The structural basis for high affinity binding of α1-acid glycoprotein to the potent antitumor compound UCN-01

The alpha 1-acid glycoprotein (AGP) is an abundant blood plasma protein with important immunomodulatory functions coupled to endogenous and exogenous ligand-binding properties. Its affinity for many drug-like structures, however, means AGP can have a significant effect on the pharmokinetics and pharmacodynamics of numerous small molecule therapeutics. Staurosporine, and its hydroxylated forms UCN-01 and UCN-02, are kinase inhibitors that have been investigated at length as antitumour compounds. Despite their potency, these compounds display poor pharmokinetics due to binding to both AGP variants, AGP1 and AGP2. The recent renewed interest in UCN-01 as a cytostatic protective agent prompted us to solve the structure of the AGP2-UCN-01 complex by X-ray crystallography, revealing for the first time the precise binding mode of UCN-01. The solution NMR suggests AGP2 undergoes a significant conformational change upon ligand binding, but also that it uses a common set of sidechains with which it captures key groups of UCN-01 and other small molecule ligands. We anticipate that this structure and the supporting NMR data will facilitate rational redesign of small molecules that could evade AGP and therefore improve tissue distribution.

Automated summary

AGP is an abundant blood plasma protein with immunomodulatory functions that can affect the pharmacokinetics of small molecule drugs. Some kinase inhibitors like UCN-01 have poor pharmacokinetics due to binding to AGP variants AGP1 and AGP2. Solving the structure of the AGP2-UCN-01 complex revealed the precise binding mode and potential for rational redesign of small molecules to improve tissue distribution.