Immuno, Volume 6, Issue 1 (March 2026) – 12 articles

Extracellular vesicles (EVs) constitute a heterogeneous group of membrane-derived particles generated through distinct biogenesis pathways, each regulated by precise molecular mechanisms. They carry a diverse array of cargo that reflects the physiological or pathological state of their parent cells. Their classification continues to evolve, as advances in isolation and characterization techniques have revealed novel vesicle subpopulations beyond the traditional categories of microvesicles, and apoptotic bodies, further highlighting the complexity of the EV landscape. Within the central nervous system (CNS), neurons, microglia, astrocytes, oligodendrocytes, and endothelial cells actively release EVs that contribute to intercellular communication. Growing evidence demonstrates that these vesicles play critical roles in neuroinflammation and neurodegeneration by transporting bioactive molecules that influence disease pathways. Their ability to cross the blood–brain barrier allows CNS-derived EVs to be detected in peripheral fluids, making them promising candidates for noninvasive biomarkers. Moreover, EVs are increasingly being explored as therapeutic tools due to their stability, biocompatibility, and capacity to deliver targeted molecular cargo. In this review, we provide a comprehensive overview of EV biogenesis and release mechanisms in CNS cell types, discuss their emerging functions in neuroinflammatory and neurodegenerative disorders, and summarize current advances in EV-based diagnostics and therapeutic approaches, including ongoing clinical trials. Full article

Stem-cell differentiation technologies have traditionally relied on recombinant growth factors, cytokines, and morphogens to initiate and guide lineage specification toward clinically relevant cell types. These approaches have enabled substantial progress in regenerative medicine, as exemplified by recent advances in cell-replacement therapies for Parkinson’s disease, type 1 diabetes, and retinal degeneration. However, protein-based ligands and soluble factors are often limited by short half-lives, pleiotropic signaling, condition-dependent effects, and challenges in achieving precise spatial and temporal control in scalable systems. In this review, we survey differentiation strategies driven by administered substances, organizing the field into five material-centric modules: recombinant growth factors, cytokines, morphogens, exogenous ligands, and agonist antibodies. For each module, we summarize mechanistic principles, representative studies, controllable variables, and translational considerations. While growth factors, cytokines, morphogens, and exogenous ligands remain central tools for directing lineage commitment and maturation, recent studies indicate that agonist antibodies offer an additional and distinct means of controlling differentiation outcomes. These antibodies can function as receptor agonists while also imparting tissue-selective effects, enabling lineage specification with coordinated spatial targeting. By focusing on differentiation methods driven by administered molecules and excluding direct physical stimulation or complex 3D constructs, this review provides a framework that is particularly relevant to immunology and translational practice. We highlight agonist antibody-based induction as an emerging strategy that complements established ligand-based approaches and may broaden the design space for clinically applicable stem-cell differentiation. Full article

Rheumatoid arthritis (RA) is triggered by dysregulated cytokine networks, but the distributional association of conventional synthetic (csDMARDs) and biologic DMARDs (bDMARDs) with circulating mediators has not been fully described. In this study, we aimed to investigate the treatment-associated modulation of TNF-α, IL-17, IL-13, and soluble CTLA-4 (sCTLA-4) in 64 RA patients (untreated, n = 14; csDMARD, n = 32; bDMARD ± csDMARD, n = 18) and 20 controls. ELISA was used to determine the serum levels, and Kruskal–Wallis tests and false discovery rate correction were used to determine the differences between groups, accompanied by DAS28- and CRP-adjusted quantile regression. Group-level analysis demonstrated that the levels of IL-17 were higher in patients treated with csDMARDs and bDMARDs than in the controls (FDR-adjusted p = 0.0009 and <0.0001, respectively), and the levels of IL-13 were higher in patients treated with bDMARDs than in the controls (p = 0.026). However, quantile regression did not reveal consistent treatment-related associations, suggesting that long-term pathway-specific immune responses and context-dependent regulation may be involved. Smoking independently predicted higher IL-13 at lower quantiles (β = 35.5; p < 0.0001), while TNF-α showed treatment-related increases only at the upper quantile in CRP-adjusted models (β = 323.7; p = 0.049). On the other hand, sCTLA-4 had the largest and most significant treatment-based increase (p < 0.0001), regardless of disease activity, and constant effects across mid-quantiles. Taken together, these findings suggest that sCTLA-4 shows therapy-responsive distributional changes, supporting its potential utility as a biomarker of biological efficacy. In contrast, the observed increases in IL-17 and IL-13 reflect ongoing immune activity and possible environmental influences. Distribution-sensitive biomarker profiling provides a nuanced approach to capturing immune response diversity in RA and may enhance precision in monitoring procedures. Full article

