Project description:RNAseq of coding and noncoding RNA isolated from intestinal tuft cells reveals murine rotavirus replication in intestinal tuft cells.

Project description:We perfromed POU2F3 ChIP-seq on intestinal tuft cells

Project description:DDX5, a DEAD box containing RNA binding protein, is involved in multiple aspects of RNA metabolism and is abundantly expressed in all subsets of the intestinal epithelial cells (IEC). Here, we characterized the DDX5-dependent transcriptome in the small intestine. In the DDX5△IEC tissue, we found that secretory IEC lineage progenitor containing spots (Atoh1hi and Sox4hi) had reduced expression of Pou2f3, a master regulator of a subset of IECs called tuft cells. As a result of the loss of Pou2f3 expression in the progenitors, DDX5△IEC tissue harbored lower number of tuft cell containing spots (Dclk1hi) compare to WT tissues.

Project description:Human intestinal organoids (hIOs) derived from human pluripotent stem cells (hPSCs) have immense potential as a source of intestines. However, due to problems obtaining mature adult-like cells from hPSCs, effective strategies for the maturation of hIOs with improved functionalities must be developed. We established conditions that enable the in vitro maturation of hIOs derived from hPSCs, recapitulating the essential features of intestinal tissue. The maturity of the hPSC-derived hIOs was enhanced by the in vitro maturation in our co-culture system, evidenced by transcriptional changes observed in our microarray data. Global transcription of in vitro-matured hIOs is highly similar to that of adult human small intestine (hSI). Compared to control hIOs, in vitro-matured hIOs exhibited significant increases in the expression of intestinal maturation markers, major transporters, and key enzymes for drug absorption and first-pass metabolism.

Project description:Murine rotavirus infects and replicates in intestinal tuft cells

Project description:Human intestinal organoids (hIOs) resemble the human intestine physiologically and structurally. We recently present an in vitro maturation technique for generating mature and functional hIOs from human pluripotent stem cells (hPSCs). Here, we investigated the mechanisms of STAT3 for inducing in vitro maturation of hIOs. Using CRISPR/Cas9-mediated gene editing, STAT3 knockout (KO) human embryonic stem cell (hESC) lines were generated and characterized. By genome-wide microarray analyses, STAT3 KO hIOs showed markedly different profiles from the in vitro matured hIOs and human small intestine and the majority of genes, which are associated with intestinal development and functions, were downregulated by STAT3 KO. This study reveals important signaling pathways for the maturation of hIOs derived from hPSCs.

Project description:The transcription factor POU2F3 defines the identity of tuft cells and underlies a distinct molecular subtype of small cell lung cancer (SCLC). Although POU2F3 is considered undruggable, its activity critically depends on the coactivators OCA-T1 and OCA-T2. Here, we demonstrate that acute suppression of either POU2F3 or OCA-T1 induces regression of tuft cell-like SCLC xenografts in vivo. To explore the structural basis and druggability of this dependency, we solved crystal structures of POU2F3 bound to OCA-T1 or OCA-T2 in complex with DNA, revealing a tripartite, DNA-dependent interface. We further employed deep mutational scanning to systematically assess the functional impact of 4,218 missense variants in POU2F3 and OCA-T1, uncovering both mutation-sensitive hotspots and structurally constrained regions critical for tumor cell fitness. These findings define a unique transcriptional complex that integrates DNA recognition with coactivator recruitment and nominate POU2F3–OCA-T as a structurally tractable vulnerability in tuft cell-like carcinomas.

Project description:The transcription factor POU2F3 defines the identity of tuft cells and underlies a distinct molecular subtype of small cell lung cancer (SCLC). Although POU2F3 is considered undruggable, its activity critically depends on the coactivators OCA-T1 and OCA-T2. Here, we demonstrate that acute suppression of either POU2F3 or OCA-T1 induces regression of tuft cell-like SCLC xenografts in vivo. To explore the structural basis and druggability of this dependency, we solved crystal structures of POU2F3 bound to OCA-T1 or OCA-T2 in complex with DNA, revealing a tripartite, DNA-dependent interface. We further employed deep mutational scanning to systematically assess the functional impact of 4,218 missense variants in POU2F3 and OCA-T1, uncovering both mutation-sensitive hotspots and structurally constrained regions critical for tumor cell fitness. These findings define a unique transcriptional complex that integrates DNA recognition with coactivator recruitment and nominate POU2F3–OCA-T as a structurally tractable vulnerability in tuft cell-like carcinomas.

Project description:The transcription factor POU2F3 defines the identity of tuft cells and underlies a distinct molecular subtype of small cell lung cancer (SCLC). Although POU2F3 is considered undruggable, its activity critically depends on the coactivators OCA-T1 and OCA-T2. Here, we demonstrate that acute suppression of either POU2F3 or OCA-T1 induces regression of tuft cell-like SCLC xenografts in vivo. To explore the structural basis and druggability of this dependency, we solved crystal structures of POU2F3 bound to OCA-T1 or OCA-T2 in complex with DNA, revealing a tripartite, DNA-dependent interface. We further employed deep mutational scanning to systematically assess the functional impact of 4,218 missense variants in POU2F3 and OCA-T1, uncovering both mutation-sensitive hotspots and structurally constrained regions critical for tumor cell fitness. These findings define a unique transcriptional complex that integrates DNA recognition with coactivator recruitment and nominate POU2F3–OCA-T as a structurally tractable vulnerability in tuft cell-like carcinomas.

Project description:The olfactory neuroepithelium serves as a sensory organ for odors and forms part of the nasal mucosal barrier. Olfactory sensory neurons are surrounded and supported by epithelial cells. Among them, microvillous cells (MVCs) are strategically positioned at the apical surface, but their specific functions are enigmatic and their relationship to the other specialized epithelial cells, particularly the solitary chemosensory cell family, is unclear. Here, we establish that the family of MVCs comprises tuft cells and ionocytes in both mice and humans. Integrating analysis of the respiratory and olfactory epithelia, we define the unique receptor expression of TRPM5+ tuft-MVCs compared to Gɑ-gustducinhigh respiratory tuft cells and characterize a new population of glandular DCLK1+ tuft cells. To establish how allergen sensing by tuft-MVCs might direct olfactory mucosal responses, we employed an integrated single-cell transcriptional and protein analysis. Inhalation of Alternaria induced mucosal epithelial effector molecules including Chil4, and a distinct pathway leading to proliferation of the quiescent olfactory horizontal basal stem cell (HBC) pool, both triggered in the absence of olfactory apoptosis. While the Chil4 pathway was dependent on STAT6 signaling and innate lymphocytes, neither were required for HBC proliferation. Alternaria- and ATP- elicited HBC proliferation was dependent on tuft-MVCs, establishing these specialized epithelial cells as regulators of olfactory stem cell responses. Together our data provide high resolution characterization of nasal tuft cell heterogeneity and uncover a novel function for TRPM5+ tuft-MVCs in directing the olfactory mucosal response to allergens.