Bistable devices are constructed using a polynucleotide platform for sensing molecular events such as binding or conformational changes of target molecules. Uses include measurement of target concentration, measuring the effect of environmental condition (such as heat, light, or pH) on the target, or screening a library for molecules that bind the target or modulate its biological function. Devices comprise three regions: a top lid, bottom lid, and flexible linker or hinge between them. A device has an open configuration in which the top and bottom lid are separated, and a closed configuration they are bound close together. Binding domains or variations of the target molecule are fixed to a device so that when the molecular event occurs, the device switches from open to closed, or vice versa, which generates a signal. Optimal device design is determined by the signal modality (optical or electronic) used to measure closure of surface-immobilized devices.

Bistable devices are constructed using a polynucleotide platform for sensing molecular events such as binding or conformational changes of target molecules. Uses include measurement of target concentration, measuring the effect of environmental condition (such as heat, light, or pH) on the target, or screening a library for molecules that bind the target or modulate its biological function. Devices comprise three regions: a top lid, bottom lid, and flexible linker or hinge between them. A device has an open configuration in which the top and bottom lid are separated, and a closed configuration they are bound close together. Binding domains or variations of the target molecule are fixed to a device so that when the molecular event occurs, the device switches from open to closed, or vice versa, which generates a signal. Optimal device design is determined by the signal modality (optical or electronic) used to measure closure of surface-immobilized devices.

Fluorescence resonance energy transfer (FRET)-based nucleic acid sensors and methods of their use for detecting nucleic acids are provided. The sensors are highly sensitive and detect nucleic acids at the femtomolar (fM) level, without the need for labeling and amplification.

Fluorescence resonance energy transfer (FRET)-based nucleic acid sensors and methods of their use for detecting nucleic acids are provided. The sensors are highly sensitive and detect nucleic acids at the femtomolar (fM) level, without the need for labeling and amplification.

The present disclosure provides methods and compositions for surface functionalization of solid substrates. The compositions include functionalized silanes and nucleic acid constructs which may react to immobilize the nucleic acid constructs on the surface on the solid substrate. The disclosure also provides methods for immobilization of silanes and nucleic acid constructs on the surface of the substrate.

The present disclosure provides methods and compositions for surface functionalization of solid substrates. The compositions include functionalized silanes and nucleic acid constructs which may react to immobilize the nucleic acid constructs on the surface on the solid substrate. The disclosure also provides methods for immobilization of silanes and nucleic acid constructs on the surface of the substrate.

Provided herein are compositions, kits and methods for synthesis of nucleic acids. Also provided herein are compositions and methods for synthesizing strands of nucleic acid across different nucleic acid back-bones hybridized together using a strand displacing polymerase.

Provided herein are compositions, kits and methods for synthesis of nucleic acids. Also provided herein are compositions and methods for synthesizing strands of nucleic acid across different nucleic acid back-bones hybridized together using a strand displacing polymerase.

Methods, compositions, kits and apparatuses that include a fluid, the fluid containing a ternary complex and Li.sup.+, wherein the ternary complex includes a primed template nucleic acid, a polymerase, and a nucleotide cognate for the next correct base for the primed template nucleic acid molecule. As an alternative or addition to Li.sup.+, the fluid can contain betaine or a metal ion that inhibits polymerase catalysis such as Ca.sup.2+. In addition to Li.sup.+, the fluid can contain polyethylenimine (PEI) with or without betaine.

Methods, compositions, kits and apparatuses that include a fluid, the fluid containing a ternary complex and Li.sup.+, wherein the ternary complex includes a primed template nucleic acid, a polymerase, and a nucleotide cognate for the next correct base for the primed template nucleic acid molecule. As an alternative or addition to Li.sup.+, the fluid can contain betaine or a metal ion that inhibits polymerase catalysis such as Ca.sup.2+. In addition to Li.sup.+, the fluid can contain polyethylenimine (PEI) with or without betaine.