Robust T-cell Research Articles

Truncated NS1 Influenza A Virus Induces a Robust Antigen-Specific Tissue-Resident T-Cell Response and Promotes Inducible Bronchus-Associated Lymphoid Tissue Formation in Mice.

Influenza viruses with truncated NS1 proteins show promise as viral vectors and candidates for mucosal universal influenza vaccines. These mutant NS1 viruses, which lack the N-terminal half of the NS1 protein (124 a.a.), are unable to antagonise the innate immune response. This creates a self-adjuvant effect enhancing heterologous protection by inducing a robust CD8+ T-cell response together with immunoregulatory mechanisms. However, the effects of NS1 modifications on T-follicular helper (Tfh) and B-cell responses remain less understood. C57bl/6 mice were immunised intranasally with 10 μL of either an influenza virus containing a truncated NS1 protein (PR8/NS124), a cold-adapted influenza virus with a full-length NS1 (caPR8/NSfull), or a wild-type virus (PR8/NSfull). Immune responses were assessed on days 8 and 28 post-immunisation by flow cytometry, ELISA, and HAI assay. In this study, we demonstrate that intranasal immunisation with PR8/NS124 significantly increases tissue-resident CD4+ and CD8+ T cells in the lungs and activates Tfh cells in regional lymph nodes as early as day 8 post-immunisation. These effects are not observed in mice immunised with caPR8/NSfull or PR8/NSfull. Notably, PR8/NS124 immunisation also leads to the development of inducible bronchus-associated lymphoid tissue (iBALT) in the lungs by day 28, characterised by the presence of antigen-specific Tfh cells and GL7+Fas+ germinal centre B cells. Our findings further underscore the potential of NS1-truncated influenza viruses to drive robust mucosal immune responses and enhance vaccine efficacy.

Impact of Combined Antiretroviral Treatment (cART) on Latent Cytomegalovirus Infection.

Cytomegalovirus infections and reactivations are more frequent in people living with HIV (PLWH) and have been associated with increased risk of HIV progression and immunosenescence. We explored the impact of combination antiretroviral therapy (cART) on latent CMV infection in 225 young adults parenterally infected with HIV during childhood. Anti-CMV IgG antibodies were present in 93.7% of participants, with lower levels correlating with longer cART exposure and better immunologic parameters. Patients with immunological treatment success (CD4 > 350 cells/mL) had significantly lower CMV IgG titers compared to those with suboptimal immune response to cART. In total, 78% of the tested patients had robust CMV-specific T-cell responses, measured by an IFN-γ release assay. A good immune response to treatment was significantly associated with CMV-specific cellular immunity: IFN-γ level was positively correlated with CD4 and CD8-T cell counts. No differences were observed between patients with suppressed/non-suppressed HIV viremia in terms of CMV humoral and cellular immune response. CMV DNA was detected in only 17% of participants, with lower levels among those with cART-induced immune recovery. The successful antiretroviral treatment with subsequent immunologic reconstitution may lead to restoration of CMV-specific immune responses and effective control of latent infection, limiting episodes of CMV reactivation in HIV-positive individuals.

An oral vaccine based on the Ad5 vector with a double-stranded RNA adjuvant protects mice against respiratory syncytial virus.

A safe and effective vaccine is urgently needed to prevent acute respiratory infections caused by respiratory syncytial virus (RSV). Oral administration offers several advantages, including ease of delivery, minimal stress for vaccine recipients, and greater safety than the systemic injection. In this study, we developed an oral vaccine candidate based on the human adenovirus serotype 5 (Ad5) vector, Ad5-PreF-DS2, encoding a prefusion protein of RSV with a dsRNA as an endogenous adjuvant. We evaluated the immunogenicity and protective efficacy of oral immunization against an RSV challenge in mice, comparing it with those of IM and IN immunizations. Subsequently, we performed an in-depth analysis of the B cell immune response to the oral vaccine. Our findings indicate that oral vaccines elicited a robust antibody response, T-cell response, and B-cell response, and provide effective protection against RSV infection in mice. Importantly, dsRNA adjuvants significantly enhanced T-cell immune responses and increased neutralizing antibody levels when administered via oral vaccination (P<0.05). These preclinical data demonstrate the capacity of an oral vaccine to induce protective immunity against RSV and support further development of RSV vaccine.

