Project description:The goals of this study are to determine tissue composition of human lung organoids (hLOs) when maintained long-term (day 230). hLOs consist of alveolar epithelial cells, mesenchymal/endothelial cells, smooth muscle cells and immune cells. After dissociated hLOs, a target capture of 1x 104 cells was performed using the 10X Genomics Chromium Single Cell RNA sequencing. Briefly, single cell gel bead-in-emulsions(GEMs) are generated by passing cells with enzyme mix, partitioning oil, and barcoded gel beads by 10X Chromium chip. After GEM formation, the gel bead is dissolved and co-partitioned cell is lysed. Subsequently, reverse transcription (RT) occurs inside GEMs and barcoded full-length cDNA is generated. After RT, amplified cDNAs with barcode sequences (cell index and UMI) are pooled and single cell library is constructed using the Single Cell 3` Reagent Kit (v3 chemistry). The resulting library was sequenced on illumina HiseqX platform with 150bp paired end. Raw base calling files generated by illumine sequencing were demultiplexed based on the sample index read to generate FASTQ files using the 10X Genomics Cell Ranger (v3.0.2) pipeline. The raw reads were trimmed from the 3’ end to get the recommended number of cycle for read pairs (read1: 28bp; read2 : 91bp). The trimmed reads were mapped to the hg38 reference human genome with subsequent analysis, including filtering, barcode counting, and UMI counting. The resulting data were used to generate the multidimensional feature-barcode matrix using the CellRanger count with default parameters.

Project description:A widespread assumption for single-cell analyses specifies that one cell’s nucleic acids are predominantly captured by one oligonucleotide barcode. However, we show that ~13-21% of cell barcodes from the 10x Chromium scATAC-seq assay may have been derived from a droplet with more than one oligonucleotide sequence, which we call “barcode multiplets”. We demonstrate that barcode multiplets can be derived from at least two different sources. First, we confirm that  approximately 4% of droplets from the 10x platform may contain multiple beads. Additionally, we find that approximately 5% of beads may contain detectable levels of multiple oligonucleotide barcodes. We show that this artifact can confound single-cell analyses, including the interpretation of clonal diversity and proliferation of intra-tumor lymphocytes. Overall, our work provides a conceptual and computational framework to identify and assess the impacts of barcode multiplets in single-cell data.

Project description:Progress in sample preparation for scRNA-seq is reported based on RevGel-seq, a reversible-hydrogel technology. Barcode bead—cell tandems stabilized by a chemical linker are dispersed in the hydrogel in the liquid state. Upon gelation the tandems are immobilized, cell lysis is triggered by detergent diffusion, and RNA molecules are captured on the adjacent barcode beads. After reverse transcription and preparation for cDNA sequencing, bioinformatic analysis reveals performance quality comparable to microfluidic-based technologies.

Project description:Progress in sample preparation for scRNA-seq is reported based on RevGel-seq, a reversible-hydrogel technology. Barcode bead-cell tandems stabilized by a chemical linker are dispersed in the hydrogel in the liquid state. Upon gelation the tandems are immobilized, cell lysis is triggered by detergent diffusion, and RNA molecules are captured on the adjacent barcode beads. After reverse transcription and preparation for cDNA sequencing, bioinformatic analysis reveals performance quality comparable to microfluidic-based technologies.

Project description:Progress in sample preparation for scRNA-seq is reported based on RevGel-seq, a reversible-hydrogel technology. Barcode bead-cell tandems stabilized by a chemical linker are dispersed in the hydrogel in the liquid state. Upon gelation the tandems are immobilized, cell lysis is triggered by detergent diffusion, and RNA molecules are captured on the adjacent barcode beads. After reverse transcription and preparation for cDNA sequencing, bioinformatic analysis reveals performance quality comparable to microfluidic-based technologies.

Project description:Progress in sample preparation for scRNA-seq is reported based on RevGel-seq, a reversible-hydrogel technology. Barcode bead-cell tandems stabilized by a chemical linker are dispersed in the hydrogel in the liquid state. Upon gelation the tandems are immobilized, cell lysis is triggered by detergent diffusion, and RNA molecules are captured on the adjacent barcode beads. After reverse transcription and preparation for cDNA sequencing, bioinformatic analysis reveals performance quality comparable to microfluidic-based technologies.

Project description:Progress in sample preparation for scRNA-seq is reported based on RevGel-seq, a reversible-hydrogel technology. Barcode bead-cell tandems stabilized by a chemical linker are dispersed in the hydrogel in the liquid state. Upon gelation the tandems are immobilized, cell lysis is triggered by detergent diffusion, and RNA molecules are captured on the adjacent barcode beads. After reverse transcription and preparation for cDNA sequencing, bioinformatic analysis reveals performance quality comparable to microfluidic-based technologies.

Project description:Progress in sample preparation for scRNA-seq is reported based on RevGel-seq, a reversible-hydrogel technology. Barcode bead-cell tandems stabilized by a chemical linker are dispersed in the hydrogel in the liquid state. Upon gelation the tandems are immobilized, cell lysis is triggered by detergent diffusion, and RNA molecules are captured on the adjacent barcode beads. After reverse transcription and preparation for cDNA sequencing, bioinformatic analysis reveals performance quality comparable to microfluidic-based technologies.

Project description:Progress in sample preparation for scRNA-seq is reported based on RevGel-seq, a reversible-hydrogel technology. Barcode bead-cell tandems stabilized by a chemical linker are dispersed in the hydrogel in the liquid state. Upon gelation the tandems are immobilized, cell lysis is triggered by detergent diffusion, and RNA molecules are captured on the adjacent barcode beads. After reverse transcription and preparation for cDNA sequencing, bioinformatic analysis reveals performance quality comparable to microfluidic-based technologies.

Project description:Tissue function relies on the precise spatial organization of cells characterized by distinct molecular profiles. Single-cell RNA-Seq captures molecular profiles but not spatial organization. Conversely, spatial profiling assays to date have lacked global transcriptome information, throughput or single-cell resolution. Here, we develop High-Density Spatial Transcriptomics (HDST), a method for RNA-Seq at high spatial resolution. Spatially barcoded reverse transcription oligonucleotides are coupled to beads that are randomly deposited into tightly packed individual microsized wells on a slide. The position of each bead is decoded with sequential hybridization using complementary oligonucleotides providing a unique bead-specific spatial address. We then capture, and spatially in situ barcode, RNA from the histological tissue sections placed on the HDST array. HDST recovers hundreds of thousands of transcript-coupled spatial barcodes per experiment at 2 μm resolution. We demonstrate HDST in the mouse brain, use it to resolve spatial expression patterns and cell types, and show how to combine it with histological stains to relate expression patterns to tissue architecture and anatomy. HDST opens the way to spatial analysis of tissues at high resolution.