Search Results (1,826)

Interleukin-10 (IL-10), a potent anti-inflammatory cytokine, plays a vital role in regulating immune responses across various infectious and inflammatory conditions. While IL-10 is essential for preventing excessive tissue damage and maintaining immune homeostasis (e.g., respiratory syncytial virus), its elevated levels could result in immunosuppression during viral infections, enabling viruses to evade host defenses (e.g., foot-and-mouth disease virus). This review aims to elucidate the mechanisms through which IL-10 mediates immunosuppression in viral infections and to explore the implications of these mechanisms for therapeutic intervention. The key scientific concepts outlined in this review include the mechanisms of IL-10 production and its varied impacts on the immune response during viral infections. Specifically, we discuss the multifaceted inhibitory effects of IL-10 on innate and adaptive immunity, including its implications for antigen presentation, T cells activation, pro-inflammatory cytokine production, immune cell differentiation, trafficking, apoptosis, and co-inhibitory expression related to T cells exhaustion. Finally, we discuss the therapeutic potential of targeting IL-10, such as monoclonal antibodies and small molecule inhibitors, and their potential to restore effective immune responses. By summarizing current knowledge on IL-10’s role in viral infections, this review offers a thorough insight into its immunosuppressive mechanisms and their therapeutic potential, paving the way for innovative treatment strategies in viral diseases. Full article

P2X receptors are a family of ATP-gated ion channels widely distributed in various tissues, especially in neuronal cells and hematopoietic cells. ATP activates P2X receptors, causing the opening of an ionic channel with preferential permeability to the passage of mono- and divalent cations. High concentrations of ATP stimulate the P2X7 subtype through prolonged activation, which opens pores and causes inflammation, proalgesic effects, and cell death. Peptides, including antimicrobials (antimicrobial peptides), are present in several organisms, such as amphibians, mammals, fish, arachnids, and plants, where they act as the first line of defense. Thus, these peptides have the capacity to eliminate a wide spectrum of microorganisms, such as bacteria, fungi, and some viruses. In general, the mechanism of action of antimicrobial peptides involves interactions with the lipid bilayer of the cell membrane, which can lead to an increase in the internal liquid content of liposomes. However, many peptides can act on ion channels, such as those of the P2X family, especially the P2X7 receptor. We investigated the action of peptides that directly modulate P2X7 receptors, such as beta-amyloid, LL-37/hCap18, Pep19-2.5, rCRAMP, ADESG, and polymyxin B. Additionally, we evaluated peptides that modulate the activity of P2X family receptor subtypes. In this review, we intend to describe the relationships between peptides with distinct characteristics and how they modulate the functionality of P2X receptors. Full article

Filtration of submicron particles and nanoparticles is an important problem in nano-industry and in air conditioning and ventilation systems. The presence of submicron particles comprising fungal spores, bacteria, viruses, microplastic, and tobacco-smoke tar in ambient air is a severe problem in air conditioning systems. Many nanotechnology material processes used for catalyst, solar cells, gas sensors, energy storage devices, anti-corrosion and hydrophobic surface coating, optical glasses, ceramics, nanocomposite membranes, textiles, and cosmetics production also generate various types of nanoparticles, which can retain in a conveying gas released into the atmosphere. Particles in this size range are particularly difficult to remove from the air by conventional methods, e.g., electrostatic precipitators, conventional filters, or cyclones. For these reasons, nanofibrous filters produced by electrospinning were developed to remove fine particles from the post-processing gases. The physical basis of electrospinning used for nanofilters production is an employment of electrical forces to create a tangential stress on the surface of a viscous liquid jet, usually a polymer solution, flowing out from a capillary nozzle. The paper presents results for investigation of the filtration process of metal oxide nanoparticles: TiO₂, MgO, and Al₂O₃ by electrospun nanofibrous filter. The filter was produced from polyvinylidene fluoride (PVDF). The concentration of polymer dissolved in dimethylacetamide (DMAC) and acetone mixture was 15 wt.%. The flow rate of polymer solution was 1 mL/h. The nanoparticle aerosol was produced by the atomization of a suspension of these nanoparticles in a solvent (methanol) using an aerosol generator. The experimental results presented in this paper show that nanofilters made of PVDF with surface density of 13 g/m² have a high filtration efficiency for nano- and microparticles, larger than 90%. The gas flow rate through the channel was set to 960 and 670 l/min. The novelty of this paper was the investigation of air filtration from various types of nanoparticles produced by different nanotechnology processes by nanofibrous filters and studies of the morphology of nanoparticle deposited onto the nanofibers. Full article

