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:Purpose: To dissect the transcriptomic profiles and unravel population-specific transcriptional heterogeneity of self renewing hair follicle stem cells in vivo Methods: We performed 10x genomics single-cell RNA sequencing (scRNA-seq) of FACS sorted CD34+/K14-H2BGFP+ hair follicle stem cells from mouse skin at mid-anagen. FACS purified CD34+/K14-H2BGFP+ single-cell suspension was processed for the barcoded single-cell 3′ cDNA libraries generation using Chromium Single Cell 3′ gel bead and library Kit v3. The final libraries were quantified using Agilent Bioanalyzer high sensitivity DNA chip and sequenced using an Illumina NextSeq-500. The raw data files were demultiplexed to generate the sample-specific FASTQ files, which were aligned to the mouse reference genome (mm10-3.0.0) using the 10x Genomics Cell Ranger pipeline (v3.1.0). The raw scRNA-seq data was processed using Cell Ranger from the 10x platform to generate an expression matrix that was further analyzed in R using the Seurat package version 3.1. Only high-quality cells that had between 200 and 5000 genes expressed and had under 10% of the UMIs mapped to mitochondrial genes were retained. Results: We obtained a total of 6736 high quality cells from two datasets for further analysis by Seurat workflow Conclusions: Obtained high quality single cell transcriptomic data to dissect molecular heterogeneity of hair follicle stem cells

Project description:This study contains single cell RNA-seq of the non-small cell lung cancer line HCC827 in three conditions. Firstly we have sequenced the RNA of single cells of a culture of HCC827 cells grown in normal conditions (POT). In our study we then evolved two arms of the cell line, one in the presence of the drug gefitinib (40nM, G1) and the other in the presence of trametinib (100nM, T4) in HYPERflasks to avoid replating. These data were analysed using cellRanger using GRCh38. Output from cellRanger was filtered for a minimum number of detected genes and UMIs. Mitochondrial reads were excluded from analysis (Acar_2020_single_cell_raw_data.txt). The data was then imported and scaled using the package Seurat. Scaled data was then filtered for low expression of housekeeping genes. Additionally genes expressed in fewer than 20 cells were excluded from analysis. Data was then renormalised using linear normalisation and scaling on the filtered raw data (Acar_2020_single_cell_processed_data.txt). Principal component analysis was run on variable genes identified using Seurat and the top 44 component were used as input for t-SNE analysis. Clusters were then identified using FindClusters in Seurat (Acar_2020_single_cell_metadata.txt). For a full description see the associated publication.

Project description:Purpose: To comprehensively characterize VE-cadherin expressing lineages during adult skin homeostasis, to dissect their population-specific transcriptomic heterogeneity, and to investigate role of Alk1 in these linegease in vivo. Methods: We performed 10x genomics single-cell RNA sequencing (scRNA-seq) of FACS sorted tdTomato+ cells from tdTomato;Cdh5-CreERT2;Krt14-H2BGFP mice (for WT) or Alk1 flox flox;tdTomato;Cdh5-CreERT2 (For Alk1KO) back skin at indicated stage/genotype. FACS purified tdTomato+ single-cell suspension was processed for the barcoded single-cell 3′ cDNA libraries generation using Chromium Single Cell 3′ gel bead and library Kit v3. The final libraries were quantified using Agilent Bioanalyzer high sensitivity DNA chip and sequenced using an Illumina NextSeq-500. The raw data files were demultiplexed to generate the sample-specific FASTQ files, which were aligned to the mouse reference genome (mm10-2020-A) using the 10x Genomics Cell Ranger pipeline (v6.0.1). The raw scRNA-seq data was processed using Cell Ranger from the 10x platform to generate expression matrix for each sample that was further analyzed in R using the Seurat package version 4.0. Only high-quality cells that had between 200 and 5000 genes expressed and had under 10% of the UMIs mapped to mitochondrial genes were retained for further analysis. Results: We obtained more than 2000 high quality cells at each stage/genotype for further analysis by Seurat pipeline Conclusions: Obtained high quality single cell transcriptomic data to dissect cellular and molecular heterogeneity of VE-cadherin expressing endothelial and non-endothelial lineages in adult mouse back skin.

