SUMMARY CD8+ T cells play a critical role limiting peripheral virus replication, yet how they locate virus-infected cells within tissues is unknown. Here, we have examined the environmental signals that CD8+ T cells use to localize and eliminate virus-infected skin cells. Epicutaneous vaccinia virus (VV) infection, mimicking human smallpox vaccination, greatly increased expression of the CXCR3 chemokine receptor ligands CXCL9 and -10 in VV-infected skin. Despite normal T cell numbers in the skin, Cxcr3−/− mice exhibited dramatically impaired CD8+ T cell-dependent virus clearance. Intravital microscopy revealed that Cxcr3−/− T cells were markedly deficient in locating, engaging, and killing virus-infected cells. Further, transfer of wild-type CD8+ T cells restored viral clearance in Cxcr3−/−animals. These findings demonstrate a function for CXCR3 in enhancing the ability of tissue-localized CD8+ T cells to locate virus-infected cells and thereby exert anti-viral effector functions.
SUMMARY Despite extensive ex vivo investigation, the spatiotemporal organization of immune cells interacting with virus-infected cells in tissues remains uncertain. To address this, we used intravital multiphoton microscopy to visualize immune cell interactions with virus-infected cells following epicutaneous vaccinia virus (VV) infection of mice. VV infects keratinocytes in epidermal foci, and numerous migratory dermal inflammatory monocytes outlying the foci. We observed Ly6G+ innate immune cells infiltrating and controlling foci, while CD8+ T cells remained on the periphery killing infected monocytes. Most antigen-specific CD8+ T cells in the skin did not interact with virus-infected cells. Blocking the generation of reactive nitrogen species relocated CD8+ T cells into foci, modestly reducing viral titers. Depletion of Ly6G+ and CD8+ cells dramatically increased viral titers, consistent with their synergistic but spatially segregated viral clearance activities. These findings highlight previously unappreciated differences in the anatomic specialization of antiviral immune cell subsets.
Alveolar macrophages (AMs) normally respond to lipopolysaccharide (LPS) by activating Toll-like receptor (TLR)-4 signaling, a mechanism critical to lung host defense against gram-negative bacteria such as Pseudomonas aeruginosa. Because granulocyte macrophage colony-stimulating factor (GM-CSF)-deficient (GM(-/-)) mice are hyporesponsive to LPS, we evaluated the role of GM-CSF in TLR-4 signaling in AMs. Pulmonary TNF-alpha levels and neutrophil recruitment 4 h after intratracheal administration of Pseudomonas LPS were reduced in GM(-/-) compared with wild-type (GM(+/+)) mice. Secretion of TNF-alpha by AMs exposed to LPS ex vivo was also reduced in GM(-/-) mice and restored in mice expressing GM-CSF specifically in the lungs (SPC-GM(+/+)/GM(-/-) mice). LPS-dependent NF-kappaB promoter activity, TNF-alpha secretion, and neutrophil chemokine release were reduced in AM cell lines derived from GM(-/-) mice (mAM) compared with GM(+/+) (MH-S). Retroviral expression of PU.1 in mAM cells, which normally lack PU.1, rescued all of these AM defects. To determine whether GM-CSF, via PU.1, regulated expression of TLR-4 pathway components, mRNA and protein levels for key components were evaluated in MH-S cells (GM(+/+), PU.1(Positive)), mAM cells (GM(-/-), PU.1(Negative)), and mAMPU.1+ cells (GM(-/-), PU.1(Positive)). Cluster of differentiation antigen-14, radioprotective 105, IL-1 receptor-associated kinase (IRAK)-M mRNA, and protein were dependent upon GM-CSF and restored by expression of PU.1. In contrast, expression of other TLR-4 pathway components (myeloid differentiation-2, TLR-4, IRAK-1, IRAK-2, Toll/IL-1 receptor domain containing adapter protein/MyD88 adaptor-like, myeloid differentiation primary-response protein 88, IRAK-4, TNF receptor-associated factor-6, NF-kappaB, inhibitor of NF-kappaB kinase) were not GM-CSF or PU.1-dependent. These results show that GM-CSF, via PU.1, enables AM responses to P. aeruginosa LPS by regulating expression of a specific subset of components of the TLR-4 signaling pathway.
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