Organ transplantation significantly enhances the survival and quality of life for recipients. However, multiple dependent and independent variables can adversely affect life expectancy after transplantation. Cancer is one of the most common causes of morbidity and mortality for long-term organ transplant recipients. The incidence of cancer in transplanted tissues can be twice as high in approximately 32 distinct cancer types. Oncogenic viruses present in graft tissues may contribute to the etiology of various cancers in transplant recipients. Such oncogenic viruses include hepatitis viruses, papillomaviruses, Epstein–Barr virus, Kaposi’s sarcoma, Merkel cell virus, JC virus, BK virus, and human T-lymphotropic virus type 1, all of which have been associated with various malignancies in these patients. To mitigate this risk, a comprehensive viral screening protocol should be integrated into the transplantation process. Depending on the type of graft, diagnostic methods, control strategies, and post-transplantation care may vary considerably. To efficiently implement any strategy to inhibit viral oncogenicity, a comprehensive understanding of viral–host interactions involving oncogenic viruses within graft tissue is essential. The current view of tumor biology is that changes in the tumor microenvironment and immune signaling influence evolutionary selection pressures. Such interactions ultimately promote conditions that favor uncontrolled host–cell proliferation and malignant transformation. This review examines these viral–host interactions and their role in cancer development among transplant recipients. Full article

Viruses can induce various mitochondrial morphological changes, which are associated with the type of immune response. Therefore, characterization and analysis of mitochondrial ultrastructural changes could provide insights into the kind of immune response elicited, especially when compared to uninfected cells. However, this analysis is highly time-consuming and susceptible to observer bias. This work presents the development of a deep learning-based approach for the automatic identification, segmentation, and analysis of mitochondria from thin-section transmission electron microscopy images of cells infected with two SARS-CoV-2 variants or the Zika virus, utilizing a convolutional neural network with a U-Net architecture. A comparison between manual and automatic segmentations, along with morphological metrics, was performed, yielding an accuracy greater than 85% with no statistically significant differences between the manual and automatic metrics. This approach significantly reduces processing time and enables a prediction of the immune response to viral infections by allowing the detection of both intact and damaged mitochondria. Therefore, the proposed deep learning-based tool may represent a significant advancement in the study and understanding of cellular responses to emerging pathogens. Additionally, its applicability could be extended to the analysis of other organelles, thereby opening up new opportunities for automated studies in cell biology. Full article

