Search Results (236)

Fungal communities in the gut influence host immunity, yet most studies have focused on cell wall components rather than genetic materials. Here, we explore how fungal genomic DNA (gDNA) from Candida albicans, Saccharomyces cerevisiae, and Cryptococcus neoformans modulate immune responses in human CD4⁺ T cells, murine splenocytes, and THP-1-derived macrophages. We find that C. albicans gDNA promotes the development of regulatory T cells and increases IL-10, fostering immune tolerance and preserving CD4⁺ T cell viability in an inflammatory setting. S. cerevisiae gDNA induces moderate Treg responses with restrained effector T cell expansion and higher checkpoint gene expression, entirely consistent with its commensal nature. In contrast, C. neoformans gDNA elicits a strongly inflammatory profile, promoting Th1/Th17 cells and driving high cytokine production. Mechanistically, C. albicans and S. cerevisiae gDNA dampen DNA-sensing pathways and enhance immune checkpoint molecules that act as brakes against overactivation, while C. neoformans gDNA robustly activates innate sensing pathways with limited checkpoint induction. These species-specific signaling profiles reveal that fungal gDNA itself can influence whether the immune system adopts a tolerant or inflammatory response toward fungi. This discovery highlights fungal genomic DNA as a previously underappreciated regulator of host–fungus interactions, offering new insight into commensal persistence, pathogenic invasion, and the potential for DNA-based antifungal interventions. Full article

Interferons (IFNs) are key cytokines at the intersection of innate and adaptive immunity. While their antiviral and antitumor roles are well recognized, emerging evidence implicates IFNs—particularly types I, II, and III—in the initiation and progression of autoimmune diseases (ADs). This review synthesizes current data on IFN biology, their immunoregulatory and pathogenic mechanisms, and their contributions to distinct AD phenotypes. We conducted a comprehensive review of peer-reviewed literature on IFNs and autoimmune diseases, focusing on publications indexed in PubMed and Scopus. Studies on molecular pathways, immune cell interactions, disease-specific IFN signatures, and clinical correlations were included. Data were extracted and thematically organized by IFN type, signaling pathway, and disease context, with emphasis on rheumatic and systemic autoimmune disorders. Across systemic lupus erythematosus, rheumatoid arthritis, Sjögren’s syndrome, systemic sclerosis, idiopathic inflammatory myopathies, multiple sclerosis, type 1 diabetes, psoriasis, and inflammatory bowel diseases, IFNs were consistently associated with aberrant activation of pattern recognition receptors, sustained expression of interferon-stimulated genes (ISGs), and dysregulated T cell and B cell responses. Type I IFNs often preceded clinical onset, suggesting a triggering role, whereas type II and III IFNs modulated disease course and severity. Notably, IFNs exhibited dual immunostimulatory and immunosuppressive effects, contingent on tissue context, cytokine milieu, and disease stage. IFNs are central mediators in autoimmune pathogenesis, functioning as both initiators and amplifiers of chronic inflammation. Deciphering the context-dependent effects of IFN signaling may inform targeted therapeutic strategies and advance precision immunomodulation in autoimmune diseases. Full article

The interaction between microorganisms in the dental microfilm (plaque) at the gingival margin, the immune system, and the brain is vital for gingival health. The brain constantly receives information regarding microbial composition and inflammation status through afferent nerves and the bloodstream. It modulates immune responses via efferent nerves and hormonal systems to maintain homeostasis. This relationship determines whether the gingiva remains healthy or develops into gingivitis (non-destructive inflammation) or periodontitis (a destructive condition), collectively referred to as periodontal disease. Factors associated with severe periodontitis heighten the responsiveness of this homeostatic system, diminishing the adaptive immune system’s defence against symbiotic microorganisms with pathogenic properties, known as pathobionts. This leads to excessive innate immune system activation, effectively preventing infection but damaging the periodontium. Consequently, investigating the microbiota–brain axis is vital for understanding its impact on periodontal health and disease. Herein, we examine recent advancements in how the defence against pathobionts is organised within the brain, and how it regulates and adapts the pro-inflammatory and anti-inflammatory immune balance, controlling microbiota composition. It also discussed how pathobionts and emotional stress can trigger neurodegenerative diseases, and how inadequate coping strategies for managing daily stress and shift work can disrupt brain circuits linked to immune regulation, weakening the adaptive immune response against pathobionts. Full article