The balance of alveolar macrophage (AM) polarization is severely disrupted in chronic inflammatory diseases like bronchiectasis, where a persistent pro-inflammatory (M1) phenotype perpetuates inflammation. To address this, we developed a high-throughput platform using a series of synthetic glycoligands (L1-L5) on a polyethyleneimine (PEI) scaffold. These ligands, which have varying affinities for macrophage lectin-like receptors, were used for phenotypic “fingerprinting” of AM subpopulations from pediatric bronchiectasis patients and a healthy control. Analysis of bronchoalveolar lavage fluid (BALF) revealed a pathogenic, M1-dominant profile (55% M1) in patients, confirming a state of chronic inflammation, which starkly contrasted with the quiescent, M0-dominant profile in the healthy control. We then leveraged this platform for targeted immunomodulation, using a drug-ligand conjugate to steer the dysregulated macrophage population toward a healthy state. The most potent conjugate, Dox-L5, dramatically suppressed the pathogenic M1 population (from 55% to 16%). This M1 suppression was accompanied by a significant shift toward the M2a (tissue-repair) phenotype and the emergence of a quiescent M0-like population, effectively remodeling the AM profile. This work validates a glycan-based platform for both diagnosing and correcting pathological macrophage imbalances. Our targeted approach offers a precise strategy to resolve chronic inflammation in bronchiectasis by suppressing M1 macrophages and promoting a pro-resolving M0/M2 phenotype, thereby restoring lung homeostasis. Full article

Chagas disease, caused by Trypanosoma cruzi, affects a significant proportion of patients who develop digestive and cardiac complications, including megaviscera. This pathogenesis has been associated with autoimmune mechanisms mediated by molecular mimicry. In this study, an in silico evaluation of the potential structural basis of cross-reactivity of β-tubulin 1.9 of T. cruzi and the human β-4A tubulin isoform 3 was conducted. Using bioinformatics tools, homologous regions were identified and potentially immunogenic epitopes were predicted, considering their structural modeling and molecular docking. The proteins shared 87% sequence identity and 95% similarity, with an almost identical structural overlap, RMSD 0.291 Å. Three epitopes, VPFPRLHFF, NDLVSEYQQYQDATI, and GQSGAGNNWAKGHYTEGAELIDS, exhibited high predicted antigenicity, with the 9-mer and 16-mer peptides displaying structurally compatible docking poses within the binding grooves of MHC class I and class II molecules, respectively, while B-cell epitope potential was inferred from sequence-based property predictions. Normal mode analysis, used as an exploratory approach, suggested comparable flexibility profiles for the parasitic- and human-derived peptide–MHC complexes. These findings provide an exploratory structural framework supporting a potential role of β-tubulin epitopes in molecular mimicry processes implicated in the development of chagasic megaviscera. Full article

Signal transducer and activator of transcription 2 (STAT2) is a key component of the type I interferon (IFN-I/III) signaling pathway, which is pivotal in host defense against cancer and viral infections and in shaping immune responses. Building on our previously reported conditional Stat2 knockout (KO) mouse, we expand its utility by validating additional tissue-specific models and exploring novel functional contexts. Mice carrying loxP-flanked Stat2 alleles were crossed with CMV-Cre, Cdx2-Cre or CD11c-Cre mice. Deletion of STAT2 was validated by PCR genotyping and western blotting in the relevant tissues. To confirm defective IFN-I signaling with STAT2 deletion, IFN-β stimulation of splenocytes from CMV-Cre Stat2 KO mice showed a lack of induction of canonical IFN-I target genes, confirming functional disruption of the pathway. In vivo, global Stat2 deletion significantly impaired the antitumor efficacy of IFN-β treatment. Similarly, lung fibroblasts isolated from globally deleted Stat2 KO mice showed defective antiviral responses to IFN-β. Tissue-specific Cre models demonstrated selective ablation of STAT2 in target compartments without affecting its expression in non-target tissues. Together, these studies expand our published conditional Stat2 KO findings and highlight the value of this model as a versatile platform for dissecting STAT2-dependent signaling pathways in a tissue- and disease-specific manner. Full article

