The present invention relates to catalytic, nucleic acid nanostmctures that enable versatile detection of RNAs, their use, and devices comprising same. The nanostructure comprises a DNA polymerase enzyme, a DNA aptamer and an inverter oligonucleotide, wherein the DNA aptamer comprising (i) a conserved sequence region for binding to the DNA polymerase enzyme, wherein the binding inactivates the polymerase activity, (ii) a variable sequence region for binding to the inverter oligonucleotide, and (iii) a duplex stabilizer region that lies between the conserved sequence region and the variable sequence region. The present invention also relates to the use of the nanostructure in a method of detection of nucleic acid for diagnosing a disease in a subject.

The disclosure relates to engineered systems and methods for detecting target nucleic acid in a sample, which may be a complex mixture. The systems and methods may improve sensitivity of target nucleic acid detection by enhancing signal generation. For example, signal generation may be enhanced through programmable capture and concentration of the target nucleic acid using an engineered type III CRISPR complex. Various ancillary nucleases such as Can1, Can2, and NucC are identified and may be used for detection. For example, binding of the engineered type III CRISPR complex may produce products that activate the identified ancillary nucleases. Different activators trigger changes in the substrate specificity of these nucleases. The activated nucleases may be used to detect programmatic detection of the target nucleic in the sample. The systems and methods are shown to detect viral RNA directly from nasopharyngeal swab samples.

The disclosure relates to engineered systems and methods for detecting target nucleic acid in a sample, which may be a complex mixture. The systems and methods may improve sensitivity of target nucleic acid detection by enhancing signal generation. For example, signal generation may be enhanced through programmable capture and concentration of the target nucleic acid using an engineered type III CRISPR complex. Various ancillary nucleases such as Can1, Can2, and NucC are identified and may be used for detection. For example, binding of the engineered type III CRISPR complex may produce products that activate the identified ancillary nucleases. Different activators trigger changes in the substrate specificity of these nucleases. The activated nucleases may be used to detect programmatic detection of the target nucleic in the sample. The systems and methods are shown to detect viral RNA directly from nasopharyngeal swab samples.

The present invention encompasses a diagnostic test and method to authenticate the veracity of a vaccine. The diagnostic test and method are especially useful in a specific and sensitive immunochromatographic assay, performable within about 15 minutes for the authentication, validation, and veracity of a vaccine, such as a COVID-19 vaccine, in a vial prior to administration to a human.

The present invention encompasses a diagnostic test and method to authenticate the veracity of a vaccine. The diagnostic test and method are especially useful in a specific and sensitive immunochromatographic assay, performable within about 15 minutes for the authentication, validation, and veracity of a vaccine, such as a COVID-19 vaccine, in a vial prior to administration to a human.

Disclosed herein is a nucleic acid probe for detecting a target nucleic acid. At least one terminal of the probe-binding region in the target nucleic acid is a guanine base, and one or more cytosine bases are present within 1 to 7 bases from the guanine base. The nucleic acid probe comprises an oligonucleotide having a cytosine base facing the guanine base on a terminal and a fluorescent dye conjugated to the cytosine base. The fluorescent dye is quenched by the interaction with a guanine base. The oligonucleotide is completely complementary to the nucleic acid in the probe-binding region except the one or more cytosine bases present within 1 to 7 bases from the terminal guanine base. The base in the oligonucleotide facing the cytosine base closest to the terminal guanine base among the one or more cytosine bases is a base having no fluorescence-quenching effect.

Disclosed herein is a nucleic acid probe for detecting a target nucleic acid. At least one terminal of the probe-binding region in the target nucleic acid is a guanine base, and one or more cytosine bases are present within 1 to 7 bases from the guanine base. The nucleic acid probe comprises an oligonucleotide having a cytosine base facing the guanine base on a terminal and a fluorescent dye conjugated to the cytosine base. The fluorescent dye is quenched by the interaction with a guanine base. The oligonucleotide is completely complementary to the nucleic acid in the probe-binding region except the one or more cytosine bases present within 1 to 7 bases from the terminal guanine base. The base in the oligonucleotide facing the cytosine base closest to the terminal guanine base among the one or more cytosine bases is a base having no fluorescence-quenching effect.

In various embodiments a molecular circuit is disclosed. The circuit comprises a negative electrode, a positive electrode spaced apart from the negative electrode, and a binding probe molecule conductively attached to both the positive and negative electrodes to form a circuit having a conduction pathway through the binding probe. In various examples, the binding probe is an antibody, the Fab domain of an antibody, a protein, a nucleic acid oligomer hybridization probe, or an aptamer. The circuit may further comprise molecular arms used to wire the binding probe to the electrodes. In various embodiments, the circuit functions as a sensor wherein electrical signals, such as changes to voltage, current, impedance, conductance, or resistance in the circuit, are measured as targets interact with the binding probe. In various embodiments, the circuit provides a means to measure the presence, absence, or concentration of an analyte in a solution.

In various embodiments a molecular circuit is disclosed. The circuit comprises a negative electrode, a positive electrode spaced apart from the negative electrode, and a binding probe molecule conductively attached to both the positive and negative electrodes to form a circuit having a conduction pathway through the binding probe. In various examples, the binding probe is an antibody, the Fab domain of an antibody, a protein, a nucleic acid oligomer hybridization probe, or an aptamer. The circuit may further comprise molecular arms used to wire the binding probe to the electrodes. In various embodiments, the circuit functions as a sensor wherein electrical signals, such as changes to voltage, current, impedance, conductance, or resistance in the circuit, are measured as targets interact with the binding probe. In various embodiments, the circuit provides a means to measure the presence, absence, or concentration of an analyte in a solution.

This specification generally relates to non-radioactive methods of detecting nucleic acid polymerase activity and methods of detecting compounds that modulate nucleic acid polymerase activity. The activity may be measured in real-time using a real-time PCR instrument.