Search Results (206)

Influenza A viruses remain a persistent global health challenge due to their rapid antigenic evolution, zoonotic potential, and pandemic threat. Universal countermeasures targeting conserved viral components are urgently needed to enhance diagnostic, surveillance, and therapeutic capabilities. Here, we report the generation and characterization of a high-affinity monoclonal antibody (2D8 mAb) against the nucleoprotein (NP) of the H9N2 avian influenza virus, a subtype with increasing relevance to human infections. Importantly, 2D8 mAb exhibited robust cross-reactivity with a broad spectrum of influenza A viruses, including H1, H3, H5, H7, and H9 subtypes, while showing no cross-reactivity with unrelated viral pathogens. Epitope mapping identified its binding target as a highly conserved NP motif ³⁸RFYIQMCTEL⁴⁷, which is invariant across all major human influenza A lineages. Isotyping revealed 2D8 mAb to be of the IgG2b/κ subclass, with an exceptionally high titer (1:20,480,000) as determined by ELISA. Given the essential role of NP in viral replication and host adaptation, this antibody offers a powerful platform for next-generation diagnostic assays capable of detecting a wide range of human and zoonotic influenza A viruses using a single reagent. Moreover, it holds potential for guiding the design of universal antiviral strategies targeting structurally constrained regions of the influenza virus. Our findings provide a valuable resource for advancing pan-influenza A interventions, with direct implications for improving pandemic preparedness and strengthening global influenza surveillance in both clinical and public health settings. Full article

The detection of environmental toxicants is transitioning from centralized laboratory methods to decentralized, point-of-care (POC) monitoring. A highly innovative approach in this field is the repurposing of commercially available, low-cost, and portable personal glucose meters (PGMs) as universal biosensing platforms. This strategy leverages the widespread availability and ease of use of PGMs to develop rapid, on-site detection methods for a wide array of non-glucose targets, significantly reducing both cost and development time. This systematic review comprehensively examines the various strategies employed to adapt PGMs for the detection of a wide array of ecotoxicants, including chemical targets (antibiotics, mycotoxins, pesticides, heavy metals, persistent organic pollutants) and biological ones (pathogenic bacteria, and viruses). The systematic review critically evaluates different sensor designs, highlighting that while aptamer-based and non-enzymatic biosensors offer advantages in stability and cost, antibody-based sensors provide high specificity. A significant finding is the persistent trade-off between analytical sensitivity and practical field deployment; many of the most sensitive assays require multi-step procedures, precise temperature control, magnetic separation, centrifugation, and the use of additional equipment, factors that undermine true POC utility. To address this gap, we propose four essential criteria for POC readiness: (i) ambient-temperature operation, (ii) no reliance on magnetic or centrifugal separation, (iii) total assay time, and (iv) robustness in complex environmental matrices. This systematic review confirms the feasibility of this approach across a broad spectrum of targets. However, the key challenge for future research lies in simplifying the assay protocols, eliminating cumbersome sample preparation steps, and enhancing robustness to make these biosensors truly practical for routine, on-site environmental monitoring. Full article

The characterization of cancer and other diseases can be aided by the development of reusable electrochemical sensors that provide broad biomarker expression information in real time. We describe an interdigitated electrode (IDE) sensor array that can be used for rapid detection of multiple biomarkers, including human midkine (MDK), HIV gp41 peptide, mAb 7B2, and single-stranded DNA (ssDNA), using electrochemical impedance spectroscopy (EIS) with coated nanoparticles (NPs). These targets represent potential biomarkers for identifying malignant cancer, HIV infection, and DNA mutation. Targets were detected by coating NPs with an antibody, a protein, and ssDNA to capture them from solution. Interacting proteins attached to the nanoparticles were then analyzed with EIS to identify interaction on the surface. In many biological contexts, more than one partner can interact with selected targets, so the determination of the identity of the interacting component is critical for interpretation. In a controlled system, we verify impedance data clusters based on the identity of the protein coated on the surface of the NPs. Data clusters corresponding to protein identity were clearly bifurcated using the impedance spectrum and unsupervised principal component analysis (PCA). NPs clustered based on surface modification, suggesting individual proteins have unique EIS spectral characteristics that can be used for identification. Full article

