The invention provides methods and compositions useful for identifying polypeptides with desired characteristics in vitro.

Materials and methods for specifically isolating and identifying biomolecules that bind to selected targets.

Provided are dyes and compositions which are useful in a number of applications, such as the detection and monitoring protein aggregation, kinetic studies of protein aggregation, neurofibrillary plaques analysis, evaluation of protein formulation stability, protein thermal stability shift assay and analysis of molecular chaperone activity. These dyes and compositions are also useful as probes in nucleic acid and protein detection.

The invention provides compounds and methods for site-specifically labeling proteins with cyanobenzothiazole derivatives of formula I. For example, the invention provides methods for labeling the N-terminus of a protein that terminates with a cysteine residue. The invention also provides methods for isolating an N-terminally labeled protein and methods for detecting an N-terminally labeled protein.

The disclosure relates to a method for selecting, isolating and/or recovering a peptide or polypeptide from a library or a repertoire of peptides and polypeptides (e.g., a display system) that is resistant to degradation by a protease such as a protease found in the serum. Generally, the method comprises providing a library or repertoire of peptides or polypeptides, incubating the library or repertoire with a protease under conditions suitable for protease activity, and selecting, isolating and/or recovering a peptide or polypeptide that is resistant to degradation by the protease and has a desired biological activity. The selected peptides and polypeptides have utility as therapeutics, e.g., for treating disease in humans.

Provided are pro-substrates useful in assays of living cells. The pro-substrates can be used to detect the presence or absence of enzymes, such as luciferase, in living cells. The pro-substrates can be coelenterazine derivatives or analogs.

A device and system for detecting an antigen present in a sample is provided. The system includes a cartridge and a reader device. The cartridge includes a solid support having an addressable array of at least one type of antibody that is specific for a target antigen and forms a complex in the presence of the target antigen, a substrate having a mounting surface for the solid support, Protein M for competitively displacing the target antigen from the complex, and a housing for protecting the substrate. The reader device is configured to detect the antigen in a liquid sample via interaction with the cartridge.

The present invention provides novel microfluidic devices and methods that are useful for performing high-throughput screening assays and combinatorial chemistry. The invention provides for aqueous based emulsions containing uniquely labeled cells, enzymes, nucleic acids, etc., wherein the emulsions further comprise primers, labels, probes, and other reactants. An oil based carrier-fluid envelopes the emulsion library on a microfluidic device, such that a continuous channel provides for flow of the immiscible fluids, to accomplish pooling, coalescing, mixing, sorting, detection, etc., of the emulsion library.

Methods and compositions are disclosed for rapid functional analysis of gene variants based on analysis of protein-protein and protein-nucleic acid interactions.

Embodiments disclosed herein are directed to microfluidic devices that allow for scalable on-chip screening of combinatorial libraries and methods of use thereof. Droplets comprising individual molecular species to be screened are loaded onto the microfluidic device. The droplets are labeled by methods known in the art, including but not limited to barcoding, such that the molecular species in each droplet can be uniquely identified. The device randomly sorts the droplets into individual microwells of an array of microwells designed to hold a certain number of individual droplets in order to derive combinations of the various molecular species. The paired droplets are then merged in parallel to form merged droplets in each microwell, thereby avoiding issues associated with single stream merging. Each microwell is then scanned, e.g., using microscopy, such as high content imaging microscopy, to detect the optical labels, thereby identifying the combination of molecular species in each microwell.