Immunogenic Potential Research Articles

Will the Real Immunogens Please Stand Up: Exploiting the Immunogenic Potential of Cryptococcal Cell Antigens in Fungal Vaccine Development

Cryptococcus neoformans is an opportunistic fungal pathogen that is a continuous global health concern, especially for immunocompromised populations. The World Health Organization recognized C. neoformans as one of four critical fungal pathogens, thus emphasizing the need for increased research efforts and clinical resource expansion. Currently, there are no fungal vaccines available for clinical use. Exciting new findings in cryptococcal vaccine development have identified whole cell-based and subunit-based vaccinations to help mitigate health risks and make commercialization attainable. Importantly, recent work has focused on how different cryptococcal cell-wall antigens modified in these vaccine candidates allow us to manipulate their immunogenicity to produce a desired long-term protective anti-fungal immune response. In this review, we discuss the different cryptococcal cell immunogens, namely the polysaccharide capsule, glucans, chitin/chitosan, mannoproteins, and extracellular vesicles, and their role in novel cryptococcal vaccination approaches. Additionally, we examine the immunological mechanisms responsible for protection in these vaccine candidates and the similar host response-stimulation pathways induced through different immunogen exposure.

Impact of polycaprolactone, alginate, chitosan and zein nanofiber physical properties on immune cells for safe biomedical applications.

Nanofiber safety, especially immunogenicity, is important for their successful translation to clinical setting. This study provides a comprehensive evaluation of how nanofiber physical properties influence immune cells cultured on them, specifically peripheral blood mononuclear cells (PBMCs). We prepared nanofibers with a wide range of physical properties including various diameters, interfibrillar pore sizes and mat thicknesses, using four main polymers: polycaprolactone, alginate, chitosan, and zein. Our findings show that nanofiber diameters had only a marginal influence on the activity of immune cells, whereas interfibrillar nanofiber pore sizes had a significant effect, and mat thickness proved to have the greatest impact. Cells that penetrated deeper into the thick nanofiber mats ceased to proliferate but did not experience cytotoxicity. Moreover, we discovered that PBMCs penetrating the zein/PVP nanofiber mesh exhibited increased metabolic activity, indicating potential immunogenicity, whereas the other tested non-immunogenic nanofibers reduced it. To best of our knowledge, this study is the first to report on the impact of various nanofiber physical properties on in vitro immune cell behavior, thereby expanding the knowledge in the relatively unexplored field of nanofiber immunological safety. It underscores the need for rigorous preclinical nanofiber assessment and setting new standards for designing nanofiber-based biomedical products.

Expression, optimization and biological activity analysis of recombinant type III collagen in Komagataella phaffii.

Type III collagen, a fundamental constituent of the extracellular matrix (ECM), is extensively utilized across the biomedicine, tissue engineering, and cosmetic industries because of its exceptional biocompatibility and biodegradability. Despite its widespread application, traditional methods of collagen production are often hindered by the limit yield, potential immunogenicity, and batch-to-batch variability. In the present study, we describe a synthetic biological approach for expressing full-length recombinant type III collagen (RCIII) in the Komagataella phaffii system. Furthermore, the protein expression level was effectively increased by co-expression of the MPR1 gene, which improved the intrinsic antioxidant defenses of yeast cells, thereby reducing oxidative stress damage. The resulting RCIII maintains its native secondary structure and exhibits robust biological activities, including the promotion of platelet coagulation, enhancement of cell migration, and anti-inflammatory efficacy. Our findings suggest a viable pathway for large-scale, industrial production of type III collagen, offering a promising biomaterial for advanced biomedical applications, and contributing to the circular economy of the biomedical sector.

Protection induced by Streptococcus pneumoniae extracellular vesicles against nasal colonization and invasive infection in mice and the role of PspA

Diseases caused by Streptococcus pneumoniae (pneumococcus) produce a great impact on public health, killing about one million people annually despite available vaccines. Recent research has revealed that the pneumococcus produces extracellular vesicles (pEVs), which display selective cargo and hold potential for vaccine development. Here, we evaluated the immunogenicity and protective potential of pEVs derived from a non-encapsulated pneumococcal strain (R6) using murine models of pneumococcal colonization and invasive pneumonia. Characterization of the immune response revealed that while pEVs contain multiple virulence determinants, immunization with these nanoparticles only induces antibodies against a subset of them. Specifically, subcutaneous immunization elicits a high antibody response against PspA, a modest response against PrsA, and limited response against Ply, MalX and PsaA. The antibody response was further supported by agglutination studies, showing that sera from pEV immunized mice agglutinate pneumococci and that PspA contributes to this response in a strain-dependent manner. Subcutaneous immunization with pEVs provides protection in the invasive pneumonia model whereas nasal immunization results in one log reduction in pneumococcal colonization of the upper respiratory tract. Finally, PspA is a strong contributor to protection in the invasive model and provides a degree of protection even across heterologous families of PspA. We conclude that pEVs demonstrate potential for vaccine development, protecting across capsular types and providing some degree of protection across heterologous PspA variants.

