Provided herein are methods and compositions for rapid, highly sensitive detection of SARS-CoV-2 in biological samples. In particular, provided herein is a rapid, low-cost method for detecting SARS-CoV-2 that provides reliable, visible test results and does not require PCR reagents, elaborate biosafety precautions, or sophisticated laboratory equipment.

Provided herein are methods and compositions for rapid, highly sensitive detection of SARS-CoV-2 in biological samples. In particular, provided herein is a rapid, low-cost method for detecting SARS-CoV-2 that provides reliable, visible test results and does not require PCR reagents, elaborate biosafety precautions, or sophisticated laboratory equipment.

The present invention determines lymphocyte clonality by contacting a sample comprising nucleic acid molecules (1) of lymphocytes with forward and reverse primers (10, 20) and amplifying the nucleic acid molecules (1) by performing PCR pre-amplification to form barcoded PCR products (50). The barcoded PCR products (50) are amplified using adapter-specific forward and reverse primers (30, 40) in a PCR application into amplified barcoded PCR products (60), which are sequenced. The sequence reads are demultiplexed, mapped to respective TCR or BCR clonotypes and used to determine lymphocyte clonality for the sample. The forward and/or reverse primers (10, 20) are barcoded by comprising UMIs (14, 24) protected inside hairpin loops.

The present invention determines lymphocyte clonality by contacting a sample comprising nucleic acid molecules (1) of lymphocytes with forward and reverse primers (10, 20) and amplifying the nucleic acid molecules (1) by performing PCR pre-amplification to form barcoded PCR products (50). The barcoded PCR products (50) are amplified using adapter-specific forward and reverse primers (30, 40) in a PCR application into amplified barcoded PCR products (60), which are sequenced. The sequence reads are demultiplexed, mapped to respective TCR or BCR clonotypes and used to determine lymphocyte clonality for the sample. The forward and/or reverse primers (10, 20) are barcoded by comprising UMIs (14, 24) protected inside hairpin loops.

The invention relates to methods for pairwise sequencing of a polynucleotide template which result in the sequential determination of nucleotide sequence in two distinct and separate regions of the polynucleotide template.

The invention relates to methods for pairwise sequencing of a polynucleotide template which result in the sequential determination of nucleotide sequence in two distinct and separate regions of the polynucleotide template.

The present disclosure relates to improved methods for detecting nucleic acids using DNA fingerloop stem loop structures, wherein the DNA fingerloop stem loop structures diminish base pairing of a detection probe to a mismatched target nucleic acid. The present disclosure also relates to improved methods for amplifying nucleic acids. Further disclosed are chimeric fingerloop DNAs for use in methods for modulating protein expression levels and/or RNA stability.

The present disclosure relates to improved methods for detecting nucleic acids using DNA fingerloop stem loop structures, wherein the DNA fingerloop stem loop structures diminish base pairing of a detection probe to a mismatched target nucleic acid. The present disclosure also relates to improved methods for amplifying nucleic acids. Further disclosed are chimeric fingerloop DNAs for use in methods for modulating protein expression levels and/or RNA stability.

A method for specifically and efficiently quantifying the expression of targeted RNA variants with specific terminal sequences suitable to identify multiple isoforms bearing complex heterogeneity in terminal sequences by hybridizing a 5′-Dbs-adapter to the 5′-end of target RNAs, wherein the 5′-Dbs-adapter has a stem-loop structure whose protruding 5′-end base-pairs with the 5′-end of target RNAs, and wherein the loop region of 5′-Dbs-adapter contains a base-lacking spacer which will terminate reverse transcription in a subsequent step; hybridizing a 3′Db-adapter to the 3′-end of target RNAs, wherein the 3′-Db-adapter has a stem-loop structure whose protruding 3′-end base-pairs with the 3′-end of target RNAs; ligating both adapters with target RNAs by RN12 ligation to form a “dumbbell-like” structure; and, amplifying and quantifying the ligation product by RT-PCR.

A method for specifically and efficiently quantifying the expression of targeted RNA variants with specific terminal sequences suitable to identify multiple isoforms bearing complex heterogeneity in terminal sequences by hybridizing a 5′-Dbs-adapter to the 5′-end of target RNAs, wherein the 5′-Dbs-adapter has a stem-loop structure whose protruding 5′-end base-pairs with the 5′-end of target RNAs, and wherein the loop region of 5′-Dbs-adapter contains a base-lacking spacer which will terminate reverse transcription in a subsequent step; hybridizing a 3′Db-adapter to the 3′-end of target RNAs, wherein the 3′-Db-adapter has a stem-loop structure whose protruding 3′-end base-pairs with the 3′-end of target RNAs; ligating both adapters with target RNAs by RN12 ligation to form a “dumbbell-like” structure; and, amplifying and quantifying the ligation product by RT-PCR.