Background: Various studies have shown that viral pneumonia pathogens display distinct inflammatory profiles, and hematological indices, such as the Neutrophil/Lymphocyte Ratio (NLR), Lymphocyte/Monocyte Ratio (LMR), and Platelet/Lymphocyte Ratio (PLR), can serve as accessible markers of disease severity. Moreover, the seasonal distribution of respiratory viruses appears to have shifted during the COVID-19 pandemic. Methods: This retrospective case–control study was conducted on patients diagnosed with PCR-confirmed viral pneumonia in the emergency department of a tertiary care center between 1 January and 31 December 2024. The control group comprised age- and sex-matched individuals without viral pneumonia. Subjects with comorbidities or ongoing treatments potentially affecting hematological indices were excluded. Seasonal distribution of viral pathogens was recorded. Hematological and inflammatory parameters at admission—including neutrophil-to-lymphocyte ratio (NLR), lymphocyte-to-monocyte ratio (LMR), and platelet-to-lymphocyte ratio (PLR)—were evaluated. The associations between these biomarkers, Pneumonia Severity Index (PSI) scores, and hospitalization status were statistically analyzed. Results: In this study, it was determined that Influenza A/B was more common in winter (67.3%) and SARS-CoV-2 in summer (70.7%). The relationship between the Pneumonia Severity Index and hemogram parameters was examined in determining the severity of pneumonia. In SARS-CoV-2, leukocyte and neutrophil counts were positively correlated (R: 0.392, p: 0.003; R: 0.466, p: <0.001), while in Influenza A/B, lymphocyte, platelet, and monocyte counts showed a negative correlation (R: −0.402, p: 0.005; R: −0.331, p: 0.021; R: −0.327, p: 0.023). Correlations were found between inflammation parameters and the Pneumonia Severity Index, except for the Lymphocyte/Monocyte Ratio, between SARS-CoV-2 and Influenza A/B (p < 0.05). Conclusions: The seasonal distribution of viral pneumonia pathogens has been revealed following the COVID-19 pandemic. Due to differences in inflammation patterns in viral infections, different leukocyte subgroups have been suggested as biomarkers. Full article

Human noroviruses (HuNov) are the major cause of foodborne illness globally. Several HuNoV outbreaks have been linked to contaminated ready-to-eat seaweed products. Standard protocols such as the ISO 15216 show limited efficiency in extracting foodborne viruses from seaweed products. Therefore, we evaluated the efficiency of an extraction protocol based on porcine gastric mucin conjugated magnetic beads (PGM-MBs) to recover HuNoVs from Wakame seaweed salad. Compared to other HuNoV extraction methods, the PGM-MB method was more efficient. We then aimed to further improve this protocol by modifying several factors such as the buffers, pH, bead concentration, centrifugation and incubation time. The optimized PGM-MB method yielded 19 ± 3% and 17 ± 4% recovery, for HuNoV GI and GII, respectively. The limit of detection (LOD₉₅) for Wakame seaweed salad was 131 and 56 genomic equivalents per 25 g for HuNoV GI and GII. Although some variability in recovery efficiency was observed between the PGM sources, the optimized PGM-MB protocol effectively extracts HuNoVs from Wakame seaweed salads of various brands and other commodities such as dates, green onions, and salted seaweed. These results support the implementation of the optimized PGM-MB method as a viable alternative for HuNoV surveillance in complex food matrices. Full article

In viral infections human heat shock proteins (HSPs) play a dual role by either protecting host cells or acting on viruses’ needs. The roles of HSPs have been extensively studied in various human pathologies, but their involvement in the progression of COVID-19 remains unexplored. It makes HSPs genetic variants particularly interesting in the context of severe COVID-19 risk. In this study, 1228 subjects (199 hospitalized COVID-19 patients and 962 controls) were genotyped for 20 SNPs in genes encoding HSPs and their regulators. SNP rs7189628 DNAJA2 (effect allele [EA] T) increased the risk of severe COVID-19 in the entire group (p = 0.002), males (p = 0.00008), and smokers (p = 0.0003). SNP rs910652 HSPA12B (EA C) decreased the risk of severe COVID-19 in the entire group (p = 0.01), females (p = 0.04), and patients with normal physical activity levels (p = 0.01). SNP rs1136141 HSPA8 (EA A) increased the risk of severe COVID-19 in patients with low fruit/vegetable intake (p = 0.004). Moreover, we observed significant changes in ground-glass opacity and alterations in blood coagulation and inflammation parameters, influenced by the SNPs of BAG3, HSF2, HSPA6, HSPA8, HSPA9, and DNAJA2. The molecular mechanisms underlying these associations are discussed. Together, our study provides preliminary evidence that SNPs of HSPs can significantly modulate the risk of severe COVID-19. Full article