From bytes to bites: In-silico creation of a novel multi-epitope vaccine against Murray Valley Encephalitis Virus

Flaviviruses transmitted by arthropods, including the Murray Valley Encephalitis Virus (MVEV), are RNA viruses capable of causing severe encephalitis in various hosts. The spread of these viruses is closely linked to climatic conditions and the habitats of host and vector species, leading to outbreaks in new geographic regions. Notable encephalitis-causing flaviviruses include Japanese encephalitis virus (JEV), West Nile virus (WNV), and Kunjin virus (KUNV). MVEV, primarily spread by the mosquito Culex annulirostris and amplified by water birds such as egrets and Nankeen night herons, has caused significant outbreaks in Australia, including severe epidemics in 1951, 1956, and 1974. Despite its severity, no rapid diagnostic techniques or effective antiviral treatments are available, and current interventions are limited to supportive care and mosquito management. Given the absence of a licensed vaccine, this study aimed to develop a multi-epitope hybrid vaccine targeting MVEV using in silico approaches. The study focused on identifying B-cell and T-cell epitopes from the MVEV Envelope (E) protein, constructing a vaccine candidate, and computationally validating its immunogenic potential. The designed vaccine underwent rigorous analysis of its antigenic properties, allergenicity, and toxicity. Disulfide engineering and assessment of physicochemical properties ensured the structural integrity of the vaccine, supported by Ramachandran plot and ProSA web analyses. Molecular docking studies assessed the vaccine's binding affinities with TLR-3, and MHC-I. Population coverage analysis of MHC-I and MHC-II epitopes evaluated global efficacy. Additionally, molecular dynamics simulations explored the stability of docked complexes, and PDBsum analysis elucidated interaction details. Immunological simulations were conducted to predict immune response outcomes, providing comprehensive validation of the vaccine's antigenicity. The findings highlight the potential of a multi-epitope vaccine as a viable strategy for MVEV prevention.

Effects of virus-induced immunogenic cues on oncolytic virotherapy

Oncolytic virotherapy is a promising form of cancer treatment that uses viruses to infect and kill cancer cells. In addition to their direct effects on cancer cells, the viruses stimulate various immune responses partly directed against the tumour. Efforts are made to genetically engineer oncolytic viruses to enhance their immunogenic potential. However, the interplay between tumour growth, viral infection, and immune responses is complex and not fully understood, leading to variable and sometimes counterintuitive therapeutic outcomes. Here, we employ a spatio-temporal model to shed more light on this interplay. We investigate systematically how the properties of virus-induced immunogenic signals (their half-life, rate of spread, and potential to promote T-cell-mediated cytotoxicity) affect the therapeutic outcome. Our simulations reveal that strong immunogenic signals, combined with faster diffusion rates, improve the spread of immune activation, leading to better tumour eradication. However, replicate simulations suggest that the outcome of virotherapy is more stochastic than generally appreciated. Our model shows that virus-induced immune responses can interfere with virotherapy, by targeting virus-infected cancer cells and/or by impeding viral spread. In the presence of immune responses, the mode of virus introduction is important, with systemic viral delivery throughout the tumour yielding the most favourable outcomes. The timing of virus introduction also plays a critical role; depending on the efficacy of the immune response, a later start of virotherapy can be advantageous. Overall, our results emphasise that the rational design of oncolytic viruses requires optimising virus-induced immunogenic signals and strategies that balance viral spread with immune activity for improved therapeutic success.

