Project description:Single-cell RNA sequencing facilitates quantitative analysis of mouse hematopoietic stem/progenitor cells and SCF/2i expanded cells

Project description:Metabolic products of the microbiota can alter hematopoiesis. However, the contribution and site of action of bile acids is poorly understood. Here we demonstrate that the secondary bile acids, deoxycholic acid (DCA), and lithocholic acid (LCA) increase bone marrow myelopoiesis. Treatment of bone marrow cells with DCA and LCA preferentially expanded immunophenotypic and functional (CFU-GM) granulocyte-monocyte progenitors (GMPs). DCA treatment of sorted hematopoietic stem/progenitor cells (HSPCs) increased CFU-GMs, indicating that direct exposure of HSPCs to DCA sufficed to expand GMPs. We determined that the vitamin D receptor (VDR) was required for the DCA-induced increase in CFU-GMs and GMPs. Finally, single-cell RNA sequencing revealed that DCA significantly upregulated genes associated with myeloid differentiation and proliferation in GMPs. The action of DCA on HSPCs to expand GMPs in a VDR-dependent manner suggests a mechanism for how microbiome-host interactions may directly impact bone marrow hematopoiesis and the severity of infectious and inflammatory disease.

Project description:Purpose: Investigate the transcriptomes of Tex14 heterogygous sample (with intercellular bridges intact) compared to Tex14 homozygous mutant (lacking intracellular bridges) to ascertain what effects the loss of cytoplasmic sharing has on mitotic to meiotic mouse ovary Methods: Single cell RNA sequencing libaries were created from embryonic day 13.5 mouse ovaries from Tex14 +/- and Tex14 -/- samples. Three Tex14+/- and two Tex14-/- E13.5 ovaries were pooled. Libaries were creating using 10X Chromium Single Cell 3' (v2 Chemistry) library kits per 10X posted protocols. Samples were sequenced on HiSeq 4000 (Illumina) with paired-end sequencing parameters: Read1, 98 cycles; Index1, 14 cycles; Index2, 8 cycles; and Read2, 10 cycles. Tex14+/- sample had 23,567 mean reads per cell, and Tex14-/- had 19,735 mean reads per cell. Since 10X Genomics recommends an average of 60k raw reads per cell, we submitted our two libaries for deeper sequencing. Our second sequencing run was done on a Novaseq S2 flowcell with the following parameters: Read 1 Length 26bp; Index 1 Length 8bp; Index 2 Length 0bp; Read 2 Length: 98 bp. Follwing deeper sequencing, Tex14+/- sample had 55,744 mean reads per cell, and Tex14-/- had 41,117 mean reads per cell. Cells which passed quality control metrics were further analyzed. Results: We used CellRanger v2.1.0 to align the sequenced data to the 10X Genomics pre-built mm10 genome. We mapped about 300,000,000 sequence reads for each shallowly sequenced library, and 750-800,000,000 reads for the deeply sequenced libraries. We used Seurat v3 to keep high quality cells, excluding cells which did not all of the following metrics: genes expressed in at least 3 cells, fewer than 25,000 unique fragments (to exclude cell doublets), greater than 200 genes expressed (to exclude GEMS with no cells), and cells with 7.0% or less mitochondrial gene expression. After quality control exclusion, cell counts for the gene by cell matrices are as follows: tex14 het shallow, 12260 cells; tex14 ko shallow, 14715 cells; tex14 het deep, 11794 cells; tex14 ko deep, 13982 cells. Conclusions: Our study represents the first single cell RNA sequencing experiment conducted on fetal mouse ovaries lacking intracellular bridges. We observed that the absence of Tex14 did not alter the transcriptional composition of ovarian somatic cells, but specifically attenuated the level of pluripotency-associated transcripts as germ cells enter meiosis.

Project description:Adult hematopoietic stem cells (HSCs) reside primarily in bone marrow. However, hematopoietic stresses such as myelofibrosis, anemia, pregnancy, infection or myeloablation can mobilize HSCs to the spleen and induce extramedullary hematopoiesis (EMH). While the bone marrow HSC niche has been studied intensively, the EMH niche has received little attention. Here, we systematically assessed the physiological sources of the key niche factors, SCF and CXCL12, in the mouse spleen after EMH induction by cyclophosphamide plus granulocyte colony-stimulating factor, blood loss, or pregnancy. In each case, Scf was expressed by endothelial cells and Tcf21+ stromal cells, primarily around sinusoids in red pulp, while Cxcl12 was expressed by a subset of Tcf21+ stromal cells. EMH induction markedly expanded the Scf-expressing endothelial cells and stromal cells by inducing proliferation. Most splenic HSCs were adjacent to Tcf21+ stromal cells in red pulp. Conditional deletion of Scf from spleen endothelial cells or Scf or Cxcl12 from Tcf21+ stromal cells severely reduced spleen EMH and reduced blood cell counts without affecting bone marrow hematopoiesis. Endothelial cells and Tcf21+ stromal cells thus create the splenic EMH niche, which is necessary for the physiological response to diverse hematopoietic stresses. Unfractionated spleen cells (2 replicates) and FACS-sorted VE-cadherein negative Scf-GFP positive cells (3 replicates)

Project description:WT GMPs (Lin- IL7R- Sca1- ckit+ FcgRhiCD34+) and inv(16)/KITD816Y GMPs (Lin- Sca1- ckit+ CD41- FcgR+ CD150-) were FACS sorted as described in material and methods from supplementary data (Estruch M et al 2020)

Project description:Animal R.401 was infused with ex-vivo expanded T-regulatory cells. After adoptive transfer, PBMC were obtained and stained with surface antibodies. Single cell libraries from sorted populations were generated using a UMI-based droplet-partitioning platform (10X Genomics) and sequenced using a NextSeq 500 (Illumina). Resulting reads were processed using Cellranger software (10X Genomics) and downstream analysis was performed using Monocle6,7 using a negative binomial model of distribution with fixed variance.

