Project description:The vertebrate ectoderm gives rise to a variety of cell lineages, including neural, neural crest, placodal and non-neural cell fates. How cell fates are specified at the neural plate border (the region surrounding the neural plate) is not fully understood. We therefore carried out 10x scRNAseq of the chick epiblast to investigate cell fate specification at the neural plate border. Embryos were dissected and pooled according to stage. The tissue was then dissociated and FAC sorted to remove dead cells and remaining doublets before cells were stored in MeOH. Due to the time required to dissect embryos, multiple rounds of collections were carried out, with collections from the same stage pooled prior to 10x sequencing. Libraries were sequenced using an Illumina HiSeq 4000 at the Francis Crick Institute, London. This collection was a follow up to E-MTAB-10408.

Project description:The goal of this experiment is to compare the transcriptomic profile of CD8+ T cells isolated from the nasal cavity and whole blood at two different state, baseline and CD3/28 activated. This will allow us to characterise the unique features of CD8+ T cells in the nasal cavity. We isolated CD8+CD45RO+ T cells from fresh nasal turbinate samples and PBMCs of four healthy donors (1 Females, 45 years old; 3 Males, 24, 40 and 41 years old). Single-cell RNA sequencing was performed on both nasal and blood CD8+ CD45RO+ T cells, either directly or following overnight TCR-mediated stimulation with anti-CD3/CD28 beads.

Project description:scRNAseq experiment of mouse dendritic cells in the lung after intranasal infection with pneumonia virus of mice (7 days postnatally) or mock and/or intranasal house dust mite or PBS sensitisation (14 days postnatally). Cells were isolated when mice were 15 days old. No prior bronchoalveolar lavage was taken and mice received intravenous labeling of immune cells with CD45 to distuinguish between circulating and lung resident immune cells.

Project description:Genetic and non-genetic heterogeneity within cancer cell populations represents a major challenge to anti-cancer therapies. We currently lack robust methods to determine how pre-existing and adaptive features affect cellular responses to therapies. Here, by conducting clonal fitness mapping and transcriptional characterization using expressed barcodes and single-cell RNA-sequencing, we have developed TraCe-seq, a method that captures at clonal resolution the origin, fate, and differential early adaptive transcriptional programs of cells in a complex population in response to distinct treatments. We used TraCe-seq to benchmark how next-generation dual EGFR inhibitors-degraders compare to standard EGFR kinase inhibitors in EGFR-mutant lung cancer cells. To QC the TraCe-seq strategy, single-cell RNA-seq libraries were generated from a variety of human cancer cell lines transduced with the TraCe-seq library to validate the TraCe-seq strategy. Specifically, 5 different cell lines (PC9, MCF-10A, MDA-MB-231, NCI-H358, and NCI-H1373) were each transduced with a unique TraCe-seq barcode. The transduced cells were selected with puromycin only, dissociated to single cell suspensions, and then mixed together. The complex mixture of the 5 cell lines was profiled by 10X scRNA-seq. Furthermore, transduced NCI-H1373 cells were sorted by FACS to enrich for the top 50% of eGFP positive cells, and sorted cells were cultured briefly and used to construct scRNA-seq libraries and profiled by 10x scRNA-seq. To carry out the full TraCe-seq experiment, ~600 PC9 cells carrying unique TraCe-seq barcodes were expanded over 12 doublings to establish the barcoded population. A subset of the barcoded PC9 population was used to generate scRNA-seq libraries and profiled by 10x scRNA-seq prior to treatment to establish a baseline transcription profile for each barcoded clone. The rest of the cells were then treated for four days with 1 µM erlotinib, 1 µM GNE-069, or 1 µM GNE-104 respectively. scRNA-seq libraries were then generated form the treated cells and profiled by 10x scRNA-seq.

Project description:Single cell RNA-seq was conducted on peripheral blood mononuclear cells (PBMCs) collected from study participants that were dengue seronegative (n=3) or dengue seropositive (n=3). Baseline single cell gene expression profiling was conducted using 10x Genomics Chromium Next GEM Single Cell 3’ Reagent Kits v3.1 (Dual Index).

