This disclosure describes a technique for performing random access in a pool of polynucleotides by using one unique primer and one homopolymer primer to selectively amplify some but not all of the polynucleotides in the pool. The polynucleotides are synthesized by a template independent polymerase such as terminal deoxynucleotide transferase (TdT) rather than by phosphoramidite synthesis. Enzymatic synthesis efficiently creates homopolymer sequences through unregulated synthesis. Use of one homopolymer primer instead of two unique primers decreases the complexity, time, and cost of synthesizing the polynucleotides. Use of a unique primer provides a sequence that can be varied to uniquely identify multiple different groups of polynucleotides. This enables random access by polymerase chain reaction (PCR) amplification while still benefitting from the efficiency of homopolymer synthesis. The polynucleotides may include payload regions that use a sequence of nucleotides to encode digital data.

This disclosure describes a technique for performing random access in a pool of polynucleotides by using one unique primer and one homopolymer primer to selectively amplify some but not all of the polynucleotides in the pool. The polynucleotides are synthesized by a template independent polymerase such as terminal deoxynucleotide transferase (TdT) rather than by phosphoramidite synthesis. Enzymatic synthesis efficiently creates homopolymer sequences through unregulated synthesis. Use of one homopolymer primer instead of two unique primers decreases the complexity, time, and cost of synthesizing the polynucleotides. Use of a unique primer provides a sequence that can be varied to uniquely identify multiple different groups of polynucleotides. This enables random access by polymerase chain reaction (PCR) amplification while still benefitting from the efficiency of homopolymer synthesis. The polynucleotides may include payload regions that use a sequence of nucleotides to encode digital data.

Provided are high throughput methods for physically linking cDNA molecules derived from mRNA molecules expressed by the same cell, and libraries of linked cDNA molecules produced by the methods. The methods comprise reverse transcribing mRNA from a single cell in a first container to produce cDNA molecules, and linking the cDNA molecules in a second container. The methods unexpectedly produced libraries of cDNA molecules with an increase in the number of molecules that are correctly linked to other molecules derived from the same cell.

Provided are high throughput methods for physically linking cDNA molecules derived from mRNA molecules expressed by the same cell, and libraries of linked cDNA molecules produced by the methods. The methods comprise reverse transcribing mRNA from a single cell in a first container to produce cDNA molecules, and linking the cDNA molecules in a second container. The methods unexpectedly produced libraries of cDNA molecules with an increase in the number of molecules that are correctly linked to other molecules derived from the same cell.

This disclosure provides a powerful screening platform that combines pre-templated instant partitions with DNA-encoded library (DEL) technologies to identify target small molecule interactions and analyze their intracellular effects in single cell resolution using methods that require minimal sample preparation and affordable sequencing costs.

This disclosure provides a powerful screening platform that combines pre-templated instant partitions with DNA-encoded library (DEL) technologies to identify target small molecule interactions and analyze their intracellular effects in single cell resolution using methods that require minimal sample preparation and affordable sequencing costs.

A method for generating region-specific amplification templates of a biological sample includes adding first oligonucleotide constructs and second oligonucleotide constructs to the biological sample. Each first or second oligonucleotide construct comprises a first or a second photoremovable cage molecule. The method further includes synthesising a complementary first strand from a template bound to target binding regions of each first oligonucleotide construct or each second oligonucleotide construct, scanning a first region of interest of the biological sample with a first focused light beam and a second region of interest of the biological sample with a second focused light beam to form uncaged first oligonucleotide constructs in the first region of interest and uncaged second oligonucleotide constructs in the second region of interest, synthesising a complementary second strand to form first amplification templates originating from the first region of interest and second amplification templates originating from the second region of interest.

A method for generating region-specific amplification templates of a biological sample includes adding first oligonucleotide constructs and second oligonucleotide constructs to the biological sample. Each first or second oligonucleotide construct comprises a first or a second photoremovable cage molecule. The method further includes synthesising a complementary first strand from a template bound to target binding regions of each first oligonucleotide construct or each second oligonucleotide construct, scanning a first region of interest of the biological sample with a first focused light beam and a second region of interest of the biological sample with a second focused light beam to form uncaged first oligonucleotide constructs in the first region of interest and uncaged second oligonucleotide constructs in the second region of interest, synthesising a complementary second strand to form first amplification templates originating from the first region of interest and second amplification templates originating from the second region of interest.

The present disclosure provide compositions, methods and kits for generating a set of combinatorial barcodes, and uses thereof for barcoding samples such as single cells or genomic DNA fragments. Some embodiments disclosed herein provide compositions comprising a set of component barcodes for producing a set of combinatorial barcodes. The set of component barcodes can comprise, for example, n×m unique component barcodes, wherein n and m are integers, each of the component barcodes comprises: one of n unique barcode subunit sequences; and one or two linker sequences or the complements thereof, wherein the component barcodes are configured to connect to each other through the one or two linker sequences or the complements thereof to produce a set of combinatorial barcodes.

The present disclosure provide compositions, methods and kits for generating a set of combinatorial barcodes, and uses thereof for barcoding samples such as single cells or genomic DNA fragments. Some embodiments disclosed herein provide compositions comprising a set of component barcodes for producing a set of combinatorial barcodes. The set of component barcodes can comprise, for example, n×m unique component barcodes, wherein n and m are integers, each of the component barcodes comprises: one of n unique barcode subunit sequences; and one or two linker sequences or the complements thereof, wherein the component barcodes are configured to connect to each other through the one or two linker sequences or the complements thereof to produce a set of combinatorial barcodes.