Project description:These datasets are test datasets of sample-multiplexed scRNA-seq, consisting of cDNA (transcriptome) and sample barcode read files: Three-sample multiplexing experiment (JS009) is a MULTI-seq dataset containing mesenchyme embryonic hind limb bud cells, embryonic stem (ES) cells, and NIH3T3 cells. Each cell sample was labelled with a distinct MULTI-seq barcode. The barcode sequences were, CATAGAGC, TCCTCGAA, and GTGTACCT for the limb bud mesenchyme cells, the ES cells, and the NIH3T3 cells, respectively. Two-sample multiplexing experiment (JS010) is a CellPlex detaset, containing ES cells and NIH3T3 cells. Each cell sample was labelled with the 3'CellPlex Kit (10X Genomics). NIH3T3 cells and ES cells were labelled with CMO301 and CMO302, respectively.

Project description:~1500 K562 cells expressing dCas9-KRAB were profiled on the 10x Genomics 3' v3 droplet-based scRNA-seq platform. The resulting library was sequenced on the Illumina and Ultima sequencing platforms.

Project description:Here, we introduce an in-silico algorithm demuxlet that harnesses naturally occurring genetic variation in a pool of cells from unrelated individuals to discover the sample identity of each cell and identify droplets containing cells from two different individuals (doublets). These two capabilities enable a simple multiplexing design that increases single cell library construction throughput by experimental design where cells from genetically diverse samples are multiplexed and captured at 2-10x over standard workflows. We further demonstrate the utility of sample multiplexing by characterizing the interindividual variability in cell type-specific responses of ~15k PBMCs to interferon-beta, a potent cytokine. Our computational tool enables sample multiplexing of droplet-based single cell RNA-seq for large-scale studies of population variation and could be extended to other single cell datasets that incorporate natural or synthetic DNA barcodes.

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:C57BL/6 mouse lymph node stromal cells were isolated for scRNA-seq, more than 2x104 cells were run on the 10X Chromium Controller (10X Genomics) to partition single cells with uniquely barcoded beads and processed for sequencing library preparation using the Chromium Single Cell 3’ Reagent Kit. cDNA libraries were sequenced on a NovaSeq 6000 sequencing system. 4 x 103 cells per sample were captured on the 10X Chromium chip. 5-10 x 104 reads/cell were obtained with characterization of 2-3 x 103 transcripts/cell.

Project description:C57BL/6 mouse lymph node stromal cells treated with anti-CD40L were isolated for scRNA-seq, more than 2x104 cells were run on the 10X Chromium Controller (10X Genomics) to partition single cells with uniquely barcoded beads and processed for sequencing library preparation using the Chromium Single Cell 3’ Reagent Kit. cDNA libraries were sequenced on a NovaSeq 6000 sequencing system. 4 x 103 cells per sample were captured on the 10X Chromium chip. 5-10 x 104 reads/cell were obtained with characterization of 2-3 x 103 transcripts/cell.

Project description:The obesity incidence is increasing worldwide with the urgent need to identify new therapeutics. Sex differences in immune cell activation drive obesity-mediated pathologies where males are more susceptible to comorbidities with exacerbated inflammation, and females are protected. The focus of this study was to identify sex-specific immune effectors that regulate obesity pathogenesis, focusing on the M2 macrophage signature gene, Resistin-like molecule α (RELMα). Here we performed single cell RNA-sequencing (scRNA-seq) on visceral adipose tissue stromal vascular fraction on wildtype and RELMα knock-out animals, both males and females, on high fat diet. We utilized the 10x Genomics 3’ CellPlex platform, to label cells with cell multiplexing oligos (CMOs) per sample in each group prior to pooling for downstream barcoding and library construction. This study revealed sex-specific and RELMα-dependent cellular targets and population differences of female and RELMα-mediated protection.

Project description:We performed single-cell transcriptome analysis with the 10X Genomic Chromium platform of CD4+ T cells infiltrating human primary and metastatic colorectal cancer (CRC) and non-small-cell lung cancer (NSCLC). Datasets derive from fresh samples collected and immediately processed by cell sorting and single-cell isolation 10X protocol. A total number of 10000 cells per sample was analyzed by scRNA-seq.

Project description:The goal of scRNA-seq is to identify the differential expressed genes in the wild-type D. discoideum at different developmental stages (vegetative, streaming, slug and fruiting bodies). Three biological replicates were assigned for each group and in total 12 groups were prepared for scRNA-seq libraries with 10000 cells as starting materials using Chromium Single Cell Gene Expression kit V3 (10x Genomics). Each sample was sequenced to an average of 393 million reads per sample with Illumina Hiseq 4000 and Novaseq 6000 platforms. The raw fastq files were processed by Cell Ranger (v 3.1.0, all with default setting except --normalize=none for aggr function) to generate the cell-barcode matrix. All downstreaming analysis was performed on R (3.6.3). Seurat package (3.1.5) was mainly used for basic analysis. Slingshot package was use for pseudotime analysis.

Project description:We reasoned that by using a distinct set of oligo-tagged antibodies against ubiquitously expressed proteins, we could uniquely label multiple populations of cells, multiplex them together, and use the barcoded antibody signal as a fingerprint. We refer to this approach as cellular "hashing", as our set of oligos defines a "look up table" to assign each multiplexed cell to its original sample. We demonstrate application of the technique to combine eight samples and run them simultaneously in a single droplet based scRNA-seq run. We show that cell hashtags allow sample multiplexing, confident multiplet identification and super-loading in the context of a commonly used droplet-based scRNA-seq method to drive down the per-cell cost of large-scale scRNA-seq experiments