A method for developing capture agents for target proteins employs a compound library to find cyclic peptide sequences that bind the target protein. The target protein is also reacted with a clickable group-provider reagent to provide the protein with clickable groups. The compounds in the library are provided with complementary clickable groups that bind the clickable group on the target protein when the peptide sequences bind the target protein. In some embodiments, the cyclic peptide sequences that bind the target protein are incorporated into constructs having one or more arms that can serve as capture agents or potential treatments against the pathogens from which the target protein is derived. Some embodiments provide pharmaceutical compositions for immunoassays, diagnostics, therapeutics or the like, that employ the constructs.

The present invention relates to the field of protein characterization, and in particular to methods for identifying critical quality attributes of therapeutic proteins by implementing a workflow including using a competitive binding assay with insufficient capture molecule followed by LC-MS.

The present invention is directed to methods for using particles (e.g, microparticulate, nanoparticulate; magnetic, non-magnetic) comprising surfaces comprising capture moieties as described herein, to remove an interference as described herein, or enrich biomarkers, especially antibodies, prior to a diagnostic test, or to be isolated and used for prophylactic or therapeutic purposes.

Methods and systems for identifying and/or quantifying polypeptide binding interactions of ligand-binding polypeptides are disclosed. Detailed methods include methods for identifying binding ligands of ligand-binding polypeptides and methods for assessing changes in binding behavior due to alterations of ligand-binding polypeptides. Detailed systems include array-based systems that permit detection of ligand binding interactions at single-analyte resolution.

The technology described herein is directed to structural analysis, particularly of small proteins via cryo-EM.

Disclosed herein is a chemo-proteomic probe for labelling and monitoring a live microbe interacting with a host cell and for qualitative and quantitative analyses of those proteins involved during a microbe infects the host cell. This probe comprises a functional group for conjugating to a surface protein of a live microbe under a physiological condition; a photo-reactive group for covalent cross-linking to an interacting cell protein of a host; and a tag for isolating the cross-linked complex of the surface protein of said live microbe and the interacting protein of a host cell for qualitative and quantitative proteomics analyses. The probe may further comprise a visualization tag. This technology takes advantage of the high throughput feature of mass spectrometry analysis and combines it with a uniquely designed chemistry to achieve high efficient isolation and analysis of host cell proteins interacting with a pathogen at different stages of an infection.

The present disclosure provides assay methods for the detection and/or quantification of an analyte in a sample. In some examples, the methods detect and/or quantify an active analyte in a sample.

The invention relates to biosensors. More particularly, this invention relates to an electrochemical biosensor and to electrochemically active enzymes or variants thereof that are suitable for detection of one or more target molecules in a sample.

Disclosed is a method of qualifying a subgroup of target binding biomolecules from a larger group of target binding biomolecules for analysis. A competitive immunoassay including a target protein is used to identify 100 interactions between different pairs of the target binding biomolecules and interaction profiles are generated 200. Each target binding biomolecule is allocated 300 to a bin representing an epitope family and identified bins are associated in a circular or semi-circular bin chart on a display with identified respective target binding biomolecule(s). Based on the association 400 between identified bins and identified respective target binding molecule(s) in the bin chart, a subgroup of target binding biomolecules is selected 500 for further analysis by selecting one or more of the target binding biomolecule(s) of one or more of the bins.

High-throughput methods for screening large populations of variant proteins are provided. The methods utilize large-scale arrays of microcapillaries, where each microcapillary comprises a solution containing a variant protein, an immobilized target molecule, and a reporter element. Immobilized target molecules may include any molecule of interest, including proteins, nucleic acids, carbohydrates, and other biomolecules. The association of a variant protein with a molecular target is assessed by measuring a signal from the reporter element. The contents of microcapillaries identified in the assays as containing variant proteins of interest can be isolated, and cells expressing the variant proteins of interest can be characterized. Also provided are systems for performing the disclosed screening methods.