Project description:Aging has multifaceted effects on the immune system, but how aging affects tissue-specific immunity is not well-defined. Bladder diseases characterized by chronic inflammation are highly prevalent in older women, but mechanisms by which aging promotes these pathologies remain unknown. Tissue transcriptomics of unperturbed, young, and aged bladders identified a highly altered immune landscape as a fundamental feature of the aging female bladder. Detailed mapping of immune cells using single cell RNA- sequencing revealed novel subsets of macrophages and dendritic cells and unique changes to the immune repertoire in the aged bladder. B and T cells are highly enriched in aged bladders and spontaneously form organized bladder tertiary lymphoid tissues (bTLTs).

Project description:Aging has multifaceted effects on the immune system, but how aging affects tissue-specific immunity is not well-defined. Bladder diseases characterized by chronic inflammation are highly prevalent in older women, but mechanisms by which aging promotes these pathologies remain unknown. Tissue transcriptomics of unperturbed, young, and aged bladders identified a highly altered immune landscape as a fundamental feature of the aging female bladder. Detailed mapping of immune cells using single cell RNA- sequencing revealed novel subsets of macrophages and dendritic cells and unique changes to the immune repertoire in the aged bladder. B and T cells are highly enriched in aged bladders and spontaneously form organized bladder tertiary lymphoid tissues (bTLTs).

Project description:To explore the classification and functional roles of bladder immune cells during urinary tract infection (UTI), we performed scRNA-seq analysis of immune cells extracted from mouse bladders.

Project description:Infection with hepatitis B and C viruses (HBV and HCV) is a major cause of hepatocellular carcinoma (HCC). While troponin T (TNNT1) is essential for actin thin filament function, little is known about its role in HBV/HCV-associated HCC. Here, we found TNNT1 expression was significantly upregulated in HBV/HCV-infected hepatoma cells, HCC tissues, and mouse models. HBV/HCV-induced c-Myc acts as a transcription factor for TNNT1 induction. HBV/HCV-induced TNNT1 binds metastasis-associated protein 2 (MTA2) and activates the PI3K-AKT-mTOR-TNNT1 loop, causing lysosomal dysfunction and autophagy suppression. This leads to increased proliferation and epithelial-mesenchymal transition (EMT) of liver cancer cells marked by Vimentin and ZEB2. Four amino acid residues (R110A, E112A, R115A, and E119A) within the TNNT1 troponin domain are required for TNNT1-MTA2 binding and mediate TNNT1’s suppression of autophagy and promotion of proliferation/EMT. Importantly, liver-specific TNNT1 deficiency in mice attenuates HBV/HCV-induced c-Myc-driven HCC EMT properties in vivo. This study reveals for the first time that hepatitis virus-induced TNNT1 can induce EMT and hepatocellular carcinogenesis. TNNT1 may be a promising target for viral HCC therapy.

Project description:To analyze the gene expression of non-bacterial bladdder inflammation, mouse cyclophosphamide(CYP)-induced model of cystitis was adapted. Forty-eight hour after CYP or vehicle treatment, total RNA was extracted from CYP-treated group (CYP150) and control group (CYP0). We used microarrays to detail the gene expression underlying bladder inflammation.

Project description:Myogenesis is a highly orchestrated process whereby muscle precursor cells, myoblasts, develop into muscle fibers to form skeletal muscle during embryogenesis and regenerate adult muscle. Here, we studied the RNA-binding protein FUS (fused in sarcoma), which has been implicated in muscular and neuromuscular pathologies but is poorly characterized in myogenesis. Given that FUS levels declined in human and mouse models of skeletal myogenesis, and that silencing FUS enhanced myogenesis, we hypothesized that FUS might be a repressor of myogenic differentiation. Interestingly, overexpression of FUS delayed myogenesis, accompanied by slower production of muscle differentiation markers. To identify the mechanisms through which FUS inhibits myogenesis, we uncovered RNA targets of FUS by ribonucleoprotein immunoprecipitation (RIP) followed by RNA-sequencing (RNA-seq) analysis. Stringent selection of the bound transcripts uncovered Tnnt1 mRNA, encoding troponin T (TNNT1), as a major effector of FUS influence on myogenesis. We found that in myoblasts, FUS sequestered Tnnt1 mRNA in the nucleus, preventing TNNT1 expression; however, reduction of FUS during myogenesis or by silencing FUS released Tnnt1 mRNA for export to the cytoplasm, where it accumulated and was translated into TNNT1, promoting myogenesis. We propose that FUS inhibits myogenesis by suppressing TNNT1 expression through a mechanism of nuclear mRNA retention.

