Dendritic cells treated with lipopolysaccharide up-regulate serine protease inhibitor 6 and remain sensitive to killing by cytotoxic T lymphocytes in vivo.

Ag presentation by dendritic cells (DC) in vivo is essential to the initiation of primary and secondary T cell responses. We have reported that DC presenting Ag in the context of MHC I molecules also become targets of specific CTL and are rapidly killed in mice. However, activated DC up-regulate expression of serine protease inhibitor (SPI)-6, a specific blocker of the cytotoxic granule protein granzyme B, which modulates their susceptibility to CTL-mediated killing in vitro. We wanted to determine whether susceptibility to CTL-mediated killing in vivo is also modulated by DC activation. As was previously reported by others, DC treated with different doses of LPS expressed higher levels of SPI-6 mRNA than did untreated DC. The increased expression of SPI-6 was functionally relevant, as LPS-treated DC became less susceptible to CTL-mediated killing in vitro. However, when these LPS-treated DC were injected in vivo, they remained sensitive to CTL-mediated killing regardless of whether the CTL activity was elicited in host mice via active immunization or was passively transferred via injection of in vitro-activated CTL. LPS-treated DC were also sensitive to killing in lymph node during the reactivation of memory CTL. We conclude that increased SPI-6 expression is not sufficient to confer DC with resistance to direct killing in vivo. However, SPI-6 expression may provide DC with a survival advantage in some conditions, such as those modeled by in vitro cytotoxicity assays.

Suppression of allergic airway disease using mycobacterial lipoglycans.

BACKGROUND: Administration of heat-killed mycobacteria can suppress allergic disease in mice and humans. The active components of mycobacteria mediating these effects remain unresolved. OBJECTIVE: We sought to identify the active components of mycobacteria mediating suppression of allergic disease and to determine structural features important for function. METHODS: Using a murine model of allergic airway disease, we tested the ability of the lipoglycan fractions of the mycobacterial cell wall to suppress airway eosinophilia. Lipoglycans isolated from different strains of mycobacteria and chemical modifications were used to explore structure-function relationships. Markers of allergic disease including bronchoalvealor lavage cytokines, spleen and lymph node T-cell cytokine production, and serum specific immunoglobulin (Ig) E/IgG1 were examined. RESULTS: We identified the mycobacterial cell wall lipoglycans lipoarabinomannan and phosphatidylinositol mannan as components of mycobacteria capable of suppressing airway disease (>70% reduction in airway eosinophilia; P <.03). Structure-function analysis identified the acyl chains and mannose groups of the molecules as having a role in mediating this effect. Mechanistic studies provided no evidence for a T-helper cell (Th) 1-mediated suppression of an ongoing Th2 response. An increased capacity of T cells to secrete interleukin 10 in the spleen and lymph node of treated animals was identified, suggesting a potential T-cell-mediated suppression mechanism. CONCLUSION: We have identified immunomodulatory component(s) of mycobacteria responsible for the protective effects observed in allergic disease; these findings will lead to the generation of synthetic compounds or agonists devoid of the unwanted characteristics of whole mycobacteria for evaluation in a human clinical setting.