The diseases caused by genotype VII Newcastle disease virus (NDV), H9N2 avian influenza virus (AIV), and fowl adenovirus serotype 4 (FAdV-4) continue to threaten the global poultry industry. However, no broad-spectrum vaccines provide simultaneous protection against these three pathogens. This study employed bioinformatics and immunoinformatics approaches to design a multi-epitope vaccine, named NFAF, which consists of B-cell, cytotoxic T lymphocyte (CTL) epitopes, and helper T lymphocyte (HTL) epitopes derived from hemagglutinin-neuraminidase (HN) and fusion (F) proteins of genotype VII NDV, hemagglutinin (HA) protein of H9N2, and Fiber2 protein of FAdV-4. The vaccine candidate was predicted to have non-allergenic properties, non-toxicity, high antigenicity, and favorable solubility. Each of its constituent antigenic epitopes has a high degree of conservation. Molecular docking demonstrated stable binding between NFAF and chicken Toll-like receptor (TLRs) and major histocompatibility complex (MHC) molecules. NFAF was expressed in soluble form in Escherichia coli and purified. Polyclonal antibodies against all three target viruses showed specific binding to NFAF. In vitro experiments revealed that NFAF effectively stimulated chicken peripheral blood mononuclear cells (PBMCs) and induced Th1, Th2, and pro-inflammatory cytokine production, confirming its immunogenicity, and increased the mRNA expression of the key signaling molecules MyD88 and NF-κB. These results suggested that NFAF could therefore be an efficacious multi-epitope vaccine against genotype VII NDV, H9N2, and FAdV-4 infections. Full article

Background/Objectives: Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) can naturally infect a broad spectrum of animal species, with cats, minks, and ferrets being highly susceptible. There is a potential risk that infected animals could transmit viruses to humans. Moreover, SARS-CoV-2 continues to evolve via mutation and genetic recombination, resulting in the continuous emergence of new variants that have triggered a wave of reinfection. Therefore, safe and effective corona virus disease 2019 (COVID-19) vaccines for animals are still being sought. Methods: We generated three recombinant Modified vaccinia virus Ankara (MVAs) expressing the prefusion-stabilized S proteins, S6P, DS6P, and BA2S6P, targeting the full-length S protein genes of the ancestral, Delta, and Omicron BA.2 strains of SARS-CoV-2. Subsequently, the safety, immunogenicity, and protective efficacy of these MVA-based oral COVID-19 vaccine candidates were assessed in mice, minks, and cats. Results: These recombinant MVAs are safe in mice, minks, and cats. Oral or intramuscular vaccination with rMVA-S6P induced a robust SARS-CoV-2 neutralizing antibody (NA) response and conferred complete protection against the SARS-CoV-2 challenge in mice. Meanwhile, oral or intramuscular administration of these recombinant MVAs in combination induced a potent and durable NA response against homotypic SARS-CoV-2 pseudovirus in mice, minks, and cats, respectively. Conclusions: These findings suggest that the MVA-vectored vaccines are promising oral COVID-19 vaccine candidates for animals, and that the combined vaccination approach is an effective administration strategy for such vaccines. Full article

Background: Natural killer (NK) cells are key effectors of innate immunity with broad-spectrum anti-tumor activity. However, peripheral blood-derived NK (PBNK) cells are typically quiescent, which limits their therapeutic utility. This study aimed to develop an efficient strategy for the in vitro activation and expansion of PBNK cells and then evaluate their potential anti-tumor efficacy in vitro and vivo. Methods: NK cells were isolated from healthy blood donors’ peripheral blood and stimulated with anti-CD16 and anti-CD137 antibodies in the presence of interleukin-2 (IL-2) and interleukin-15 (IL-15) under serum-free conditions, generating super NK (SNK) cells. The expression levels of activating and inhibitory receptors on the expanded SNK cells were assessed by flow cytometry. Cytotoxicity against tumor cells was assessed at various effector-to-target (E:T) ratios in vitro. In vivo, anti-tumor efficacy was evaluated in K562-engrafted NSG mice. RNA sequencing was performed to identify differentially expressed genes (DEGs) between SNK and PBNK cells. Results: Stimulation with anti-CD16 and anti-CD137 antibodies resulted in significant expansion of donor-derived NK cells, with over 861.9 ± 48.84-fold expansion (n = 5) within 15 days of culture. SNK cells exhibited significantly elevated expression of activating receptors, including NKG2D. Functionally, SNK cells demonstrated superior cytotoxicity compared with PBNK cells across all tested E:T ratios in vitro and higher expressions of the effector molecules interferon-gamma (IFN-γ) and granzyme B (Gzm B). In vivo, adoptive SNK cell transfer resulted in significant tumor suppression and prolonged survival in a dose-dependent manner. Transcriptomic analysis revealed significant enrichment of DEGs associated with cytokine and chemokine signaling, immune activation, and cytotoxic effector function compared with the PBNK cells. Conclusions: Anti-CD16/CD137 antibody stimulation, in combination with IL-2 and IL-15, facilitates robust activation and rapid expansion of functionally enhanced NK cells from peripheral blood. The resulting SNK cells demonstrated enhanced anti-tumor efficacy both in vitro and in vivo and may be used as allogeneic NK cell-based immunotherapy in future cancer treatment strategies. Full article

