Accumulation of CD11b+ lung dendritic cells in response to fungal infection results from the CCR2-mediated recruitment and differentiation of Ly-6Chigh monocytes

NK depletion results in increased CCL22 secretion and Treg levels in Lewis lung carcinoma via the accumulation of CCL22-secreting CD11b+CD11c+ cells

Tumor-induced immune suppression involves the accumulation of suppressive infiltrates in the tumor microenvironment such as regulatory T-cells (Tregs). Previous studies demonstrated that NK-dependant increases in CCL22 secretion selectively recruit Tregs toward murine lungs bearing Lewis Lung Carcinoma (LLC). To extend the in vitro studies, the present studies utilized in vivo depletion of NK cells to ascertain the contribution of NK-derived CCL22 toward total CCL22 and subsequent Treg levels in both normal and LLC-bearing lungs. However, NK depletion had the unexpected effect of increasing both CCL22 secretion and Treg levels in the lungs of NK-depleted LLC-bearing mice. This was concurrent with an increase in tumor burden. Flow cytometry and a series of both immunomagnetic and FACS isolations were used to identify the CCL22-producing cellular fractions in LLC-bearing lungs. A novel CD11b(+)CD11c(+) cell population was identified that accumulates in large numbers in NK-depleted LLC-bearing lung tissue. These CD11b(+)CD11c(+) cells secreted large amounts of CCL22 that may overcompensate for the loss of NK-derived CCL22 in the lungs of NK-depleted LLC-bearing mice. Taken together, these data suggest that NK cells play both a positive and negative role in the regulation of CCL22 secretion and, in turn, the recruitment of Tregs toward LLC-bearing lungs.

Dual roles of CD40 on microbial containment and the development of immunopathology in response to persistent fungal infection in the lung

Persistent pulmonary infection with Cryptococcus neoformans in C57BL/6 mice results in chronic inflammation that is characterized by an injurious Th2 immune response. In this study, we performed a comparative analysis of cryptococcal infection in wild-type versus CD40-deficient mice (in a C57BL/6 genetic background) to define two important roles of CD40 in the modulation of fungal clearance as well as Th2-mediated immunopathology. First, CD40 promoted microanatomic containment of the organism within the lung tissue. This protective effect was associated with: i) a late reduction in fungal burden within the lung; ii) a late accumulation of lung leukocytes, including macrophages, CD4+ T cells, and CD8+ T cells; iii) both early and late production of tumor necrosis factor-α and interferon-γ by lung leukocytes; and iv) early IFN-γ production at the site of T cell priming in the regional lymph nodes. In the absence of CD40, systemic cryptococcal dissemination was increased, and mice died of central nervous system infection. Second, CD40 promoted pathological changes in the airways, including intraluminal mucus production and subepithelial collagen deposition, but did not alter eosinophil recruitment or the alternative activation of lung macrophages. Collectively, these results demonstrate that CD40 helps limit progressive cryptococcal growth in the lung and protects against lethal central nervous system dissemination. CD40 also promotes some, but not all, elements of Th2-mediated immunopathology in response to persistent fungal infection in the lung.

Dynamic interplay among monocyte-derived, dermal, and resident lymph node dendritic cells during the generation of vaccine immunity to fungi

Early innate events that enable priming of antifungal CD4 T cells are poorly understood. We engineered an attenuated fungal vaccine with a model epitope, EalphaRFP, to track vaccine immunity to Blastomyces dermatitidis during yeast recognition, antigen presentation, and priming of naive T cells. After subcutaneous injection of the vaccine, monocyte-derived inflammatory dendritic cells (DCs) are the earliest and largest population that associates with yeast, carrying them into the draining lymph nodes. Despite marked association with yeast, these DCs fail to display surface peptide:MHC complexes or prime naive T cells. Instead, the ability to display antigen and prime CD4 T cells resides with lymph node-resident DCs after antigen transfer from immigrant DCs and with skin migratory DCs. Our work reveals the dynamic interplay among distinct DC subsets that prime naive CD4 T cells after yeast are injected in the skin and discloses the cellular elements underlying vaccine-induced immunity to fungi.

Disentangling the complexity of the skin dendritic cell network

Using 'knockin' mice to track and ablate dendritic cells (DCs) expressing notably the langerin (Cd207) gene, it has been possible to identify five DC subsets within the skin and to assess whether functional specialization exists among them. The present review summarizes recent information concerning the phenotype and the function of these five DC subsets before and after their migration to cutaneous draining lymph nodes. Moreover, it integrates this information into a unifying model that emphasizes the similarities that exist among the mouse DC subsets that are found in both lymphoid and nonlymphoid tissues.