A method for spatially tagging nucleic acids of a biological specimen, including steps of (a) providing a solid support comprising different nucleic acid probes that are randomly located on the solid support, wherein the different nucleic acid probes each includes a barcode sequence that differs from the barcode sequence of other randomly located probes on the solid support; (b) performing a nucleic acid detection reaction on the solid support to locate the barcode sequences on the solid support; (c) contacting a biological specimen with the solid support that has the randomly located probes; (d) hybridizing the randomly located probes to target nucleic acids from portions of the biological specimen; and (e) modifying the randomly located probes that are hybridized to the target nucleic acids, thereby producing modified probes that include the barcode sequences and a target specific modification, thereby spatially tagging the nucleic acids of the biological specimen.

A method for spatially tagging nucleic acids of a biological specimen, including steps of (a) providing a solid support comprising different nucleic acid probes that are randomly located on the solid support, wherein the different nucleic acid probes each includes a barcode sequence that differs from the barcode sequence of other randomly located probes on the solid support; (b) performing a nucleic acid detection reaction on the solid support to locate the barcode sequences on the solid support; (c) contacting a biological specimen with the solid support that has the randomly located probes; (d) hybridizing the randomly located probes to target nucleic acids from portions of the biological specimen; and (e) modifying the randomly located probes that are hybridized to the target nucleic acids, thereby producing modified probes that include the barcode sequences and a target specific modification, thereby spatially tagging the nucleic acids of the biological specimen.

The present invention provides methods, antibodies and kits for detecting and/or quantifying expression of both non-nucleic acid molecules, such as proteins, and nucleic acid molecules in a single sample or single cell. The antibody is covalently conjugated to an oligonucleotide, such as a single-stranded DNA molecule, which comprises an identification tag and a blocking group, such as a ddNTP or an inverted dTTP, which prevents extension of the oligonucleotide by a polymerase. The method comprises the steps of reverse transcribing the conjugated oligonucleotide and the target nucleic acid simultaneously, amplifying both transcription production, and detecting the amplicons thereof. The method is also useful for detecting and/or quantifying the number of cells in a sample expressing a given non -nucleic acid molecule (e.g. protein).

The present invention provides methods, antibodies and kits for detecting and/or quantifying expression of both non-nucleic acid molecules, such as proteins, and nucleic acid molecules in a single sample or single cell. The antibody is covalently conjugated to an oligonucleotide, such as a single-stranded DNA molecule, which comprises an identification tag and a blocking group, such as a ddNTP or an inverted dTTP, which prevents extension of the oligonucleotide by a polymerase. The method comprises the steps of reverse transcribing the conjugated oligonucleotide and the target nucleic acid simultaneously, amplifying both transcription production, and detecting the amplicons thereof. The method is also useful for detecting and/or quantifying the number of cells in a sample expressing a given non -nucleic acid molecule (e.g. protein).

The invention relates to micro-particles in which polynucleotides are joined to a bead at the 3′ end and include a linker that can be cleaved to separate the polynucleotides from the bead and provide free 3′ hydroxyl groups. Also provided are arrays of polynucleotides, pluralities of micro-particles, fluidic compartments comprising micro-particles, methods of synthesising the arrays and methods of generating libraries using the array.

The invention relates to micro-particles in which polynucleotides are joined to a bead at the 3′ end and include a linker that can be cleaved to separate the polynucleotides from the bead and provide free 3′ hydroxyl groups. Also provided are arrays of polynucleotides, pluralities of micro-particles, fluidic compartments comprising micro-particles, methods of synthesising the arrays and methods of generating libraries using the array.

Provided herein, among other things, are a variety of methods for transposase-mediated tagging and amplification of short DNA fragments, e.g., between about 150 bp and 1.5 Kb in length. In some aspects, the method includes tagging the DNA fragments with a first primer sequence using barcoded transposases followed by a primer extension reaction to introduce a second primer sequence, e.g., using random or gene-specific primers. Kits for performing this method are also provided.

Provided herein, among other things, are a variety of methods for transposase-mediated tagging and amplification of short DNA fragments, e.g., between about 150 bp and 1.5 Kb in length. In some aspects, the method includes tagging the DNA fragments with a first primer sequence using barcoded transposases followed by a primer extension reaction to introduce a second primer sequence, e.g., using random or gene-specific primers. Kits for performing this method are also provided.

A system, methods, and apparatus are described to collect and prepare single cells and groups of cells from microsamples of specimens and encode spatial information of the physical position of the cells in the specimen. In some embodiment, beads or surfaces with oligonucleotides containing spatial barcodes are used to analyze DNA or RNA. The spatial barcodes allow the position of the cell to be defined and the nucleic acid sequencing information, such as target sequencing, whole genome, gene expression, used to analyze the cells in a microsample for cell type, expression pattern, DNA sequence, and other information, in the context of the cell's physical position in the specimen. In other embodiment, markers such as isotopes are added to a microsample to encode spatial position with mass spectoscopy or other analysis. The spatial encoded information is then readout by analysis such as DNA sequencing, mass spectrometry, fluorescence, or other methods.

A system, methods, and apparatus are described to collect and prepare single cells and groups of cells from microsamples of specimens and encode spatial information of the physical position of the cells in the specimen. In some embodiment, beads or surfaces with oligonucleotides containing spatial barcodes are used to analyze DNA or RNA. The spatial barcodes allow the position of the cell to be defined and the nucleic acid sequencing information, such as target sequencing, whole genome, gene expression, used to analyze the cells in a microsample for cell type, expression pattern, DNA sequence, and other information, in the context of the cell's physical position in the specimen. In other embodiment, markers such as isotopes are added to a microsample to encode spatial position with mass spectoscopy or other analysis. The spatial encoded information is then readout by analysis such as DNA sequencing, mass spectrometry, fluorescence, or other methods.