Project description:We have noticed that the proliferative potential of epithelial cells in the mouse proximal prostatic ducts is less than those at the distal prostatic ducts. To determine whether specific signaling is differentially activated in distal and proximal prostate basal cells, we isolated respective basal cells in the two regions and performed an RNA-seq analysis.
Project description:We have noticed that the proliferative potential of epithelial cells in the mouse proximal prostatic ducts is less than those at the distal prostatic ducts. We were curious whether the tissue microenvironment in the two anatomic regions play a role in the distinct epithelial proliferative indices. So we isolated respective stromal cells in the two regions and performed an RNA-seq analysis.
Project description:To investigate the molecular reprogramming of epithelial cells of the prostate during basal to luminal differentiation in vivo, we took advantage of the spatial restriction of multipotent basal cells at the distal region (tip - 100μm) of the developing prostate at postnatal day (P)10 (Tika et al., Development, 2019). The distal tips (100μm) of P10-P13 prostate glands were manually dissected from the main ducts under the stereoscope in order to enrich for multipotent basal cells and basal-derived luminal cells. Cell populations were isolated for RNA sequencing based on EpCAM and Cd49f expression via FACS.
Project description:We performed spatial RNA-Seq of prostate and urethra tissues from C57Bl/6 wild type mice. Downstream analyses demonstrated that Foxf2 is highly expressed in the mouse proximal prostate as compaired to the distal ducts.
Project description:Analysis of gene expression in proximal versus distal part of the mouse large intestine. Three (3) animals (biological replicates) were used to isolate tissue from proximal and distal areas of the large intestine.
Project description:The proximal-distal patterning program determines unique structural and functional properties of proximal and distal airways in the adult lung. Based on the knowledge that remod-eling of distal airways is the major pathologic feature of chronic obstructive pulmonary disease (COPD), and that small airway epithelium (SAE), which covers distal airways, is the primary site of the initial smoking-induced changes relevant to COPD pathogenesis, we hypothesized that in COPD smokers, the SAE transcriptome loses its region-specific biologic identity and takes on the transcriptional pattern of the proximal airways. By analyzing human airway epithelium col-lected by bronchoscopic brushings from proximal and distal airways of healthy smokers, proxi-mal and distal airway epithelial transcriptome signatures were identified. Dramatic smoking-dependent suppression of distal signature paralleled by acquisition of the proximal airway epithe-lial phenotype was found in the SAE of COPD smokers. Distal-proximal re-patterning observed in the SAE of smokers in vivo was reproduced in vitro by stimulating SAE basal cells (BC), the stem/progenitor cells of the SAE, with EGF, a growth factor up-regulated in airway epithelium by smoking. Together, this study identifies distal-proximal SAE re-patterning as a characteristic feature of small airway disordering in COPD smokers potentially driven by EGF/EGFR-mediated reprogramming of SAE BC stem/progenitor cells.
Project description:Analogous to alternative splicing, alternative polyadenylation (APA) has long been thought to result from competition between proximal and distal polyA sites. By Fractionation-seq, we unexpectedly identified several hundred APA genes where their distal polyA isoforms are retained in chromatin/nuclear matrix and proximal polyA isoforms released into the cytoplasm. Global metabolic PAS-seq and Nanopore long-read RNA-seq provided further evidence that the strong distal polyA sites are first processed and the resulting transcripts are anchored in chromatin/nuclear matrix for further processing at proximal polyA sites and removal of certain slowly spliced introns. By engineering an autocleavable ribozyme between the proximal and distal polyA sites, we demonstrated that the distal polyA isoform is indeed the precursor to the proximal polyA isoform. Therefore, unlike alternative splicing, APA sites are recognized independently, rather than competitively, and in many cases, in a sequential manner. This provides a versatile strategy to regulate gene expression in mammalian cells.
Project description:By comparing the transcriptome from proximal (quadriceps femoris, QF) and distal (tibialis anterior, TA)muscle groups in dysferlin deficient mouse muscle (the SJL mutation bred onto C57BL/10 to produces C57BL/10-SJL.Dysf) with proximal and distal muscle groups from control C57BL/10 mice of an equivalent age (3-weeks old, prior to the onset of overt pathology) we aim to address the issues of muscle selectivity in this this form of muscular dystrophy. Keywords: parallel sample
Project description:Isolation of prostate stem cells is crucial for understanding their biology during normal development and tumorigenesis. In this aim, we used a transgenic mouse model expressing GFP from the stem cell-specific s-SHIP promoter to mark putative stem cells during postnatal prostate development. We showed that cells identified by s-SHIP/GFP expression are present transiently during early prostate development and localize to the basal cell layer of the epithelium. These prostate s-SHIP/GFP-positive cells represent a subpopulation of the lineage-negative / CD24-positive / Sca-1-positive / CD49f-positive (LSC) cells and are capable of self–renewal together with enhanced growth potential in sphere–forming assay in vitro, a phenotype consistent with that of a prostate stem cell population. Transplantation assays of these prostate GFP-positive cells demonstrate reconstitution of prostate ducts containing both basal and luminal cells in renal grafts. Altogether, these results demonstrate that s-SHIP promoter expression is a new marker for neonatal basal prostate cells exhibiting stem cell properties that enables prostate stem cells in situ identification and isolation via a single consistent parameter. Since the GFP-positive cell population is a small subset of basal LSC cells and is most responsible for stem-like activity, we performed transcriptional profiling of GFP-negative LSC and GFP-positive LSC cells to distinguish a basal cell profile from a tissue stem cell profile.