Quantitation of strain-specific hemagglutinin trimers in mosaic quadrivalent influenza nanoparticle vaccine by ELISA.

An enzyme linked immunosorbent assay (ELISA) method was developed to analyze the assembly of a tetravalent mosaic influenza nanoparticle (NP) vaccine, Flumos-v1, consisting of hemagglutinin trimers (HAT) from H1 (A/Idaho/07/2018), H3 (A/Perth/1008/2019), HBV (Vic-B/Colorado/06/2017) and HBY (Yam-B/Phuket/3073/2013) strains. The sandwich ELISA assay used lectin from Galanthus nivalis as a universal capture reagent for all HAT strains and specific monoclonal antibody (mAb) to detect corresponding hemagglutinin antigen. The mAb binding of HATs incorporated into NPs diverged from those for single HAT solutions, resulting in inaccurate quantitation of assembled HATs. An optimized zwittergent treatment was used to fully dissociate the influenza NP and aligned binding activities in each pair of single HAT and dissociated HAT from NP. The dissociated HATs were then quantified against their corresponding HAT standard solutions for three development lots of FluMos-v1 vaccine and the assembly ratio of all four HATs was calculated. The molar ratio of different HATs incorporated into this quadrivalent NP vaccine was consistent and determined as H3:H1: HBV: HBY âˆ¼ 1.00:0.92:0.96:0.87, which was close the expected 1:1:1:1 ratio and confirmed a proper assembling of multivalent NP.

Characterization of Flu MOSAIC nanoparticle vaccine candidate using high performance size-exclusion chromatography to support vaccine process development.

This report describes an application of analytical high performance size exclusion chromatography with UV and Fluorescent detection (HPSEC-UV/FLR) method that enabled a bridging from research vaccine candidate discovery (His-tagged model) to clinical product development (Non-His-tagged molecules). HPSEC measurement can accurately determine the total trimer-to-pentamer molar ratio by either titration evaluation during the nanoparticle being assembled or dissociation during a well-formed nanoparticle being dis-assembled. Through experimental design with small sample consumptions, HPSEC can provide a quick determination on the nanoparticle assembling efficiency which can therefore guide the buffer optimization for an assembly, from His-tagged model nanoparticle, to non-His-tagged clinical development product. HPSEC has also discovered a difference in assembling efficiencies for various strains of HAx-dn5B with Pentamer-dn5A components, and different efficiencies for monovalent assembly vs. multivalent assembly. The present study demonstrates HPSEC as a pivotal tool to support the Flu Mosaic nanoparticle vaccine development from research to clinical production.

A multispecific antibody confers pan-reactive SARS-CoV-2 neutralization and prevents immune escape

Summary ParagraphDespite effective countermeasures, SARS-CoV-2 persists worldwide due to its ability to diversify and evade human immunity1. This evasion stems from amino-acid substitutions, particularly in the receptor-binding domain of the spike, that confer resistance to vaccines and antibodies 2-16. To constrain viral escape through resistance mutations, we combined antibody variable regions that recognize different receptor binding domain (RBD) sites17,18 into multispecific antibodies. Here, we describe multispecific antibodies, including a trispecific that prevented virus escape >3000-fold more potently than the most effective clinical antibody or mixtures of the parental antibodies. Despite being generated before the evolution of Omicron, this trispecific antibody potently neutralized all previous variants of concern and major Omicron variants, including the most recent BA.4/BA.5 strains at nanomolar concentrations. Negative stain electron microscopy revealed that synergistic neutralization was achieved by engaging different epitopes in specific orientations that facilitated inter-spike binding. An optimized trispecific antibody also protected Syrian hamsters against Omicron variants BA.1, BA.2 and BA.5, each of which uses different amino acid substitutions to mediate escape from therapeutic antibodies. Such multispecific antibodies decrease the likelihood of SARS-CoV-2 escape, simplify treatment, and maximize coverage, providing a strategy for universal antibody therapies that could help eliminate pandemic spread for this and other pathogens.

