The present disclosure provides materials and methods for co-determining the cellular location and nucleotide sequence of a DNA that is contacted by (or in close proximity to) a protein of interest in a single cell. Thus the present disclosure provides methods and materials wherein the cellular location of the DNA comprising a DNA-binding site or otherwise in close proximity to a protein of interest is coupled to the sequence of said DNA to provide contemporaneous imaging and sequence measurement of a protein-DNA interaction.

The present disclosure provides materials and methods for co-determining the cellular location and nucleotide sequence of a DNA that is contacted by (or in close proximity to) a protein of interest in a single cell. Thus the present disclosure provides methods and materials wherein the cellular location of the DNA comprising a DNA-binding site or otherwise in close proximity to a protein of interest is coupled to the sequence of said DNA to provide contemporaneous imaging and sequence measurement of a protein-DNA interaction.

The invention(s) cover a composition, where units of the composition are configured to interact with each other (e.g., as neighbors) in order enable decoding of positions of captured target material relative to neighboring units of the composition. In embodiments, the composition includes: a body; and a set of molecules coupled to the body, the set of molecules comprising a first subset and a second subset, wherein the first subset is structured for target analyte capture, and wherein the second subset is structured for interactions with one or more neighboring objects. The invention(s) also cover systems incorporating one or more units of the composition and methods implementing units of the composition.

The invention(s) cover a composition, where units of the composition are configured to interact with each other (e.g., as neighbors) in order enable decoding of positions of captured target material relative to neighboring units of the composition. In embodiments, the composition includes: a body; and a set of molecules coupled to the body, the set of molecules comprising a first subset and a second subset, wherein the first subset is structured for target analyte capture, and wherein the second subset is structured for interactions with one or more neighboring objects. The invention(s) also cover systems incorporating one or more units of the composition and methods implementing units of the composition.

Provided herein are compositions and methods for simultaneously measuring target oligonucleotides and protein in single cells. Compositions comprise an antibody-tagged oligonucleotide, including an origin specific barcode handle sequence, a first primer handle sequence, a second primer handle sequence, and a target binding region. The composition may also include an adapter sequence, a unique molecular identifier (UMI), and a poly-A sequence. Methods for simultaneously measuring target oligonucleotides and protein in single cells generally involve delivering a mixture of the composition to a population of cells and encapsulating individual cells in an individual discrete volume comprising PCR primers on a bead. The individual discrete volume may be suspended in a reverse transcription mixture and the nucleotide sequence of the origin specific barcode handle sequence may be detected, thereby assigning the target oligonucleotide and protein of interest to a specific individual discrete volume, while maintaining information about sample origin of the target oligonucleotide.

Provided herein are compositions and methods for simultaneously measuring target oligonucleotides and protein in single cells. Compositions comprise an antibody-tagged oligonucleotide, including an origin specific barcode handle sequence, a first primer handle sequence, a second primer handle sequence, and a target binding region. The composition may also include an adapter sequence, a unique molecular identifier (UMI), and a poly-A sequence. Methods for simultaneously measuring target oligonucleotides and protein in single cells generally involve delivering a mixture of the composition to a population of cells and encapsulating individual cells in an individual discrete volume comprising PCR primers on a bead. The individual discrete volume may be suspended in a reverse transcription mixture and the nucleotide sequence of the origin specific barcode handle sequence may be detected, thereby assigning the target oligonucleotide and protein of interest to a specific individual discrete volume, while maintaining information about sample origin of the target oligonucleotide.

The present methods are exemplified by a process in which maternal blood containing fetal DNA is diluted to a nominal value of approximately 0.5 genome equivalent of DNA per reaction sample. Digital analysis is then be used to detect aneuploidy, such as the trisomy that causes Down Syndrome. Since aneuploidies do not present a mutational change in sequence, and are merely a change in the number of chromosomes, it has not been possible to detect them in a fetus without resorting to invasive techniques such as amniocentesis or chorionic villi sampling. Digital amplification allows the detection of aneuploidy using massively parallel amplification and detection methods, examining, e.g., 10,000 genome equivalents.

The present methods are exemplified by a process in which maternal blood containing fetal DNA is diluted to a nominal value of approximately 0.5 genome equivalent of DNA per reaction sample. Digital analysis is then be used to detect aneuploidy, such as the trisomy that causes Down Syndrome. Since aneuploidies do not present a mutational change in sequence, and are merely a change in the number of chromosomes, it has not been possible to detect them in a fetus without resorting to invasive techniques such as amniocentesis or chorionic villi sampling. Digital amplification allows the detection of aneuploidy using massively parallel amplification and detection methods, examining, e.g., 10,000 genome equivalents.

Provided herein are methods and compositions for depleting targeted nucleic acid sequences from a sample, enriching for sequences of interest from a sample, and/or partitioning of sequences from a sample. The methods and compositions are applicable to biological, clinical, forensic, and environmental samples.

Provided herein are methods and compositions for depleting targeted nucleic acid sequences from a sample, enriching for sequences of interest from a sample, and/or partitioning of sequences from a sample. The methods and compositions are applicable to biological, clinical, forensic, and environmental samples.