Described herein are methods for determining a sequence of a region of interest from an mRNA molecule. Sequenced polynucleotides can include a barcode region, a homopolymer region (e.g., a poly-A region), and a target region associated with the mRNA molecule. According to some methods, the barcode region omits the same base present in the homopolymer region. According to some methods, extension of the primer used for sequencing is stalled within the homopolymer region. According to some methods, sequencing flow cycles and the different barcode regions of the polynucleotides configured are such that the primer is extended to the end of the barcode region across the plurality of polynucleotides before being extended into the homopolymer region. According to some methods, two primers or a cleavable primer is used to separately sequence the barcode region and the target region.

Described herein are methods for determining a sequence of a region of interest from an mRNA molecule. Sequenced polynucleotides can include a barcode region, a homopolymer region (e.g., a poly-A region), and a target region associated with the mRNA molecule. According to some methods, the barcode region omits the same base present in the homopolymer region. According to some methods, extension of the primer used for sequencing is stalled within the homopolymer region. According to some methods, sequencing flow cycles and the different barcode regions of the polynucleotides configured are such that the primer is extended to the end of the barcode region across the plurality of polynucleotides before being extended into the homopolymer region. According to some methods, two primers or a cleavable primer is used to separately sequence the barcode region and the target region.

Methods of identifying test compounds or mixtures of test compounds from microbiota that bind to a fusion protein, such as a G-protein coupled receptor, are described. Also described are methods for high throughput screening of microbiota metabolites that are capable of activating G-protein coupled receptors.

Methods of identifying test compounds or mixtures of test compounds from microbiota that bind to a fusion protein, such as a G-protein coupled receptor, are described. Also described are methods for high throughput screening of microbiota metabolites that are capable of activating G-protein coupled receptors.

The present disclosure in some aspects relates to methods and compositions for accurately detecting and quantifying multiple analytes present in a biological sample. In some aspects, the methods and compositions provided herein address issues associated with the heterogeneity of analyte abundance (e.g., gene expression levels) and variations among reactions at different locations of a sample (e.g., amplification reaction starting earlier at one location than another location). In some aspects, a method disclosed herein provides a tighter distribution of signal spot size and intensity in a sample, as compared to methods that result in a wide and heterogeneous size and intensity distribution of signal spots.

The present disclosure in some aspects relates to methods and compositions for accurately detecting and quantifying multiple analytes present in a biological sample. In some aspects, the methods and compositions provided herein address issues associated with the heterogeneity of analyte abundance (e.g., gene expression levels) and variations among reactions at different locations of a sample (e.g., amplification reaction starting earlier at one location than another location). In some aspects, a method disclosed herein provides a tighter distribution of signal spot size and intensity in a sample, as compared to methods that result in a wide and heterogeneous size and intensity distribution of signal spots.

Provided herein are methods, compositions, and kits, for capturing analytes from an embedded biological sample and spatially barcoding the analytes with an array.

Provided herein are methods, compositions, and kits, for capturing analytes from an embedded biological sample and spatially barcoding the analytes with an array.

The disclosed invention is related to a universal strand-specific protocol for the sequencing preparation of all classes of RNA. The protocol allows for sequencing for dozens to more than thousands of samples simultaneously. Specifically, the disclosed invention is a method for parallel sequencing target RNA from samples from multiple sources while maintaining source identification. The method includes providing samples of RNA comprising target RNA from two or more sources; labeling, at the 3′ end, the RNA from the two or more sources with a first nucleic acid adaptor that comprises a nucleic acid sequence that differentiates between the RNA from the two or more sources; reverse transcribing the two or more sources to create a single stranded DNA comprising the nucleic acid sequence that differentiates between the RNA from the two or more sources; amplifying the single stranded DNA to create DNA amplification products that comprise the nucleic acid sequence that differentiates between the RNA from the two or more sources; sequencing the DNA amplification products thereby parallel sequencing target RNA from samples from multiple sources while maintaining source identification.

The present disclosure provides methods and kits for performing high multiplex PCR using molecular barcodes. The methods disclosed herein separately extend a set of primers (BC primers) that each comprise a target-specific sequence, a molecular barcode and a universal sequence, and amplify the resulting extension products using another set of primers (LA primers) that each comprise another target-specific sequence and a universal sequence. The methods may further comprise amplification using universal primers (preferably comprising an adapter).