Efferocytosis, the process by which macrophages clear apoptotic cells, plays a vital role in maintaining immune homeostasis. This study explores the influence of inflammatory cytokines—tumor necrosis factor-alpha (TNF-α) and transforming growth factor-beta (TGF-β)—on efferocytosis dysregulation in coronary artery disease (CAD). Peripheral blood samples were collected from 27 non-obstructive and 29 obstructive CAD patients to isolate monocytes, which were then differentiated into M1 and M2 macrophages using specific cytokine stimuli. These macrophages were transfected with TNF-α and TGF-β siRNA to assess cytokine impact on efferocytosis. Expression levels of the efferocytosis receptor MERTK and its regulatory protease ADAM17 were quantified via qPCR. Statistical analysis revealed significantly higher MERTK expression in M2 macrophages compared to M1 (p = 0.002). Notably, TNF-α silencing enhanced efferocytosis in M2 macrophages, with increased clearance of early apoptotic bodies in non-obstructive CAD and late apoptotic bodies in obstructive CAD (both p < 0.001). These findings suggest that macrophage phenotype, apoptotic stage, and cytokine environment influence efferocytosis efficiency and may involve pathways beyond MERTK-ADAM17. They offer preliminary mechanistic insights into cytokine-mediated modulation of efferocytosis in CAD. Further in vivo studies are needed to confirm these observations and evaluate their relevance for future therapeutic strategies. Full article

Colorectal tumors consist of diverse cell populations, including cancer cells and immune cells. Sorafenib (Nexavar), an oral multikinase inhibitor, targets tumor growth and angiogenesis while inducing apoptosis. However, its clinical use is hindered by poor solubility, rapid metabolism, and low bioavailability. This study explores a nanotechnology-based approach to enhance Sorafenib’s efficacy against colon cancer. Nexavar was encapsulated into nanoparticles using an oil phase and Span 80 as a stabilizer to produce sub-100 nm droplets. The resulting Nano-Nexavar was evaluated for cytotoxicity on Caco-2 colorectal cancer cells and compared with free Nexavar on both Caco-2 and normal NCM-460 colon cells. Nano-Nexavar significantly reduced cancer cell viability at lower concentrations, with no observed toxicity to normal cells. Both formulations induced lactate dehydrogenase release and cell reduction at 2.5 µM, but Nano-Nexavar triggered nearly 60% apoptosis in Caco-2 cells. It inhibited Raf-1, NFκB, and ERK signaling, and reduced epidermal growth factor (EGF) and vascular endothelial growth factor (VEGF) levels over time. Notably, unlike Nexavar, the Nano-Nexavar suppressed aspartate β-hydroxylase (ASPH) and enhanced mitochondrial-mediated apoptosis by increasing Bax expression, mitochondrial accumulation, and mtDNA levels indicated by immunofluorescence, immunoblotting, flow cytometry, and qRT-PCR. These data demonstrate that Nano-Nexavar potentiates Sorafenib’s anticancer activity by targeting ASPH, thereby amplifying mitochondrial signaling–induced cell death. Full article

Tuberculosis (TB) has various clinical presentations; pulmonary TB (PTB) affects only the lungs, whereas extrapulmonary TB involves other organs, including pleural TB (PLTB). Immunological studies of patients with extrapulmonary TB primarily focus on the cellular Th1 response, which produces key cytokines, including IFN-γ, TNF, IL-12, and IL-6. TNF and IL-6 play functional roles in host resistance to Mycobacterium tuberculosis (Mtb) infection. Findings suggest that TNF facilitates macrophage containment of Mtb, whereas IL-6 increases macrophage apoptosis induced by Mtb. Studies of the human genome have identified single-nucleotide polymorphisms (SNPs) in genes encoding cytokines associated with TB susceptibility. This study aimed to assess the potential of the IL6-174G/C (rs1800795), TNF-308G/A (rs1800629), and TNF-238G/A (rs361525) SNPs as genetic biomarkers of susceptibility to PLTB in the Venezuelan mestizo population. A total of 269 individuals were included: 69 patients with PLTB and 200 healthy individuals. The IL6-174G/C, TNF-308G/A, and TNF-238G/A polymorphisms were determined by sequence-specific primer polymerase chain reaction (SSP-PCR). Results showed significantly higher frequencies of the G/C, G/A, and G/A genotypes in patients with PLTB (94.0%, 94.2%, and 83.3%) than in controls (40.0%, 19.0%, and 13.4%) for the IL6-174G/C, TNF-308G/A, and TNF-238G/A polymorphisms, respectively. Logistic regression analysis showed significant associations between the G/C, G/A, and G/A genotypes and susceptibility to PLTB. The IL6-174G/C, TNF-308G/A, and TNF-238G/A gene polymorphisms may serve as genetic biomarkers of susceptibility to PLTB in the Venezuelan mestizo population. Full article