Project description:Purpose: To unravel the molecular heterogeneity and characterise cell states of LRC/Non-LRC domains in interfollicular epidermis in vivo Methods: We performed 10x genomics single-cell RNA sequencing (scRNA-seq) of FACS purified basal (Sca1+/alpha6-integrin+) IFE cells as H2BGFP LRCs, mid-LRCs, and non-LRCs from K5-tTA x pTRE-H2BGFP mice. Single-cell suspension from back (2-week chase) and tail skin (3-week chase) was processed for the barcoded single-cell 3′ cDNA libraries generation using Chromium Single Cell 3′ gel bead and library Kit v3. The final libraries were quantified using Agilent Bioanalyzer high sensitivity DNA chip and sequenced using an Illumina NextSeq-500. The raw data files were demultiplexed to generate the sample-specific FASTQ files, which were aligned to the mouse reference genome (mm10-3.0.0) using the 10x Genomics Cell Ranger pipeline (v3.1.0). The raw scRNA-seq data was processed using Cell Ranger from the 10x platform to generate an expression matrix that was further analyzed in R using the Seurat package version 3.1. Only high-quality cells that had between 200 and 5000 genes expressed and had under 10% of the UMIs mapped to mitochondrial genes were retained. Results: We obtained a total of 13484 and 14884 high quality cells from two different skin types after combining two datasets each from LRCs/mid-LRCs/Non-LRCs for further analysis by Seurat workflow Conclusions: Obtained high quality single cell transcriptomic data to dissect molecular and proliferative heterogeneity of interfollicular epidermis (IFE)

Project description:For both PBMC and cells from the in vitro cultures, RNA purification and library generation was performed using the Chromium Single Cell Controller apparatus and associated protocols (10X Genomics). Libraries were sequenced by 75-bp single-end reading on a NextSeq500 sequencer (Illumina). Reads were aligned on the GRCh38 human genome assembly. Data analysis was performed using the R software package Seurat (https://github.com/satijalab/seurat)

Project description:We performed a study investigating donors previously infected with SARS-CoV-2 during the first wave of the COVID-19 pandemic to understand how vaccination may reshape T cell populations formed after infection. 10 donors were investigated using single-cell RNA-sequencing consisting of a) 3 mild non-hospitalised donors, b) 3 severe hospitalised donors, c) 1 mild recently vaccinated donor and d) 3 recently convalescent donors. For each of these groups we sampled at the following timepoints a) 6-9 months and 18 months after infection, b) 6-9 months and 18 months after infection, c) 13 months and 15 months after infection and d) 35 days after infection. All donors were unvaccinated at the first time point and vaccinated at the second time point. We stimulated PBMC with an overlapping peptide pool derived from the spike glycoprotein of the SARS-CoV-2 virus and sorted spike-specific CD4+ T cells (CD4+CD69+CD40L+) and spike-specific CD8+ T cells (CD8+CD69+4-1BB+) from every donor and time point using flow cytometry for 10X single-cell sequencing (5' protocol). Each time point from Dnr4868 was sequenced across two 10X reactions/libraries performed on the same day. Multiple samples were hashed and pooled together for sequencing using TotalSeq-C anti-human hashing antibodies from BioLegend. Individual library expression matrix files were generated using the CellRanger pipeline from 10X Genomics. The processed data file named immune.combined220929.rds is a Seurat Object containing all samples and generated using the Seurat package in R.

Project description:An equal mixture of cells from the 3 Human Lung Adenocarcinoma cell lines (H2228, NCI-H1975 and HCC827) were processed on the Chromium 3' single cell platform (10X Genomics) and sequenced on an Illumina NextSeq 500. FASTQ data were preprocessed using both scPipe and CellRanger.

