Project description:Primary prostate organoid transcriptomic profile in co-culture with primary prostate stroma

Project description:The stromal microenvironment plays key roles in prostate development and cancer. Cancer associated fibroblasts (CAFs) and other stromal cells stimulate tumourigenesis via several mechanisms including the expression of pro-tumourigenic factors. Mesenchyme (embryonic stroma) controls prostate organogenesis, and in some circumstances can re-differentiate prostate tumours. Epithelia are regulated by powerful paracrine signalling from the stroma in both development and disease, and identification of these stromal signals is important. We have applied next-generation Tag profiling to fetal human prostate, normal human prostate fibroblasts (NPFs) and CAFs to identify molecules expressed in prostatic stroma Each sample was used for Tag library construction, by Solexa Inc

Project description:The stromal microenvironment plays key roles in prostate development and cancer. Cancer associated fibroblasts (CAFs) and other stromal cells stimulate tumourigenesis via several mechanisms including the expression of pro-tumourigenic factors. Mesenchyme (embryonic stroma) controls prostate organogenesis, and in some circumstances can re-differentiate prostate tumours. Epithelia are regulated by powerful paracrine signalling from the stroma in both development and disease, and identification of these stromal signals is important. We have applied next-generation Tag profiling to fetal human prostate, normal human prostate fibroblasts (NPFs) and CAFs to identify molecules expressed in prostatic stroma

Project description:Primary tumor growth induces host tissue responses that are believed to support and promote tumor progression. Identification of the molecular characteristics of the tumor microenvironment and elucidation of its crosstalk with tumor cells may therefore be crucial for improving our understanding of the processes implicated in cancer progression, identifying potential therapeutic targets, and uncovering stromal gene expression signatures that may predict clinical outcome. A key issue to resolve, therefore, is whether the stromal response to tumor growth is largely a generic phenomenon, irrespective of the tumor type, or whether the response reflects tumor-specific properties. To address similarity or distinction of stromal gene expression changes during cancer progression, oligonucleotide-based Affymetrix microarray technology was used to compare the transcriptomes of laser-microdissected stromal cells derived from invasive human breast and prostate carcinoma. Invasive breast and prostate cancer-associated stroma was observed to display distinct transcriptomes, with a limited number of shared genes. Interestingly, both breast and prostate tumor-specific dysregulated stromal genes were observed to cluster breast and prostate cancer patients, respectively, into two distinct groups with statistically different clinical outcomes. By contrast, a gene signature that was common to the reactive stroma of both tumor types did not have survival predictive value. Univariate Cox analysis identified genes whose expression level was most strongly associated with patient survival. Taken together, these observations suggest that the tumor microenvironment displays distinct features according to the tumor type that provides survival-predictive value. 6 samples of stroma surrounding invasive breast primary tumors; 6 matched samples of normal stroma. 6 samples of stroma surrounding invasive prostate primary tumors; 6 matched samples of normal stroma.

Project description:Studies centered at the intersection of embryogenesis and carcinogenesis have identified striking parallels involving signaling pathways that modulate both developmental and neoplastic processes. In the prostate, reciprocal interactions between epithelium and stroma are known to influence neoplasia and also exert morphogenic effects via the urogenital sinus mesenchyme. In this study, we sought to determine molecular relationships between aspects of normal prostate development and prostate carcinogenesis. We first characterized the gene expression program associated with key points of murine prostate organogenesis spanning the initial in utero induction of prostate budding through maturity. We identified a highly reproducible temporal program of gene expression that partitioned according to the broad developmental stages of prostate induction, branching morphogenesis, and secretory differentiation. Comparisons of gene expression profiles of murine prostate cancers arising in the context of genetically engineered alterations in the Pten tumor suppressor and Myc oncogene identified significant associations between the profile of branching morphogenesis and both cancer models. Further, the expression of genes comprising the branching morphogenesis program, such as PRDX4, SLC43A1, and DNMT3A, was significantly altered in human neoplastic prostate epithelium. These results indicate that components of normal developmental processes are active in prostate neoplasia and provide further rationale for exploiting molecular features of organogenesis to understand cancer phenotypes.