Optimizing encephalomyocarditis virus VP1 protein assembly on pseudorabies virus envelope via US9 protein anchoring

ABSTRACT Live herpesvirus-vectored vaccines are critical in veterinary medicine, but they can sometimes offer insufficient protection due to suboptimal antigen expression or localization. Encephalomyocarditis virus (EMCV) is a significant zoonotic threat, with VP1 protein as a key immunogen on its capsid. To enhance immunogenicity, we explored the use of recombinant pseudorabies virus (rPRV) as a vaccine vector against EMCV. In silico analysis indicated that fusing VP1 with US9 enhances the formation of a type II transmembrane heterodimer. We constructed six rPRV groups expressing different VP1 variants and found that VP1 fused with US9’s C-terminal (US9-VP1) enhances VP1’s membrane localization and its incorporation into the PRV envelope, unlike wild-type VP1. Immunogold electron microscopy illustrated that rPRV with deleted US8 and US9, supplemented with US8 regulatory sequence (rΔ89-U9VP1), improved VP1 incorporation into the viral envelope. Post-immunization, only rΔ89-U9VP1 provided 100% protection against EMCV in mice and induced high levels of virus-neutralizing antibodies in piglets. Additionally, rPRV expressing VP1 stimulated robust T-cell responses, as demonstrated by flow cytometry and ELISpot assays. This study introduces rPRV as a potential EMCV vaccine, demonstrating that the selection of the US9 C-terminal domain and US8 regulatory sequence significantly enhances the presentation of heterologous antigens, improving vaccine efficacy.

Replicating RNA vaccine confers durable immunity against Crimean Congo hemorrhagic fever virus challenge in mice

Spread by Hyalomma genus ticks, Crimean-Congo hemorrhagic fever virus (CCHFV) causes a severe hemorrhagic disease endemic throughout Southern and Eastern Europe, Asia, and Africa. To date, there are no widely approved vaccines for CCHFV and treatment for disease is largely supportive. Due to this lack of intervention, the WHO lists CCHFV as a high-priority pathogen. Recently, we described a highly efficacious self-replicating RNA vaccine which is protective against CCHFV disease in mice and non-human primates. This vaccine induces high titers of non-neutralizing anti-nucleoprotein (NP) antibodies and a robust T-cell response against the viral glycoprotein. Here, we assess the durability of this vaccine in mice by monitoring the immunogenicity and efficacy of this vaccine up to 1 year post vaccination. We found that while glycoprotein-specific T-cell responses and anti-NP antibody titers waned over time, mice remained protected against lethal CCHFV challenge for at least 1 year post vaccination.

Expanded tumor-associated polymorphonuclear myeloid-derived suppressor cells in Waldenstrom macroglobulinemia display immune suppressive activity

The role of the bone marrow (BM) microenvironment in regulating the antitumor immune response in Waldenstrom macroglobulinemia (WM) remains poorly understood. Here we transcriptionally and phenotypically profiled non-malignant (CD19- CD138-) BM cells from WM patients with a focus on myeloid derived suppressive cells (MDSCs) to provide a deeper understanding of their role in WM. We found that HLA-DRlowCD11b+CD33+ MDSCs were significantly increased in WM patients as compared to normal controls, with an expansion of predominantly polymorphonuclear (PMN)-MDSCs. Single-cell immunogenomic profiling of WM MDSCs identified an immune-suppressive gene signature with upregulated inflammatory pathways associated with interferon and tumor necrosis factor (TNF) signaling. Gene signatures associated with an inflammatory and immune suppressive environment were predominately expressed in PMN-MDSCs. In vitro, WM PMN-MDSCs demonstrated robust T-cell suppression and their viability and expansion was notably enhanced by granulocyte colony stimulating factor (G-CSF) and TNFα. Furthermore, BM malignant B-cells attracted PMN-MDSCs to a greater degree than monocytic MDSCs. Collectively, these data suggest that malignant WM B cells actively recruit PMN-MDSCs which promote an immunosuppressive BM microenvironment through a direct T cell inhibition, while release of G-CSF/TNFα in the microenvironment further promotes PMN-MDSC expansion and in turn immune suppression. Targeting PMN-MDSCs may therefore represent a potential therapeutic strategy in patients with WM.