Project description:Spatial transcriptomic data was generated from human fetal cochleae across 10, 14, and 16 post-conceptual weeks (PCW) using the Stereo-seq platform. Fresh-frozen tissues were sectioned at 10 μm thickness and mounted on pre-chilled capture chips of 0.5×0.5 cm or 1×1 cm sizes. The protocol involved on-chip tissue fixation, permeabilization with 0.1% pepsin, and reverse transcription using a Stereo-seq-specific TSO oligonucleotide. First-strand cDNA was amplified for 15 cycles. Sequencing libraries were constructed via Tn5 transposase fragmentation of 20 ng input cDNA, followed by a 13-cycle amplification with platform-specific primers. Final libraries were sequenced on the MGI DNBSEQ-T7 platform, producing paired-end reads of 35 bp (Read1) and 100 bp (Read2) in length. Raw data was processed through the SAW pipeline (v4.1.0), with reads aligned to the GRCh38 human genome using STAR (v2.5.3). The final output is a spatial gene expression matrix where molecules are quantified by unique Molecular Identifiers (MIs) and mapped to precise spatial locations via Coordinate Identifiers (CIDs).

Project description:Spatial transcriptomic data was generated from human fetal cochleae of 16 post-conceptual weeks (PCW) using the Stereo-seq platform. Fresh-frozen tissues were sectioned at 10 μm thickness and mounted on pre-chilled capture chips of 0.5×0.5 cm or 1×1 cm sizes. The protocol involved on-chip tissue fixation, permeabilization with 0.1% pepsin, and reverse transcription using a Stereo-seq-specific TSO oligonucleotide. First-strand cDNA was amplified for 15 cycles. Sequencing libraries were constructed via Tn5 transposase fragmentation of 20 ng input cDNA, followed by a 13-cycle amplification with platform-specific primers. Final libraries were sequenced on the MGI DNBSEQ-T7 platform, producing paired-end reads of 35 bp (Read1) and 100 bp (Read2) in length. Raw data was processed through the SAW pipeline (v4.1.0), with reads aligned to the GRCh38 human genome using STAR (v2.5.3). The final output is a spatial gene expression matrix where molecules are quantified by unique Molecular Identifiers (MIs) and mapped to precise spatial locations via Coordinate Identifiers (CIDs).

Project description:We performed 10x single cell RNA-seq on sorted populations: T cell (7AAD- Calcein blue+ CD45+ THY1.1- TCRb+), fibroblasts (7AAD- Calcein Blue+ CD45- THY1.1- CD31- PDPN+), myeloid cells (7AAD- Calcein Blue+ CD45+ THY1.1- CD11b+) and tumor cells (7AAD- Calcein Blue+ CD45- THY1.1+) from cells in an orthotopic EMT6 tumor model 7 days after treatment initiation in four experimental groups: 1) Control 2) aPD-L1 3) aTGFb 4) aPD-L1 and aTGFb.

Project description:We present a new experimental and computational workflow to analyze single-cell proteomics data applied to single-cardiomyocytes. By using an optimized isolation procedure and by taking advantage of the integrative capabilities of iSanXoT application, we eliminate batch effects, minimize cell size-related biases, obtain quantitative subcellular compartment information and detect protein alterations within subcellular compartments. This approach enhances data quantification accuracy and facilitates biological interpretation. We show that the overexpression of the Myc transcription factor switches the metabolism of adult cardiomyocytes and establishes a subpopulation of pro-regenerative cardiomyocytes. The reported advances pave the way for systematic analysis of single-cell proteomes, including those of sensitive cells, like cardiomyocytes.

Project description:We present a new experimental and computational workflow to analyze single-cell proteomics data applied to single-cardiomyocytes. By using an optimized isolation procedure and by taking advantage of the integrative capabilities of iSanXoT application, we eliminate batch effects, minimize cell size-related biases, obtain quantitative subcellular compartment information and detect protein alterations within subcellular compartments. This approach enhances data quantification accuracy and facilitates biological interpretation. We show that the overexpression of the Myc transcription factor switches the metabolism of adult cardiomyocytes and establishes a subpopulation of pro-regenerative cardiomyocytes. The reported advances validate the used workflow for the systematyic analysis of single-cell proteomics data and shows its application in defining subpopulations of cells that may be prompt to regenerate based on their proteomic signature.