Project description:This repository contains all the FASTQ files for the five data modalities (scRNA-seq, scATAC-seq, Multiome, CITE-seq+scVDJ-seq, and spatial transcriptomics) used in the article \\"An Atlas of Cells in The Human Tonsil,\\" published in Immunity in 2024. Inspired by the TCGA barcodes, we have named each fastq file with the following convention: [TECHNOLOGY].[DONOR_ID].[SUBPROJECT].[GEM_ID].[LIBRARY_ID].[LIBRARY_TYPE].[LANE].[READ].fastq.gz which allows to retrieve all metadata from the name itself. Here is a full description of each field: - TECHNOLOGY: scRNA-seq, scATAC-seq, Multiome, CITE-seq+scVDJ-seq, and spatial transcriptomics (Visium). We also include the fastq files associated with the multiome experiments performed on two mantle cell lymphoma patients (MCL). - DONOR_ID: identifier for each of the 17 patients included in the cohort. We provide the donor-level metadata in the file \\"tonsil_atlas_donor_metadata.csv\\", including the hospital, sex, age, age group, cause for tonsillectomy and cohort type for every donor. - SUBPROJECT: each subproject corresponds to one run of the 10x Genomics Chromium™ Chip. - GEM_ID: each run of the 10x Genomics Chromium™ Chip consists of up to 8 \\"GEM wells\\" (see https://www.10xgenomics.com/support/software/cell-ranger/getting-started/cr-glossary): a set of partitioned cells (Gel Beads-in-emulsion) from a single 10x Genomics Chromium™ Chip channel. We give a unique identifier to each of these channels. - LIBRARY_ID: one or more sequencing libraries can be derived from a GEM well. For instance, multiome yields two libraries (ATAC and RNA) and CITE-seq+scVDJ yields 4 libraries (RNA, ADT, BCR, TCR). - LIBRARY_TYPE: the type of library for each library_id. Note that we used cell hashing () for a subset of the scRNA-seq libraries, and thus the library_type can be \\"not_hashed\\", \\"hashed_cdna\\" (RNA expression) or \\"hashed_hto\\" (the hashtag oligonucleotides). - LANE: to increase sequencing depth, each library was sequenced in more than one lane. Important: all lanes corresponding to the same sequencing library need to be inputed together to cellranger, because they come from the same set of cells. - READ: for scATAC-seq we have three reads (R1, R2 or R3), see cellranger-atac's documentation. While we find these names to be the most useful, they need to be changed to follow cellranger's conventions. We provide a code snippet in the README file of the GitHub repository associated with the tonsil atlas to convert between both formats (https://github.com/Single-Cell-Genomics-Group-CNAG-CRG/TonsilAtlas/). Besides the fastq files, cellranger (and other mappers) require additional files, which we also provide in this repository: - cell_hashing_metadata.csv: as mentioned above, we ran cell hashing (10.1186/s13059-018-1603-1) to detect doublets and reduce cost per cell. This file provides the sequence of the hashtag oligonucleotides in cellranger convention to allow demultiplexing. - cite_seq_feature_reference.csv: similar to the previous file, this one links each protein surface marker to the hashtag oligonucleotide that identified it in the CITE-seq experiment. - V10M16-059.gpr and V19S23-039.gpr: these correspond to the two slides of the two Visium experiments performed in the tonsil atlas. They are needed to run spaceranger. - [GEM_ID]_[SLIDE]_[CAPTURE_AREA].jpg: 8 images associated with the Visium experiments. Here, GEM_ID refers to each of the 4 capture areas in each slide. - [TECHNOLOGY]_sequencing_metadata.csv: the GEM-level metadata for each technology. It includes the relationship between subproject, gem_id, library_id, library_type and donor_id. These are the other repositories associated with the tonsil atlas: - Expression and accessibility matrices: https://zenodo.org/records/10373041 - Seurat objects: https://zenodo.org/records/8373756 - HCATonsilData package: https://bioconductor.org/packages/release/data/experiment/html/HCATonsilData.html - Azimuth: https://azimuth.hubmapconsortium.org/ - Github: https://github.com/Single-Cell-Genomics-Group-CNAG-CRG/TonsilAtlas

Project description:Single human primary prostate epithelial cells grown as a monolayer (2D) or as organoids (3D) were separated, collected and prepped for RNA-seq using the 10x Genomics Chromium Genome Reagent kit v2 Chemistry. 3,500-5,000 cells were collected from each sample and sequenced at a depth of ~45,000 genes per cells on a 2x150nt lane in a HiSeq 4000. CellRanger alignment was performed to produce the RAW data files.