Testing the Antigenic Potential of Transmembrane Proteins To Develop a Thermostable Tuberculosis MOF-Liposomal Vaccine.

Tuberculosis is one of the deadliest infectious diseases and continues to be a major health risk in many parts of the world. Even today, the century-old Bacillus Calmette-Guerin (BCG) vaccine is the only formulation on the market and is ineffective for several sections of the global population responsible for transmission. In the search for antigens that can mount a robust immune response, we have reported the recombinant expression and purification of two novel membrane proteins, the Cation transporter protein V (CtpV) and the Mycobacterial copper transporter B (MctB) present on the membrane surface of Mycobacterium tuberculosis. CtpV was tested as an antigen against the plasma of tuberculosis patients and was found to have a unique immune response profile compared with more commonly studied tuberculosis (TB) antigens. CtpV and MctB were reconstituted into proteoliposomes─individually and in combination─to stabilize them in a lipid bilayer and create a nanoparticle vaccine platform. In vivo experiments demonstrated that when delivered with an adjuvant, these antigens generated a robust Th1-biased T-cell response in mice, with the combination of both antigens performing the best and generating a response comparable to BCG. Since tuberculosis vaccines often need to be shipped to areas with fluctuating power supply, we encapsulated the proteoliposomes and the adjuvant in ZIF-8 to create a shelf-stable formulation. Complementary in vivo studies were carried out to confirm that the ZIF-8 coating did not interfere with or compromise the immunogenicity of the antigens.

Mycobacterium tuberculosis Antigen Rv1471 Induces Innate Immune Memory and Adaptive Immunity against Infection.

Protein subunit vaccines form a key pipeline for developing novel tuberculosis (TB) vaccines. Mycobacterium tuberculosis (Mtb) contains approximately 4000 individual proteins. However, only approximately 100 have been evaluated as antigens in the clinical and preclinical stages of vaccine development. Trained immunity-targeting vaccines induce innate immune memory against heterologous infections and enhance antigen-specific adaptive immune responses. However, no trained immunity-targeting subunit TB vaccine has been reported yet. This study tested Rv1471, a thioredoxin secreted by Mtb, as a candidate TB vaccine antigen due to its capacity to stimulate mouse bone marrow-derived macrophages (BMDMs). Rv1471 induced functional and phenotypic maturation of BMDMs in vitro, reflected by the increased production of inflammatory cytokines and surface expression of co-stimulatory molecules. Transcription analysis of Rv1471-trained BMDMs indicated that innate immune memory was activated through pathways of Akt-mTOR-HIF-1α and aerobic glycolysis. Rv1471 also enhanced innate immune memory responses and protection against intracellular infections of different mycobacteria. In a murine model of TB, immunization with Rv1471 formulated with liposomal DDA/MPLA adjuvant produced robust antigen-specific multi-functional CD4+ and CD8+ T-cell immune responses and had substantial protective efficacy against Mtb challenge. Analysis of recall immunity showed that the Rv1471 subunit vaccine triggered robust T-cell immunity post Mtb infection. These findings support the development of an innate immune memory-targeting subunit TB vaccine to increase TB vaccine efficacy.

Abstract A030: Beyond the LNP: Self-amplifying RNA with LION nanoformulation technology for development of safe and effective cancer therapeutics