Project description:Total gallbladder/extrahepatic duct tissue digest from Pou2f3-/- (KO) and Pou2f3+/+, Pou2f3+/- (heterozygous and homozygous WT mice together in WT sample) littermated mice were sorted for live cells on Moflo XDP cell sorter (singlets, FSCAxSSCA, DAPI-). Immediately post-sorting, cells were run on 10X Chromium (10X Genomics) and then through library preparation by the Institute for Human Genetics at UCSF following the recommended protocol for the Chromium Single Cell 3′ Reagent Kit (v3 Chemistry). Libraries were run on the NovaSeq 6000 for Illumina sequencing. Post-processing and quality control were performed by the Genomics Core Facility at the Institute for Human Genetics at UCSF using the 10X Cell Ranger package (Cell Ranger Version 3.0.2, 10X Genomics). Primary assessment with this software for WT DC sample reported 2,441 cell-barcodes with 7,651 median unique molecular identifiers (UMIs, transcripts) per cell and 2,004 median genes per cell sequenced to 61.4% sequencing saturation with 48,559 mean reads per cell. Primary assessment with this software for MARCH1-/- DC sample reported 681 cell-barcodes with 6,309 median unique transcripts per cell and 1,774 median genes per cell sequenced to 73.1% sequencing saturation with 202,410 mean reads per cell.

Project description:Purpose: Analyzing the cytokine transcription and associated signalings of h8E5(2I)-mBBZ and h8E5(2I)-mBBZ-CXCR4 CAR T cells.Methods: Mouse h8E5(2I)-mBBZ and h8E5(2I)-mBBZ-CXCR4 CAR T cells were stimulated with antigen peptides for four hours.Results: Using an optimized data analysis workflow, we mapped about 50 million sequence reads per sample to the mouse genome

Project description:To characterize gene expression changes in AML induced by CNTRL-FGFR1, we used RNA-seq analysis of sorted Mac+Gr1+B220+ AML cells (n = 2) from the SP and BM of leukemic mice, as well as sorted Mac+Gr1+ myeloid cells (n=3) from normal mice. Methods: cDNA libraries were generated using the Illumina TruSeq RNA Sample Preparation kit following the manufacturer’s instructions. The quality of the resulting cDNA libraries were assessed using a Bioanalyzer DNA 1000 chip (Agilent) and quantified by quantitative PCR (Bio-Rad). The cDNA libraries were sequenced using paired end Illumina Hiseq2000 protocols (50 cycles). The Illumina sequencing pipeline version 1.8 was employed for transferring raw images to base calls, generating sequence reads, and de-multiplexing the reads. The generated FASTQ files were imported to CLC Genomics Workbench and aligned to the mouse genome, NCBI37/mm9. The transcript expression levels were determined in terms of number of reads per kilobase per million (RPKM) and compared between sorted normal myeloid (Gr1+Mac1+) cells and sorted leukemic myeloid cells. Results: The result showed a remarkable difference between normal (Gr1+Mac1+) and leukemic (Mac+Gr1+B220+) myeloid cells. Gene Set Enrichment Analysis and leading-edge analysis suggested that Mac+Gr1+B220+ cells have the potential to differentiate into either myeloid or T-cell, but not a B-cell, lineages. Quantitative RT-PCR analysis of lineage-specific genes showed increased expression of Flt3, Gfi1, and Kit related to early myeloid-lineage commitment, while genes related to myeloid differentiation, Irf8, Klf4, Csf1r, Myc, and Spi1 were decreased compared with normal myeloid cells. Quantitative RT-PCR also confirmed that the Cd3e and Lmo2 T-cell specific genes were markedly increased in AML cells. Conclusions: We demonstrate that the CNTRL-FGFR1 fusion kinase induces bi-lineage myeloid and T-lymphoid disease in model mice. Genetic and molecular analyses in these models demonstrated that multiple signaling pathways, specifically related to myeloid and T-lymphoid lineages, were altered in neoplasms, which underscores the importance of developing therapies that target all of these signaling pathways to eradicate the leukemia-initiating-cells

Project description:We report that ES cells cultured in ground state (2i and 2i/LIF) culture conditions are heterogeneous and show heterogeneus expression of extraembryonic markers. Using a highly sensitive reporter for the endoderm marker Hex we can sort Hex high and low populations from either serum/LIF or 2i/LIF and demonstrate that they have different functional properties. Here we explored the transcriptional basis of these functional differences and noted that Hex low (HV-) and Hex high (HV+) populations showed more distinct expression profiles in 2i/LIF than in serum/LIF. Additionally in 2i/LIF the HV+ population showed an upregulation of extraembryonic markers (such as trophoblast stem cell specific genes) and also imprinted genes compared to the HV- population, which is not observed when these populations are sorted from serum/LIF. We also analysed the transcriptional effect of LIF in 2i by analysing unsorted ES cells cultured in either 2i alone or 2i with LIF. We observed that the addition of LIF led to an upregulation of extraembryonic markers but did not effect the expression of pluripotency genes, other than Klf4. Additionally, the most significantly upregulated genes from 2i/LIF cultured ES cells compared to 2i cultured ES cells showed the greatest correlation to placental tissue when compared to the GNF tissue specific expression database. This analysis, alongside functional experiments, suggested that HV+ ES cells in 2i/LIF corresponded to an extraembryonically primed population of cells and that the addition of LIF supported this population. RNA-seq of sorted Hex low and high expressing ES cell populations cultured in serum/LIF or 2i/LIF as well as unsorted ES cells from 2i or 2i/LIF.