Immunogenicity of COVID-eVax Delivered by Electroporation Is Moderately Impacted by Temperature and Molecular Isoforms.
Federico D'AlessioLucia LioneErika SalvatoriFederica BucciAlessia MuziGiuseppe RoscilliMirco CompagnoneEleonora PintoGianfranco BattistuzziAntonella ConfortiLuigi AurisicchioFabio PalomboPublished in: Vaccines (2023)
DNA integrity is a key issue in gene therapy and genetic vaccine approaches based on plasmid DNA. In contrast to messenger RNA that requires a controlled cold chain for efficacy, DNA molecules are considered to be more stable. In this study, we challenged this concept by characterizing the immunological response induced by a plasmid DNA vaccine delivered using electroporation. As a model, we used COVID-eVax, a plasmid DNA-based vaccine that targets the receptor binding domain (RBD) of the SARS-CoV-2 spike protein. Increased nicked DNA was produced by using either an accelerated stability protocol or a lyophilization protocol. Surprisingly, the immune response induced in vivo was only minimally affected by the percentage of open circular DNA. This result suggests that plasmid DNA vaccines, such as COVID-eVax that have recently completed a phase I clinical trial, retain their efficacy upon storage at higher temperatures, and this feature may facilitate their use in low-/middle-income countries.
Keyphrases
- circulating tumor
- sars cov
- cell free
- single molecule
- coronavirus disease
- escherichia coli
- clinical trial
- nucleic acid
- immune response
- randomized controlled trial
- gene therapy
- gene expression
- respiratory syndrome coronavirus
- magnetic resonance imaging
- circulating tumor cells
- physical activity
- deep learning
- mental health
- oxidative stress
- study protocol
- double blind
- dendritic cells
- open label
- copy number
- diabetic rats