Natural killer (NK) cells are classically viewed as lymphocytes that provide innate surveillance against virally-infected cells and tumor cells through release of cytolytic mediators and IFN-γ. In humans, blood CD56dim NK cells specialize in lysis of cell targets1. In lymph nodes, CD56bright NK cells secrete IFN-γ cooperating with dendritic cells (DC) and T cells in the generation of adaptive responses1, 2. Here we report the characterization of a human NK cell subset located in mucosa-associated lymphoid tissues (MALT), such as tonsils and Payer’s patches, which is hard-wired to secrete interleukin (IL)-22, IL-26, and leukaemia inhibitory factor (LIF). These NK cells, which we refer to as NK-22 cells, are triggered by acute exposure to IL-23. In vitro, NK-22-secreted cytokines stimulate epithelial cells to secrete IL-10, proliferate and express a variety of mitogenic and anti-apoptotic molecules. NK-22 cells are also found in mouse MALT and appear in the small intestine lamina propria during bacterial infection suggesting that NK-22 cells provide an innate source of IL-22 that may help constrain inflammation and protect mucosal sites.
We have generated a panel of mAbs that identify three presumably novel human dendritic cell Ags: BDCA-2, BDCA-3, and BDCA-4. In blood, BDCA-2 and BDCA-4 are expressed on CD11c− CD123bright plasmacytoid dendritic cells, whereas BDCA-3 is expressed on small population of CD11c+ CD123− dendritic cells. All three Ags are not detectable on a third blood dendritic cell population, which is CD1c+ CD11cbright CD123dim, or on any other cells in blood. BDCA-4 is also expressed on monocyte-derived and CD34+ cell-derived dendritic cells. Expression of all three Ags dramatically changes once blood dendritic cells undergo in vitro maturation. BDCA-2 is completely down-regulated on plasmacytoid CD11c− CD123bright dendritic cells, expression of BDCA-3 is up-regulated on both plasmacytoid CD11c− CD123bright dendritic cells and CD1c+ CD11cbright CD123dim dendritic cells, and expression of BDCA-4 is up-regulated on CD1c+ CD11cbright CD123dim dendritic cells. BDCA-2 is rapidly internalized at 37°C after mAb labeling. The three presumably novel Ags serve as specific markers for the respective subpopulations of blood dendritic cells in fresh blood and will be of great value for their further analysis and to evaluate their therapeutic potential.
Mucosal innate lymphoid cell (ILC) subsets promote immune responses to pathogens by producing distinct signature cytokines in response to changes in the cytokine microenvironment. We previously identified human ILC3 distinguished by interleukin-22 (IL-22) secretion. Here we characterized a human ILC1 subset that produced Interferon-γ in response to IL-12 and IL-15, had a unique integrin profile, intraepithelial location, hallmarks of TGF-β imprinting and a memory-activated phenotype. Because tissue-resident memory CD8+ T cells share this profile, intraepithelial ILC1 may be their innate counterparts. In mice, intraepithelial ILC1 were distinguished by CD160 expression and required Nfil3-and Tbx21-encoded transcription factors for development, but not IL-15 receptor-α, indicating that intraepithelial ILC1 are distinct from conventional NK cells. Intraepithelial ILC1 were amplified in Crohn’s disease patients and contributed to pathology in the anti-CD40-induced colitis model in mice. Thus, intraepithelial ILC1 may initiate interferon-γ responses against pathogens, but contribute to pathology when dysregulated.
The diversity of innate lymphoid cells (ILCs) is rapidly expanding. Three ILC classes have emerged, ILC1, ILC2, and ILC3, with ILC1 and ILC3 including several subsets. The classification of some subsets is unclear and it remains controversial whether NK cells and ILC1 are distinct cell types. To address these issues, we analyzed ILCs and NK cells gene expression within mouse small intestine, spleen, and liver, as part of the Immunological Genome Project. Results identify unique gene-expression patterns for some ILCs and overlapping patterns between ILC1 and NK cells, whereas few ILC subsets remain indistinguishable. A transcriptional program shared by small intestine ILCs and a core ILC signature is identified. Transcripts that suggest novel ILC functions and developmental paths are revealed and discussed.
