A method for developing capture agents for target proteins employs a compound library to find cyclic peptide sequences that bind the target protein. The target protein is also reacted with a clickable group-provider reagent to provide the protein with clickable groups. The compounds in the library are provided with complementary clickable groups that bind the clickable group on the target protein when the peptide sequences bind the target protein. In some embodiments, the cyclic peptide sequences that bind the target protein are incorporated into constructs having one or more arms that can serve as capture agents or potential treatments against the pathogens from which the target protein is derived. Some embodiments provide pharmaceutical compositions for immunoassays, diagnostics, therapeutics or the like, that employ the constructs.

The present invention relates to methods for the identification of cell culture factors for cell maintenance and cell conversion

The present invention relates to methods for the joint analysis of regulation of gene expression and gene expression in single cells. Provided are methods for obtaining gene expression information for a single nucleus, the methods comprising deriving a DNA library from the genomic DNA in one or more nuclei and deriving an RNA library from the RNA in one or more nuclei, sequencing the molecules in the RNA library and the DNA library, and correlating the RNA library and the DNA library for each of the one or more nuclei.

The present invention relates to methods for the joint analysis of regulation of gene expression and gene expression in single cells. Provided are methods for obtaining gene expression information for a single nucleus, the methods comprising deriving a DNA library from the genomic DNA in one or more nuclei and deriving an RNA library from the RNA in one or more nuclei, sequencing the molecules in the RNA library and the DNA library, and correlating the RNA library and the DNA library for each of the one or more nuclei.

[Problem] Provided are a production method for a multi-input/multi-output-type genetic switch or a transcription factor, and a multi-input/multi-output-type genetic switch or a transcription factor. [Solving Means] The inventors of the present invention have completed a production method for a multi-input/multi-output-type genetic switch or a transcription factor, essentially including the steps of “fusing two or more transcription factor genes to each other” and “introducing mutations into the fusion-type transcription factor gene,” and have further succeeded in obtaining a multi-input/multi-output-type genetic switch or a transcription factor by the method.

Provided is a design method for dividing primer pairs into reaction containers, the design method showing an optimum division example. The design method for dividing primer pairs into reaction containers has a design step of, for a plurality of target nucleic acids, designing a plurality of primer pairs each composed of two types of primers, an evaluation step of evaluating non-specific amplification inducibility between the primer pairs, and an assignment step of performing an assignment to the reaction containers, based on the non-specific amplification inducibility, such that primer pairs having the non-specific amplification inducibility are not present in the same reaction container. The assignment step has a graph generation step of generating a graph having the primer pairs as vertices and non-specific amplification inducibility as an edge or a data structure equivalent to the graph, a coloring step of applying a solution to a graph coloring problem or the like to the graph to perform coloring such that the vertices adjacent to each other have different colors, and an association step of associating the plurality of colors with the reaction containers to associate the primer pair with the reaction containers of the corresponding colors.

The present invention relates to genomic analysis. In particular, the present invention provides methods and compositions for mapping genomic interactions.

The present disclosure provides methods of generating recombinant bacteriophage genomes. Specifically, the present technology provides methods of integrating a heterologous nucleic acid sequence into a linear bacteriophage DNA genome, and isolating recombinant bacteriophages that express the heterologous nucleic acid sequence.

Disclosed herein are methods of high-throughput screening test agents for treating a disease. Also disclosed herein are methods of high-throughput screening diseases. Systems for high-throughput screening are also disclosed herein.

The present application provides a method and a system for integrating morphological characteristics and gene expression of individual cells. The method comprises the following steps: providing a microfluidic device, which comprises a microwell array and an interdigital electrode, and each microwell comprises a plurality of capture oligonucleotides; injecting cells into the microwells, capturing a single cell and recording morphological characteristics of the cell; lysing the cell so that the mRNA released by the cell is captured by the capture oligonucleotide; reverse transcribing the captured mRNA to obtain cDNA; performing a PCR amplification reaction on the cDNA to obtain a cDNA library and sequencing the cDNA library; reading the cell barcode sequence and the unique molecular identifier sequence according to sequencing results, and the morphological characteristics and gene expression of the cell in the microwell are integrated together.