Cellular senescence is an irreversible cell cycle arrest, triggered by stressors like telomere shortening, DNA damage, and oncogenic signaling. These cells, often referred to as ‘zombie cells’ because they cease dividing yet resist apoptosis, drive the Senescence-Associated Secretory Phenotype (SASP), releasing pro-inflammatory cytokines, chemokines, growth factors, and matrix-remodeling enzymes. While senescence is a protective mechanism against malignant proliferation, its persistence in tissues contributes to aging and age-related diseases (inflammaging). Recognizing this dual role forms the basis for developing therapies that bridge anti-aging, regenerative medicine, and oncology, as precise molecular regulatory mechanisms remain incompletely understood. This review interrelates these disciplines, focusing on targeted interventions against senescent cells (SnCs). These interventions include senolytics (agents that selectively eliminate SnCs) and senomorphics (agents that suppress the SASP), offering translational insights from anti-aging/aesthetic applications into integrated treatment models. The framework addresses cancer therapeutics via immunologic modalities such as monoclonal antibodies (mAbs) and CAR T-cell therapy, alongside nucleic acid-based therapeutics (mRNA and siRNA), and is used in combination with broad-spectrum therapeutics. The novelty lies in synthesizing these disparate fields, unified by cellular senescence as a central mechanistic target. Ultimately, the goal is to identify targets that induce tumor regression, mitigate age-related vulnerabilities, promote tissue homeostasis and regeneration, and improve quality of life and overall survival. Full article

The Japanese encephalitis virus (JEV) remains a major cause of viral encephalitis in Asia, and recent epidemiological shifts driven by the predominance of genotype I and the re-emergence of genotype V have renewed concerns regarding control efforts. Licensed vaccines have a reduced incidence of more than 90% in several endemic regions; however, evidence of reduced cross-neutralization against heterologous genotypes indicates that vaccines derived from genotype III strains may not fully match the evolving antigenic landscape. This review synthesizes current knowledge on vaccine performance, genotype-driven antigenic variation, and implications for future strain alignment. Emerging platforms, including mRNA, DNA, virus-like particles, and structure-guided recombinant antigens, have been evaluated for their potential to enhance cross-genotype breadth, scalability, and thermostability. We also summarize the progress in antiviral discovery targeting viral nonstructural proteins, host pathways, and monoclonal antibody development, along with immunomodulatory and neuroprotective strategies. Translational challenges, such as blood–brain barrier penetration, therapeutic timing, and durability of immunity, have been highlighted as key barriers to clinical application. By integrating molecular, immunological, and epidemiological evidence, this review outlines strategic directions for developing broad-spectrum vaccines and therapeutics capable of addressing the evolving genetic and ecological landscape of JEV. Full article

Background: Encephalitis is a severe and potentially life-threatening inflammatory disorder of the central nervous system. Without prompt diagnosis and appropriate treatment, it often results in poor clinical outcomes. The study aimed to develop an artificial intelligence-based model that distinguishes autoimmune encephalitis from infectious encephalitis, encompassing a broad spectrum of autoimmune encephalitis phenotypes, serostatuses, and neuroimmunological entities. Methods: We conducted a retrospective analysis of patients diagnosed with autoimmune encephalitis, including paraneoplastic neurological syndromes and/or infectious encephalitis, at Vilnius University Hospital Santaros Klinikos from 2016 to 2024. Supervised machine learning techniques were used to train the models, and Shapley Additive Explanations analysis was applied to improve their interpretability. Results: A total of 233 patients were included in the study. The Random Forest model demonstrated the best performance in differentiating the etiology of encephalitis, achieving an AUROC of 0.966. Further analysis revealed that laboratory, electroencephalography, and clinical data were the most influential predictors, whereas imaging data contributed less to classification accuracy. Conclusions: We developed a machine learning model capable of distinguishing infectious encephalitis from both seropositive and seronegative autoimmune encephalitis. Since autoimmune cases may be misdiagnosed as infectious in the absence of detectable antibodies, our model has the potential to support clinical decision-making and reduce diagnostic uncertainty. Full article