Autoimmune diseases arise from complex interactions of genetic, environmental, and hormonal factors, yet their precise causes remain elusive. Beyond its canonical role in fibrin degradation, the fibrinolytic system is increasingly recognized as both a pathogenic driver and a regulatory modulator in autoimmunity. Key factors—plasminogen (Plg), plasmin, α2-antiplasmin (α2AP), tissue-type plasminogen activator (tPA), urokinase-type plasminogen activator (uPA), its receptor (uPAR), and plasminogen activator inhibitor-1 (PAI-1)—not only reflect secondary responses to vascular and immune dysregulation but also actively shape innate and adaptive immunity. They influence macrophage activation, dendritic cell maturation, T cell responses, and cytokine production, thereby bridging coagulation, inflammation, and tissue repair. This review integrates current evidence on the dual pathogenic and regulatory roles of fibrinolytic factors, organizing autoimmune diseases into systemic, organ-specific, and secondary syndromes. We further discuss how the imbalance of fibrinolysis can either promote inflammatory persistence or, conversely, facilitate resolution through fibrin clearance and immune homeostasis. By highlighting this bidirectional influence, the review aims to refine our understanding of fibrinolytic components as both contributors to and regulators of autoimmune disease pathogenesis. Full article

The intricate crosstalk between intestinal microbiota and host defense peptides (HDPs) in aquaculture has emerged as a cornerstone for advancing sustainable disease management and reducing reliance on antibiotics. This review synthesizes current insights into the bidirectional interactions shaping aquatic animal health, where HDPs, multifunctional immune molecules, directly neutralize pathogens while selectively modulating intestinal microbial communities to favor beneficial taxa (including Lactobacillus, Bacillus, Cetobacterium, Lactococcus, and so on) and suppress harmful species. Conversely, intestinal microbiota regulate HDP expression through microbial-derived signals, such as lipopolysaccharides and metabolites, which activate host immune pathways like Toll-like receptors (TLRs) to amplify innate defenses. This dynamic interplay underpins critical physiological functions, including nutrient absorption, intestinal barrier integrity, and systemic immune homeostasis, offering a dual mechanism to enhance disease resistance and growth performance. Practical applications, such as HDP-enriched feeds and probiotic–HDP synergies, have demonstrated efficacy in reducing mortality and improving productivity across species like shrimp, salmon, and carp. However, challenges such as HDP instability, species-specific variability in peptide efficacy, and the complexity of microbiota–HDP networks hinder broad implementation. Future research must prioritize innovative strategies, including engineered microbial systems for scalable HDP production, multi-omics approaches to unravel interaction mechanisms, and eco-friendly combinatorial therapies integrating HDPs, probiotics, and plant-derived compounds. By bridging immunology, microbiology, and aquaculture science, this field can transition toward antibiotic-free practices, ensuring ecological sustainability and global food security in the face of rising aquatic disease threats and environmental pressures. 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

Caffeic acid (CA), a plant-derived phenolic compound, is emerging as a promising natural feed additive for sustainable aquaculture. Its growth-promoting, immunomodulatory, and antimicrobial activities suggest utility as an alternative that diminishes antibiotic use in fish farming. Evidence across multiple species indicates improvements in innate immune responses, enhanced antioxidant capacity, and increased survival during pathogen challenge. Nevertheless, adoption remains limited by unresolved questions regarding optimal inclusion levels, species-specific physiological responses, interactions with other dietary components, and effects on the gut microbiota. This review synthesizes current research on CA, critically evaluates its functional roles in aquaculture, and assesses its relevance to sustainable production. Priorities for future work include elucidating mechanisms of action, conducting cross-species dose–response studies, standardizing dosing protocols, clarifying microbiome effects, and evaluating economic feasibility for large-scale use. Addressing these gaps will be essential to realize the full potential of CA as a functional feed additive in sustainable aquaculture systems. Full article

The zoonotic disease fasciolosis poses a significant global threat to both humans and livestock. The causative agent of fasciolosis is Fasciola hepatica, which is commonly referred to as liver fluke. The emergence of drug resistance has underscored the urgent need for new therapeutic treatments against F. hepatica. The tegument surface of F. hepatica is characterized by a dynamic syncytial layer surrounded by a glycocalyx, which serves as a crucial interface in host–parasite interactions, facilitating functions such as nutrient absorption, sensory input, and defense against the host immune response. Despite its pivotal role, only recently have we delved deeper into understanding glycans at the host–parasite interface and the glycosylation of hidden antigens. These glycan antigens have shown promise for vaccine development or as targets for drug manipulation across various pathogenic species. This review aims to consolidate current knowledge on the glycosylation of F. hepatica, exploring glycan motifs identified through generic lectin probing and mass spectrometry. Additionally, it examines the interaction of glycoconjugates with lectins from the innate immune systems of both ruminant and human host species. An enhanced understanding of glycans’ role in F. hepatica biology and their critical involvement in host–parasite interactions will be instrumental in developing novel strategies to combat these parasites effectively. In the future, a more comprehensive approach may be adopted in selecting and designing potential vaccine targets, integrating insights from glycosylation studies to improve efficacy. Full article