A patient stratification signature mirrors the immunogenic potential of high grade serous ovarian cancers

BackgroundWhile high-grade serous ovarian cancer (HGSC) has proven largely resistant to immunotherapy, sporadic incidents of partial and complete response have been observed in clinical trials and case reports. These observations suggest that a molecular basis for effective immunity may exist within a subpopulation of HGSC. Herein, we developed an algorithm, CONSTRU (Computing Prognostic Marker Dependencies by Successive Testing of Gene-Stratified Subgroups), to facilitate the discovery and characterization of molecular backgrounds of HGSC that confer resistance or susceptibility to protective anti-tumor immunity.MethodsWe used CONSTRU to identify genes from tumor expression profiles that influence the prognostic power of an established immune cytolytic activity signature (CYTscore). From the identified genes, we developed a stratification signature (STRATsig) that partitioned patient populations into tertiles that varied markedly by CYTscore prognostic power. The tertile groups were then analyzed for distinguishing biological, clinical and immunological properties using integrative bioinformatics approaches.ResultsPatient survival and molecular measures of immune suppression, evasion and dysfunction varied significantly across STRATsig tertiles in validation cohorts. Tumors comprising STRATsig tertile 1 (S-T1) showed no immune-survival benefit and displayed a hyper-immune suppressed state marked by activation of TGF-β, Wnt/β-catenin and adenosine-mediated immunosuppressive pathways, with concurrent T cell dysfunction, reduced potential for antigen presentation, and enrichment of cancer-associated fibroblasts. By contrast, S-T3 tumors exhibited diminished immunosuppressive signaling, heightened antigen presentation machinery, lowered T cell dysfunction, and a significant CYTscore-survival benefit that correlated with mutational burden in a manner consistent with anti-tumor immunoediting. These tumors also showed elevated activity of DNA damage/repair, cell cycle/proliferation and oxidative phosphorylation, and displayed greater proportions of Th1 CD4 + T cells. In these patients, but not those of S-T1 or S-T2, validated predictors of immunotherapy response were prognostic of longer patient survival. Further analyses showed that STRATsig tertile properties were not explained by known HGSC molecular or clinical subtypes or singular immune mechanisms.ConclusionsSTRATsig is a composite of parallel immunoregulatory pathways that mirrors tumor immunogenic potential. Approximately one-third of HGSC cases classify as S-T3 and display a hypo-immunosuppressed and antigenic molecular composition that favors immunologic tumor control. These patients may show heightened responsiveness to current immunotherapies.

Epitope Analysis of Hypothetical Proteins in Leptospira interrogans Serovar Lai Reveals Potential Diagnostic Markers

Leptospirosis is a neglected zoonosis caused by a pathogenic spirochete, Leptospira interrogans. The mode of infection in humans is through an abrasion in human skin or the conjunctiva and mucous membrane. Infected patients usually show different symptoms resembling bacterial or viral infections such as the flu. Hence, diagnosing leptospirosis in the early stage is complex, and can be easily confused with other infections. A strategical pathway was developed to analyze the hypothetical proteins in L. interrogans and unveil their potential as diagnostic markers. Subcellular localization tools such as PSORTb, CELLO, SOSUI-GramN, and ProtCompB were used to segregate the outer membrane and surface proteins from the overall pool of hypothetical proteins. The shortlisted proteins were checked for their virulency, and antigenicity through tools such as VirulentPred, and VaxiJen, respectively. Proteins with the highest scores were fed into ElliPro which predicted both linear and discontinuous epitopes in each protein. Proteins with many epitopes were further analyzed with BepiPred 3.0, which provided the epitope probability for each protein’s amino acid. Epitope probability of the potential proteins was compared with the standard diagnostic marker, LipL32. The comparison revealed that a protein (UniProt ID D4YW28) has better immunogenic potential than the gold standard marker, LipL32. In conclusion, this protein can be used as a diagnostic marker for the detection of leptospirosis and it will also serve as a better vaccine candidate.

Non‐Natural MUC1 Glycopeptide Homogeneous Cancer Vaccine with Enhanced Immunogenicity and Therapeutic Activity

