Presentation of peptide:MHCII by RORγ-expressing group 3 innate lymphoid cells (ILC3s), which are enriched within gut tissue, is required for control of CD4 T-cell responses to commensal bacteria. It is not known whether ILC populations migrate from their mucosal and peripheral sites to local draining secondary lymphoid tissues. Here we demonstrate that ILC3s reside within the interfollicular areas of mucosal draining lymph nodes, forming a distinct microenvironment not observed in peripheral lymph nodes. By photoconverting intestinal cells in Kaede mice we reveal constitutive trafficking of ILCs from the intestine to the draining mesenteric lymph nodes, which specifically for the LTi-like ILC3s was CCR7-dependent. Thus, ILC populations traffic to draining lymph nodes using different mechanisms.
RAR-related orphan receptor γt (ROR-γt) directs differentiation of pro-inflammatory T helper 17 (TH17) cells and is a potential therapeutic target in chronic autoimmune and inflammatory diseases1–3. However, ROR-γt-dependent group 3 innate lymphoid cells (ILC3s) provide essential immunity and tissue protection in the intestine4–11, suggesting that targeting ROR-γt could also result in impaired host defense to infection or enhanced tissue damage. Here, we demonstrate that transient chemical inhibition of ROR-γt in mice selectively reduces cytokine production from TH17 cells but not ILC3s in the context of intestinal infection with Citrobacter rodentium, resulting in preserved innate immunity. Transient genetic deletion of ROR-γt in mature ILC3s also did not impair cytokine responses in the steady state or during infection. Finally, pharmacologic inhibition of ROR-γt provided therapeutic benefit in mouse models of intestinal inflammation, and reduced the frequencies of TH17 cells but not ILC3s isolated from primary intestinal samples of individuals with inflammatory bowel disease (IBD). Collectively, these results reveal differential requirements for ROR-γt in the maintenance of TH17 cell versus ILC3 responses, and suggest that transient inhibition of ROR-γt is a safe and effective therapeutic approach during intestinal inflammation.
The OX40-OX40L pathway provides crucial co-stimulatory signals for CD4 T cell responses, however the precise cellular interactions critical for OX40L provision in vivo and when these occur, remains unclear. Here, we demonstrate that provision of OX40L by dendritic cells (DCs), but not T cells, B cells nor group 3 innate lymphoid cells (ILC3s), is critical specifically for the effector Th1 response to an acute systemic infection with Listeria monocytogenes (Lm). OX40L expression by DCs is regulated by cross-talk with NK cells, with IFNγ signalling to the DC to enhance OX40L in a mechanism conserved in both mouse and human DCs. Strikingly, DC expression of OX40L is redundant in a chronic intestinal Th1 response and expression by ILC3s is necessary. Collectively these data reveal tissue specific compartmentalisation of the cellular provision of OX40L and define a mechanism controlling DC expression of OX40L in vivo.
Previous work by Tomura et al. reporting the generation and use of Kaede transgenic mice was inadvertently omitted from the reference list of this article and should have been cited at instances where these mice are referred to. For example, in the Results section, Tomura et al. should have been cited as follows: 'Since ILC3s are concentrated within the gut, we sought to test whether an ILC3 bias in the mLN reflected direct trafficking of ILC3s from the intestine to the mLN using transgenic Kaede mice (Tomura et al.)'. The Methods section should have included the following: 'The Kaede mice used in this study were kindly provided and transferred by Dr Miwa in Tsukuba University and Dr Tomura and Dr Kanagawa in RCAI, RIKEN, Japan.'
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