Pan-genome study underlining the extent of genomic variation of invasiveStreptococcus pneumoniaein Malawi

Abstract

AbstractStreptococcus pneumoniaeis a common cause of acute bacterial infections in Malawi. Understanding the molecular mechanisms underlying its invasive behavior is crucial for designing new therapeutic strategies. We conducted a pan-genome analysis to identify potential virulence genes inS. pneumoniaeby comparing the gene pool of isolates from carriers’ nasopharyngeal secretions to isolates from the blood and cerebrospinal fluid of patients. Our analysis involved 1,477 pneumococcal isolates from Malawi, comprising 825 samples from carriers (nasopharyngeal swab) and 652 from patients (368 from blood and 284 from cerebrospinal fluid). We identified 56 serotypes in the cohort. While most serotypes exhibited a similar prevalence in both carriage and disease groups, serotypes 1 and 5, the most abundant serotypes in the entire cohort, were significantly more commonly detected in specimens from patients compared to the carriage group. This difference is presumably due to their shorter nasopharyngeal colonization period. Furthermore, these serotypes displayed genetic distinctiveness from other serotypes. A magnificent genetic difference was observed in the absence of genes from the RD8a genomic island in serotypes 1 and 5 compared to significantly prevalent serotypes in the nasopharynx. RD8a genes play pivotal roles in binding to epithelial cells and performing aerobic respiration to synthesize ATP through oxidative phosphorylation. The absence of RD8a from serotypes 1 and 5 may be associated with a shorter duration in the nasopharynx, theoretically due to a reduced capacity to bind to epithelial cells and access free oxygen molecules required for aerobic respiration (essential to maintain the carriage state). Serotypes 1 and 5, significantly harbor operons that encode phosphoenolpyruvate phosphotransferase systems, which might relate to transporting carbohydrates, relying on phosphoenolpyruvate as the energy source instead of ATP. In conclusion, serotypes 1 and 5 as the most prevalent invasive pneumococcal strains in Malawi, displayed considerable genetic divergence from other strains, which may offer insights into their invasiveness and potential avenues for further research.Author summaryDespite introducing the pneumococcal conjugate vaccine in 2011,Streptococcus pneumoniaeremains a major cause of bacterial infection in Malawi. Whilst some pneumococcal strains harmlessly colonize the nasopharynx, others find their way into normally sterile sites, such as lungs, blood, and nervous system, resulting in serious illness. Our study identified specific pneumococcal serotypes as the most invasive in Malawi, characterized by a short colonization period and significant genetic distinctiveness from other strains. This genetic divergence notably included the absence of several genes associated with aerobic respiration and the presence of genes facilitating ATP-independent carbohydrate transport. The presence or absence of these genes may underlie their heightened invasiveness and shorter colonization period. This hypothesis positions these genes as potential candidates for future therapeutic research. We propose that the specific gene gain and/or loss in invasive versus other serotypes may be linked to the development of invasive pneumococcal diseases.Impact StatementOur research applied pan-genomics principles to comprehensively assess diversity within the pneumococcus genome, with the primary objective of identifying pneumococcal virulence genes for advancing vaccine design and drug development. Within this study, we identified Serotypes 1 and 5 as the predominant and highly invasive pneumococcal strains in Malawi, characterized by a short nasopharyngeal colonization period, suggesting their potential for rapid infection of sterile sites within the human body such as blood and the central nervous system. These serotypes exhibited significant genetic divergence from other serotypes in Malawi, notably lacking key genes within the RD8a operon while harboring transporters functioning independently of ATP. It’s important to note that these findings are based on computational analysis, and further validation through laboratory experiments is essential to confirm their biological significance and potential clinical applications. The implications of our research offer potential avenues for more effective pneumococcal disease prevention and treatment, not only in Malawi but also in regions facing similar challenges.