Project description:IL-17-producing gd T (Tgd17) cells are innate-like mediators of intestinal barrier immunity. While Th17 cell and ILC3 plasticity have been extensively studied, the mechanisms governing Tgd17 cell effector flexibility remain undefined. Here, we combined type 3 fate-mapping with single cell ATAC/RNA-seq multiome profiling to define the cellular features and regulatory networks underlying Tgd17 cell plasticity. During homeostasis, Tgd17 cell effector identity was stable across tissues, including for intestinal T-bet+ Tgd17 cells that restrained IFNg production. However, S. typhimurium infection induced intestinal Vg6+ Tgd17 cell conversion into type 1 effectors, with loss of IL-17A production and partial RORgt downregulation. Multiome analysis revealed a trajectory along Vg6+ Tgd17 effector conversion, with TIM-3 marking ex-Tgd17 cells with enhanced type 1 functionality. Lastly, we characterized and validated a critical AP-1 regulatory axis centered around JunB and Fosl2 that controls Vg6+ Tgd17 cell plasticity by stabilizing type 3 identity and restricting type 1 effector conversion.

Project description:Tgd17 cells are critical immune effector cells that exit the thymus committed to peripheral IL-17 responses, but whether the development of cells into this lineage is pre-programmed or driven by instructive TCR signals is unresolved. Using newly generated reporter mice for a gene necessary for Tgd17 cell development, Sox13, we identified progenitor cells (known as DN1d cells) that expressed high levels of Sox13 prior to expression of the TCR. To interrogate whether DN1d cells could be a candidate Tgd17-biased progenitor, whole transcriptome RNA sequencing was performed on these progenitors as well as canonical T cell progenitors thought to generate all T cell subsets and the proposed progeny Tgd17 cells. The data demonstrated that DN1d cells most closely resemble Tgd17 cells at a transcriptome level, while canonical T cell progenitors were very different from both DN1d cells and Tgd17 cells. Further studies demonstrated that DN1d cells generated Tgd17 cells in developmental assays, and that the transcriptional signature of DN1d cells is established and maintained independently of TCR expression or signaling but is instead dependent on HMG transcription factors SOX13 and TCF1. Thus, T cell lineage identity can be pre-programmed at the progenitor level and is not necessarily specified by specific TCR signals.

Project description:Restriction of innate Tgd17 cell plasticity by an AP-1 regulatory axis [multiome]

Project description:We examine the transcriptional profile of lung Tgd17 cells from mice that are deficient for Aire compared to wild-type mice.

Project description:Restriction of innate Tgd17 cell plasticity by an AP-1 regulatory axis

Project description:RNA Sequencing of Tgd17 progenitors

Project description:IL-17-producing gd T (Tgd17) cells are early mediators of immunity and autoimmunity that undergo effector programming in the thymus. While Vg subset-restricted regulators of Tgd17 specialization are known, a universal type 17 commitment factor for all gd T cells remains undefined. In this study, we identify the transcription factor c-Maf as an essential and uniform regulator of Tgd17 differentiation and maintenance. The absolute lineage block caused by Maf deficiency reveals a critical effector acquisition checkpoint at the immature CD24+ CD45RBlo gd thymocyte stage. Here, c-Maf enforces Tgd17 identity by promoting chromatin accessibility and activating expression of lineage-defining RORgt and key type 17 program genes, while coordinately antagonizing the negative regulator TCF1, which promotes the alternative IFNg+ Tgd1 fate. During specialization, c-Maf expression is tuned by gdTCR signal strength, implicating c-Maf as a rheostat controlling effector gd T cell generation and connecting gdTCR signals to a core node in the Tgd17 network.

Project description:IL-17-producing gd T (Tgd17) cells are early mediators of immunity and autoimmunity that undergo effector programming in the thymus. While Vg subset-restricted regulators of Tgd17 specialization are known, a universal type 17 commitment factor for all gd T cells remains undefined. In this study, we identify the transcription factor c-Maf as an essential and uniform regulator of Tgd17 differentiation and maintenance. The absolute lineage block caused by Maf deficiency reveals a critical effector acquisition checkpoint at the immature CD24+ CD45RBlo gd thymocyte stage. Here, c-Maf enforces Tgd17 identity by promoting chromatin accessibility and activating expression of lineage-defining RORgt and key type 17 program genes, while coordinately antagonizing the negative regulator TCF1, which promotes the alternative IFNg+ Tgd1 fate. During specialization, c-Maf expression is tuned by gdTCR signal strength, implicating c-Maf as a rheostat controlling effector gd T cell generation and connecting gdTCR signals to a core node in the Tgd17 network.

Project description:Single-cell RT-PCR analysis of Tgd17 progenitors

Project description:Restriction of innate Tgd17 cell plasticity by an AP-1 regulatory axis [CUT&Run]