Two key players in the immune system, dendritic cells (DCs) and innate lymphoid cells (ILCs), interact in a crucial way to fight infectious diseases. DCs play a key role in recognizing pathogens, and ILCs respond to cytokines released by DCs. This response triggers the production of specific effector cytokines that help control pathogens and maintain the body’s barrier integrity. DCs have various receptors, including Toll-like receptors (TLRs), that detect microbial components and trigger immune responses. Likewise, ILCs act as essential initial responders in the immune system in viral, bacterial, and parasitic infections. Successfully managing diseases caused by pathogens mainly depends on the combined actions of DCs and ILCs, which work to suppress and eliminate pathogens. DCs also play a crucial role in activating innate and adaptive immune cell subsets, including ILCs. Furthermore, the use of DCs in developing vaccines and immunotherapy for cancers, along with the dedication of many researchers to improve immune responses through DCs, has increased interest in the potential of DC therapies for treating and preventing infectious diseases. This review examines approaches that may enhance DC vaccines and boost anti-infection immune responses by fostering better interactions of DCs with ILCs. Full article

The innate immune response is an important defense against invading pathogens. Stimulator of interferon gene (STING) plays an important role in the cyclic GMP-AMP synthase (cGAS)-mediated activation of type I IFN responses. However, some viruses have evolved the ability to inhibit the function of STING and evade the host antiviral defenses. Understanding both the mechanism of action and the viruses targets of STING effector is important because of their importance to evade the host antiviral defenses. In this study, the STING (IpSTING) of Ictalurus punctatus was first identified and characterized. Subsequently, the yeast two-hybrid system (Y2HS) was used to screen for proteins from channel catfish virus (CCV, Ictalurid herpesvirus 1) that interact with IpSTING. The ORFs of the CCV were cloned into the pGBKT7 vector and expressed in the AH109 yeast strain. The bait protein expression was validated by autoactivation, and toxicity investigation compared with control (AH109 yeast strain transformed with empty pGBKT7 and pGADT7 vector). Two positive candidate proteins, ORF41 and ORF65, were identified through Y2HS screening as interacting with IpSTING. Their interactions were further validated using co-immunoprecipitation (Co-IP). This represented the first identification of interactions between IpSTING and the CCV proteins ORF41 and ORF65. The data advanced our understanding of the functions of ORF41 and ORF65 and suggested that they might contribute to the evasion of host antiviral defenses. However, the interaction mechanism between IpSTING, and CCV proteins ORF41 and ORF65 still needs to be further explored. Full article

Drug resistance in Candida may result in either a fitness cost or a fitness advantage. Candida auris, whose intrinsic drug resistance remains unclear, has emerged as a significant human pathogen. We aimed to investigate whether Candida fitness, including early interaction with the host innate immune system, depends on the antifungal susceptibility phenotype and putative-associated resistance mutations. We compared interleukin-1β, interleukin-6, interleukin-8, and tumor necrosis factor α production by human colorectal adenocarcinoma cells stimulated by fluconazole-susceptible and fluconazole-resistant strains of Candida albicans, C. parapsilosis, C. tropicalis, and C. glabrata, as well as fluconazole-resistant C. auris strains. Sensitive Candida strains induced lower cytokine levels compared with C. auris and resistant strains, except for TNF a. Resistant strains induced cytokine levels like C. auris, except for higher IL-1β and lower TNF-α. Susceptible strains exhibited cytokine profiles distinct from those of resistant strains. C. auris induced cytokine levels comparable to resistant strains but displayed profiles resembling those of susceptible strains. This study highlights the relationship among antifungal susceptibility, fungal fitness and host early immunity. C. auris behavior appears to be between fluconazole-sensitive and fluconazole-resistant strains. Understanding these dynamics may enhance the knowledge of the survival and reproduction of resistant Candida and the epidemiology of fungal infections. Full article

Heat shock proteins (HSPs) play a key role in enhancing insect resilience to abiotic and biotic stresses by preserving cellular integrity and modulating immune responses. This review summarizes the main functions of HSPs in insects, including protein stabilization, interaction with antioxidant systems, and involvement in the innate immune response. The expression of HSPs under environmental conditions reflects their evolutionary adaptation to various stressors, including thermal changes, chemical exposure, and pathogens. Future research should focus on the interaction between HSPs and other stress response systems to improve our understanding of insect adaptation. Furthermore, in the context of global climate change, HSPs emerge as a crucial resilience factor and potential biomarkers for environmental monitoring. Full article

