The present invention relates generally methods and kits for detecting binding interactions, in particular protein-protein interactions, and particularly to high throughput methods for labelling, analysing, detecting and measuring protein-protein interactions.

To efficiently analyze interaction and function between proteins, the present invention relates to a method for forming a light-induced protein nanocluster, comprising: an expression vector preparation step of preparing a first expression vector including polynucleotides coding a first fusion protein including a light-induced heterodimer-forming protein and a first self-assembly protein, and a second expression vector including polynucleotides coding a couple protein that forms a homodimer with said light-induced heterodimer-forming protein, or a second fusion protein including said couple protein and a second self-assembly protein; a transformed cell, tissue or individual preparation step of transforming cells, tissues or individuals using said first expression vector and second expression vector; and a light radiation step of radiating light having a wavelength for inducing the formation of heterodimer between said light-induced heterodimer-forming protein and said couple protein, to said transformed cells, tissue or individuals.

Methods of detecting an interaction between a macromolecule and an interaction partner are described. Kits are also described.

In some embodiments, methods of detecting an association between a query protein and a target moiety are described. In some embodiments, compositions are described. In some embodiments, kits are described.

A method for detecting an interaction between one or more protein bait and one or more candidate prey in a eukaryotic cell, comprising the steps of: a) providing an eukaryotic cell expressing (i) one or more protein bait, and (ii) one or more candidate prey, wherein said protein bait comprises a bait moiety and a polymerized-tubulin binding moiety. b) determining the occurence of an interaction between said one or more protein bait and said one or more candidate prey in the eukaryotic cell, wherein said protein bait is bound to polymerized tubulin in the eukaryotic cell, thereby localizing said one or more candidate prey along said polymerized tubulin, thereby detecting said interaction.

The present invention relates to the use of camptothecin derivatives as anti-HIV agents that disrupt self-association of the viral infectivity factor (Vif) found in HIV and other retroviruses. The present invention also relates to methods of identifying agents that disrupt VIf self-association and methods of using these agents, including methods of treating or preventing HIV infection.

This invention provides a method that allows selection of antibodies against cells (e.g., tumor cells) in situ using laser capture microdissection. By restricting antibody selection to binders of internalizing epitopes, a panel of phage antibodies was generated that targets clinically represented prostate cancer antigens.

Surface structures that enable the preparation of three-dimensional microarrays of proteins or small molecules or other types of macromolecules are disclosed. The three-dimensional microarrays possess higher sensitivity for detecting protein-macromolecule and small molecule-protein interactions in a high-throughput fashion.

Provided herein are biological vesicles displaying cell surface proteins, as well as methods of using such vesicles to identify and characterize protein-protein interactions.

A method of determining the effect of non-specific interactions in simulated in vivo conditions is presently disclosed. The method includes (a) contacting a solution comprising a biologically relevant molecular crowding agent and a target molecule with a biosensor, wherein the surface of the biosensor comprises a capture molecule that specifically binds the target molecule; (b) allowing the target molecule to bind to the capture molecule; and (c) determining an amount of the target molecule bound to capture molecule using biolayer interferometry.