Abstract HDT Bio, a Seattle biotech company, has developed a platform technology based on self-amplifying RNA and a proprietary nanoparticle delivery system. mRNA have been increasingly used in the development of vaccines in both infectious diseases and oncology. Especially LNP- delivered mRNA has been deployed, following the success during the COVID pandemic, However, self-ampliying RNA (repRNA) possesses several features of particular relevance to cancer medicine. HDT has developed a nanoparticle technology named LION[TM] to safely and effectively deliver RNA to patients. In vivo studies showed that repRNA not only is capable of delivering robust cell-mediated immune responses but also doing so with a significanlty improved safety profile compared to administration using LNP-based formulations. These data will be presented in the context of clinical safety data with repRNA/LION. Furthermore, repRNA/LION was siuccessfully used to induce robust T-cell responses against tumor antigens, and will be discussed. Citation Format: Peter Berglund. Beyond the LNP: Self-amplifying RNA with LION nanoformulation technology for development of safe and effective cancer therapeutics [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: RNAs as Drivers, Targets, and Therapeutics in Cancer; 2024 Nov 14-17; Bellevue, Washington. Philadelphia (PA): AACR; Mol Cancer Ther 2024;23(11_Suppl):Abstract nr A030.

Customizable Glycopolymers as Adjuvants for Cancer Immunotherapy: From Branching Degree Optimization to Cell Surface Engineering.

Engineering dendritic cell (DC) maturation is paramount for robust T-cell responses and immunological memory, critical for cancer immunotherapy. This work unveils a novel strategy using precisely controlled branching in synthetic glycopolymers to optimize DC activation. Using the distinct copolymerization kinetics of 2-(methacrylamido) glucopyranose (MAG) and diethylene glycol dimethacrylate (DEGDMA) in a RAFT polymerization, unique glycopolymers with varying branching degrees are created. These strategically produced gradient branched glycopolymers with sugar moieties on the outer chain potently promote DC maturation. Strikingly, low-branched glycopolymers demonstrate superior activity, both in pure form and when engineered on tumor cell surfaces. Quartz crystal microbalance and theoretical simulations elucidate the crucial role of branching in modulating glycopolymer-DC receptor interactions. Low-branched gradient glycopolymers have shown a notable advantage and are promising adjuvants in DC-based cancer immunotherapy.

Evaluating the Impact of Adjunctive Partial Cryoablation on Dual Checkpoint Inhibitor Immunotherapy Response in a Murine Model.

Purpose To evaluate the impact of adjunctive partial cryoablation on checkpoint inhibitor (CPI) immunotherapy response. Materials and Methods One hundred fifty-six mice (equal number of male and female animals) with dual-implanted tumor models were treated with dual CPI or a vehicle and randomized to treatment of a single tumor with partial cryoablation. Tumors were followed for 60 days following cryoablation for response assessment. In additional groups, the tumor microenvironment was characterized via flow cytometry, cytokine analysis, and immunohistochemistry. Statistical comparison was made between the different treatment groups regarding T-cell infiltration and activation characteristics within the noncryoablated tumor and cytokine levels within the partially ablated tumor. Additionally, qualitative assessment of T-cell activation within the cryoablated and noncryoablated tumors at immunofluorescence was carried out. Results At 60 days following treatment, CPI and adjunctive cryoablation-treated MC-38 mice had a significantly increased survival rate (79%) compared with mice treated with CPI alone (61%; P < .001). CT-26 mice also had an increased survival rate (57% vs 35%, respectively; P = .04). Following cryoablation, increases in inflammatory cytokines and chemokines within the treated tumors were observed. Flow cytometry of noncryoablated tumor showed increased CD8 T-cell activation. Immunofluorescence and histologic evaluation following cryoablation further demonstrated a robust CD8 T-cell and myeloid infiltrate. Conclusion Adjunctive cryoablation significantly increased the response to dual CPI in multiple cancer models at both partially ablated and distant (nonablated) tumor sites. Immune analysis suggests cryoablation promotes a vigorous immune response within the partially cryoablated tumor that increases activation of the adaptive immune system within distant tumor sites. Keywords: Cancer, Cryoablation, Checkpoint Inhibitor Immunotherapy, Tumor Response Supplemental material is available for this article. © RSNA, 2024.

Synergy Effects of HPV E6-E7 Encoding mRNA and Nucleic Acid Immunostimulators Improve Therapeutic Potential in TC-1 Graft Tumor.

