Streptococcus pneumoniae accessory capsular genes modulate fitness, pathogenicity and immune evasion
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Globally, Streptococcus pneumoniae disproportionally affects children in resource-poor settings, older adults and people living with HIV. Frequently found as an asymptomatic colonizer of the nasopharynx, this versatile pathogen is a prominent cause of pneumonia, meningitis, bacteraemia and otitis media. Recently, a serotype 3 capsule variant (GPSC10-ST700) has expanded in Malawi with enhanced vaccine escape potential. Here, using a mutational and complementation approach, we show that loss of accessory capsular genes in GPSC10-ST700 contribute to increased opsonophagocytic resistance in this lineage. Although originally thought to be nonfunctional pseudogenes, we show that these genes modulate fitness and the global phosphoproteome in serotype 3 strains. These findings highlight that vaccine escape may be mediated through variations in the pneumococcal capsular locus that enhance fitness, pathogenicity and immune evasion, without capsule switching.
IMPORTANCE
Pneumococcal polysaccharide-conjugate vaccines (PCV) target the polysaccharide capsule (CPS), which is a dominant virulence factor. However, current PCVs induce suboptimal protection against serotype 3 strains, which produce a thicker capsule that when released from the bacterial surface, interferes with antibody-mediated bacterial killing and protection. We recently described the clonal expansion of a sequence type (ST) 700–GPSC10 serotype 3 lineage in Malawi post-PCV13 introduction. This lineage is characterized by the absence of at least 6 genes in its cps locus and a distinct antimicrobial resistance (AMR) profile compared to other serotype 3 strains. Here we uncovered a functional role for the accessory capsular genes ( acl ) in serotype 3, previously considered to be pseudogenes, which modulate capsule production, shedding, serum tolerance, and bacterial fitness. By linking genotype to phenotype, our work provides new insights into the molecular basis of serotype 3 immune evasion, informing the design of more effective pneumococcal vaccines.
