Aspects of the present disclosure include methods of making barcoded solid supports. In some embodiments, the methods include producing a concatemer by rolling circle amplification (RCA) of a circular nucleic acid template, where the circular nucleic acid template includes a barcode and a stem-loop forming region, and where the concatemer includes a plurality of linked units, each unit including the barcode and a stem-loop structure formed from the stem-loop forming region. Such methods further include disposing the concatemer on a solid support to produce a barcoded solid support including a plurality of the stem-loop structures extending from the surface of the solid support. The methods may further include treating the stem-loop structures with an agent that produces stem structures having ends compatible with target nucleic acids, and attaching the target nucleic acids to the stem structures. Barcoded solid supports and methods of using the barcoded solid supports are also provided.

Provided are methods for profiling cellular analytes of a cell by barcoding the cell in a combinatorial split and pool iterative process. In some instances, a cell bead may be generated from the cell, and the analytes therein barcoded in a combinatorial split and pool iterative process while the analytes are retained in the cell bead during iterative partitioning.

Provided are methods for profiling cellular analytes of a cell by barcoding the cell in a combinatorial split and pool iterative process. In some instances, a cell bead may be generated from the cell, and the analytes therein barcoded in a combinatorial split and pool iterative process while the analytes are retained in the cell bead during iterative partitioning.

Provided herein are methods for de-crosslinking fixed biological samples (e.g., fixed biological samples including aminal crosslinks). The compositions and methods disclosed can de-crosslink oligonucleotides (e.g., DNA or RNA) or proteins from fixed biological samples (e.g., fixed biological samples with aminal crosslinks), wherein the de-crosslinked biological sample is compatible with and can be used in spatial gene expression analysis.

Provided herein are methods for de-crosslinking fixed biological samples (e.g., fixed biological samples including aminal crosslinks). The compositions and methods disclosed can de-crosslink oligonucleotides (e.g., DNA or RNA) or proteins from fixed biological samples (e.g., fixed biological samples with aminal crosslinks), wherein the de-crosslinked biological sample is compatible with and can be used in spatial gene expression analysis.

Disclosed herein are methods and systems for correcting errors in sample amplification, including the errors occurred in determining the number of targets in samples. In some embodiments, the method comprises: stochastically barcoding a plurality of targets in the samples using oligonucleotides comprising stochastic barcodes to generate stochastically barcoded targets; contacting one or more defined barcoded primers with each of the one or more samples; and determining an amplification noise.

Disclosed herein are methods and systems for correcting errors in sample amplification, including the errors occurred in determining the number of targets in samples. In some embodiments, the method comprises: stochastically barcoding a plurality of targets in the samples using oligonucleotides comprising stochastic barcodes to generate stochastically barcoded targets; contacting one or more defined barcoded primers with each of the one or more samples; and determining an amplification noise.

The present invention is concerned with linear double stranded DNA, which is coupled to a single support or a tag at the 3′ end of its non-coding strand and methods for producing said linear double stranded DNA. The present invention further relates to the use of said linear double stranded DNA in an RNA in vitro transcription reaction and also to a method for producing RNA in vitro. The present invention also relates to a bioreactor for RNA in vitro transcription.

The present invention is concerned with linear double stranded DNA, which is coupled to a single support or a tag at the 3′ end of its non-coding strand and methods for producing said linear double stranded DNA. The present invention further relates to the use of said linear double stranded DNA in an RNA in vitro transcription reaction and also to a method for producing RNA in vitro. The present invention also relates to a bioreactor for RNA in vitro transcription.

The present disclosure provides methods and compositions for molecular tagging of complex populations of nucleic acid molecules. The disclosure provides methods and compositions to obtain phase information of tagged nucleic acid molecules from high-throughput nucleic acid sequencing data.