Single-cell sequencing provides a new level of granularity in studying the heterogeneous nature of cancer cells. For some cancers, this heterogeneity is the result of copy number changes of genes within the cellular genomes. The ability to accurately determine such copy number changes is critical in tracing and understanding tumorigenesis. Current single-cell genome sequencing methodologies infer copy numbers based on statistical approaches followed by rounding decimal numbers to integer values. Such methodologies are sample dependent, have varying calling sensitivities which heavily depend on the sample's ploidy and are sensitive to noise in sequencing data. Described herein are novel methods for reconstructing the genome of a single cell. The methods comprise fragmenting the genome using a loaded transposase, linking together fragments based on the overlapping 8-10 nucleotide genomic sequence immediately next to the transposon end to restore the order of the fragments as originally present in the genome, and reconstructing the genome by disregarding fragments that result from a defective transposase reaction and therefore cannot be linked with a neighboring fragment.

This application provides a bead with a covalently attached chemical compound and a covalently attached DNA barcode and methods for using such beads. The bead has many substantially identical copies of the chemical compound and many substantially identical copies of the DNA barcode. The compound consists of one or more chemical monomers, where the DNA barcode takes the form of barcode modules, where each module corresponds to and allows identification of a corresponding chemical monomer. The nucleic acid barcode can have a concatenated structure or an orthogonal structure. Provided are a method for sequencing the bead-bound nucleic acid barcode, for cleaving the compound from the bead, and for assessing biological activity of the released compound.

This application provides a bead with a covalently attached chemical compound and a covalently attached DNA barcode and methods for using such beads. The bead has many substantially identical copies of the chemical compound and many substantially identical copies of the DNA barcode. The compound consists of one or more chemical monomers, where the DNA barcode takes the form of barcode modules, where each module corresponds to and allows identification of a corresponding chemical monomer. The nucleic acid barcode can have a concatenated structure or an orthogonal structure. Provided are a method for sequencing the bead-bound nucleic acid barcode, for cleaving the compound from the bead, and for assessing biological activity of the released compound.

Provided are methods and compositions for detecting genome editing events at the single cell level. The methods and compositions described herein utilize sequence-based methods with combinatorial barcoding to track the identity of single cells over single or multiple genome editing events.

The present disclosure relates generally to genetically tagged bacterial delivery vehicles comprising unique tracer nucleic acid sequences (herein referred to as “tracers”) for use in detecting and/or quantitating the presence of two or more different said bacterial delivery vehicles within a mixture of vehicles. The present disclosure relates to methods wherein the bacterial delivery vehicles are detected through, for example, performance of multiple cycles of amplification using primers that bind to sequences within the unique tracer. Such methods can be advantageously used in quality control to detect and quantitate mixtures of bacterial delivery vehicles within a pharmaceutical composition.

The present disclosure relates generally to genetically tagged bacterial delivery vehicles comprising unique tracer nucleic acid sequences (herein referred to as “tracers”) for use in detecting and/or quantitating the presence of two or more different said bacterial delivery vehicles within a mixture of vehicles. The present disclosure relates to methods wherein the bacterial delivery vehicles are detected through, for example, performance of multiple cycles of amplification using primers that bind to sequences within the unique tracer. Such methods can be advantageously used in quality control to detect and quantitate mixtures of bacterial delivery vehicles within a pharmaceutical composition.

Methods, systems and related compositions are provided to perform single-cell marking of a nucleic acid and/or protein in a sample based on in-cell or in-organelle barcoding of nucleic acid and/or protein complexes of the cell or organelle; the methods and systems herein described are configured to provide in-cell or in-organelle single-cell marked nucleic acid and/or protein complexes comprising a single-cell, cell-specific, or a single-cell organelle-specific marker.

Provided is an in vitro method for making a recombinant DNA molecule. The method includes combining in vitro a recombination-site-mediated evolution (a SCRaMbLE) ready DNA polynucleotide that contains at least one transcription unit (TU) and an introduced site-specific recombinase recognition sites that can be recognized by a recombinase, with a recombinase that recognizes the site-specific recombinase recognition sites. The method results in a polynucleotide that is recombined to provide a recombined polynucleotide. The method may further include determining the sequence, or determining the expression of the recombined polynucleotide. Polynucleotides made by this process, and modified yeast that contain the modified polynucleotides, are also provided.

The present invention relates to a composition for screening various signal peptides to select specific ones that allow efficient secretion of a target protein to out of host cells. The present invention also relates to a method for selecting specific signal peptides that express a target protein in host cells and efficiently secrete the target protein to out of the host cells. The use of the composition and/or method according to the present invention enables ultrafast selection of optimal signal peptides for a target protein through barcoding sequences corresponding to the signal peptides, leading to the maximization of the production yield of the recombinant protein.

Various approaches for generating read-sets from nucleic acid molecules and segments and phasing are disclosed. Nucleic acids are assembled into complexes using binding moieties and exposed nucleic acid ends are tagged with nucleic acid tags. Read-sets can be generated from tagged nucleic acid molecules and segments. Physical linkage relationships between nucleic acid molecules and segments can be examined using the nucleic acid tags. Various approaches to generating read-sets and phasing are presented.