The present invention discloses a naïve antibody phage display library (APDL), a process for producing the same and a method of obtaining manufacturable antibodies as soluble Fabs from the antibody phage display library.

The present invention discloses a naïve antibody phage display library (APDL), a process for producing the same and a method of obtaining manufacturable antibodies as soluble Fabs from the antibody phage display library.

The disclosure describes novel systems, methods, and compositions for the manipulation of nucleic acids in a targeted fashion. The disclosure describes non-naturally occurring, engineered CRISPR systems, components, and methods for targeted modification of nucleic acids. Each system includes one or more protein components and one or more nucleic acid components that together target nucleic acids.

Described herein a polycistronic expression cassettes and expression vectors that include a promoter operably linked to a nucleic acid segment that encodes a Sox2 and Klf4 polypeptide. The nucleic acid segment can also encode a c-Myc polypeptide. Expression of such polycistronic expression cassettes/vectors in host cells can reprogram the host cells to stem cells or other types of reprogrammed cells.

Methods and systems are provided for massively parallel genetic analysis of single cells in emulsion droplets or reaction containers. Genetic loci of interest are targeted in a single cell using a set of probes, and a fusion complex is formed by molecular linkage and amplification techniques. Methods are provided for high-throughput, massively parallel analysis of the fusion complex in a single cell in a population of at least 10,000 cells. Also provided are methods for tracing genetic information back to a cell using barcode sequences.

Methods and systems are provided for massively parallel genetic analysis of single cells in emulsion droplets or reaction containers. Genetic loci of interest are targeted in a single cell using a set of probes, and a fusion complex is formed by molecular linkage and amplification techniques. Methods are provided for high-throughput, massively parallel analysis of the fusion complex in a single cell in a population of at least 10,000 cells. Also provided are methods for tracing genetic information back to a cell using barcode sequences.

The invention provides methods for preparing DNA sequencing libraries by assembling short read sequencing data into longer contiguous sequences for genome assembly, full length cDNA sequencing, metagenomics, and the analysis of repetitive sequences of assembled genomes.

The invention provides methods for preparing DNA sequencing libraries by assembling short read sequencing data into longer contiguous sequences for genome assembly, full length cDNA sequencing, metagenomics, and the analysis of repetitive sequences of assembled genomes.

Provided herein is a method for sample analysis. In some embodiments, the method may involve: (a) incubating a nucleic acid sample with a terminal transferase and a cyclooctene-functionalized nucleotide to produced cyclooctene-functionalized nucleic acid molecules; (b) tethering the cyclooctene-functionalized nucleic acid molecules to a tetrazine-functionalized support via an Alder cycloaddition reaction; (c) performing at least two separate primer extension reactions using the tethered nucleic acid molecules as a template to produce multiple distinct sets of primer extension products; (d) separately analyzing the sets of primer extension products using different methods to produce multiple data sets; and (e) integrating the data sets.

Provided herein is a method for sample analysis. In some embodiments, the method may involve: (a) incubating a nucleic acid sample with a terminal transferase and a cyclooctene-functionalized nucleotide to produced cyclooctene-functionalized nucleic acid molecules; (b) tethering the cyclooctene-functionalized nucleic acid molecules to a tetrazine-functionalized support via an Alder cycloaddition reaction; (c) performing at least two separate primer extension reactions using the tethered nucleic acid molecules as a template to produce multiple distinct sets of primer extension products; (d) separately analyzing the sets of primer extension products using different methods to produce multiple data sets; and (e) integrating the data sets.