Project description:Murine bronchioalveolar stem cells play a key role in pulmonary epithelial maintenance and repair but their molecular profile is poorly described so far. In this study, we used antibodies directed against Sca-1 and CD34, two markers originally ascribed to pulmonary cells harboring regenerative potential, to isolate single putative stem cells from murine lung tissue. The mean detection rate of positive cells was 8 per 106 lung cells. We then isolated and globally amplified the mRNA of positive cells to analyze gene expression in single cells. The resulting amplicons were then used for molecular profiling by transcript specific polymerase chain reaction (PCR) and global gene expression analysis using microarrays. Single marker-positive cells displayed a striking heterogeneity for the expression of epithelial and mesenchymal transcripts on the single cell level. Nevertheless, they could be subdivided into two cell populations: Sca-1+/CD34- and Sca-1+/CD34+ cells. In these subpopulations, transcripts of the epithelial marker Epcam (CD326) were exclusively detected in Sca-1+/CD34- cells (p = 0.03), whereas mRNA of the mesenchymal marker PdgfrM-NM-1 (CD140a) was detected in both subpopulations and more frequently in Sca-1+/CD34+ cells (p = 0.04). FACS analysis confirmed the existence of a PdgfrM-NM-1 positive subpopulation within Epcam+/Sca-1+/CD34- epithelial cells. Gene expression analysis by microarray hybridization identified transcripts differentially expressed between the two cell types as well as between epithelial reference cells and Sca-1+/CD34+ single cells, and selected transcripts were validated by quantitative PCR. Our results suggest a more mesenchymal commitment of Sca-1+/CD34+ cells and a more epithelial commitment of Sca-1+/CD34- cells. In summary, the study shows that single cell analysis enables the identification of novel molecular markers in yet poorly characterized populations of rare cells. Our results could further improve our understanding of Sca-1+/CD34+,- cells in the biology of the murine lung. Single cells of 10 Sca-1+/CD34+/CD31-/CD45-, 7 Sca-1+/CD34-/CD31-/CD45-, and 12 Sca-1-/CD34-/CD31-/CD45- were analyzed. Although the raw data are two channel only Cy5 signal of each file as analyzed. The Cy5 channel for each gene is normalized to the average Cy5 intensity of the gene across all samples.

Project description:Bone is the most frequent site of metastasis in prostate cancer (PCa) and patients with bone metastases are deemed incurable. Targeting prostate cancer cells that disseminated to the bone marrow (BM) prior to surgery and before metastatic outgrowth may therefore prevent lethal metastasis. This prompted us to directly analyse the transcriptome of disseminated cancer cells (DCC) isolated from non-metastatic (UICC stage M0) prostate cancer patients. We screened 105 BM samples of M0-stage prostate cancer patients and 18 BM samples of patients without malignancy for the presence of EpCAM+ single cells. In total we isolated 270 cells from both groups by micromanipulation and globally amplified their mRNA. We used targeted transcriptional profiling to unambiguously identify DCCs for subsequent in-depth analysis. Transcriptomes of all cells were examined for the expression of EPCAM, KRT8, KRT18, KRT19, KRT14, KRT6a, KRT5, KLK3 (PSA), MAGEA2, MAGEA4, PTPRC (CD45), CD33, CD34, CD19, GYPC, SCL4A1 (band 3), and HBA2. Using these transcripts we found it impossible to reliably identify true DCCs. We then applied combined genome and transcriptome analysis of single cells and found that EpCAM+ cells from controls expressed transcripts thought to be epithelial-specific, while true DCCs may express haematopoietic transcripts. These results point to an unexpected plasticity of epithelial cancer cells in bone marrow and question common transcriptional criteria to identify DCCs. Array-CGH was used to analyze EpCAM-positive single cells isolated from bone marrow of M0-stage prostate cancer patients, and individuals without cancer. The purpose was to demonstrate that cells with genomic aberrations are true tumour cells.

Project description:A set of 56 EpCAM-positive cells derived from bone marrow aspirates of breast cancer patients or patients without a cancererous disease (30 cells from 21 M0-stage and 11 cells from five M1-stage breast cancer patients, 15 cells from seven non-cancer patients serving as controls). EpCAM-positive cells from breast cancer patients were considered disseminated tumor cells as they harbored copy number alterations and showed high expression of the epithelial marker EpCAM and the mammary luminal progenitor marker KIT in comparison to EpCAM-positive bone marrow cells from non-cancer patients. Paired-end RNA-Sequencing of the samples was performed on Illumina NovaSeq6000, raw data are provided in the Fastq format.

Project description:Purpose: The goals of this study were to identify Pathways that Tregs utilize in the skin to maintain tissue homesostasis in the context of hair follcile cycling. Methods: Hair follicle stem cells (HFSCs), in the presence and absence of Tregs, were induced into cycle through a model of depilation induced anagen. HFSCs were then purified by cell sorting at day 4 post depilation based on cell surface marker expression (CD45 negative, MHC Class II negative, Sca-1 negative, EpCAM negative, CD34 Positive, Integrin alpha6 High) to generate mRNA transcription profiles. Results: Transcriptional profiling revealed a significant reduction in proliferation/differentiation associated genes expressed in HFSCs isolated from Treg depleted mice Conclusion: Our study represents the first detailed analysis of Treg modulation of tissue stem cell behaviour

Project description:Purpose: The goals of this study were to identify Pathways that Tregs utilize in the skin to maintain tissue homesostasis in the context of hair follcile cycling. Methods: Hair follicle stem cells (HFSCs), in the presence and absence of Tregs, were induced into cycle through a model of depilation induced anagen. HFSCs were then purified by cell sorting at day 4 post depilation based on cell surface marker expression (CD45 negative, MHC Class II negative, Sca-1 negative, EpCAM negative, CD34 Positive, Integrin alpha6 High) to generate mRNA transcription profiles. Results: Transcriptional profiling revealed a significant reduction in proliferation/differentiation associated genes expressed in HFSCs isolated from Treg depleted mice Conclusion: Our study represents the first detailed analysis of Treg modulation of tissue stem cell behaviour mRNA profiles of HFSC isolated from 7-10 week old WT and Foxp3-DTR mice at 4 days post depilation of dorsal skin.

