Use of cDNA microarrays to analyze responses to pneumococcal virulence factors.

BACKGROUND & OBJECTIVES: The complex interactions that occur between host and pathogen during bacteraemia caused by Streptococcus pneumoniae are not well understood. Upon entering the blood stream the pneumococcus intiates responses through contact with naïve monocytes and macrophages resulting in an inflammatory response. To elucidate the role of microbial virulence factors in the host response to the pneumococcus, cDNA microarray analysis was used to identify genes in THP-1 cells, a human monocytic cell line, that are responsive to pneumococcal virulence factors. METHODS: S. pneumoniae D39, a serotype 2 pneumococcus, and PLN an isogenic mutant of D39 that does not express pneumolysin were used. Gene expression profiles elicited by both wild-type and mutant were compared with that of THP-1 cells not exposed to pneumococci. Results obtained from microarray analysis were confirmed and further characterized using reverse transcriptase (RT)-PCR, real-time RT-PCR, and ELISA. RESULTS: Genes in THP-1 cells that were responsive to the pneumococcus independent of the presence of the specific virulence factor, pneumolysin, were identified. THP-1 cell genes that were differentially expressed independent of pneumolysin included the ones involved in cell-to-cell signaling and antipathogen responses. Those that were responsive to pneumolysin included genes encoding adhesion molecules, chemokines, cytokine receptors, and cell cycle and apoptosis proteins. INTERPRETATION & CONCLUSION: The global transcriptional response of naïve monocytes to contact with the pneumococcus was characterized and the utility of cDNA microarray analysis in elucidating the role of specific factors in host-pathogen interactions were demonstrated.

Interaction of human factor H with PspC of Streptococcus pneumoniae.

BACKGROUND & OBJECTIVES: Streptococcus pneumoniae has acquired virulence factors such as the polysaccharide capsule and various surface proteins, which prevent opsonization mediated by the complement system. PspC is one of the multi-functional pneumococcal surface proteins capable of eliciting an antibody response in mice. Our study further explores the role of pneumococcal surface proteins in resistance to complement mediated opsonophagocytosis by providing evidence that PspC binds human Factor H (FH), a regulatory protein of the alternative complement pathway. The present study was carried out to map the binding regions on PspC and FH, and to assess the functional activity of FH upon binding to PspC. METHODS: FH binding to D39 and other pneumococcal strains was observed by flow cytometry. A series of FH truncated and deletion mutants and PspC mutants were used to localize binding regions within these molecules. The functional activity of FH upon binding to PspC was measured by a haemolysis assay. RESULTS: FH binding to D39 and not to TRE108 (PspC-) cells was demonstrated by flow cytometry. Pneumococcal isolates of 14 different strains varied in their ability to bind FH. The binding region of FH within PspC to the first 225 amino acids of the alpha-helical domain was localized. The corresponding binding site for PspC is located within the SCR 6-10 region of FH. Haemolysis of rabbit red blood cells was inhibited by FH even in the presence of PspC. INTERPRETATION & CONCLUSION: FH binding is specific to PspC on the pneumococcal cell surface. The binding region on PspC mapped to the non-conserved N-terminal region of the alpha-helical domain. The binding site on FH to PspC is different from the active site that functions in degradation of C3b. A haemolysis assay provided evidence that the functional activity of FH was maintained upon binding to PspC. Thus, binding of FH to PspC might be an important mechanism by which S. pneumoniae resist complement activation and opsonophagocytosis.