A method for testing a sample for the presence of one or more targets comprises multiplexed catalyzed reporter deposition (CARD) is provided.

The invention provides a method of identifying a peptide interaction site on a target protein wherein the target protein modulates the phenotype of a mammalian cell, using mammalian encoded peptides (SEPs) such as short open reading frame (sORF) encoded peptides. The invention further provides a method for the identification of new therapeutic targets and protein interaction sites for use in drug discovery.

The invention provides a method of identifying a peptide interaction site on a target protein wherein the target protein modulates the phenotype of a mammalian cell, using mammalian encoded peptides (SEPs) such as short open reading frame (sORF) encoded peptides. The invention further provides a method for the identification of new therapeutic targets and protein interaction sites for use in drug discovery.

The disclosure relates to a method for specific detection of a target analyte using probe DNA specific to the target analyte and non-functionalized, carbohydrate-capped metal nanoparticles such as non-functionalized, dextrin-capped gold nanoparticles. A sample mixture including a target DNA analyte and a probe DNA specific thereto is incubated to from a probe DNA-target DNA complex. The non-functionalized, carbohydrate-capped metal nanoparticles and an ionic species such as sodium chloride or other salt are added to the probe DNA-target DNA complex, and the mixture is incubated. Addition of the ionic species creates a detectable distinction, such as color of the resultant mixture, between stabilized metal nanoparticles when the probe DNA-target DNA complex is present and destabilized metal nanoparticles when the probe DNA-target DNA complex is absent. The method can be used for colorimetric detection of plant pathogens and associated diseases in agricultural production systems.

The disclosure relates to a method for specific detection of a target analyte using probe DNA specific to the target analyte and non-functionalized, carbohydrate-capped metal nanoparticles such as non-functionalized, dextrin-capped gold nanoparticles. A sample mixture including a target DNA analyte and a probe DNA specific thereto is incubated to from a probe DNA-target DNA complex. The non-functionalized, carbohydrate-capped metal nanoparticles and an ionic species such as sodium chloride or other salt are added to the probe DNA-target DNA complex, and the mixture is incubated. Addition of the ionic species creates a detectable distinction, such as color of the resultant mixture, between stabilized metal nanoparticles when the probe DNA-target DNA complex is present and destabilized metal nanoparticles when the probe DNA-target DNA complex is absent. The method can be used for colorimetric detection of plant pathogens and associated diseases in agricultural production systems.

Disclosed herein is a G protein-coupled receptor (GPCR) assay platform comprised of two complementary systems that equate dynamic intermolecular interactions between a receptor and transducer with more complex stimulus-response cascades in living cells. In the disclosed in vitro ADSoRB method, the forced dissociation of transducers like G protein heterotrimers from receptors alters receptor conformations and ligand interactions to simulate pathway activation in a cell. In the disclosed TRUPATH method, measuring the extent of engineered G protein heterotrimer complex dissociation provides single transducer resolution in a cell.

Disclosed herein is a G protein-coupled receptor (GPCR) assay platform comprised of two complementary systems that equate dynamic intermolecular interactions between a receptor and transducer with more complex stimulus-response cascades in living cells. In the disclosed in vitro ADSoRB method, the forced dissociation of transducers like G protein heterotrimers from receptors alters receptor conformations and ligand interactions to simulate pathway activation in a cell. In the disclosed TRUPATH method, measuring the extent of engineered G protein heterotrimer complex dissociation provides single transducer resolution in a cell.

The present invention is to provide a method for hybridization of a photo-responsive oligonucleotide to a nucleic acid by providing the nucleic acid with a complementary oligonucleotide, wherein the oligonucleotide functions as a starting point for a polymerase for nucleic acid synthesis characterized in that the photo-responsive oligonucleotide comprises at least two photo-responsive elements which change from a first to a second conformation upon irradiation with light thereby disabling or enabling the oligonucleotide hybridization. In addition to that, the current invention provides a method for spatially controlled oligonucleotide hybridization to specific sites by spatial illumination of areas of no interest, thus changing the oligonucleotide conformation to a non-binding state. The reversable hybridization of the oligonucleotide can be used for controlling several reactions such as rolling circle amplification and a sequencing reaction.

The present invention is to provide a method for hybridization of a photo-responsive oligonucleotide to a nucleic acid by providing the nucleic acid with a complementary oligonucleotide, wherein the oligonucleotide functions as a starting point for a polymerase for nucleic acid synthesis characterized in that the photo-responsive oligonucleotide comprises at least two photo-responsive elements which change from a first to a second conformation upon irradiation with light thereby disabling or enabling the oligonucleotide hybridization. In addition to that, the current invention provides a method for spatially controlled oligonucleotide hybridization to specific sites by spatial illumination of areas of no interest, thus changing the oligonucleotide conformation to a non-binding state. The reversable hybridization of the oligonucleotide can be used for controlling several reactions such as rolling circle amplification and a sequencing reaction.

Provided are microparticle probes for isolating and detecting nucleic acids to detect target nucleic acids. Each of the microparticle probes includes: a microparticle; capture probes introduced on the surface of the microparticle and including sequences complementary to those of the target nucleic acids; and reporter nucleic acids introduced on the surface of the microparticle and generating signals in response to an external stimulus. Also provided are a kit including the microparticle probes, a method for detecting target nucleic acids, and a multiplex diagnostic method. The microparticle probes of the present invention enable rapid identification of multiple viral infections such as respiratory syncytial virus (RSV), influenza, and coronavirus infections and can be used to accurately determine diseases (infectious diseases) with high sensitivity.