Insights into structural vaccinology harnessed for universal coronavirus vaccine development.
Chin Peng LimChiuan Herng LeowHui Ting LimBoon Hui KokCandy ChuahJonas Ivan Nobre OliveiraMalcolm K JonesLeow Chiuan YeePublished in: Clinical and experimental vaccine research (2024)
Structural vaccinology is pivotal in expediting vaccine design through high-throughput screening of immunogenic antigens. Leveraging the structural and functional characteristics of antigens and immune cell receptors, this approach employs protein structural comparison to identify conserved patterns in key pathogenic components. Molecular modeling techniques, including homology modeling and molecular docking, analyze specific three-dimensional (3D) structures and protein interactions and offer valuable insights into the 3D interactions and binding affinity between vaccine candidates and target proteins. In this review, we delve into the utilization of various immunoinformatics and molecular modeling tools to streamline the development of broad-protective vaccines against coronavirus disease 2019 variants. Structural vaccinology significantly enhances our understanding of molecular interactions between hosts and pathogens. By accelerating the pace of developing effective and targeted vaccines, particularly against the rapidly mutating severe acute respiratory syndrome coronavirus 2 and other prevalent infectious diseases, this approach stands at the forefront of advancing immunization strategies. The combination of computational techniques and structural insights not only facilitates the identification of potential vaccine candidates but also contributes to the rational design of vaccines, fostering a more efficient and targeted approach to combatting infectious diseases.
Keyphrases
- infectious diseases
- respiratory syndrome coronavirus
- coronavirus disease
- molecular docking
- sars cov
- dendritic cells
- binding protein
- transcription factor
- gene expression
- molecular dynamics simulations
- small molecule
- protein protein
- copy number
- climate change
- dna methylation
- single molecule
- amino acid
- dna binding
- capillary electrophoresis