Cervical cancer is the second most common cancer among women globally and the most prevalent cancer in developing countries, which was caused by human papillomavirus (HPV) infection. Messenger RNA (mRNA) vaccines have opened up new avenues for vaccine development and pandemic preparedness with potent scalability, which may possess the potential antitumor effects of an mRNA-HPV therapeutic vaccine containing nononcogenic E6 and E7 proteins. Here, we reported a lipid nanoparticle (LNP) plus nucleic acid immunostimulators (CPG 1018 and Poly I:C) mRNA vaccine platform. The LNP-CPG 1018 capsulated HPV E6-E7 mRNA significantly promoted the maturation of bone marrow-derived dendritic cells (BMDC) in vitro and were capable of efficiently migrating to lymph nodes (LN) in vivo. In TC-1 tumor-bearing mice, the subcutaneous immunization of LNP-CPG 1018 capsulated HPV E6-E7 mRNA elicited robust tumor-specific T-cell immunity, reshaped the tumor microenvironment, and inhibited tumor growth. In conclusion, the LNP-CPG 1018 system is a promising delivery platform for facilitating the development of HPV E6-E7 mRNA cancer vaccines.

PRR adjuvants restrain high stability peptides presentation on APCs.

Adjuvants can affect APCs function and boost adaptive immune responses post-vaccination. However, whether they modulate the specificity of immune responses, particularly immunodominant epitope responses, and the mechanisms of regulating antigen processing and presentation remain poorly defined. Here, using overlapping synthetic peptides, we screened the dominant epitopes of Th1 responses in mice post-vaccination with different adjuvants and found that the adjuvants altered the antigen-specific CD4+ T-cell immunodominant epitope hierarchy. MHC-II immunopeptidomes demonstrated that the peptide repertoires presented by APCs were significantly altered by the adjuvants. Unexpectedly, no novel peptide presentation was detected after adjuvant treatment, whereas peptides with high binding stability for MHC-II presented in the control group were missing after adjuvant stimulation, particularly in the MPLA- and CpG-stimulated groups. The low-stability peptide present in the adjuvant groups effectively elicited robust T-cell responses and formed immune memory. Collectively, our results suggest that adjuvants (MPLA and CpG) inhibit high-stability peptide presentation instead of revealing cryptic epitopes, which may alter the specificity of CD4+ T-cell-dominant epitope responses. The capacity of adjuvants to modify peptide-MHC (pMHC) stability and antigen-specific T-cell immunodominant epitope responses has fundamental implications for the selection of suitable adjuvants in the vaccine design process and epitope vaccine development.

PRR adjuvants restrain high stability peptides presentation on APCs

Adjuvants can affect APCs function and boost adaptive immune responses post-vaccination. However, whether they modulate the specificity of immune responses, particularly immunodominant epitope responses, and the mechanisms of regulating antigen processing and presentation remain poorly defined. Here, using overlapping synthetic peptides, we screened the dominant epitopes of Th1 responses in mice post-vaccination with different adjuvants and found that the adjuvants altered the antigen-specific CD4+ T-cell immunodominant epitope hierarchy. MHC-II immunopeptidomes demonstrated that the peptide repertoires presented by APCs were significantly altered by the adjuvants. Unexpectedly, no novel peptide presentation was detected after adjuvant treatment, whereas peptides with high binding stability for MHC-II presented in the control group were missing after adjuvant stimulation, particularly in the MPLA- and CpG-stimulated groups. The low-stability peptide present in the adjuvant groups effectively elicited robust T-cell responses and formed immune memory. Collectively, our results suggest that adjuvants (MPLA and CpG) inhibit high-stability peptide presentation instead of revealing cryptic epitopes, which may alter the specificity of CD4+ T-cell-dominant epitope responses. The capacity of adjuvants to modify peptide–MHC (pMHC) stability and antigen-specific T-cell immunodominant epitope responses has fundamental implications for the selection of suitable adjuvants in the vaccine design process and epitope vaccine development.

Vδ2 T-cell engagers bivalent for Vδ2-TCR binding provide anti-tumor immunity and support robust Vγ9Vδ2 T-cell expansion.