Project description:BPH-1 prostate epithelial cells when cultured in Matrigel form 3D acini which closely recapitulate the tissue architecture of the prostate. The presence of primary stroma increases epithelial adhesions and causes changes in morphology. To identify the stromal signals which control actin/cadherin dynamics in epithelial cells we performed a microarray analysis on the stroma using Affymetrix U133 plus 2.0 arrays. Primary stroma from 7 different patients were cultured with (PSE) or without (PS) 3D BPH-1 epithelial acini to determine the gene expression changes within the stroma. The RNA from the Primary epithelia and stromal cultures were used at passages 1 or 1-3, respectively.

Project description:Organs consist of not only parenchyma but also stroma, the latter of which coordinates generation of organotypic structures. Despite recent advances in organoid technology, induction of organ-specific stroma and recapitulating the complex organ configurations from pluripotent stem cells (PSCs) has remained challenging. For the kidney, the stromal progenitor coordinates differentiation of the two parenchymal progenitors: nephron progenitor and ureteric bud. By identifying the origin and dorsoventral patterning of the renal stromal progenitor, we established its induction protocol from mouse PSCs. When the three types of progenitors were differentially induced from PSCs and assembled, the all PSC-derived organoids reproduced the complex kidney structures, with multiple types of stromal cells distributed around differentiating nephrons and branching ureteric buds. Thus, integration of PSC-derived stroma into the conventional organoids enables recapitulation of organotypic architecture.

Project description:The primary goal of this study was to assess differences in gene expression between prostate cancer cell lines and normal prostate epithelial and stromal cells in primary culture. Experiment Overall Design: 9 samples were analyzed with 1 replicate each. Samples included 6 prostate cancer cell lines, 1 normal prostate epithelial cell system in primary culture, and 2 normal prostate stromal cell systems in primary culture.

Project description:We sought to determine whether molecular alterations in tumor stroma influence prostate cancer progression and metastatic potential. To accomplish this, we compared mesenchymal cells from four genetically engineered mouse models (GEMMs) of prostate cancer representing different stages of the disease to their wild-type (WT) counterparts by single-cell RNA sequencing (scRNA-seq) and, ultimately, to human tumors with comparable genotypes. We identified 8 transcriptionally and functionally distinct stromal populations responsible for both common and GEMM-specific transcriptional programs. These are conserved between mouse models and human prostate cancers with the same genomic drivers. The transcriptional profiles of the stroma of murine models of advanced disease were similar to those of human prostate cancer bone metastases, with periostin expression by stromal cells influencing invasion and neuroendocrine differentiation. These profiles were then used to build a robust gene signature that can predict metastatic progression in localized disease independent of Gleason score. Taken together, this offers new evidence that the stromal microenvironment mediates prostate cancer progression.

Project description:We sought to determine whether molecular alterations in tumor stroma influence prostate cancer progression and metastatic potential. To accomplish this, we compared mesenchymal cells from four genetically engineered mouse models (GEMMs) of prostate cancer representing different stages of the disease to their wild-type (WT) counterparts by single-cell RNA sequencing (scRNA-seq) and, ultimately, to human tumors with comparable genotypes. We identified 8 transcriptionally and functionally distinct stromal populations responsible for both common and GEMM-specific transcriptional programs. These are conserved between mouse models and human prostate cancers with the same genomic drivers. The transcriptional profiles of the stroma of murine models of advanced disease were similar to those of human prostate cancer bone metastases, with periostin expression by stromal cells influencing invasion and neuroendocrine differentiation. These profiles were then used to build a robust gene signature that can predict metastatic progression in localized disease independent of Gleason score. Taken together, this offers new evidence that the stromal microenvironment mediates prostate cancer progression.