Fibrinogen (FIB), a key component of the coagulation cascade, is traditionally recognized for its role in hemostasis and tissue repair. However, due to its high plasma abundance and susceptibility to proteolytic cleavage during inflammation, it may also represent a previously unrecognized source of bioactive peptides. This study presents, for the first time, a comprehensive analysis of the antimicrobial, anti-inflammatory, and antiviral properties of six cationic antimicrobial peptides (AMPs) deriving from the C-terminal extremities of the three subunits of human fibrinogen (FIBα, FIBβ, and FIBγ), identified using a scoring function developed by our group. Antibacterial assays against Gram-positive and Gram-negative pathogens revealed different antimicrobial activity profile depending on their parent protein. Selected peptides displayed additive or synergistic effects when combined with conventional antibiotics or the thrombin-derived peptide (P)GKY20, highlighting their potential for combination therapies. Hemolytic assay confirmed the biocompatibility of fibrinogen-derived cryptic peptides with erythrocytes. Furthermore, the peptides significantly reduced LPS-induced nitric oxide release in murine macrophages Raw 264.7 cells, indicating anti-inflammatory activity. Notably, antiviral activity was observed against enveloped viruses (HCoV-229E and HSV-1) under various treatment conditions, while no activity was detected against the non-enveloped virus CVB3. Overall, these findings reveal human fibrinogen as a source of multifunctional cryptic peptides with broad-spectrum antimicrobial, antiviral, and immunomodulatory activities, supporting their potential as part of the innate immune system. Full article

Swine acute diarrhea syndrome coronavirus (SADS-CoV), similar to other coronaviruses, exhibits extensive host tropism and has caused huge losses to the pig industry since its first outbreak in 2017. However, the susceptibility of SADS-CoV in waterfowl remains unclear. In the present study, 10-day-old ducklings were orally administered 5.95 log₁₀ TCID₅₀ (the tissue culture infective dose 50%) of SADS-CoV, with a medium serving as a control treatment, to assess ducklings’ susceptibility. Results indicated that the ducklings exhibited mild diarrhea symptoms, experienced slow weight gain, and one duckling died seven days after inoculation. Histopathological examination revealed that the viral infection caused pathological damage to the spleen, intestine, and lungs. Tissue immunofluorescence demonstrated viral replication in the spleen, lungs, and intestine. This study provides the first evidence that SADS-CoV can infect ducklings under laboratory conditions. Given that waterfowl may serve as significant reservoirs for various viruses, this finding raises considerable concerns. Full article

The COVID-19 pandemic has inflicted unprecedented pressure on communities and healthcare systems around the world. An outstandingly broad and intensive investigation of possible therapeutic interventions is currently taking place to prevent similar future threats to the global population. Investigating the related mechanisms of action is often complex and time consuming. Moreover, research on biochemical interactions of new drugs involves a considerable amount of effort, consequently bearing inherent financial and operational risks for pharmaceutical companies. An interesting approach to counteract colonization and infection is the concept of antiseptic treatment in vivo. Antiseptics are cost-effective and globally accessible, due to their ease of production, transportation and handling. A broad spectrum of active agents with different properties is readily available. One of these substances is hypochlorous acid (HOCl), which is also a naturally occurring biocidal agent and as such part of the innate immune system. Its successful history of medical use in wound treatment, combined with low cytotoxicity and documented efficacy against various pathogens, suggests that HOCl might be an effective agent for treating the respiratory mucosa. This could potentially enable therapeutic inhalation for combating bacterial infections and viral pathogens such as human respiratory syncytial, influenza, and SARS-CoV-2 viruses, which will be discussed in the present article. Full article