AbstractGlycopeptides derived from the glycoprotein mucin‐1 (MUC1) have shown potential as tumor‐associated antigens for cancer vaccine development. However, their low immunogenicity and non‐selective conjugation to carriers present significant challenges for the clinical efficacy of MUC1‐based vaccines. Here, we introduce a novel vaccine candidate based on a structure‐guided design of an artificial antigen derived from MUC1 glycopeptide. This engineered antigen contains two non‐natural amino acids and has an α‐S‐glycosidic bond, where sulfur replaces the conventional oxygen atom linking the peptide backbone to the sugar N‐acetylgalactosamine. The glycopeptide is then specifically conjugated to the immunogenic protein carrier CRM197 (Cross‐Reactive Material 197), a protein approved for human use. Conjugation involves selective reduction and re‐bridging of a disulfide in CRM197, allowing the attachment of a single copy of MUC1. This strategy results in a chemically defined vaccine while maintaining both the structural integrity and immunogenicity of the protein carrier. The vaccine elicits a robust Th1‐like immune response in mice and generates antibodies capable of recognizing human cancer cells expressing tumor‐associated MUC1. When tested in mouse models of colon adenocarcinoma and pancreatic cancer, the vaccine is effective both as a prophylactic and therapeutic use, significantly delaying tumor growth. In therapeutic applications, improved outcomes were observed when the vaccine was combined with an anti‐programmed cell death protein 1 (anti‐PD‐1) checkpoint inhibitor. Our strategy reduces batch‐to‐batch variability and enhances both immunogenicity and therapeutic potential. This site‐specific approach disputes a prevailing dogma where glycoconjugate vaccines require multivalent display of antigens.

Exploring structure-directed immunogenic cytotoxicity of arginine-rich peptides for cytolysis-induced immunotherapy of cancer

The same cells can die with varied immunological consequences. For the purpose of cancer therapy, stronger immunogenic death of cancer cells is considered favorable. Membrane disruptive peptides are cytotoxic agents with tunable structures capable of not just killing heterogeneous cancer cells, but also inducing immunogenic death. However, the chemo-structural principles that underlie their immunogenic cytotoxicity remain elusive. Here we investigated a series of arginine-rich amphipathic peptides with representative structures on the relationship between the mode of cell death and the immunogenic potency. Among several hydrophobic motif-appended cyclic octaarginine peptides, FC-14 was found to induce cell stress and necroptotic death, unlike apoptotic peptide RL2 and membrane-dissolving peptide RL1. Their differing abilities to release immunogenic death markers correlated well with their potential to activate innate immunity and protective vaccinal effect in a prophylactic model, with FC-14 being the most potent. FC-14 can be pre-opsonized with albumin into nanoparticles (PopAN-FC-14) using PopAN technology to improve its pharmacokinetic properties for intravenous injection. In a syngeneic mouse model of subcutaneous breast cancer, PopAN-FC-14 showed superior therapeutic effect and safety profile than the albumin formulated nanomedicine Nab-paclitaxel (Nab-PTX). Boost injections of PopAN-FC-14 significantly enhanced tumor-specific cellular and humoral immunities, acting similarly as in-situ cancer vaccine. Overall, this work demonstrates a novel focus on the immunogenic cytotoxicity of peptides and a practical approach for effective systemic therapy of cancer.

Reprogramming cellular senescence in the tumor microenvironment augments cancer immunotherapy through multifunctional nanocrystals.

Harnessing the immunogenic potential of senescent tumor cells provides an opportunity to remodel tumor microenvironment (TME) and boost antitumor immunity. However, this potential needs to be sophisticatedly wielded to avoid additional immunosuppressive capacity of senescent cells. Our study shows that blocking the JAK2/STAT3 pathway enhances immunogenic efficacy of Aurora kinase inhibitor alisertib (Ali)-induced senescence by reducing immunosuppressive senescence-associated secretory phenotype (SASP) while preserving immunogenic SASP. Hypothesizing that SASP reprogramming with Ali and JAK2 inhibitor ruxolitinib (Rux) will benefit cancer immunotherapy, we create nanoparticulate crystals (Ali-Rux) composed of Ali and Rux with a fully active pharmaceutical ingredient. Immunization with Ali-Rux-orchestrated senescent cells promotes stronger activation of antigen-presenting cells, enhancing antitumor immune surveillance. This approach remodels the TME by increasing CD8+ T cell and NK recruitment and activation while decreasing MDSCs. Combined with PD-L1 blockade, Ali-Rux elicits a durable antitumor immune response, suggesting the TME reshaping approach as a potential cancer immunotherapy.

New insights for the development of efficient DNA vaccines.