Vγ9Vδ2 T-cells are antitumor immune effector cells that can detect metabolic dysregulation in cancer cells through phosphoantigen-induced conformational changes in the butyrophilin (BTN) 2A1/3A1 complex. In order to clinically exploit the anticancer properties of Vγ9Vδ2 T-cells, various approaches have been studied including phosphoantigen stimulation, agonistic BTN3A-specific antibodies, adoptive transfer of expanded Vγ9Vδ2 T-cells, and more recently bispecific antibodies. While Vγ9Vδ2 T-cells constitute a sizeable population, typically making up ~1-10% of the total T cell population, lower numbers have been observed with increasing age and in the context of disease. We evaluated whether bivalent single domain antibodies (VHHs) that link Vδ2-TCR specific VHHs with different affinities could support Vγ9Vδ2 T-cell expansion and could be incorporated in a bispecific engager format when additionally linked to a tumor antigen specific VHH. Bivalent VHHs that link a high and low affinity Vδ2-TCR specific VHH can support Vγ9Vδ2 T-cell expansion. The majority of Vγ9Vδ2 T-cells that expanded following exposure to these bivalent VHHs had an effector or central memory phenotype and expressed relatively low levels of PD-1. Bispecific engagers that incorporated the bivalent Vδ2-TCR specific VHH as well as a tumor antigen specific VHH triggered antitumor effector functions and supported expansion of Vγ9Vδ2 T-cells in vitro and in an in vivo model in NOG-hIL-15 mice. By enhancing the number of Vγ9Vδ2 T-cells available to exert antitumor effector functions, these novel Vδ2-bivalent bispecific T cell engagers may promote the overall efficacy of bispecific Vγ9Vδ2 T-cell engagement, particularly in patients with relatively low levels of Vγ9Vδ2 T-cells.

Computational multi-epitope based design of a multivalent subunit vaccine against co-infecting African swine fever virus and porcine circovirus type 2

African swine fever virus (ASFV) and porcine circovirus type 2 (PCV2) are two prevalent and economically significant viruses causing high rates of pig mortality and large-scale losses to global pork production. Since there is currently no vaccine simultaneously targeting both viruses, this study aimed to computationally design a safe, stable, and effective multi-epitope based multivalent subunit vaccine against co-infecting ASFV and PCV2. Cytotoxic T-lymphocyte (CTL), helper T-lymphocyte (HTL), and linear B-lymphocyte (LBL) epitopes were screened from sequences of the Rep, Cap, and ORF3 PCV2 proteins. PCV2 epitopes predicted to be antigenic, non-allergenic, and non-toxic were linked to previously screened ASFV epitopes and Vibrio vulnificus FlaB flagellin as an adjuvant to create the final vaccine construct, which underwent physicochemical assessment and structure prediction. The vaccine construct was predicted to be stable, soluble, non-cross-reactive, antigenic, and nonallergenic. An immune simulation demonstrated that the vaccine could elicit robust antibody, T-cell, and B-cell responses. The vaccine construct stably docked to TLR5 and formed significant molecular interactions. A 200-ns molecular dynamics simulation showed that the vaccine-TLR5 complex exhibited stability and compactness throughout the run. These results show that the designed vaccine is safe, stable, and effective and warrants experimental validation.

Mpox Recurrence and Tecovirimat Resistance in a Patient With Advanced Human Immunodeficiency Virus Disease.

We present a case of mpox recurrence in a transgender woman with AIDS. Her recurrent lesions required several courses of antiviral therapy over a 5-month period and her monkeypox viral genome was subsequently noted to have tecovirimat resistance mutations. Interestingly, she developed a robust orthopoxvirus-specific T-cell response.

