Characterization of Antigenic Properties of Two Immunogenic Proteins of Streptococcus pneumoniae 

Abstract: The bacterium Streptococcus pneumoniae (pneumococcus), is considered to be a leading cause of morbidity and mortality globally, particularly in infants and the elderly. It is one of the most frequent causes of respiratory tract infections, which sporadically have the potential to develop into serious invasive symptoms including sepsis and meningitis. The development of effective vaccination against this pathogen is essential for reducing the morbidity and mortality it causes since the currently available vaccines can protect against only a limited number of the 100 pneumococci serotypes which target the polysaccharidic capsule of the bacterium. The potential use of conserved protein antigens could provide a defense to a wider range of serotypes and clonal types. The immunogenic properties of the proteins MalX and PrsA as well as their role in vital biological functions of S. pneumoniae have made them stand out as potential targets. MalX is a crucial membrane protein involved in the metabolism of maltose, whereas PrsA is a chaperone-like protein that is connected to the cell envelope. To understand these proteins' potential as vaccine candidates, it is essential to understand their immunogenic characteristics and physiological roles. In this project, we tried to characterize the two antigens to determine the functional significance of different regions and domains in antigen recognition and their expression dynamics in bacterial host. A better understanding of the antigenic properties of the PrsA and MalX proteins will drive the construction of improved versions of antigens for vaccine prototypes. Some approaches were used to clarify the structural characteristics and antigenic determinants associated with these proteins including, protein expression, purification, and structural characterization. Additionally, their expression in E. coli was examined using immunological assays including ELISA and Western blot. The identification of antigenic regions of these proteins also provides insight into how to develop epitope-based vaccinations that specifically target S. pneumoniae. This project discusses the possibility of using membrane vesicles (MVs) as a platform for vaccination. Membrane vesicles made from bacterial cells have innate immunogenic qualities that expose the immune system to a wide variety of antigens. Incorporating MalX and PrsA into such vesicles can improve the vaccine candidate's overall immunogenicity and effectiveness and trigger a stronger immune response against S. pneumoniae.