Despite the great potential of DNA vaccines for a broad range of applications, ranging from prevention of infections, over treatment of autoimmune and allergic diseases to cancer immunotherapies, the implementation of such therapies for clinical treatment is far behind the expectations up to now. The main reason is the poor immunogenicity of DNA vaccines in humans. Consequently, the improvement of the performance of DNA vaccines invivo is required. This mini-review provides an overview of the current state of DNA vaccines and the various strategies to enhance the immunogenic potential of DNA vaccines, including (i) the optimization of the DNA construct itself regarding size, nuclear transfer and transcriptional regulation; (ii) the use of appropriate adjuvants; and (iii) improved delivery, for example, by careful choice of the administration route, physical methods such as electroporation and nanomaterials that may allow cell type-specific targeting. Moreover, combining nanoformulated DNA vaccines with other immunotherapies and prime-boost strategies may help to enhance success of treatment.

Preparation of bovine coronavirus virus-like particles and its immunogenicity in mice and cattle

The widespread prevalence of bovine coronavirus (BCoV) disease worldwide has impacted the livestock industry economically. No effective vaccine is available in China. In this study, we produced BCoV virus-like particles (VLPs) containing E, M, N, S, and hemagglutinin-esterase (HE) proteins using a baculovirus expression system. Five recombinant baculoviruses were co-infected with Sf9 cells, and the VLPs were assembled and characterized. Mice and cattle were immunized by VLPs mixed with MF59 and CpG 55.2 adjuvants. Two doses of the VLPs/MF59/CpG vaccine were administered in mice and cattle. The immune effect of the VLPs/MF59/CpG vaccine was measured using indirect ELISA and neutralization assays. After immunization, the serum IgG-specific antibody titer against S protein and neutralization antibody titer increased to 1:1.28 × 104 (p < 0.01) and 1:128 (p < 0.01) in mice, respectively. Interestingly, the high IgG antibody and neutralizing antibody titers were maintained for seven days in mice. In addition, the serum IgG-specific antibody titer against S proteins and neutralization antibody titer increased to 1:1.024 × 105 and 1:512 (p < 0.05) in cattle, respectively. The high IgG antibody and neutralizing antibody titers were maintained for 21 days in cattle. Notably, BCoV VLPs group interferon-gamma (IFN-γ) lymphocytes in spleens were significantly increased (p < 0.01). These findings suggest that BCoV VLPs induced strong cellular and humoral immune responses in mice and cattle. These findings suggest that BCoV VLPs could serve as a potent immunogen for vaccine development.

Evaluating surfactant effectiveness in preventing antibody adsorption directly on medical surfaces using a novel device

Biopharmaceuticals, specifically antibody-based therapeutics, have revolutionized disease treatment. Throughout their lifecycle, these therapeutic proteins are exposed to several stress conditions, for example at interfaces, posing a risk to the drug product stability, safety and quality. Therapeutic protein adsorption at interfaces may lead to loss of active product and protein aggregation, with potential immunogenicity risks. Non-ionic surfactants are commonly added in formulations to mitigate protein-surface interactions. However, their effectiveness varies with the monoclonal antibody (mAb), and model surface material. Extrapolating findings from model surfaces to real medical surfaces is challenging due to diverse properties.This study pioneers the evaluation of surfactant effectiveness in preventing mAb adsorption directly on medical surfaces at the medical bag/formulation interface, utilizing the ELIBAG device. The adsorption of different protein modalities, mAbs and antibody-drug conjugate (ADC), using three surfactants (PS80, PS20, and P188), was examined across various medical surfaces, IV bags and manufacturing bags, and model surfaces. Our findings reveal that surfactants prevent mAb adsorption depending on the mAb modality, surfactant type and concentration, and surface material. This research underscores the importance of considering real medical surfaces in direct contact with formulations, offering insights for enhancing drug product development and ensuring material-protein compatibility in real world use.

Ethnic diversity in Chilean blood groups: A comprehensive analysis of genotypes, phenotypes, alleles and the immunogenic potential of antigens in northern, southern and central regions.

The available information on blood groups in the Chilean population is derived from studies on aboriginal cohorts and routine serological test results. The purpose of this study is to conduct a comprehensive analysis of genotypes, phenotypes and blood group alleles in donors from northern, central and southern Chile using molecular methods. Overall, 850 samples from donors in northern, central and southern Chile were genotyped. Allelic, genotypic and antigenic frequencies were calculated and compared among regions. Of these, 602 samples were analysed by haemagglutination, and discrepancies found between phenotypes and genotypes were investigated. The immunogenic potential of antigens was calculated by the Giblett equation, using the antigenic frequencies of donors from Santiago and the alloantibody frequencies of patients from the same region. Alleles of low prevalence, variant alleles and those responsible for the absence of high-prevalence antigens were found. Significant differences were observed between the antigenic frequencies of the three regions. Discrepancies between serologic and molecular results were mostly attributed to the molecular background affecting antigen expression. In the calculation of the immunogenic potential of antigens, the highest value was attributed to the Dia antigen. These findings represent the first molecular characterization of blood group antigens in Chileans. Our results highlight the necessity of using molecular tools to explore the genotypes underlying variant phenotypes, low-frequency antigens and antigens lacking specific antisera that cannot be detected by haemagglutination. Additionally, they emphasize the importance of understanding the distribution of blood groups among different populations.

