Activated macrophages infected with Legionella inhibit T cells by means of MyD88-dependent production of prostaglandins.

To understand how macrophages (Mphi) activated with IFN-gamma modulate the adaptive immune response to intracellular pathogens, the interaction of IFN-gamma-treated bone marrow-derived murine Mphi (BMphi) with Legionella pneumophila was investigated. Although Legionella was able to evade phagosome lysosome fusion initially, and was capable of de novo protein synthesis within IFN-gamma-treated BMphi, intracellular growth of Legionella was restricted. It was determined that activated BMphi infected with Legionella suppressed IFN-gamma production by Ag-specific CD4 and CD8 T cells. A factor sufficient for suppression of T cell responses was present in culture supernatants isolated from activated BMphi following Legionella infection. Signaling pathways requiring MyD88 and TLR2 were important for production of a factor produced by IFN-gamma-treated BMphi that interfered with effector T cell functions. Cyclooxygenase-2-dependent production of PGs by IFN-gamma-treated BMphi infected with Legionella was required for inhibition of effector T cell responses. From these data we conclude that activated Mphi can down-modulate Ag-specific T cell responses after they encounter bacterial pathogens through production of PGs, which may be important in preventing unnecessary immune-mediated damage to host tissues.

Legionella reveal dendritic cell functions that facilitate selection of antigens for MHC class II presentation.

To understand how adaptive immune responses are generated against bacteria that avoid being delivered to lysosomes, interactions between professional antigen-presenting cells (APCs) and the intracellular pathogen Legionella pneumophila were examined. In contrast to murine bone marrow-derived macrophages (BMMs), we show that dendritic cells (DCs) restrict the growth of intracellular Legionella. Similar to what has been reported in BMMs, phagosomes containing Legionella matured into endoplasmic reticulum (ER)-derived organelles after DC internalization. Biogenesis of an ER-derived vacuole did not effectively sequester Legionella antigens from presentation on MHC class II molecules (MHC II). It was determined that proteins synthesized after Legionella had established residence in an ER-derived vacuole were presented by infected APCs. These data indicate that the ability of DCs to restrict intracellular growth of Legionella could be an important property that facilitates priming of protective T cell-mediated immune responses to vacuolar pathogens.

Immunity to vacuolar pathogens: what can we learn from Legionella?

Intracellular pathogens can manipulate host cellular pathways to create specialized organelles. These pathogen-modified vacuoles permit the survival and replication of bacterial and protozoan microorganisms inside of the host cell. By establishing an atypical organelle, intracellular pathogens present unique challenges to the host immune system. To understand pathogenesis, it is important to not only investigate how these organisms create unique subcellular compartments, but to also determine how mammalian immune systems have evolved to detect and respond to pathogens sequestered in specialized vacuoles. Recent studies have identified genes in the respiratory pathogen Legionella pneumophila that are essential for establishing a unique endoplasmic reticulum-derived organelle inside of mammalian macrophages, making this pathogen an attractive model system for investigations on host immune responses that are specific for bacteria that establish vacuoles disconnected from the endocytic pathway. This review will focus on the host immune response to Legionella and highlight areas of Legionella research that should help elucidate host strategies to combat infections by intracellular pathogens.