In this study we demonstrate a new form of immunoregulation: engagement on CD4+ T cells of the complement regulator CD46 promoted the effector potential of T helper type 1 cells (TH1 cells), but as interleukin 2 (IL-2) accumulated, it switched cells toward a regulatory phenotype, attenuating IL-2 production via the transcriptional regulator ICER/CREM and upregulating IL-10 after interaction of the CD46 tail with the serine-threonine kinase SPAK. Activated CD4+ T cells produced CD46 ligands, and blocking CD46 inhibited IL-10 production. Furthermore, CD4+ T cells in rheumatoid arthritis failed to switch, consequently producing excessive interferon-γ (IFN-γ). Finally, γδ T cells, which rarely produce IL-10, expressed an alternative CD46 isoform and were unable to switch. Nonetheless, coengagement of T cell antigen receptor (TCR) γδ and CD46 suppressed effector cytokine production, establishing that CD46 uses distinct mechanisms to regulate different T cell subsets during an immune response.
The poliovirus receptor (PVR) belongs to a large family of Ig molecules called nectins and nectin-like proteins, which mediate cell-cell adhesion, cell migration, and serve as entry receptors for viruses. It has been recently shown that human NK cells recognize PVR through the receptor DNAM-1, which triggers NK cell stimulation in association with β2 integrin. In this study, we show that NK cells recognize PVR through an additional receptor, CD96, or T cell-activated increased late expression (Tactile). CD96 promotes NK cell adhesion to target cells expressing PVR, stimulates cytotoxicity of activated NK cells, and mediates acquisition of PVR from target cells. Thus, NK cells have evolved a dual receptor system that recognizes nectins and nectin-like molecules on target cells and mediates NK cell adhesion and triggering of effector functions. As PVR is highly expressed in certain tumors, this receptor system may be critical for NK cell recognition of tumors.
Summary The signals guiding differentiation of innate lymphoid cells (ILCs) within tissues are not well understood. Salivary gland (SG) ILCs as well as liver and intestinal intraepithelial ILC1 have markers that denote tissue residency and transforming growth factor–β (TGF-β) imprinting. We deleted Tgfbr2 in cells expressing the ILC and NK marker NKp46 and found that SG ILCs were reduced in number. They lost distinct tissue markers, such as CD49a, and the effector molecules TRAIL and CD73. Expression of the transcription factor Eomes, which promotes NK cell differentiation, was elevated. Conversely, Eomes deletion in NKp46+ cells enhanced TGF-β-imprinting of SG ILCs. Thus, TGF-β induces SG ILC differentiation by suppressing Eomes. TGF-β acted through a JNK-dependent, Smad4-independent pathway. Transcriptome analysis demonstrated that SG ILCs had characteristic of both NK cells and ILC1. Finally, TGF-β imprinting of SG ILCs was synchronized with SG development, highlighting the impact of tissue microenvironment on ILC development
The complement system plays an essential protective role in the initial defense against many microorganisms. Flavivirus NS1 is a secreted nonstructural glycoprotein that accumulates in blood, is displayed on the surface of infected cells, and has been hypothesized to have immune evasion functions. Herein, we demonstrate that dengue virus (DENV), West Nile virus (WNV), and yellow fever virus (YFV) NS1 attenuate classical and lectin pathway activation by directly interacting with C4. Binding of NS1 to C4 reduced C4b deposition and C3 convertase (C4b2a) activity. Although NS1 bound C4b, it lacked intrinsic cofactor activity to degrade C4b, and did not block C3 convertase formation or accelerate decay of the C3 and C5 convertases. Instead, NS1 enhanced C4 cleavage by recruiting and activating the complement-specific protease C1s. By binding C1s and C4 in a complex, NS1 promotes efficient degradation of C4 to C4b. Through this mechanism, NS1 protects DENV from complement-dependent neutralization in solution. These studies define a novel immune evasion mechanism for restricting complement control of microbial infection.
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