Histidine phosphatase-ferroptosis crosstalk modulation for efficient hepatocellular carcinoma treatment

Altering the mechanisms of tumor cell death and overcoming the limitations of traditional chemotherapy is pivotal to contemporary tumor treatment. Inducing ferroptosis, while circumventing safety concerns associated with ferrous vectors, through nonferrous ferroptosis is a promising but underexplored frontier in cancer therapy. Histidine phosphatase (LHPP) has emerged as a novel therapeutic target in treating hepatocellular carcinoma (HCC), but the precise mechanism of LHPP against HCC remains unclear. Herein, we explore the effects of upregulating LHPP expression on ferroptosis and tumor immunogenicity induction by simply delivering a miRNA-363-5p inhibitor (miR-363-5pi) via a previously optimized gemcitabine-oleic acid (GOA) prodrug. Efficient miRNA encapsulation was achieved through hydrogen bonding at an optimized GOA/miRNA molar feed ratio of 250:1, affording spherical nanoparticles with a uniform hydrodynamic size of 147.1 nm and a negative potential of -21.5 mV. The mechanism of this LHPP-ferroptosis crosstalk is disclosed to be an inhibited phosphorylation of the PI3K/Akt pathway, leading to a remarkable tumor inhibition rate of 88.2% in nude mice bearing Bel-7402 tumor xenografts via a combination of LHPP-triggered nonferrous ferroptosis and GOA-induced chemotherapy. The biocompatibility of GOA/miR-363-5pi is strongly supported by their non-hematologic toxicity and insignificant organ damage. In addition, the tumor immunogenic activation potential of GOA/miR-363-5pi was finally explored. Overall, this study is the first work that elucidates the precise mechanism of LHPP for treating HCC via ferroptosis induction and achieves the transformation of chemotherapy and gene therapy into ferroptosis activation with tumor cell immunogenicity, which lays a new therapeutic foundation for the clinical treatment of HCC.Graphical

Generation of dengue 3 envelope domain III using tobacco mosaic virus-based vector system and its immunological response mouse model by generating anti-dengue virus antibodies.

Producing recombinant proteins in plants has become a valuable alternative to traditional microbial or mammalian systems due to its cost-effectiveness, scalability, and ability to perform post-translational modifications. This study investigates the use of the Tobacco Mosaic Virus (TMV)-based vector system for producing the Dengue virus serotype 3 (DENV-3) envelope domain III (EDIII) protein in plants.. A fragment of the gene that encodes domain III of the dengue 3 envelope protein (D3EIII, comprising 300-420 amino acids), was effectively expressed within Nicotiana tabacum plants utilizing a transient expression system based on tobacco mosaic virus (TMV). The N-terminal 5' UTR region upstream of D3EIII notably enhanced protein yield in infected tissues. The produced recombinant protein exhibited reactivity with both (anti) D3EIII polyclonal antibodies and antibodies of anti-His tag. Upon injection of EDIII in mice, it stimulated the generation of antibodies against the dengue-specific virus. The induced antibodies demonstrated neutralizing activity against dengue virus type 3. These findings indicate that the TMV expression system is effective for producing dengue virus antigens in plants, resulting in antigens with appropriate properties and strong immunogenic potential.

Impact of Manufacturing Process and Compounding on Properties and Quality of Follow-On GLP-1 Polypeptide Drugs.

