Methods in enzymology
-
Measuring the strength of binding of low molecular weight ligands to a target protein is a significant challenge to fragment-based drug discovery that must be solved. Thermal shift assays are uniquely suited for this purpose, due to the thermodynamic effects of a ligand on protein thermal stability. We show here how to implement a thermal shift assay, describing the basic features and analysis of the protein unfolding data. ⋯ We describe the unique aspects of concentration-response curves, the effect of protein unfolding energetics, and the stoichiometry of the interaction. We outline a typical assay development strategy for optimizing dye type and concentration, protein concentration, and buffer conditions. Guidelines are presented to demonstrate the limits of detection for weak-binding ligands, as applied to sulfonamide-based inhibitors of carbonic anhydrase II and applied to nucleotide binding to the death-associated protein kinase 1 catalytic domain.
-
Methods in enzymology · Jan 2011
The emerging role of histone deacetylases (HDACs) in UPR regulation.
Although the function of histone deacetylases (HDACs) have primarily been associated with influencing transcription through chromatin remodeling, the capacity of these enzymes to interface with a diverse array of biologic processes by modulating a growing list of nonhistone substrates has gained recent attention. Recent investigations have demonstrated the potential of HDACs to directly regulate the unfolded protein response (UPR) through acetylation of its central regulatory protein, Grp78. Further, this appears to be an important mechanism underlying the anti-tumor activity of HDAC inhibitors. Herein, we provide a summary of the literature supporting the role HDACs play in regulating the UPR and a detailed description of methods to allow for the study of both acetylation of nonhistone proteins and UPR pathway activation following HDAC inhibition.