Glycosaminoglycan binding facilitates entry of a bacterial pathogen into central nervous systems.

Certain microbes invade brain microvascular endothelial cells (BMECs) to breach the blood-brain barrier (BBB) and establish central nervous system (CNS) infection. Here we use the leading meningitis pathogen group B Streptococcus (GBS) together with insect and mammalian infection models to probe a potential role of glycosaminoglycan (GAG) interactions in the pathogenesis of CNS entry. Site-directed mutagenesis of a GAG-binding domain of the surface GBS alpha C protein impeded GBS penetration of the Drosophila BBB in vivo and diminished GBS adherence to and invasion of human BMECs in vitro. Conversely, genetic impairment of GAG expression in flies or mice reduced GBS dissemination into the brain. These complementary approaches identify a role for bacterial-GAG interactions in the pathogenesis of CNS infection. Our results also highlight how the simpler yet genetically conserved Drosophila GAG pathways can provide a model organism to screen candidate molecules that can interrupt pathogen-GAG interactions for future therapeutic applications.

Host and pathogen glycosaminoglycan-binding proteins modulate antimicrobial peptide responses in Drosophila melanogaster.

During group B streptococcal infection, the alpha C protein (ACP) on the bacterial surface binds to host cell surface heparan sulfate proteoglycans (HSPGs) and facilitates entry of bacteria into human epithelial cells. Previous studies in a Drosophila melanogaster model showed that binding of ACP to the sulfated polysaccharide chains (glycosaminoglycans) of HSPGs promotes host death and is associated with higher bacterial burdens. We hypothesized that ACP-glycosaminoglycan binding might determine infection outcome by altering host responses to infection, such as expression of antimicrobial peptides. As glycosaminoglycans/HSPGs also interact with a number of endogenous secreted signaling molecules in Drosophila, we examined the effects of host and pathogen glycosaminoglycan/HSPG-binding structures in host survival of infection and antimicrobial peptide expression. Strikingly, host survival after infection with wild-type streptococci was enhanced among flies overexpressing the endogenous glycosaminoglycan/HSPG-binding morphogen Decapentaplegic-a transforming growth factor ß-like Drosophila homolog of mammalian bone morphogenetic proteins-but not by flies overexpressing a mutant, non-glycosaminoglycan-binding Decapentaplegic, or the other endogenous glycosaminoglycan/HSPG-binding morphogens, Hedgehog and Wingless. While ACP-glycosaminoglycan binding was associated with enhanced transcription of peptidoglycan recognition proteins and antimicrobial peptides, Decapentaplegic overexpression suppressed transcription of these genes during streptococcal infection. Further, the glycosaminoglycan-binding domain of ACP competed with Decapentaplegic for binding to the soluble glycosaminoglycan heparin in an in vitro assay. These data suggest that, in addition to promoting bacterial entry into host cells, ACP competes with Decapentaplegic for binding to glycosaminoglycans/HSPGs during infection and that these bacterial and endogenous glycosaminoglycan-binding structures determine host survival and regulate antimicrobial peptide transcription.

Targeting of protein kinase C-epsilon during Fcgamma receptor-dependent phagocytosis requires the epsilonC1B domain and phospholipase C-gamma1.

Protein kinase C-epsilon (PKC-epsilon) translocates to phagosomes and promotes uptake of IgG-opsonized targets. To identify the regions responsible for this concentration, green fluorescent protein (GFP)-protein kinase C-epsilon mutants were tracked during phagocytosis and in response to exogenous lipids. Deletion of the diacylglycerol (DAG)-binding epsilonC1 and epsilonC1B domains, or the epsilonC1B point mutant epsilonC259G, decreased accumulation at phagosomes and membrane translocation in response to exogenous DAG. Quantitation of GFP revealed that epsilonC259G, epsilonC1, and epsilonC1B accumulation at phagosomes was significantly less than that of intact PKC-epsilon. Also, the DAG antagonist 1-hexadecyl-2-acetyl glycerol (EI-150) blocked PKC-epsilon translocation. Thus, DAG binding to epsilonC1B is necessary for PKC-epsilon translocation. The role of phospholipase D (PLD), phosphatidylinositol-specific phospholipase C (PI-PLC)-gamma1, and PI-PLC-gamma2 in PKC-epsilon accumulation was assessed. Although GFP-PLD2 localized to phagosomes and enhanced phagocytosis, PLD inhibition did not alter target ingestion or PKC-epsilon localization. In contrast, the PI-PLC inhibitor U73122 decreased both phagocytosis and PKC-epsilon accumulation. Although expression of PI-PLC-gamma2 is higher than that of PI-PLC-gamma1, PI-PLC-gamma1 but not PI-PLC-gamma2 consistently concentrated at phagosomes. Macrophages from PI-PLC-gamma2-/- mice were similar to wild-type macrophages in their rate and extent of phagocytosis, their accumulation of PKC-epsilon at the phagosome, and their sensitivity to U73122. This implicates PI-PLC-gamma1 as the enzyme that supports PKC-epsilon localization and phagocytosis. That PI-PLC-gamma1 was transiently tyrosine phosphorylated in nascent phagosomes is consistent with this conclusion. Together, these results support a model in which PI-PLC-gamma1 provides DAG that binds to epsilonC1B, facilitating PKC-epsilon localization to phagosomes for efficient IgG-mediated phagocytosis.