Successful implantation requires a finely regulated endometrial microenvironment during the window of implantation. Chronic endometritis, defined by plasma cell infiltration, and stromal senescence, indicated by p16 expression, represent separate but potentially interacting mechanisms associated with impaired endometrial receptivity. The relationship between these processes remains poorly understood. We aim to examine whether stromal senescence is associated with plasma cell density and clustering in the human endometrium during the implantation window. Forty mid-luteal (LH+7) endometrial biopsies were retrospectively analyzed and stratified into low-senescence (<0.5% stromal p16⁺ cells, n = 20) and high-senescence (>3.5%, n = 20) groups. Plasma cells were identified by immunohistochemistry for MUM1 and CD138 and quantified using HALO^® software (version 3.4). Group comparisons were performed using Student’s t-test and chi-squared analysis. CD138⁺ plasma cells were significantly more abundant in high-senescence endometria than in low-senescence controls (0.065 ± 0.10 vs. 0.014 ± 0.027 cells/mm², p = 0.02). Only MUM1⁺ cells formed stromal clusters, which were more frequent in high-senescence samples (67% vs. 31%, p = 0.05). High endometrial stromal senescence during the implantation window is associated with increased plasma cell infiltration and clustering. This interplay may contribute to chronic endometritis and impaired receptivity, providing new insights into potential diagnostic and therapeutic strategies for reproductive failure. Full article

Hericium erinaceus is a medicinal mushroom valued in the wellness industry for its neuroprotective, immunomodulatory, and antioxidant activities. While many extracts and bioactive compounds from both mycelium and fruit bodies have been characterized, the mechanisms driving their effects are not fully understood. Here, the transcriptomic and protein-level effects of H. erinaceus mycelium (HDLM) in human peripheral blood mononuclear cells (PBMCs) were investigated, along with antioxidant and iron chelating activity. A commercially available H. erinaceus fruit body extract (FBE) claiming high β-glucan content was included in a subset of assays to compare immune-related outcomes between mycelial and fruit body constituents. HDLM activated a wide array of immune- and oxidative stress-related transcripts and pathways, exhibited significant antioxidant activity, and consistently reduced IL-1β, TNF-α, and IL-8 during LPS challenge while maintaining low basal cytokine expression, indicating targeted immunomodulatory activity. FBE almost doubled production of IL-1β when challenged by LPS, whereas HDLM significantly decreased production of this stress mediator. HDLM also demonstrated augmented iron chelating ability when compared to FBE. Depending on tissue source and preparation methods, different H. erinaceus materials may either potentiate or quench stress responses, highlighting the need for further bioactivity and safety comparisons across H. erinaceus supplements, particularly with respect to cytokine regulation under conditions of immune challenge. Full article

Unexplained infertility and idiopathic recurrent pregnancy loss (RPL) have a prevalence of 1–5% of women of reproductive age in different populations. There are a few reports comparing the circulating immune cell populations and subpopulations in these medical entities in admixed populations. The study aimed to assess the different leukocyte, mononuclear cell populations, and T lymphocyte subpopulations and HLADR expression, as a marker of activation, in an admixed group of Venezuelan women: 80 controls, 73 women with RPL (53 primary, 20 secondary), and 26 infertile (20 primary, six secondary). Endometriosis was clinically ruled out in all patients and controls. Total leukocytes were 10–12% higher (p < 0.0001) in the infertile group, while neutrophils were 11% in the infertility group (p < 0.0001). In contrast, lymphocytes, CD3CD4 cells, NK cells, and HLADR+ cells were elevated (10–15, 18–22, 50–60, and 700–800% increase, respectively) in all patient groups. Changes in B cell numbers and monocyte counts were also observed. HLADR expression was significantly increased (p < 0.0001) in T cells, CD56+ cells, and monocytes of all patients. In infertile patients, a correlation was recorded between HLADR and T memory cells. Marked differences in peripheral blood leukocytes, NK cells, monocytes, T-cell populations, and HLADR suggest a proinflammatory effect. HLADR can be used as a simple biomarker to monitor pharmacological treatment in these patients. Full article