Project description:Bone is the most frequent site of metastasis in prostate cancer (PCa) and patients with bone metastases are deemed incurable. Targeting prostate cancer cells that disseminated to the bone marrow (BM) prior to surgery and before metastatic outgrowth may therefore prevent lethal metastasis. This prompted us to directly analyse the transcriptome of disseminated cancer cells (DCC) isolated from non-metastatic (UICC stage M0) prostate cancer patients. We screened 105 BM samples of M0-stage prostate cancer patients and 18 BM samples of patients without malignancy for the presence of EpCAM+ single cells. In total we isolated 270 cells from both groups by micromanipulation and globally amplified their mRNA. We used targeted transcriptional profiling to unambiguously identify DCCs for subsequent in-depth analysis. Transcriptomes of all cells were examined for the expression of EPCAM, KRT8, KRT18, KRT19, KRT14, KRT6a, KRT5, KLK3 (PSA), MAGEA2, MAGEA4, PTPRC (CD45), CD33, CD34, CD19, GYPC, SCL4A1 (band 3), and HBA2. Using these transcripts we found it impossible to reliably identify true DCCs. We then applied combined genome and transcriptome analysis of single cells and found that EpCAM+ cells from controls expressed transcripts thought to be epithelial-specific, while true DCCs may express haematopoietic transcripts. These results point to an unexpected plasticity of epithelial cancer cells in bone marrow and question common transcriptional criteria to identify DCCs.

Project description:Epidermal keratinocytes were isolated from adult murine skin and FACS sorted into three populations based on their surface maker expression of alpha 6 integrin, CD34 and Sca-1. <br>- Alpha 6 positive cells constitute the entire population of basal or proliferative keratinocytes from the interfollicular epidermis and hair follicle. Both BIB and Bulge cells are contained within the total population of alpha 6 positive cells. <br>- BIB cells reside in the hair follicle in a region between the infundibulum and bulge and these cells are characterized by low alpha 6 integrin surface levels and are negative for CD34 and Sca-1 surface proteins. <br>- Bulge cells are derived from the bulge region of the hair follicle and are characterized by low + high alpha 6 integrin surface levels and are positive for CD34 but negative for Sca-1.

Project description:EpCAM is frequently overexpressed in human invasive breast cancer. We reported EpCAM overexpression to be an independent prognostic marker for poor overall survival in node-positive breast cancer. We used microarrays in order to investigate changes of the transcriptome on EpCAM gene overexpression in human breast cancer cells

Project description:Stromal-epithelial interactions play a fundamental role in tissue homeostasis, controlling cell proliferation and differentiation. The goals and objectives of this study were 1.) To generate gene expression profiles and identify signatures of freshly isolated, non-cultured, luminal epithelial or basal epithelial and CD10 positive or negative stromal cell populations from the human breast. 2.) Use the generated signatures to characterize and validate the molecular identity of human primary epithelial and stromal/mesenchymal breast cells maintained long-term in novel ex vivo culture conditions in serum free medium (previous study in our lab) Breast tissue from three different reduction mammoplasties was dissociated and single cells were labeled with antibodies against lineage markers (CD31, CD45 CD235ab), CD10, EpCAM, CD49f and DAPI. Different cell populations were identified, separated and sorted with a fluorescence activated cell sorter. Gene expression profiling of luminal epithelial (EpCAM+, CD49f+/-), basal epithelial (EPCAM-, CD49f+), CD10 negative and CD10 positive stromal cells was performed and distinct gene expression signatures for the four cell populations were identified.

Project description:We aimed to improve the efficiency of isolating endometrial epithelial and stromal cells (EMECs and EMSCs) from hysterectomy specimens. We revealed by immunohistochemical staining that the large tissue fragments remaining after collagenase treatment, which are usually discarded after the first filtration in the conventional protocol, consisted of glandular epithelial and stromal cells. Therefore, we established protease-treatment and cell suspension conditions to dissociate single cells from the tissue fragments, and isolated epithelial (EPCAM-positive) and stromal (CD13-positive) cells by fluorescence-activated cell sorting. Four independent experiments showed that, on average, 1.2 x 10^6 of EMECs and 2.8 x 10^6 EMSCs were isolated from one hysterectomy specimen. We confirmed that the isolated cells presented transcriptomic features highly similar to those of epithelial and stromal cells obtained by the conventional method. Our improved protocol facilitates future studies to better understand the epigenetic regulation underlying the dynamic changes of the endometrium during the menstrual cycle. Although protocols for the isolation of endometrial stromal and epithelial cells (EMSCs and EMECs) have been well established, the number of EMECs obtainable by the current protocols is relatively small. To improve the efficiency of isolating EMECs as well as EMSCs from endometrial tissues, we established protease-treatment and cell suspension conditions to efficiently dissociate single cells from endometrial tissue fragments, and isolated epithelial (EPCAM-positive) and stromal (CD13-positive) cells by fluorescence-activated cell sorting. By conducting a microarray-based transcriptome analysis, we confirmed that the cells isolated by the modified protocol developed in this study maintain the transcriptomic properties of endometrial epithelial and stromal cells.