Project description:The transcription factor FOXN1 is a master regulator of thymic epithelial cell development and function. Here we demonstrate that FOXN1 expression is differentially regulated during organogenesis and participates in multi-molecular nuclear condensates essential for the factor's transcriptional activity. FOXN1's C-terminal sequence regulates the diffusion velocity within these aggregates and modulates the binding to proximal gene regulatory regions. These dynamics are significantly altered in a patient's FOXN1 mutant modified in its C-terminal sequence. This mutant is transcriptionally inactive and acts as a dominant negative factor displacing wild-type FOXN1 from condensates and causing athymia and severe lymphopenia in heterozygotes. Expression of the mutated mouse ortholog, Foxn1, selectively impairs mouse thymic epithelial cell (TEC) differentiation, revealing a gene dose dependency for individual TEC subtypes. We have therefore identified the cause for a primary immunodeficiency disease and determined the mechanism by which this FOXN1 gain-of-function mutant mediates its dominant negative effect.

Project description:Normal thymic T cell development is enabled by a stromal microenvironment most importantly composed of distinct epithelial cell populations in cortex and medulla. Their differentiation, growth and function require the expression of the transcription factor Foxn1. Direct targets of Foxn1 have, however, remained largely undefined. Utilizing newly created static and inducible genetic model systems, we now provide a genome wide map of Foxn1 target genes and the sequences bound by this master regulator. Foxn1 controls not only essential steps early in intrathymic lymphoid development including T cell lineage commitment but is also indispensable for later stages in T cell maturation such as the selection of CD4 and CD8 T cells. Thus, Foxn1 function critically choreographs both early and late events in thymic lympho-stromal cross-talk. Foxn1 ChIP-seq and RNA-seq in mouse models of hypofunctional or conditional knock-out of Foxn1 Brief sample descriptions are shown below: Foxn1 ChIP-seq (GSM1945905) - chromatin immunoprecipitated using an antibody against FOXN1-FLAG (wt*); 2 samples Input ChIP-seq (GSM1945906) - input chromatin; 2 samples 42cT (GSM1945907) - RNA-seq on wt*/-::nu/nu cTEC; 3 samples 42mT (GSM1945908) - RNA-seq on wt*/-::nu/nu mTEC; 2 samples 96cT (GSM1945909) - RNA-seq on wt*/wt*::nu/nu cTEC; 3 samples 96mT (GSM1945910) - RNA-seq on wt*/wt*::nu/nu mTEC; 2 samples NcT (GSM1945911) - RNA-seq on Dox-treated TetO- iFoxn1(del7,8) cTEC; 5 samples PcT (GSM1945912) - RNA-seq on Dox-treated TetO+ iFoxn1(del7,8) cTEC; 5 samples C57BL/6 mice (GSM1945913) - ATAC-seq on wild-type cTEC; 1 sample Please see each sample for more detailed information.

Project description:Normal thymic T cell development is enabled by a stromal microenvironment most importantly composed of distinct epithelial cell populations in cortex and medulla. Their differentiation, growth and function require the expression of the transcription factor Foxn1. Direct targets of Foxn1 have, however, remained largely undefined. Utilizing newly created static and inducible genetic model systems, we now provide a genome wide map of Foxn1 target genes and the sequences bound by this master regulator. Foxn1 controls not only essential steps early in intrathymic lymphoid development including T cell lineage commitment but is also indispensable for later stages in T cell maturation such as the selection of CD4 and CD8 T cells. Thus, Foxn1 function critically choreographs both early and late events in thymic lympho-stromal cross-talk.

Project description:We previously identified a recurrent mutation L424H in the transcription factor GTF2I in thymic epithelial tumors. The precise role of the GTF2I mutation in these tumors is unclear. Here we describe the generation and characterization of a mouse model in which the Gtf2i L424H mutation was conditionally knocked-in in the Foxn1+ thymic epithelial cells. The Gtf2i mutation impairs development of thymic medulla and maturation of medullary thymic epithelial cells in the young mice and causes tumor formation in the thymus of the aged KI mice. To characterize the molecular features of murine thymomas, we performed digital spatial profiling with GeoMx moue whole transcriptome atlas assay with FFPE thymic tissues of 4 KI and 4 control mice.