The prevalence of follow-on and compounded products of glucagon-like peptide-1 analogs is increasing. We assessed glucagon-like peptide-1 analogs semaglutide and liraglutide for purity, potential immunogenicity, and expected stability, by comparing a representative selection of commercially available follow-on drug substances (DSs) and drug products (DPs) with their corresponding originators. Tests included several chromatography methods coupled with ultraviolet and mass spectrometry detectors, inductively coupled plasma optical emission spectroscopy, inductively coupled plasma mass spectrometry, nuclear magnetic resonance, dissolution analyses, in silico peptide/major histocompatibility complex II-binding prediction, and fibrillation assays. Overall, 16 injectable semaglutide, 8 oral semaglutide, and 2 injectable liraglutide follow-on products were analyzed alongside originator products. Compared with originator, follow-on injectable semaglutide DSs and DPs had new impurities and impurity patterns, including high molecular weight proteins, trace metals, anions, counterions, and residual solvents. Analyses showed that several commercialized follow-on oral semaglutide DPs had a markedly lower quantity of semaglutide than the label claim, while dissolution tests indicated different semaglutide and sodium N-(8-[2-hydroxybenzoyl] amino)caprylate (SNAC) release profiles, which may reduce bioavailability. Neoepitopes were identified in DS and DP semaglutide follow-ons, indicating potential immunogenicity. Fibrillation assays showed increased fibrillation tendency and reduced physical stability in liraglutide follow-on DP samples compared with originator. This study highlights that differences in the manufacturing processes of follow-on semaglutide and liraglutide (vs those used for originators) can result in several changes to the DSs and DPs. The impact of these changes on efficacy and safety outcomes remains unknown and should be investigated by clinical studies.

Tumor Antigen-Tethered Spiked Virus-Like- Poly(Lactic-Co-Glycolic Acid)-Nanoparticle Vaccine Enhances Antitumor Ability Through Th9 Promotion in Mice.

Immunotherapy emerges as a promising frontier in cancer therapy and prevention. This study investigates the capacity of tumor-antigenic nanoparticles, specifically ovalbumin-tethered spiked virus-like poly(lactic-co-glycolic acid) nanoparticles (OVA-sVLNP), to effectively elicit humoral and cellular immune responses against tumors. OVA-sVLNP were synthesized through thiol-maleimide crosslinking using a single emulsion method. Comprehensive characterization was performed through Nuclear Magnetic Resonance (NMR), dynamic light scattering, Cryo-electron microscopy (Cryo-EM), confocal microscopy, and flow cytometry. Immunogenicity was evaluated using an enzyme-linked immunosorbent assay (ELISA) for quantifying immunoglobulin levels (IgG, IgG1, IgG2a) and cytokines in mouse sera. Flow cytometry profiled cellular immune responses in mouse spleens, and organ biosafety was assessed using immunohistochemistry and hematoxylin and eosin (H&E) staining. OVA-sVLNP had a mean particle size of 193.8 ± 11.9 nm, polydispersity index of 0.307 ± 0.04, and zeta potential of -39.6 ± 10.16 mV, remaining stable for one month at 4°C. In vitro studies revealed significant upregulation of CD80/CD86 in dendritic cells, indicating robust activation. In vivo, the optimal concentration (V25) induced potent IgG, IgG1, and IgG2a antibodies, significant populations of CD3+CD4+, CD3+CD8+, and a rare subset of CD3+CD4+CD8+ memory T cells. Notably, Th9 induction resulted in the secretion of IL-9, IL-10, and other cytokines, which are crucial for orchestrating cytotoxic T cell activity and antitumor effects. Overall, higher doses did not improve outcomes, highlighting the significance of optimal dosing. This study demonstrated potent immunogenicity of OVA-sVLNP, characterized by the induction of specific IgG antibodies and the stimulation of cellular immune responses, particularly tumor-killing Th9 cells. The simplicity and cost-effectiveness of the manufacturing process augment the potential of OVA-sVLNP as a viable candidate for antitumor vaccines, opening new avenues for cancer prevention and cell-based therapeutic strategies.

Sprayable anti-adhesive hydrogel for peritoneal macrophage scavenging in post-surgical applications

Post-surgical adhesions frequently occur after intra-abdominal surgery, leading to severe complications. Despite the development of various types of adhesion barriers to address post-surgical adhesions, several limitations persist, including off-target localization, handling difficulties, and potential immunogenicity. Here, we report a spray-type adhesion barrier for broad, fast application, forming two sequential networks. The first network is formed by a polyelectrolyte complex of sulfated hyaluronic acid and chitosan, while the second network is established through pluronic® F127 thermogelation. This sprayable barrier served as both a physical protector for the damaged peritoneum and an immunomodulator for peritoneal macrophages, as evidenced its effectiveness in a rat ischemic button model. Taken together, this efficient adhesion barrier presents a promising solution for post-surgical adhesions.