Described herein are systems and methods for multiplexed analysis of two or more targets in a test sample including a first set of particles including a first set of target-specific reagents and a first optically detectable identifier capable of emitting a first wavelength indicative of a first target, and at least one second set of particles including a second set of target-specific reagents and a second optically detectable identifier capable of emitting a second wavelength indicative of a second target; and at least one optically detectable reporter probe capable of constitutively emitting a third wavelength in response to reaction of the first set of target-specific reagents with the first target in the test sample and/or reaction of the second set of target-specific reagents with the second target in the test sample, wherein the first wavelength, the second wavelength, and the third wavelength are optically discernable from one another.

Described herein are systems and methods for multiplexed analysis of two or more targets in a test sample including a first set of particles including a first set of target-specific reagents and a first optically detectable identifier capable of emitting a first wavelength indicative of a first target, and at least one second set of particles including a second set of target-specific reagents and a second optically detectable identifier capable of emitting a second wavelength indicative of a second target; and at least one optically detectable reporter probe capable of constitutively emitting a third wavelength in response to reaction of the first set of target-specific reagents with the first target in the test sample and/or reaction of the second set of target-specific reagents with the second target in the test sample, wherein the first wavelength, the second wavelength, and the third wavelength are optically discernable from one another.

The present invention provides a TNA-based probe for detecting and imaging a target miRNA in living cells. TNA-based probe is composed of a fluorophore-labeled TNA reporter strand partially hybridizing to a quencher-labeled TNA recognition strand which is designed to be antisense to the target RNA transcript via pair pairing. Upon cellular entry without the need of harmful transfection treatment, the quencher-labeled TNA recognition strand binds to targeted transcript, and these target binding events displace the reporter strand from the quencher, resulting in a discrete “turning-on” of the fluorescence. The extent of fluorescence enhancement is quantifiably related to the target RNA expression level. Additionally, the TNA-based probe shows rapid detection response, excellent selectivity and specificity toward target miRNAs and is able to distinguish the target molecules with 1-2 base mismatches.

The present invention provides a TNA-based probe for detecting and imaging a target miRNA in living cells. TNA-based probe is composed of a fluorophore-labeled TNA reporter strand partially hybridizing to a quencher-labeled TNA recognition strand which is designed to be antisense to the target RNA transcript via pair pairing. Upon cellular entry without the need of harmful transfection treatment, the quencher-labeled TNA recognition strand binds to targeted transcript, and these target binding events displace the reporter strand from the quencher, resulting in a discrete “turning-on” of the fluorescence. The extent of fluorescence enhancement is quantifiably related to the target RNA expression level. Additionally, the TNA-based probe shows rapid detection response, excellent selectivity and specificity toward target miRNAs and is able to distinguish the target molecules with 1-2 base mismatches.

Methods, assays, compositions and kits for the ligation of short polynucleotides are presented herein. The short polynucleotides are optionally no more than 7 nucleotides in length, and can be as short as 3 or 4 nucleotides in length. The ligation is optionally performed by CV ligase.

Methods, assays, compositions and kits for the ligation of short polynucleotides are presented herein. The short polynucleotides are optionally no more than 7 nucleotides in length, and can be as short as 3 or 4 nucleotides in length. The ligation is optionally performed by CV ligase.

Provided herein are methods of imaging non-repetitive genomic loci using unique guide ribonucleic acids (gRNAs), an RNA-guided nuclease, and a detectable conjugate.

Provided herein are methods of imaging non-repetitive genomic loci using unique guide ribonucleic acids (gRNAs), an RNA-guided nuclease, and a detectable conjugate.

Provided herein are methods, compositions, and systems for multiplexed analysis of individual cells or cell populations. Cells encapsulated in beads and/or biomolecules are sequentially co-partitioned, allowing for analysis of two different types of biomolecules (e.g., RNA and DNA). The present invention leverages different polymer dissociation mechanisms, accompanied with barcoding of biomolecules (e.g., nucleic acid molecules) for multiplexed measurements in single cells. Sequential co-partitioning and barcode technology enables identification and quantitation of DNA and RNA from single cells.

Provided in the present invention is a composition capable of detecting and typing novel coronavirus 2019-nCoV, coronavirus 229E, coronavirus NL63, coronavirus OC43, coronavirus HKU1, coronavirus MERSr-CoV, and coronavirus SARSr-CoV. At the same time, further provided is a kit comprising the composition and a method for detecting and typing coronaviruses. The composition of the present invention in combination with a fluorescent probe method and a melting curve method can perform simultaneous detection and typing of seven coronaviruses in one tube.