Silver nanoparticles (AgNPs), lauded for their unique antibacterial and physicochemical attributes, are proliferating across industrial sectors, raising concerns about their environmental fate, in aquatic systems. While “green” synthesis offers a sustainable production route with reduced chemical byproducts, the safety of these AgNPs for aquatic fauna remains uncertain due to nanoparticle-specific effects. Conversely, mast cells play crucial roles in fish immunity, orchestrating innate and adaptive immune responses by releasing diverse mediators and recognizing danger signals. Goblet cells are vital for mucosal immunity and engaging in immune surveillance, regulation, and microbiota interactions. The interplay between these two cell types is critical for maintaining mucosal homeostasis, is central to defending against fish diseases and is highly responsive to environmental cues. This study investigates the acute dermatotoxicity of environmentally relevant AgNP concentrations (0, 0.031, 0.250, and 5.000 μg/L) on zebrafish epidermis. A 96 h assay revealed a biphasic response: initial mucin hypersecretion at lower AgNP levels, suggesting an early stress response, followed by a concentration-dependent collapse of mucosal integrity at higher exposures, with mucus degradation and alarm cell depletion. A rapid and generalized increase in epidermal mucus production was observed across all AgNP exposure groups within two hours of exposure. Further mechanistic insights into AgNP-induced toxicity were revealed by concentration-dependent alterations in goblet cell dynamics. Lower AgNP concentrations initially led to an increase in both goblet cell number and size. However, at the highest concentration, this trend reversed, with a significant decrease in goblet cell numbers and size evident between 48 and 96 h post-exposure. The simultaneous presence of neutral and acidic mucins indicates a dynamic epidermal response suggesting a primary physical barrier function, with acidic mucins specifically upregulated early on to enhance mucus viscosity, trap AgNPs, and inhibit pathogen invasion, a clear defense mechanism. The subsequent reduction in mucin-producing cells at higher concentrations signifies a critical breakdown of this protective strategy, leaving the epidermis highly vulnerable to damage and secondary infections. These findings highlight the vulnerability of fish epidermal defenses to AgNP contamination, which can potentially compromise osmoregulation and increase susceptibility to threats. Further mechanistic research is crucial to understand AgNP-induced epithelial damage to guide sustainable nanotechnology. Full article

Monomeric C-reactive protein (mCRP), derived from the dissociation of the native pentameric CRP (pCRP), has been implicated in the pathophysiology of various neurological conditions, particularly intracerebral hemorrhage (ICH) and neurodegenerative diseases. mCRP accumulates in the brain after hemorrhagic stroke, contributing to the formation of the metabolic penumbra and promoting inflammation. Recent studies have linked mCRP to the activation of microglia, endothelial cells, and complement pathways, which collectively intensify neuroinflammation and disrupt tissue repair mechanisms. Additionally, mCRP is associated with cognitive decline, particularly in ICH survivors, by promoting microvascular damage, neurodegeneration, and vascular instability. The presence of mCRP in distant regions of the brain, including the hypothalamus, suggests its potential role in spreading inflammation and exacerbating long-term neurological damage. This review synthesizes findings on the pathogenic role of mCRP in stroke and neurodegeneration, proposing that mCRP could serve as both a biomarker and a therapeutic target for improving outcomes in stroke patients. Emerging immunopharmacological strategies are being actively pursued to mitigate the pathogenic activity of mCRP, a potent pro-inflammatory effector implicated in a variety of immune-mediated and neuroinflammatory conditions. These approaches encompass the inhibition of native pentameric CRP dissociation into its monomeric isoform, the disruption of mCRP’s high-affinity interactions with lipid rafts and cell surface receptors involved in innate immune activation, and the enhancement of its clearance through mechanisms such as solubilization, opsonin-mediated tagging, and phagocytic engagement. Targeting these immunoregulatory pathways offers a compelling therapeutic framework for attenuating mCRP-driven inflammatory cascades in both systemic and CNS-specific pathologies. Full article

Experimental models have been widely used to study the mechanisms of inflammation due to their genetic and physiological relevance to humans. These models include rodents (rats and mice), zebrafish, and nematodes (C. elegans). Considering the similarities and divergences between experimental models and the human organism, this narrative review aimed to compare and discuss their applicability in inflammation studies. Rodents, in particular, share significant similarities with humans across approximately 85% of their genome, making them ideal for investigating complex diseases and inflammatory responses. Zebrafish also stand out for showing high conservation of the immune system compared to humans, being useful for studies of adaptive and innate inflammation. Despite not having adaptive immunity, Caenorhabditis elegans is a robust model for understanding innate immune responses, especially in studies involving host–pathogen interactions. These organisms allow us to efficiently investigate the acute and chronic phases of inflammation, offering an accessible platform to study complex biological processes that are unfeasible in humans due to ethical and financial constraints. Thus, the use of these models has been essential for inflammation research. However, the use of each one will depend on the research question and hypothesis raised. Full article