Project description:We report a method enabling simultaneous, ultra-high throughput single-cell-barcoding, of millions of cells for targeted single cell analysis of proteins and RNAs. This method termed Quantum Barcoding (QBC) circumvents the need to isolate single cells by building cell-specific oligo barcodes dynamically within each cell. With minimal instrumentation (four 96-well plates and a multichannel pipette) cell-specific codes are added to each tagged molecule within cells. This is accomplished through sequential rounds of the well-established process of classic “split-pool synthesis”. We demonstrate the utility of this currently research use only technology in multiple model systems.

Project description:Ultra-High Throughput Single Cell Analysis of Proteins and RNAs by Split-pool Synthesis

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Project description:We introduce microSPLiT, a low cost and high-throughput single-cell RNA-sequencing method for gram-negative and gram-positive bacteria. We applied microSPLiT to >25,000 Bacillus subtilis cells sampled at different growth stages, creating a detailed atlas of changes in metabolism and lifestyle. We not only retrieve detailed gene expression profiles associated with known, but rare, states such as competence and PBSX prophage induction, but also identify novel and unexpected gene expression states including a heterogeneous activation of a niche metabolic pathway (myo-inositol catabolism) in a subpopulation of cells.

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Project description:Cell atlas projects and high-throughput perturbation screens require single-cell sequencing at a scale that is challenging with current technology. To enable cost-effective single-cell sequencing for millions of individual cells, we developed “single-cell combinatorial fluidic indexing” (scifi). The scifi-RNA-seq assay combines one-step combinatorial pre-indexing of entire transcriptomes inside permeabilized cells with subsequent single-cell RNA-seq using microfluidics. Pre-indexing allows us to load multiple cells per droplet and bioinformatically demultiplex their individual expression profiles. Thereby, scifi-RNA-seq massively increases the throughput of droplet-based single-cell RNA-seq, and it provides a straightforward way of multiplexing thousands of samples in a single experiment. Compared to multi-round combinatorial indexing, scifi-RNA-seq provides an easier, faster, and more efficient workflow. In contrast to cell hashing methods, which flag and discard droplets containing more than one cell, scifi-RNA-seq resolves and retains individual transcriptomes from overloaded droplets.

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