Project description:Myogenesis is a highly orchestrated process whereby muscle precursor cells, myoblasts, develop into muscle fibers to form skeletal muscle during embryogenesis and regenerate adult muscle. Here, we studied the RNA-binding protein FUS (fused in sarcoma), which has been implicated in muscular and neuromuscular pathologies but is poorly characterized in myogenesis. Given that FUS levels declined in human and mouse models of skeletal myogenesis, and that silencing FUS enhanced myogenesis, we hypothesized that FUS might be a repressor of myogenic differentiation. Interestingly, overexpression of FUS delayed myogenesis, accompanied by slower production of muscle differentiation markers. To identify the mechanisms through which FUS inhibits myogenesis, we uncovered RNA targets of FUS by ribonucleoprotein immunoprecipitation (RIP) followed by RNA-sequencing (RNA-seq) analysis. Stringent selection of the bound transcripts uncovered Tnnt1 mRNA, encoding troponin T (TNNT1), as a major effector of FUS influence on myogenesis. We found that in myoblasts, FUS sequestered Tnnt1 mRNA in the nucleus, preventing TNNT1 expression; however, reduction of FUS during myogenesis or by silencing FUS released Tnnt1 mRNA for export to the cytoplasm, where it accumulated and was translated into TNNT1, promoting myogenesis. We propose that FUS inhibits myogenesis by suppressing TNNT1 expression through a mechanism of nuclear mRNA retention.

Project description:Although there are several reports describing a stem cell fraction to form urothelium and lineage tracing studies in urinary bladder, it is still unclear about stem cells in mouse bladder epithelium. Here, we have established the cloning system of mouse stem cells from wild type and p63 knockout bladder. We isolated stem/progenitor cells from wild type and p63 knockout epithelium. From wild type bladder, we have cloned keratin 5-positive stem cells, and from p63 knockout epithelium, which loses basal cell fraction, we have cloned morphologically-distinct keratin 8 and claudin 3 positive stem cells, which may be reminiscent of intestinal metaplasia in bladder.

Project description:Inflammatory bowel disease (IBD) is characterized by dysbiosis of the gut microbiota and dysfunction of in testinal stem cells (ISCs). However, the direct interactions between IBD microbial factors and ISCs are unde scribed. Here, we identify α2A-adrenergic receptor (ADRA2A) as a highly expressed GPCR in ISCs. Through PRESTO-Tango screening, we demonstrate that tyramine, primarily produced by Enterococcus via tyrosine decarboxylase (tyrDC), serves as a microbial ligand for ADRA2A. Using an engineered tyrDC deficient Enterococcus faecalis strain and intestinal epithelial cell-specific Adra2a knockout mice, we show that Enterococcus-derived tyramine suppresses ISC proliferation, thereby impairing epithelial regeneration and exacerbating DSS-induced colitis through ADRA2A. Importantly, blocking the axis with an ADRA2A antagonist, yohimbine, disrupts tyramine-mediated suppression on ISCs and alleviates colitis.Our findings highlight a microbial ligand-GPCR pair in ISCs, revealing a causal link between microbial regulation of ISCs and colitis exacerbation and yielding a targeted therapeutic approach to restore ISC function in colitis.

Project description:To analyze the gene expression of non-bacterial bladdder inflammation, mouse cyclophosphamide(CYP)-induced model of cystitis was adapted. Forty-eight hour after CYP or vehicle treatment, total RNA was extracted from CYP-treated group (CYP150) and control group (CYP0). We used microarrays to detail the gene expression underlying bladder inflammation. Five-week-old female Balbc/A mice were injected intraperitoneally with 150mg/kg body weight of CYP diluted in 15ml/kg body weight of saline. Mice injected with saline alone served as controls. Treated mice were killed 48 hours after administaration and the whole bladders harvested. Total RNA was extracted and microarray analysis was performed.