Quantification of prefusion conformation for HIV vaccine using size-exclusion chromatography.

A closed prefusion conformation or an open (non-prefusion) conformational state of a protein vaccine candidate molecule can determine if it effectively elucidates a desired immunity. A quick and reliable method to monitor conformational state is important during vaccine development. In addition to our existing immunoassays, we have developed a unique physicochemical approach using size-exclusion chromatography to assess binding between antibody and the structurally desired antigen protein. Through the bound monoclonal antibody protein vaccine peak shift in the size-exclusion chromatography profile, this method determines the percent closed (prefusion) conformation present in a sample. Since only the closed prefusion conformation binds to the specific antibody, the population of the closed versus the open conformation of the vaccine molecule can be monitored without the need for a reference calibrator. This new method can be applied broadly to vaccine development, as well as for antibody selection during antibody drug discovery. The mAb CAP256V2LS (250 µg/mL) specific to prefusion conformation was mixed with HIV trimer (250 µg/mL) at 2:1 volume ratio, incubated at 37 °C for 30 mins and injected onto HPLC column. The percent of non-prefusion conformation was calculated based on ratio of peak area of unbound trimer and total area of control trimer sample (without mAb).

Protein and glycan molecular weight determination of highly glycosylated HIV-1 envelope trimers by HPSEC-MALS.

High Performance Size-Exclusion Chromatography coupled with Multi-Angle Light Scattering detection (HPSEC-MALS) is an important tool to provide a reliable molecular weight measurement for a large complex biomolecule. A recent HIV-1 soluble envelope trimer vaccine candidate, BG505 DS-SOSIP.664, is among the most glycosylated proteins to enter a clinical trial to date, and determination of its protein and glycan molecular weight is one of the key attributes in pre-clinical characterization. However, protein and glycans possess disparate dndcvalues making molecular weight measurement inaccurate in conventional SEC-MALS. To overcome these challenges, a simple mathematically guided experiment was explored, and a composite dndcvalue was established by utilizing protein and glycan mass contributions for the HIV-1 envelope trimer. This establishment was further verified by an orthogonal mass spectrometry analysis. This innovative, simple, and quick analytical approach can be applied broadly to measuring the molecular weight of various composite molecular structures, such as complex glycoconjugates.

Quantitation of residual valproic acid in flu vaccine drug substance.

Quantitative measurement of process-related impurities is a critical safety requirement for the production of drug substances of vaccine and therapeutic biologics. A simple and sensitive HPLC method has been developed for separation and quantitation of residual valproic acid (VPA) used in the cell transfection procedure for the manufacturing of an influenza vaccine. The method is comprised of a modified Dole liquid phase extraction followed by a quick pre-column derivatization using 2-bromoacetophenone. Nonanoic acid (NNA) is used as the internal standard (IS) and the quantification is performed by reversed-phase liquid chromatography. This new method can accurately measure as low as 6.8 µg/mL (LOQ) residual VPA in the vaccine drug substance.

Quantification of residual hydrophobic fusion peptide with monomer and dimer forms using reversed-phase liquid chromatography.

A fusion peptide mimicking a part of the sequence of HIV-1 envelope glycoprotein with an additional cysteine at its C-terminus (FP8: AVGIGAVFC) was conjugated to a carrier protein through a linker for development of an HIV-1 vaccine. Since this fusion peptide is very hydrophobic with poor solubility and can self-dimerize via a disulfide bond, co-existence of monomeric and dimeric forms presented a major challenge for residual unconjugated FP8 quantification. A reversed-phase liquid chromatography (RPLC) with UV detection was developed to monitor residual FP8 using an experimental correction factor of 0.85 for UV peak area measurement between FP8 dimer and monomer. Therefore, both forms of unconjugated residual FP8 can be measured based on a single FP8 monomer reference curve. Overall, this study demonstrated that the current purification process can remove free residual FP8 to a low level, <20 µg/mL, which showed negligible impact (<10%) for the conjugated FP8 ratio measurement using another method, amino acid analysis.