Identification of Small Molecule-binding Proteins in a Native Cellular Environment by Live-cell Photoaffinity Labeling

Overview

Journal J Vis Exp

Specialties Biology
General Medicine

Date 2016 Sep 30

PMID 27684515

Citations 1

Authors

Sarah A Head

Jun O Liu

Affiliations

Soon will be listed here.

Abstract

Identifying the molecular target(s) of small molecules is a challenging but necessary step towards understanding their mechanism of action. While several target identification methods have been developed and used to successfully elucidate the binding proteins of a variety of small molecules, these techniques have drawbacks that make them unsuitable for detecting certain types of small molecule-target interactions. In particular, non-covalent interactions that depend on native cellular conditions, such as those of membrane proteins whose structures may be perturbed upon cell lysis, are often not amenable to affinity-based target identification methods. Here, we demonstrate a method wherein a probe containing a photolabile group is used to covalently crosslink to the small molecule binding protein within the environment of the live cell, allowing the detection and isolation of the target protein without the need for maintenance of the interaction after cell lysis. This technique is a valuable tool for studying biologically interesting small molecules with unknown mechanisms, both in the context of basic biology as well as drug discovery.

Citing Articles

Combining Neurobehavioral Analysis and Photoaffinity Labeling to Understand Protein Targets of Methamphetamine in Casper Zebrafish.

Tackie-Yarboi E, Wisner A, Horton A, Chau T, Reigle J, Funk A ACS Chem Neurosci. 2020; 11(17):2761-2773.

PMID: 32786314 PMC: 8356474. DOI: 10.1021/acschemneuro.0c00416.

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