Project description:The goal of this study was to document the gene expression profile of FOXN1+ thymic endoderm cells derived from the in vitro differentiation of human pluripotent stem cells. Thymic epithelial cells (TECs) play a critical role in T-cell maturation and tolerance induction. The generation of TECs from in vitro differentiation of human pluripotent stem cells (PSCs) would provide a platform for studying the mechanisms of this interaction and have implications for immune reconstitution. To facilitate analysis of PSC-derived TECs, we generated human embryonic stem cell (hESC) reporter lines in which sequences encoding GFP were targeted to FOXN1, a gene required for TEC development. Using this FOXN1GFP/w line as a read out, we developed a reproducible protocol for generating FOXN1-GFP+ thymic endoderm cells. Transcriptional profiling and flow cytometry identified Integrin-β4 (ITGB4, CD104) and HLA-DR as markers that could be used in combination with EpCAM to selectively purify FOXN1+ TEC progenitors from differentiating cultures of unmanipulated PSCs. Human FOXN1+ TEC progenitors generated from PSCs will facilitate the study of thymus biology and are a valuable resource for future applications in regenerative medicine Human embryonic stem cells were differentiated for 30 days using the protocol described by Soh et al, 2014. The hESCs used in this protocol had been genetically modified by targeting sequences encoding GFP to the FOXN1 locus, thus enabling FOXN1 expressing cells to be identified on the basis of GFP expression. At differentiation day 30, differentiating cells were separated into three fractions using FACS. These fractions were the FOXN1+(GFP+)EpCAM+, FOXN1-(GFP-)EpCAM+, FOXN1-(GFP-)EpCAM-.

Project description:Specialized niche environments specify and maintain stem and progenitor cells, but little is known about the identities and functional interactions of niche components in vivo. Here, we describe a modular system for the generation of artificial hematopoietic niches in the mouse embryo. A circumscribed tissue that lacks niche function but is physiologically accessible for hematopoietic progenitor cells is functionalized by individual and combinatorial expression of four factors, the chemokines Ccl25 and Cxcl12, the cytokine Scf and the Notch ligand DLL4. The distinct phenotypes and variable numbers of hematopoietic cells in the resulting niches reveal synergistic, context-dependent and hierarchical interactions among niche effector molecules. The surprisingly simple rules determining niche outcomes enable the in vivo engineering of artificial niches conducive to the presence of distinct myeloid or T or B lymphoid lineage precursors. The dataset comprises 24 samples divided into eight sample groups each representing a different lymphoid progenitor cell type isolated from wild-type (+/-) or transgenic (-/-) thymic niches. -/-, Foxn1-deficient genotype; +/-, Foxn1 heterozygous phenotype; DP, CD4/CD8 double-poisztive thymocytes; DN3, CD4/CD8-negative stage 3 thymocytes; SP4, CD4 single-positive thymocytes; SP8, CD8 single-positive thymocytes; B IgM-, IgM surface negative B cells; B IgM+, IgM surface positive B cells; B IgM- -/-, IgM surface negative B cells from Foxn1-deficient genotype.

Project description:Loss-of-function mutations in Foxn1 or Aff4 cause similar defects in skin morphology. To determine whether these similar phenotypes result from similar changes in gene expression, skin from wild-type, Foxn1-null, or Aff4 conditional knockout (cko) mice was analysed by RNA-seq at a time when the animals were attempting to grow their first hair coats (P6).

Project description:Hoxc13 has been shown to be essential for proper hair shaft differentiation as Hoxc13 gene-targeted (Hoxc13tm1Mrc) mice completely lack external hair. Because of the phenotypic parallels to the Foxn1nu (nude) mutant mice, we tested whether Hoxc13 and Foxn1 act in a common pathway of hair follicle (HF) differentiation. We show that the alopecia exhibited by both the Hoxc13tm1Mrc and Foxn1nu mice is due to strikingly similar defects in hair shaft differentiation and that both mutants suffer from a severe nail dystrophy. These similarities are consistent with the overlap of Hoxc13 and Foxn1 expression patterns in the HF and nail matrix. DNA microarray analysis of scapular skin from Hoxc13tm1Mrc mutant (mut) compared to wild type (wt) mice identified Foxn1 as significantly down-regulated along with numerous hair keratin genes. This Foxn1 down-regulation apparently reflects the loss of direct transcriptional control by HOXC13 as indicated by our results obtained through co-tranfection and chromatin immunoprecipitation (ChIP) assays. Total number of samples was 6. The experiment was perfomed in triplicate involving 3 indendent wild type skin samples (sample 1, 2, and 3) and 3 independent mutant skin samples (sample 4, 5, and 6).

Project description:Disruption of higher order nuclear condensates by a dominant negative FOXN1 mutation causes immunodeficiency

Project description:The thymus is the site of T cell development. Although much is known about the development and differentiation of the T lymphocyte compartment, less is known about the thymic epithelial cell (TEC). Foxn1 is critical for the development and function of the thymus. Here, we used ATAC-Seq to identify regions of accessible chromatin in TEC and keratinocytes of the skin to identify candidate active regulatory elements critical for tissue specific expression of Foxn1.