This application relates to methods for ligating oligonucleotides having complementarity to a target nucleic acid, and amplifying the ligated oligonucleotides, where ligation and amplification occur in the same reaction mixture.

A reaction mixture for providing a reaction batch for performing a quantitative real-time PCR contains at least one target DNA, which at least in parts corresponds to the DNA section being quantified, at least one reference DNA of defined sequence and in a defined amount, at least two different fluorescent probes of different sequence which generate a signal at different wavelengths, primers, deoxynucleotides and a DNA polymerase. The target DNA and the reference DNA have the same primer binding sites and different probe binding sites. At least one of the fluorescent probes is intended for binding to a section of the target DNA outside the primer binding sites in the amplicon, and at least one of the fluorescent probes is intended for binding to a section of the reference DNA outside the primer binding sites in the amplicon.

A reaction mixture for providing a reaction batch for performing a quantitative real-time PCR contains at least one target DNA, which at least in parts corresponds to the DNA section being quantified, at least one reference DNA of defined sequence and in a defined amount, at least two different fluorescent probes of different sequence which generate a signal at different wavelengths, primers, deoxynucleotides and a DNA polymerase. The target DNA and the reference DNA have the same primer binding sites and different probe binding sites. At least one of the fluorescent probes is intended for binding to a section of the target DNA outside the primer binding sites in the amplicon, and at least one of the fluorescent probes is intended for binding to a section of the reference DNA outside the primer binding sites in the amplicon.

The present invention is directed to compositions, methods and kits useful for the synthesis of nucleic acid molecules. More specifically, compositions, methods and kits are provided for the amplification of nucleic acid molecules in a one-step RT-PCR procedure comprising one or more agents used to increase tolerance to PCR inhibitors.

The present invention is directed to compositions, methods and kits useful for the synthesis of nucleic acid molecules. More specifically, compositions, methods and kits are provided for the amplification of nucleic acid molecules in a one-step RT-PCR procedure comprising one or more agents used to increase tolerance to PCR inhibitors.

The present disclosure describes improved SELEX methods for producing aptamers that are capable of binding to target molecules and improved photoSELEX methods for producing photoreactive aptamers that are capable of both binding and covalently crosslinking to target molecules. Specifically, the present disclosure describes methods for producing aptamers and photoaptamers having slower dissociation rate constants than are obtained using prior SELEX and photoSELEX methods. The disclosure further describes aptamers and photoaptamers having slower dissociation rate constants than those obtained using prior methods. In addition, the disclosure describes aptamer constructs that include a variety of functionalities, including a cleavable element, a detection element, and a capture or immobilization element.

The present disclosure describes improved SELEX methods for producing aptamers that are capable of binding to target molecules and improved photoSELEX methods for producing photoreactive aptamers that are capable of both binding and covalently crosslinking to target molecules. Specifically, the present disclosure describes methods for producing aptamers and photoaptamers having slower dissociation rate constants than are obtained using prior SELEX and photoSELEX methods. The disclosure further describes aptamers and photoaptamers having slower dissociation rate constants than those obtained using prior methods. In addition, the disclosure describes aptamer constructs that include a variety of functionalities, including a cleavable element, a detection element, and a capture or immobilization element.

This application relates to methods for ligating oligonucleotides having complementarity to a target nucleic acid, and amplifying the ligated oligonucleotides, where ligation and amplification occur in the same reaction mixture.

This application relates to methods for ligating oligonucleotides having complementarity to a target nucleic acid, and amplifying the ligated oligonucleotides, where ligation and amplification occur in the same reaction mixture.

A method for template-directed sequencing-by-synthesis of an array of target polynucleotide can include: (a) providing an array of target polynucleotides in a fluidic vessel; (b) contacting the array of polynucleotides with a solution comprising (i) polymerization complex and (ii) reversibly terminating and differently labeled A,C,G, and T/U nucleotides; (c) incorporating one of the differently labeled nucleotides, using the polymerization complex, into a chain complementary to at least one of the array of polynucleotides; (d) binding imaging tags to the differently labeled nucleotides of step (c); (e) imaging and storing the identity and position of the imaging tags of step (d); (f) reversing termination (b)-(e); (g) repeating steps (b)-(e) and assembling a sequence for each of the array of target polynucleotides from the stored identity and position of the imaging tags, optionally as a homogeneous or one pot reaction. Additional methods of sequencing target polynucleotides are described herein.