Project description:Induced pluripotent stem (iPS) cells are a valuable resource for discovery of epigenetic changes critical to cell type-specific differentiation. Although iPS cells have been generated from other terminally differentiated cells, the reprogramming of normal adult human basal prostatic epithelial (E-PZ) cells to a pluripotent state has not been reported. Here, we attempted to reprogram E-PZ cells by forced expression of Oct4, Sox2, c-Myc, and Klf4 using lentiviral vectors and obtained embryonic stem cell (ESC)-like colonies at a frequency of 0.01%. These E-PZ-iPS-like cells with normal karyotype gained expression of pluripotent genes typical of iPS cells (Tra-1-81, SSEA-3, Nanog, Sox2, and Oct4) and lost gene expression characteristic of basal prostatic epithelial cells (CK5, CK14, and p63). E-PZ-iPS-like cells demonstrated pluripotency by differentiating into ectodermal, mesodermal, and endodermal cells in vitro, although lack of teratoma formation in vivo and incomplete demethylation of pluripotency genes suggested only partial reprogramming. Importantly, E-PZ-iPS-like cells re-expressed basal epithelial cell markers (CD44, p63, MAO-A) in response to prostate-specific medium in spheroid culture. Androgen induced expression of androgen receptor (AR), and co-culture with rat urogenital sinus further induced expression of prostate-specific antigen, a hallmark of secretory cells, suggesting that E-PZ-iPS-like cells have the capacity to differentiate into prostatic basal and secretory epithelial cells. Finally, when injected into mice, E-PZ-iPS-like cells expressed basal epithelial cell markers including CD44 and p63. When co-injected with rat urogenital mesenchyme, E-PZ-iPS-like cells expressed AR and expression of p63 and CD44 was repressed. DNA methylation profiling identified key pathways and regulators of prostatic differentiation including Wnt5a, BPM7, PTEN, and NKx3.1 using E-PZ-iPS-lke cells. Our results suggest that iPS-like cells can be derived from prostatic epithelial cells. These cells are pluripotent and capable of prostatic differentiation, and therefore provide a novel model for investigating epigenetic changes involved in prostate cell lineage specification. Bisulphite converted DNA from the 10 samples were hybridised to the Illumina Infinium HumanMethylation450K Beadchip v1.2

Project description:Tissue remodeling or regeneration is believed to initiate from organ-specific stem and/or progenitor cells. We report here the establishment of two spontaneously immortalized adult human benign prostate epithelial cell lines, NHPrE1 and BHPrE1. NHPrE1CD133(++)/CD44(++)/OCT4(++)/CK14(+++) was characterized as a putative progenitor cell, and BHPrE1CD133(+)/CD44(+)/OCT4(+)/CK14(++) as a putative intermediate cell. aCGH analysis demonstrated a largely intact diploid karyotype with DNA amplification of PTEN in NHPrE1 or Beta-Catenin in BHPrE1 cells, respectively. A tissue recombination-xenografting model was utilized to compare remodeling of human prostatic tissues in vivo by the NHPrE1 and BHPrE1 cell lines and their parental primary cells. A series of tissue recombinants, made by mixing different ratios of human prostatic epithelial cells and inductive rat urogenital sinus mesenchyme (UGM), were grafted to the renal capsule of SCID mice. Both cell lines were able to regenerate ductal/acinar structures in vivo containing basal and luminal epithelial populations confirmed by the expression of appropriate cytokeratin profiles. Androgen receptor (AR), prostate specific antigen (PSA), and 15-lipoxigenase-2 (15-LOX-2) expression were appropriately expressed in the regenerated epithelial structures. Regeneration of benign human prostatic ductal/acinar architecture could be achieved using as few as 10 NHPrE1 cells while 200,000 BHPrE1 cells were required to achieve prostatic structure. This suggests a greater proportion of progenitor cells in NHPrE1 facilitated regeneration of prostatic morphology and function. These cell lines provide important data on progenitor and intermediate cell phenotypes and represent significant new tools for the elucidation of molecular mechanisms of human prostatic regeneration, pathogenesis and carcinogenesis. Two channel CGH from Agilent platform was used to detect DNA amplification or deletion in genomic samples from NHPrE1 and BHPrE1 cell lines. A common pooled normal DNA refernce was used.

Project description:Tissue remodeling or regeneration is believed to initiate from organ-specific stem and/or progenitor cells. We report here the establishment of two spontaneously immortalized adult human benign prostate epithelial cell lines, NHPrE1 and BHPrE1. NHPrE1CD133(++)/CD44(++)/OCT4(++)/CK14(+++) was characterized as a putative progenitor cell, and BHPrE1CD133(+)/CD44(+)/OCT4(+)/CK14(++) as a putative intermediate cell. aCGH analysis demonstrated a largely intact diploid karyotype with DNA amplification of PTEN in NHPrE1 or Beta-Catenin in BHPrE1 cells, respectively. A tissue recombination-xenografting model was utilized to compare remodeling of human prostatic tissues in vivo by the NHPrE1 and BHPrE1 cell lines and their parental primary cells. A series of tissue recombinants, made by mixing different ratios of human prostatic epithelial cells and inductive rat urogenital sinus mesenchyme (UGM), were grafted to the renal capsule of SCID mice. Both cell lines were able to regenerate ductal/acinar structures in vivo containing basal and luminal epithelial populations confirmed by the expression of appropriate cytokeratin profiles. Androgen receptor (AR), prostate specific antigen (PSA), and 15-lipoxigenase-2 (15-LOX-2) expression were appropriately expressed in the regenerated epithelial structures. Regeneration of benign human prostatic ductal/acinar architecture could be achieved using as few as 10 NHPrE1 cells while 200,000 BHPrE1 cells were required to achieve prostatic structure. This suggests a greater proportion of progenitor cells in NHPrE1 facilitated regeneration of prostatic morphology and function. These cell lines provide important data on progenitor and intermediate cell phenotypes and represent significant new tools for the elucidation of molecular mechanisms of human prostatic regeneration, pathogenesis and carcinogenesis.

