The present invention concerns reagents for the reversible protection of biological molecules. It relates in particular to compounds derived from azaisatoic anhydride and their uses for the protection of biological molecules, particularly enzymes, in order to block their activity. The invention also relates to the biological molecules protected in this manner and to the methods for making use of these reagents.

The present invention concerns reagents for the reversible protection of biological molecules. It relates in particular to compounds derived from azaisatoic anhydride and their uses for the protection of biological molecules, particularly enzymes, in order to block their activity. The invention also relates to the biological molecules protected in this manner and to the methods for making use of these reagents.

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.

A method of amplifying a target nucleic acid in a DNA sample comprising (a) contacting the DNA sample containing the target nucleic acid with a DNA polymerase, at least two oligonucleotide primers designed to flank the target nucleic acid, a mixture of dATP, dGTP, dCTP, and dTTP, and a conjugate comprising a DNA polymerase inhibitor covalently attached to a negative temperature sensitive polymer, (b) heating the output of step (a) to a temperature at which the conjugate precipitates and thus the DNA polymerase is no longer inhibited and (c) amplifying the target nucleic acid, e.g. by performing PCR steps of denaturing the target nucleic acid, annealing the primers to the target nucleic acid, and extending the primers, wherein step (c) is repeated at least two times. Also provided is a conjugate comprising a DNA polymerase inhibitor covalently attached to a negative temperature sensitive polymer and kits and aqueous compositions comprising the same.

This disclosure describes kits, reagents and methods for Recombinase Polymerase Amplification (RPA) of a target DNA that exploit the properties of recombinase and related proteins, to invade double-stranded DNA with single stranded homologous DNA permitting sequence specific priming of DNA polymerase reactions. The disclosed kits, reagents and methods have the advantage of not requiring thermocycling or thermophilic enzymes, thus offering easy and affordable implementation and portability relative to other amplification methods.

This disclosure describes kits, reagents and methods for Recombinase Polymerase Amplification (RPA) of a target DNA that exploit the properties of recombinase and related proteins, to invade double-stranded DNA with single stranded homologous DNA permitting sequence specific priming of DNA polymerase reactions. The disclosed kits, reagents and methods have the advantage of not requiring thermocycling or thermophilic enzymes, thus offering easy and affordable implementation and portability relative to other amplification methods.

The present invention pertains to hybrid RNase H2 proteins that include fragments of amino acid sequences from Pyrococcus abyssi (P.a.), Thermococcus kodakarensis (T.kod), and Pyrococcus furiosus organisms, as well as methods of using the same to improve mismatch discrimination and activity in a high-fidelity DNA polymerase buffer.

The present invention pertains to hybrid RNase H2 proteins that include fragments of amino acid sequences from Pyrococcus abyssi (P.a.), Thermococcus kodakarensis (T.kod), and Pyrococcus furiosus organisms, as well as methods of using the same to improve mismatch discrimination and activity in a high-fidelity DNA polymerase buffer.

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.