Emerging arboviruses of the Orthoflavivirus genus such as West Nile virus (WNV) and Usutu virus (USUV), primarily transmitted by Culex mosquitoes, pose significant public health threats due to their ability to cause severe neurological diseases in humans and animals. While studies in North America and Central Europe have shown that these viruses can persist in overwintering mosquitoes, their role in viral maintenance during the cold season in northeastern France remains unknown. This study aimed to assess whether overwintering female mosquitoes in this region could harbor WNV or USUV during the cold season, potentially maintaining viral circulation until the following transmission season. Between October 2021 and February 2024, a total of 10,617 overwintering female mosquitoes were collected in various types of habitats across five departments in northeastern France. The most common species was Culex pipiens (88%). Mosquitoes were grouped into 1121 pools (1–10 individuals each) and tested by real-time RT-PCR for WNV, USUV, and other flaviviruses using a pan-Flavivirus NS5-targeting assay. All pools tested negative, indicating no evidence of viral RNA in overwintering females. These results suggested that overwintering female mosquitoes in northeastern France do not act as reservoirs for WNV or USUV, and do not contribute to their overwintering maintenance. Full article

Age-related macular degeneration (AMD) is a leading cause of irreversible vision loss in the elderly, characterized by progressive degeneration of the retinal pigment epithelium (RPE) and photoreceptors in the macula. Current treatment options primarily focus on slowing disease progression in neovascular AMD, while effective therapies for dry AMD remain limited. Optogenetics, a revolutionary technique utilizing light-sensitive proteins (opsins) to control the activity of genetically targeted cells, has emerged as a promising therapeutic strategy for restoring vision in retinal degenerative diseases. In retinal disease models, adeno-associated viruses (AAVs) serve as delivery vectors via intravitreal or subretinal injections. This review explores the principles of optogenetics, its application in preclinical AMD models, and the potential for clinical translation of this approach. We discuss the various optogenetic tools, delivery methods, and the challenges and future directions in harnessing this technology to combat AMD-related vision loss. Full article

The use of viruses as natural pathogens of pest insects is a promising approach in biocontrol. The main drawback of this approach is its relatively slow mode of action, which could be addressed through genetic modifications of the strains used. In this article, we propose the use of the commercially available Bac-to-Bac system for infecting pest insects with a recombinant virus and assessing the impact of various molecules on their viability. Using the laboratory-friendly model organism Galleria mellonella and baculovirus carrying the eGFP gene, we demonstrated a 100% infection rate, with a consistent and stable spread of the viruses throughout insect bodies and a gradual increase in recombinant protein expression. Notably, at day 5 post-infection the insects remained viable and active. This approach enables the identification of pathogenic effects caused by the virus-induced expression of other molecules, such as toxins. Full article

Background/Objectives: The human skin provides a protective barrier composed of bacteria, fungi, viruses, and archaea that prevents the invasion of harmful organisms. Recent advancements in genomic sequencing have allowed for greater accuracy of species detection. This review aims to summarize the most up-to-date skin microbiome shifts in various dermatological diseases. Methods: A systematic search was conducted to examine microbiome shifts comparing lesional and nonlesional or diseased and healthy skin across various dermatological conditions. A literature search was conducted on PubMed, Web of Science, and Embase Databases from inception through April 2024, yielding 38 studies. Results: Staphylococcus aureus was reported unanimously in all skin conditions. Most studies in this review, except those investigating acne vulgaris, showed a decreased microbiome diversity in diseased skin. Finally, there was a greater shift in the proportion of pro-inflammatory bacterial and fungal strains. Conclusions: The skin microbiome is significantly altered in the progression of numerous dermatological diseases. Diversity of the skin microbiome is decreased, and there is an increased proportion of pro-inflammatory bacterial and fungal strains. The skin microbiome also provides a more comprehensive understanding of the development and progression of many inflammatory skin diseases. Prebiotic treatments may propose a much safer and cheaper alternative to antibiotics, which can have highly toxic side effects and negative implications for public health regarding antibiotic resistance. More research is required to fully understand both the microbiome changes and efficacy and viability of using probiotic treatments to restore the skin microbiome, thereby improving patient outcomes in all dermatological conditions. Full article