Methods for enhancing specificity of an analyte binding moiety or probe oligonucleotide to an analyte are provided herein. For example, methods provided herein include blocking a capture binding domain, thereby preventing hybridization to the capture domain of the capture probe affixed to a substrate. Further methods include releasing the block from the capture binding domain, thereby allowing the capture binding domain to specifically bind to the capture domain of the capture probe on the substrate.

The present invention provides methods, compositions and kits for assembling an enzyme-deoxyribonucleic acid (DNA) complex for use in preparing a double stranded DNA molecule comprising one or more loci of interest for determining the methylation status of the one or more loci of interest therein.

The present invention provides methods, compositions and kits for assembling an enzyme-deoxyribonucleic acid (DNA) complex for use in preparing a double stranded DNA molecule comprising one or more loci of interest for determining the methylation status of the one or more loci of interest therein.

The present disclosure relates to the field of biotechnology, in particular, to a combination product for detecting DNA. The product includes ribonuclease H II and a probe; the probe is a single-stranded probe and has a sequence which can be partially or entirely complementary to a target DNA molecule to be detected, and one or more RNA bases are embedded in the complementary region of the probe and divide the complementary region of the probe into at least two segments, each of which independently has DNA bases and base substitutions of less than or equal to 13 in total.

The present disclosure relates to the field of biotechnology, in particular, to a combination product for detecting DNA. The product includes ribonuclease H II and a probe; the probe is a single-stranded probe and has a sequence which can be partially or entirely complementary to a target DNA molecule to be detected, and one or more RNA bases are embedded in the complementary region of the probe and divide the complementary region of the probe into at least two segments, each of which independently has DNA bases and base substitutions of less than or equal to 13 in total.

This disclosure relates to biosensors, and in particular, biosensors based on nucleic acid cleaving enzymes such as ribonucleotide-cleaving DNAzymes for the detection of analytes, and methods of use.

This disclosure relates to biosensors, and in particular, biosensors based on nucleic acid cleaving enzymes such as ribonucleotide-cleaving DNAzymes for the detection of analytes, and methods of use.

A recombinant ribonuclease is disclosed. The recombinant ribonuclease is produced by introducing a recombinant DNA sequence into a host; activating expression of the recombinant DNA sequence within the host to produce the recombinant ribonuclease; and isolating the recombinant ribonuclease from the host. Additionally, a method of analyzing an RNA sequence includes digesting the RNA with a first recombinant ribonuclease to give digestion products comprising nucleotides of the RNA sequence; and analyzing the digestion products using an analytical method to provide the identity of at least some of the nucleotides. The recombinant ribonuclease includes at least one of a uridine-specific recombinant RNase MC1 and a cytidine-specific recombinant RNase Cusativin.

A recombinant ribonuclease is disclosed. The recombinant ribonuclease is produced by introducing a recombinant DNA sequence into a host; activating expression of the recombinant DNA sequence within the host to produce the recombinant ribonuclease; and isolating the recombinant ribonuclease from the host. Additionally, a method of analyzing an RNA sequence includes digesting the RNA with a first recombinant ribonuclease to give digestion products comprising nucleotides of the RNA sequence; and analyzing the digestion products using an analytical method to provide the identity of at least some of the nucleotides. The recombinant ribonuclease includes at least one of a uridine-specific recombinant RNase MC1 and a cytidine-specific recombinant RNase Cusativin.

Provided herein is a method for detecting the presence of a COVID-19 virus RNA or other pathogenic respiratory viruses, such as an influenza virus, or other RNA of interest in a sample. Nucleic acids are obtained from the sample and are used as a template in a combined isothermal reverse transcription, RNAse H and isothermal amplification reaction to generate single stranded RNA amplicons containing sequences complementary to fluorescent labeled detector probes. The single-stranded RNA amplicons hybridize to the detector probe and to hybridization probes with sequences complementary to a sequence determinant in the COVID-19 or other virus RNAs. The microarray is imaged to detect fluorescent signals thereby identifying the virus.