The invention, in part, includes compositions comprising quadruplet decoding tRNAs and their encoding sequences. The invention also includes assay methods to assess quadruplet decoding as well as methods of preparing quadruplet decoding suppression tRNAs.

Compositions comprising aptamers capable of specifically binding to a surface protein of Clostridium difficile spore are provided. A method for detecting, enriching, separating, and/or isolating Clostridium difficile spores is provided.

Compositions comprising aptamers capable of specifically binding to a surface protein of Clostridium difficile spore are provided. A method for detecting, enriching, separating, and/or isolating Clostridium difficile spores is provided.

The purpose of the present invention is to provide an aptamer to a cancer cell, said aptamer being superior to conventional aptamers in binding ability, specificity, and/or stability. To solve this problem, provided is a DNA aptamer binding to a cancer cell, said DNA aptamer containing an artificial base(s).

The invention provides xeno-nucleic acid particle display libraries, methods for identifying functional non-natural nucleic acid (XNA) aptamers using the particle display libraries, and compositions comprising XNA aptamers identified by screening candidate molecules using the xeno-nucleic acid particle display libraries.

Provided herein are methods for selection of circular aptamers using a circular nucleic acid library. Also provided are circular aptamers, circular aptamer probes, biosensor systems, and the methods for their use in detecting a microorganism target, or a target molecule present on or generated from a microorganism or a virus in a test sample, including C. difficile glutamate dehydrogenase and methods for determining whether a subject has a C. difficile infection.

Provided are a novel nucleic acid structure, its use as an aptamer template, and a method for preparing an aptamer using thereof.

The subject invention provides methods, assays, and products for detecting small molecules in a sample, in particular, in both clinical and field settings. The method for detecting a small-molecule target, preferably, a synthetic cathinone in a sample comprises contacting the sample with an aptamer-based sensor selective for the small-molecule target, and detecting the small-molecule target in the sample. Specifically, the method utilizes an aptamer-based sensor comprising a dye binding to a three-way junction binding domain of an aptamer. Binding of small-molecule target to the aptamer displaces the dye, generating a spectroscopic signal that can be used for detection of the small-molecule target and quantitative measurement of the target concentration.

The present invention relates functional ligands to target molecules, particularly to functional nucleic acids and modifications thereof, and to methods for simultaneously generating, for example, numerous different functional biomolecules, particularly to methods for generating numerous different functional nucleic acids against multiple target molecules simultaneously. The present invention further relates to functional ligands which bind with affinity to target molecules, such as molecules used proteins or peptides, such as LL37.

The present disclosure describes compositions and methods for rapid selection of both binding and functional oligonucleotides (DNA, RNA, or any natural or synthetic analog of these). In certain embodiments, provided herein are flow cells (e.g., flow cells for an Illumina sequencing instrument or a Polonator sequencing instrument) comprising within its flow chamber a plurality of immobilized aptamer clusters (e.g., from an aptamer library described herein) and, optionally, one or more target cells (e.g., cancer cells, immune cells, etc.) and/or a detectable indicator of cellular function (e.g., a fluorescent indicator of apoptosis, cell proliferation, gene or protein expression, etc.). In certain embodiments, provided herein are methods of using such an aptamer cluster-containing flow cell to identify functional aptamers from an aptamer library (e.g., in a sequencing instrument, such as an Illumina sequencing instrument).