Project description:Transcription factor p63 is a key regulator of stratified epithelia. In humans mutations in p63 are associated with developmental disorders that manifest defects in stratified epithelia including the epidermis. We established an epidermal commitment model using human pluripotent stem cells (PSCs) and characterized differentiation defects of PSCs carrying p63 mutations. Transcriptome analyses revealed distinct phases of epidermal commitment, multipotent simple epithelial, basal stratified epithelial and mature epidermal fates. Differentiation defects of p63 mutant PSCs occurred during the specification switch from the simple epithelium to the basal stratified epithelial fate. Single-cell transcriptome and pseudotime analyses identified enhanced mesodermal signatures associated with the deviated commitment route of p63 mutant PSCs. Repressing mesodermal differentiation improved epidermal commitment of PSCs. Our study demonstrate that p63 is required for specification of stratified epithelia but not sufficient for epidermal maturation. It provides insights into disease mechanisms underlying defects of stratified epithelia caused by p63 mutations.

Project description:Evaluation of gene expression changes corresponding to urogenital epithelial migration during early mouse prostatic development We used microarrays to investigate the global programme of gene expression in early mouse prostate tissue and identified necessary mediators of urogenital epithemial migration and relation to SOX9

Project description:To obtain a comprehensive view of the transcriptional programs in prostatic stromal cells of different histological/pathological origin, we profiled 18 adult human stromal cell cultures from normal transition zone (TZ), normal peripheral zone (PZ), benign prostatic hyperplasia (BPH), and prostate cancer (CA) using cDNA microarrays.

Project description:Isolation and culture of primary prostate epithelial stem/progenitor cells (PESC) has been proven difficult and ineffective. Here we present methods to grow and expand both murine and human basal PESCs long-term in serum- and feeder-free conditions. The method enriches for adherent mouse basal PESCs with a Lin-Sca1+ CD49f+Trop2high phenotype. Progesterone and sodium selenite are additionally required for the growth of human Lin-CD49f+Trop2high PESCs. The gene expression profiles of expanded basal PESCs show similarities to ES cells and Lamin B1 and PRDX1 were identified as novel PESC markers. If transplanted in combination with urogenital sinus mesenchyme, expanded mouse and human PESCs generate ectopic prostatic tubules demonstrating their stem cell activity in vivo. The novel methods will facilitate the cellular, molecular and genomic characterization of normal and pathologic prostate glands of mouse and human origin. Murine prostate cells were seperately cultured under spheroid and adherent stem cell conditions and subsequently used for RNA extraction

Project description:Isolation and culture of primary prostate epithelial stem/progenitor cells (PESC) has been proven difficult and ineffective. Here we present methods to grow and expand both murine and human basal PESCs long-term in serum- and feeder-free conditions. The method enriches for adherent mouse basal PESCs with a Lin-Sca1+ CD49f+Trop2high phenotype. Progesterone and sodium selenite are additionally required for the growth of human Lin-CD49f+Trop2high PESCs. The gene expression profiles of expanded basal PESCs show similarities to ES cells and Lamin B1 and PRDX1 were identified as novel PESC markers. If transplanted in combination with urogenital sinus mesenchyme, expanded mouse and human PESCs generate ectopic prostatic tubules demonstrating their stem cell activity in vivo. The novel methods will facilitate the cellular, molecular and genomic characterization of normal and pathologic prostate glands of mouse and human origin. Human prostate cells derived from two individual patients were seperately cultured under spheroid and adherent stem cell conditions and subsequently used for RNA extraction

Project description:Isolation and culture of primary prostate epithelial stem/progenitor cells (PESC) has been proven difficult and ineffective. Here we present methods to grow and expand both murine and human basal PESCs long-term in serum- and feeder-free conditions. The method enriches for adherent mouse basal PESCs with a Lin-Sca1+ CD49f+Trop2high phenotype. Progesterone and sodium selenite are additionally required for the growth of human Lin-CD49f+Trop2high PESCs. The gene expression profiles of expanded basal PESCs show similarities to ES cells and Lamin B1 and PRDX1 were identified as novel PESC markers. If transplanted in combination with urogenital sinus mesenchyme, expanded mouse and human PESCs generate ectopic prostatic tubules demonstrating their stem cell activity in vivo. The novel methods will facilitate the cellular, molecular and genomic characterization of normal and pathologic prostate glands of mouse and human origin.

Project description:Isolation and culture of primary prostate epithelial stem/progenitor cells (PESC) has been proven difficult and ineffective. Here we present methods to grow and expand both murine and human basal PESCs long-term in serum- and feeder-free conditions. The method enriches for adherent mouse basal PESCs with a Lin-Sca1+ CD49f+Trop2high phenotype. Progesterone and sodium selenite are additionally required for the growth of human Lin-CD49f+Trop2high PESCs. The gene expression profiles of expanded basal PESCs show similarities to ES cells and Lamin B1 and PRDX1 were identified as novel PESC markers. If transplanted in combination with urogenital sinus mesenchyme, expanded mouse and human PESCs generate ectopic prostatic tubules demonstrating their stem cell activity in vivo. The novel methods will facilitate the cellular, molecular and genomic characterization of normal and pathologic prostate glands of mouse and human origin.