AI Article Synopsis
- - The cellular thermal shift assay (CETSA) is a valuable technique for studying how drugs interact with target proteins, which is essential in drug development and mechanistic research.
- - This review covers the basics of CETSA, including its variations like western blot-based CETSA and mass spectrometry-based thermal proteome profiling (TPP), and their various applications in research.
- - CETSA and TPP enhance the understanding of how ligands bind to target proteins, evaluate protein interactions, and can accelerate the drug development process by revealing the biological effects of these interactions.
Article Abstract
Introduction: A comprehensive and global knowledge of protein target engagement is of vital importance for mechanistic studies and in drug development. Since its initial introduction, the cellular thermal shift assay (CETSA) has proven to be a reliable and flexible technique that can be widely applied to multiple contexts and has profound applications in facilitating the identification and assessment of protein target engagement.
Areas Covered: This review introduces the principle of CETSA, elaborates on western blot-based CETSA and MS-based thermal proteome profiling (TPP) as well as the major applications and prospects of these approaches.
Expert Opinion: CETSA primarily evaluates a given ligand binding to a particular target protein in cells and tissues with the protein thermal stabilities analyzed by western blot. When coupling mass spectrometry with CETSA, thermal proteome profiling allows simultaneous proteome-wide experiment that greatly increased the efficiency of target engagement evaluation, and serves as a promising strategy to identify protein targets and off-targets as well as protein-protein interactions to uncover the biological effects. The CETSA approaches have broad applications and potentials in drug development and clinical research.
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| http://dx.doi.org/10.1080/14789450.2024.2406785 | DOI Listing |
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