Statin exposure has been associated with a broad spectrum of muscle toxicity, ranging from asymptomatic creatine kinase (CK) elevation to immune-mediated necrotizing myopathy (IMNM) with anti-3-hydroxy-3-methylglutaryl-coenzyme A reductase (HMGCR) antibodies. The mechanisms underlying these adverse effects are not fully understood, and genetic predisposition may play a role. This observational study evaluated the association of HLA-DRB1*11 and SLCO1B1 rs4149056 variants with statin-induced muscle toxicity. A total of 62 statin-exposed patients treated at a single tertiary center were included and classified as follows: IMNM with anti-HMGCR antibodies (n = 11), non-immune myotoxicity (n = 20), and statin-exposed controls without myopathy (n = 31). The mean age was 66 ± 7.5 years, and 62% were women. The frequency of the HLA-DRB1*11 allele was significantly higher in patients with anti-HMGCR IMNM compared to those with non-immune myotoxicity (81.0% vs. 25.0%; OR = 13.5, 95% CI 1.73–15.3; p < 0.01) and controls (81.0% vs. 17.2%; OR = 21.6, 95% CI 2.87–23.7; p < 0.01). No significant difference was found between the non-immune myotoxicity and control groups. Likewise, the SLCO1B1 rs4149056 variant showed no association with either IMNM or non-immune muscle toxicity. These findings confirm a strong association between the HLA-DRB1*11 allele and anti-HMGCR IMNM. This genetic marker may help to better distinguish immune-mediated from non-immune forms of statin-related myopathy. Full article

Duck viral hepatitis (DVH), a highly contagious disease, is caused primarily by duck hepatitis A virus (DHAV). The viral genotypes exhibit significant diversity, creating a challenge as monovalent vaccines fail to provide cross-genotype protection in ducklings. This study aimed to design a multi-epitope peptide vaccine targeting different genotypes of DHAV. Using immunoinformatics approaches, we systematically identified key antigenic determinants, including linear B-cell epitopes, cytotoxic T-cell epitopes (CTL), and helper T-cell epitopes (HTL). Based on these, a novel vaccine candidate was developed. The vaccine construct was subjected to rigorous computational validation: (1) Molecular docking with Toll-like receptors (TLRs) predicted immune interaction potential. (2) Molecular dynamics simulations assessed complex stability. (3) In silico cloning ensured prokaryotic expression feasibility. Then, we conducted preliminary experimental validation for the actual effect of the vaccine candidate, including recombinant protein expression in E. coli, enzyme-linked immunosorbent assay (ELISA) quantification of humoral responses, and Western blot analysis of cross-reactivity. ELISA results demonstrated that the vaccine candidate could induce high-titer antibodies in immunized animals, with potency reaching up to 1:128,000, and the immune serum showed strong reactivity with recombinant VP proteins. Western blot analysis using duck sera confirmed epitope conservancy across genotypes. Collectively, the multi-epitope vaccine candidate developed in this study represents a highly promising broad-spectrum strategy against DHAV. The robust humoral immunity it elicits, coupled with its demonstrated cross-reactivity, constitutes compelling proof-of-concept, laying a solid foundation for advancing to subsequent challenge trials and translational applications. Full article

Antimicrobial peptides (AMPs), evolutionarily conserved components of the immune system, have attracted considerable attention as promising therapeutic candidates. Derived from diverse organisms, AMPs represent a heterogeneous class of molecules, typically cationic, which facilitates their initial electrostatic interaction with anionic microbial membranes. Unlike conventional single-target antibiotics, AMPs utilize rapid, multi-target mechanisms, primarily physical membrane disruption, which results in a significantly lower incidence of resistance emergence. Their broad-spectrum antimicrobial activity, capacity to modulate host immunity, and unique mechanisms of action make them inherently less susceptible to resistance compared with traditional antibiotics. Despite these advantages, the clinical translation of natural AMPs remains limited by several challenges, including poor in vivo stability, and potential cytotoxicity. Bioengineering technology offers innovative solutions to these limitations of AMPs. Two techniques have demonstrated promise: (i) a chimeric recombinant of AMPs with stable scaffold, such as human serum albumin and antibody Fc domain and (ii) chemical modification approaches, such as lipidation. This review provides a comprehensive overview of AMPs, highlighting their origins, structures, and mechanisms of antimicrobial activity, followed by recent advances in bioengineering platforms designed to overcome their therapeutic limitations. By integrating natural AMPs with bioengineering and nanotechnologies, AMPs may be developed into next-generation antibiotics. Full article

