Immunogenicity and protective capacity of a CpG ODN adjuvanted alum adsorbed bivalent meningococcal outer membrane vesicle vaccine

Optimization of methods for isolation and purification of outer membrane vesicles (OMVs) from Neisseria lactamica

Outer membrane vesicles (OMVs) are nanoparticles released by Gram-negative bacteria during growth, mainly under stress conditions. OMV-based vaccines have played an important role in vaccination against Neisseria meningitidis serogroup B (MenB), stimulating research into novel approaches for developing more effective vaccines. OMVs released by the bacterium Neisseria lactamica have emerged as a promising platform for new vaccine development, especially as carriers in subunit vaccines. Despite their importance, some challenges remain in obtaining and purifying OMVs. The most commonly employed methods for OMV isolation and purification are ultracentrifugation (UC) and size exclusion chromatography (SEC). However, these techniques could present limitations for large-scale production and often result in low yields. This study investigated techniques such as tangential flow filtration (TFF), membrane chromatography, and mixed-mode (multimodal) chromatography as potential replacements for UC and SEC. Among the TFF methods evaluated, the sample obtained on the membrane with a 300-kDa cutoff showed a profile more similar to UC but with more than double the total protein recovery. Sartobind® Q membrane chromatography was ineffective for OMV purification, in the conditions evaluated, with a recovery of 8.7%. Conversely, multimodal Capto™ Adhere chromatography recovered 59.0%, while Capto™ Core 400 yielded a recovery of 72.0%, proving to be more effective for purification when analyzed by high-performance liquid chromatography (HPLC). Thus, combining TFF with a 300-kDa membrane followed by Capto™ Core 400 chromatography can be applied as strategy for large-scale applications offering high recovery and purity. KEY POINTS: • Evaluation of TFF, membrane and multimodal chromatography techniques for OMV purification. • Improved Neisseria lactamica OMV yields combining TFF and multimodal chromatography. • A process for OMV purification from a non-pathogenic organism feasible to scale up.

Recombinant ClearColi™-derived outer membrane vesicles as an effective carrier for development of neoepitope-based vaccine candidate against colon carcinoma

BACKGROUND

Colorectal carcinoma (CRC) is the third most common cancer worldwide, with high clonal heterogeneity due to somatic mutations. Poly neoepitope vaccines can inhibit the tumor's escape from the immune system. However, they have rapid clearance and low immunogenicity. Bacteria-derived recombinant outer membrane vesicles (OMVs) have gained increased attention as ideal cancer vaccine candidates due to their unique adjuvant properties and ability to carry antigens. Herein, the benefits of OMV-based and polyneoepitope-based vaccines were combined to obtain a functional individualized cancer vaccine.

METHODS

OMVs and rOMVs displaying CT26 polytopes were isolated from ClearColi™ and recombinant ClearColi™ containing pET-22b (ClyA-CT26 polytope) by the AS (70 %) + UDF method. BALB/c mice were immunized with OMVs (40 µg) and rOMVs (20 and 40 µg) and subcutaneously challenged with CT26 cells. Then, IgG1 and IgG2a antibodies specific for CT26 M90 and CT26 polytope, the stimulated IFN-γ, TNF-α, and IL-10 cytokines and the stimulated CTL responses by measuring granzyme B were evaluated. To investigate whether pooled sera and pooled splenocytes are indicators of individual responses, pooled and individual methods for determining the elicited immunity were compared. Additionally, the ability of OMVs and rOMVs (20 and 40 µg) to prevent tumor growth against the CT26 challenge was investigated.

RESULTS

Immunization with rOMVs displaying CT26 polytopes induced a higher titer of CT26 polytope- and CT26 M90 peptide-specific IgG2a than IgG1 antibodies in a dose-dependent manner, thus directing immunity to Th1. The antibody responses determined by pooled sera can be used as indicators of individual responses. In addition, both OMVs and rOMVs displaying CT26 polytopes could induce tumor-suppressing cytokines (IFN-γ and TNF-α). The ability of rOMVs displaying CT26 polytopes to induce these cytokines was higher than OMVs in a dose-dependent way. The results of the granzyme B assay were also in agreement with the cytokine assay. The survival of mice after the CT26 challenge was 100 % in the OMVs and rOMVs groups, and inhibition of tumor growth was significantly higher by rOMVs (40 µg) compared to OMVs.

CONCLUSION

The bioengineered OMVs displaying CT26 neoepitopes have the potential for the development of personalized tumor vaccines. Our results can provide new insights for developing rOMV-based vaccines displaying polytopes against diseases containing highly variable antigens.

A methamphetamine vaccine using short monoamine and diamine peptide linkers and poly-mannose

Methamphetamine (METH) substance use disorder is a long-standing and ever-growing public health concern. Efforts to develop successful immunotherapies are ongoing with vaccines that generate strong antibody responses are an area of significant research interest. Herein, we describe the development of a METH Hapten conjugate vaccine comprised of either two short-length peptides as linkers and mannan as an immunogenic delivery carrier. Initially, Hapten 1 (with a monoamine linker) and Hapten 2 (with a diamine linker) were synthesised. Each step of the Hapten synthesis were characterized by LC-MS and purified by Flash Chromatography and the identity of the purified Haptens were confirmed by 1H NMR. Haptens were conjugated with mannan (a polymannose), and conjugation efficiency was confirmed by LC-MS, TLC, 1H NMR, and 2,4 DNPH tests. The immunogenic potential of the two conjugated vaccines were assessed in mice with a 3-dose regimen. Concentrations of anti-METH antibodies were measured by enzyme-linked immunosorbent assay. All the analytical techniques confirmed the identity of Hapten 1 and 2 during the synthetic phase. Similarly, all the analytical approaches confirmed the conjugation between the Haptens and mannan. Mouse immunogenicity studies confirmed that both vaccine candidates were immunogenic and the vaccine with the monoamine linker plus adjuvants induced the highest antibody response after the second booster.