon metabolism, facilitated by the folate cofactor, supports numerous physiological processes, including biosynthesis, amino acid homeostasis, epigenetic maintenance, and redox defense. Folates share a common pterin heterocyclic ring structure capable of undergoing redox reactions and existing in various protonation states. This study aimed to derive molecular mechanics (MM) parameters compatible with the CHARMM36 all-atom additive force field for pterins and biologically important folates, including pterin, biopterin, and folic acid. Three redox forms were considered: oxidized, dihydrofolate, and tetrahydrofolate states. Across all protonation states, a total of 18 folates were parameterized. Partial charges were derived using the CHARMM force field parametrization protocol, based on targeting reference quantum mechanics monohydrate interactions, electrostatic potential, and dipole moment. Bonded terms were parameterized using one-dimensional adiabatic potential energy surface scans, and two-dimensional scans to parametrize in-ring torsions associated with the puckering states of dihydropterin and tetrahydropterin. The quality of the model was demonstrated through simulations of three protein complexes using optimized and initial parameters. These simulations underscored the significantly enhanced performance of the folate model developed in this study compared to the initial model without optimization in reproducing structural properties of folate-protein complexes. Overall, the presented MM model will be valuable for modeling folates in various redox states and serve as a starting point for parameterizing other folate derivatives.

Comparative Analysis of miRNA Expression Profiles of Yak Milk-Derived Exosomes at Different Altitudes.

Yaks are a rare and unique animal species inhabiting the Qinghai-Tibet Plateau; they are renowned for their remarkable ability to thrive in harsh environments. Milk-derived exosomes, tiny vesicles containing various biological molecules, play crucial roles in numerous pathological and physiological processes, including cell growth, development, and immune regulation. This study delved into the microRNA expression profiles of yak milk-derived exosomes collected from both high- and low-altitude populations using small RNA sequencing. These miRNAs were found to be implicated in pathways associated with mammary gland inflammation, virus infection regulation, and heat stress response. Functional enrichment analyses, utilizing GO and KEGG databases, revealed that the target genes of these differentially expressed miRNAs are enriched in signaling pathways crucial for Th17 cell differentiation and the Ras-MAPK signaling pathway. In conclusion, this research illuminates the adaptive mechanisms of yaks through the differential expression of miRNAs in their milk-derived exosomes across varying environmental conditions. These findings provide a valuable foundation for future investigations into yak resilience and the potential of milk-derived exosomes as tools for disease management and immune modulation.

PRMT1-Mediated Arginine Methylation Promotes Corneal Epithelial Wound Healing via Epigenetic Regulation of ANXA3.

Protein arginine methyltransferase 1 (PRMT1) is an integral constituent of numerous cellular processes. However, its role in corneal epithelial wound healing (CEWH) remains unclear. This study investigates the impact of PRMT1 on cellular mechanisms underlying corneal epithelial repair and its potential to improve wound healing outcomes. The murine CEWH model was established using an Alger brush. Corneal epithelial-specific Prmt1 knockout mice were generated using the Cre-lox system. Quantitative reverse transcription polymerase chain reaction and Western blot analyses determined the expression of candidate genes at mRNA and protein expression levels. Human corneal epithelial cells (HCECs) were transfected with siRNA using Lipofectamine RNAiMAX or infected with lentivirus to precisely alter the expression of PRMT1 or Annexin A3 (ANXA3). EdU and a scratch wound-healing assay evaluated the effects of PRMT1 or ANXA3 on HCEC proliferation and migration, respectively. Rescue experiment and chromatin immunoprecipitation assay validate the correlation between PRMT1 and ANXA3. Prmt1 is significantly upregulated during CEWH, accompanied by an elevated global arginine methylation level. Knockdown of PRMT1 in HCECs or in vivo knockout impairs cell proliferation, migration, and the CEWH process. Furthermore, ANXA3 was identified as a critical target of PRMT1, with PRMT1 enhancing ANXA3 expression through histone arginine methylation at its promoter region, establishing a causal correlation between them. Moreover, PRMT1 can modulate the NF-κB and JNK signaling pathways via ANXA3. PRMT1 is a critical epigenetic regulator in CEWH, promoting wound healing by upregulating ANXA3 via histone arginine methylation. These findings highlight the potential of targeting PRMT1 to enhance corneal epithelial repair.