Human T-lymphotropic virus type 1 (HTLV-1) infection is associated with a spectrum of clinical outcomes, ranging from lifelong asymptomatic carriage to severe conditions such as HTLV-1-associated myelopathy/tropical spastic paraparesis (HAM/TSP) and adult T-cell leukemia/lymphoma (ATLL). Although antibody responses are known to shape immune regulation, the functional relevance of IgG idiotype repertoires in HTLV-1 pathogenesis remains poorly understood. This study investigated the immunomodulatory effects of IgG from individuals with distinct HTLV-1 clinical outcomes. IgG was purified from pooled serum samples of asymptomatic carriers (ACs), HAM/TSP, and ATLL patients and used to stimulate peripheral blood mononuclear cells (PBMCs) from healthy donors. Cytokine production in CD4⁺, CD8⁺, and γδ T cells was assessed by flow cytometry. Additionally, proteome-wide IgG reactivity was evaluated using a human protein microarray encompassing over 21,000 proteins, and bioinformatic analyses were conducted to identify protein–protein interaction networks and tissue-specific autoreactivity. HAM/TSP-derived IgG selectively enhanced IFN-γ production in all T-cell subsets and suppressed IL-4 in CD4⁺ T cells. ATLL-derived IgG induced IL-9 and IL-13 production in CD4⁺ T cells, and both HAM/TSP and ATLL IgG elevated IL-13 levels in CD8⁺ T cells. Microarray data revealed distinct autoreactive IgG profiles across clinical groups, targeting immune-related proteins, apoptotic regulators, and proteins expressed in T cells, monocytes, and non-immune tissues such as brain and testis. Notably, no functional or structural clustering was observed in protein–protein interaction networks, suggesting these reactivities reflect complex, idiotype-specific immune alterations rather than compensatory responses. The present findings suggest that HTLV-1 infection may be associated with the development of distinct IgG repertoires that potentially modulate cytokine responses and exhibit broad reactivity toward human proteins. Such patterns could contribute to immune dysregulation and may partially explain the divergent clinical trajectories observed in HAM/TSP and ATLL. Further investigations are warranted to validate these observations at the individual level and to clarify their mechanistic relevance in disease progression. Full article

Background/Objectives: This review discusses the development and application of targeted protein degradation strategies, particularly focusing on the ubiquitin–proteasome pathway and PROteolysis-TArgeting Chimeras (PROTAC) technology, for antiviral therapies. Methods/Results: The synthesis of specific PROTACs exemplifies the potential of this approach to inhibit viral replication. The discussion also covers ongoing efforts to develop broad-spectrum antivirals and explores the limitations of small-molecule ligands, proposing antibody mimetics as a versatile alternative. The review details innovative strategies involving engineered antibody mimetics, termed ‘diving antibodies’ (DAbs), capable of intracellular delivery and targeting viral proteins within cells. These molecules are engineered using modular nanotransporters to facilitate intracellular delivery. The integration of E3 ligase-binding sites into DAbs enhances their capacity to induce targeted protein degradation, with experimental evidence supporting their efficacy. Conclusions: Overall, the review underscores the potential of combining targeted degradation technologies with innovative delivery systems to create effective antiviral therapies, especially for viruses with limited treatment options. Full article

The COVID-19 pandemic, caused by SARS-CoV-2, has profoundly affected global health and the economy. The emergence of variants with spike mutations, particularly within the receptor-binding domain (RBD), has reduced the efficacy of many neutralizing antibodies (nAbs), and recent variants, including KP.3 and other circulating strains, show partial escape from infection- or vaccine-induced immunity. To overcome this, developing broad-spectrum nAbs that target the conserved S2 subunit of the spike protein is crucial. Unlike the highly mutable RBD, the S2 region remains structurally conserved, providing a promising foundation for universal protection. Deeper insight into S2 structure and function, together with advances in bispecific antibody design, could facilitate the development of next-generation therapeutics resilient to viral evolution. This review examines the structural evolution of the SARS-CoV-2 spike, focusing on the therapeutic potential of S2-targeting antibodies and strategies to overcome antibody resistance. Full article