Abstract
Visualizing ligand binding interactions is important for structure-based drug design and fragment-based screening methods. Rapid and uniform soaking with potentially reduced lattice defects make small macromolecular crystals attractive targets for studying drug binding using microcrystal electron diffraction (MicroED). However, so far no drug binding interactions could unambiguously be resolved by electron diffraction alone. Here, we use MicroED to study the binding of a sulfonamide inhibitor to human carbonic anhydrase isoform II (HCA II). We show that MicroED data can efficiently be collected on a conventional transmission electron microscope from thin hydrated microcrystals soaked with the clinical drug acetazolamide (AZM). The data are of high enough quality to unequivocally fit and resolve the bound inhibitor. We anticipate MicroED can play an important role in facilitating in-house fragment screening for drug discovery, complementing existing methods in structural biology such as X-ray and neutron diffraction.
Highlights
Visualizing ligand binding interactions is important for structure-based drug design and fragment-based screening methods
We demonstrate that drug binding can be studied efficiently by soaking the 3D microcrystals with inhibitor and collecting microcrystal electron diffraction (MicroED) data using a conventional transmission electron microscope (TEM), making it effectively feasible to screen for possible protein-inhibitor-binding interactions on a home source
Inhibitor-bound protein complexes were obtained after 20 min of soaking human carbonic anhydrase isoform II (HCA II) microcrystals with the inhibitor AZM
Summary
Visualizing ligand binding interactions is important for structure-based drug design and fragment-based screening methods. Rapid and uniform soaking with potentially reduced lattice defects make small macromolecular crystals attractive targets for studying drug binding using microcrystal electron diffraction (MicroED). We use MicroED to study the binding of a sulfonamide inhibitor to human carbonic anhydrase isoform II (HCA II). We use MicroED to investigate drug-binding interactions to the active site of human carbonic anhydrase isoform II (HCA II), a small ubiquitous metalloenzyme with a molecular weight of 29 kDa. Carbonic anhydrases catalyze the reversible reaction of CO2 hydration to produce HCO3− and H+. Neutron studies of HCA II in complex with various sulfonamides revealed additional hydrogen-bonding interactions and water displacements in the active site that are important determinants in understanding inhibitor binding[30,31,32]. The net effect is that less aqueous humor is formed, reducing intralocular pressure[34]
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