The present disclosure provides methods of processing or analyzing a sample. A method for processing a sample may comprise hybridizing a probe molecule to a target region of a nucleic acid molecule (e.g., a ribonucleic acid (RNA) molecule), barcoding the probe-nucleic acid molecule complex, and performing extension, denaturation, and amplification processes. A method for processing a sample may comprise hybridizing first and second probes to adjacent or non-adjacent target regions of a nucleic acid molecule (e.g., an RNA molecule), linking the first and second probes to provide a probe-linked nucleic acid molecule, and barcoding the probe-linked nucleic acid molecule. One or more processes of the methods described herein may be performed within a partition, such as a droplet or well. One or more processes of the methods described herein may be performed on a cell, such as a permeabilized cell.

The present disclosure provides a high-throughput screening system and method for identification of novel drugs and drug targets. The method enables large-scale analysis of interactions between allogeneic pairs of target cells and immune cells by using an immune-bridge protein, library of guide RNA, and/or 3D tumor model.

The disclosure provides for methods, compositions, and kits for multiplex nucleic acid analysis of single cells. The methods, compositions and systems may be used for massively parallel single cell sequencing. The methods, compositions and systems may be used to analyze thousands of cells concurrently. The thousands of cells may comprise a mixed population of cells (e.g., cells of different types or subtypes, different sizes).

The disclosure provides for methods, compositions, and kits for multiplex nucleic acid analysis of single cells. The methods, compositions and systems may be used for massively parallel single cell sequencing. The methods, compositions and systems may be used to analyze thousands of cells concurrently. The thousands of cells may comprise a mixed population of cells (e.g., cells of different types or subtypes, different sizes).

Disclosed herein are methods and compositions for generating a repertoire of recombinant fusion polypeptides from immune cells, and uses thereof.

The invention provides barcode libraries and methods of making and using them including obtaining a plurality of nucleic acid constructs in which each construct comprises a unique N-mer and a functional N-mer and segregating the constructs into a fluid compartments such that each compartment contains one or more copies of a unique construct. The invention further provides methods for digital PCR and for use of barcode libraries in digital PCR.

Provided are high throughput methods for physically linking cDNA molecules derived from mRNA molecules expressed by the same cell, and libraries of linked cDNA molecules produced by the methods. The methods comprise reverse transcribing mRNA from a single cell in a first container to produce cDNA molecules, and linking the cDNA molecules in a second container. The methods unexpectedly produced libraries of cDNA molecules with an increase in the number of molecules that are correctly linked to other molecules derived from the same cell.

Provided are high throughput methods for physically linking cDNA molecules derived from mRNA molecules expressed by the same cell, and libraries of linked cDNA molecules produced by the methods. The methods comprise reverse transcribing mRNA from a single cell in a first container to produce cDNA molecules, and linking the cDNA molecules in a second container. The methods unexpectedly produced libraries of cDNA molecules with an increase in the number of molecules that are correctly linked to other molecules derived from the same cell.

This disclosure provides a decentralized workflow for analyzing single cell gene expression. The workflow makes use of pre-templated instant partitions to segregate cells into separate compartments to individually capture and barcode RNA from single cells in a massively parallel single tube format. The workflow includes steps for processing the RNA from the single cells for sequencing. Separate portions of the decentralized workflow are performed by a research lab and a core facility, allowing increased flexibility in time and location of protocol steps.

This disclosure provides a decentralized workflow for analyzing single cell gene expression. The workflow makes use of pre-templated instant partitions to segregate cells into separate compartments to individually capture and barcode RNA from single cells in a massively parallel single tube format. The workflow includes steps for processing the RNA from the single cells for sequencing. Separate portions of the decentralized workflow are performed by a research lab and a core facility, allowing increased flexibility in time and location of protocol steps.