Chimeric adenovirus-based herpes zoster vaccine with the tPA signal peptide elicits a robust T-cell immune response

Herpes zoster (HZ), or shingles, is caused by reactivation of the varicella-zoster virus (VZV), which remains latent in the sensory ganglia until immunity wanes with age. The representative HZ vaccine, Shingrix is efficacious but causes side effects due to vaccine adjuvants. Therefore, the development of highly efficacious vaccines with minimal side effects is required. We developed chimeric adenovirus vector (ChimAd)-based HZ vaccine candidates encoding the VZV glycoprotein E (gE). These candidates include ChimAd-tPAgE, in which the signal peptide is replaced with tissue plasminogen activator (tPA), and ChimAd-WTgE, which retains the original signal peptide. C57BL/6 mice were immunized with VZV-vaccine candidates, and cellular and humoral immune responses were evaluated using interferon-γ ELISPOT and ELISA. The ChimAd-based HZ vaccines induced high levels of gE-specific antibodies and cell-mediated immunity. ChimAd-tPAgE (optimal dose: 1 × 107 IFU) elicited a more robust gE-specific T-cell response than Shingrix and Zostavax, showing potential as HZ prophylactic vaccines.

Evaluating Nanoparticulate Vaccine Formulations for Effective Antigen Presentation and T-Cell Proliferation Using an In Vitro Overlay Assay.

Inducing T lymphocyte (T-cell) activation and proliferation with specificity against a pathogen is crucial in vaccine formulation. Assessing vaccine candidates' ability to induce T-cell proliferation helps optimize formulation for its safety, immunogenicity, and efficacy. Our in-house vaccine candidates use microparticles (MPs) and nanoparticles (NPs) to enhance antigen stability and target delivery to antigen-presenting cells (APCs), providing improved immunogenicity. Typically, vaccine formulations are screened for safety and immunostimulatory effects using in vitro methods, but extensive animal testing is often required to assess immunogenic responses. We identified the need for a rapid, intermediate screening process to select promising candidates before advancing to expensive and time-consuming in vivo evaluations. In this study, an in vitro overlay assay system was demonstrated as an effective high-throughput preclinical testing method to evaluate the immunogenic properties of early-stage vaccine formulations. The overlay assay's effectiveness in testing particulate vaccine candidates for immunogenic responses has been evaluated by optimizing the carboxyfluorescein succinimidyl ester (CFSE) T-cell proliferation assay. DCs were overlaid with T-cells, allowing vaccine-stimulated DCs to present antigens to CFSE-stained T-cells. T-cell proliferation was quantified using flow cytometry on days 0, 1, 2, 4, and 6 upon successful antigen presentation. The assay was tested with nanoparticulate vaccine formulations targeting Neisseria gonorrhoeae (CDC F62, FA19, FA1090), measles, H1N1 flu prototype, canine coronavirus, and Zika, with adjuvants including Alhydrogel® (Alum) and AddaVax™. The assay revealed robust T-cell proliferation in the vaccine treatment groups, with variations between bacterial and viral vaccine candidates. A dose-dependent study indicated immune stimulation varied with antigen dose. These findings highlight the assay's potential to differentiate and quantify effective antigen presentation, providing valuable insights for developing and optimizing vaccine formulations.

Lipo-pam™ adjuvanted herpes zoster vaccine induces potent gE-specific cellular and humoral immune responses

Herpes zoster (HZ), also known as shingles, is caused by the reactivation of latent varicella-zoster virus (VZV). Decreased VZV-specific T-cell immune responses significantly contribute to the development of HZ. Shingrix is a recombinant zoster vaccine that is currently used to prevent HZ. However, Shingrix has high reactogenicity and pain at the injection site due to QS21, one of the adjuvant components. In this study, we developed a new herpes zoster vaccine formulation called CVI-VZV-001, containing gE protein and a novel liposome-based adjuvant Lipo-pam™, which consists of two TLR agonists. We evaluated the immunogenicity of CVI-VZV-001 in mouse and rabbit models. CVI-VZV-001 elicited robust gE-specific T-cell immune responses and gE-specific antibody production. Specifically, CVI-VZV-001 induced polyfunctional CD4+ T cell populations that secrete multiple cytokines. Furthermore, CVI-VZV-001 sustained the gE-specific immune responses for up to six months after immunization. To ensure CVI-VZV-001’s safety for further development, we conducted a good laboratory practice (GLP) toxicity test, which confirmed that CVI-VZV-001 is safe for use. At present, CVI-VZV-001 is undergoing phase I clinical trials. This study suggests that CVI-VZV-001 can be a potent candidate for the HZ vaccine with high immunogenicity and safety.