Transcriptional profiles of Streptococcus pneumoniae associated with adaptation to the nasopharynx environment

Streptococcus pneumoniae is a major cause of global morbidity and mortality. It behaves as a commensal in the host nasopharynx, but can become pathogenic, invading the lungs, blood, and meninges. As such, identification of pneumococcal virulence and colonisation factors remains a major research objective. We previously described an experimental evolution approach for the identification of pneumococcal genes that make niche-specific contributions to fitness and virulence. Sequential passage of pneumococci through mouse models of nasopharyngeal-carriage and pneumonia was performed, generating bacterial lineages adapted to the nasopharynx and lungs, respectively.

Using RNA-Seq differential gene expression analysis, this study compared the transcriptomic profile of a nasopharynx-evolved pneumococcal lineage that showed evidence of enhanced nasopharyngeal colonisation potential, with a lab-adapted ancestor strain. Here, we describe how the genomic adaptations acquired by this lineage, and which we have demonstrated facilitate survival in the nasopharynx, can influence bacterial gene expression.

One key finding was the identification of five adjacent upregulated genes, representing a putative pneumococcal operon. These poorly characterised genes are predicted to encode a carbohydrate-scavenging pathway. Expression of the operon within the nasopharynx may facilitate sugar acquisition from host glycoproteins. Of note, the nasopharynx evolved pneumococcal lineage carries a single nucleotide insertion mutation immediately adjacent to the -10 element of the operon predicted promotor sequence. This may contribute to increased operon gene expression in the nasopharynx-adapted pneumococcus, thereby enhancing colonisation potential. Confirmatory mechanistic investigations are underway, which will aid the identification of pneumococcal virulence factors involved in the commensal to pathogen switch.