Journal:Protein Science:2
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these report the presence of individual PEGs. We here report a case in which presence of PEG in a crystal structure markedly affected the bound ligand’s position. Specifically, we compared the positions of methylene blue and of decamethonium in the acetylcholinesterase complexes obtained using isomorphous crystals precipitated with PEG200 or ammonium sulfate. The ligands’ positions within the active-site gorge in complexes obtained using PEG200 as precipitant are influenced by the presence of ethyleneglycol oligomers. In both cases, an ethyleneglycol dimer is bound to W84 at the gorge’s bottom, preventing their proximal quaternary groups’ interaction with its indole. Consequently, both ligands are ~2.5 Å further up the gorge than in complexes obtained using crystals precipitated with ammonium sulfate, in which these quaternary groups make a direct π-cation interaction with the indole. These findings have implications for structure-based drug design, since data for ligand-protein complexes with PEG as precipitant may not reflect the ligand’s position in its absence, and could result in selection of incorrect lead compounds for drug discovery. Docking methylene blue into the protein structure of the complex obtained with PEG200, but omitting the ethyleneglycol dimer yields results in poor agreement with the crystal structure; excellent agreement is obtained if the ethyleneglycol dimer is included. Many proteins display structural elements in which precipitants like PEG might lodge. It will be important to investigate presence of precipitants in published crystal structures, and whether it has resulted in misinterpretation of electron density maps, thus adversely affecting drug design. | these report the presence of individual PEGs. We here report a case in which presence of PEG in a crystal structure markedly affected the bound ligand’s position. Specifically, we compared the positions of methylene blue and of decamethonium in the acetylcholinesterase complexes obtained using isomorphous crystals precipitated with PEG200 or ammonium sulfate. The ligands’ positions within the active-site gorge in complexes obtained using PEG200 as precipitant are influenced by the presence of ethyleneglycol oligomers. In both cases, an ethyleneglycol dimer is bound to W84 at the gorge’s bottom, preventing their proximal quaternary groups’ interaction with its indole. Consequently, both ligands are ~2.5 Å further up the gorge than in complexes obtained using crystals precipitated with ammonium sulfate, in which these quaternary groups make a direct π-cation interaction with the indole. These findings have implications for structure-based drug design, since data for ligand-protein complexes with PEG as precipitant may not reflect the ligand’s position in its absence, and could result in selection of incorrect lead compounds for drug discovery. Docking methylene blue into the protein structure of the complex obtained with PEG200, but omitting the ethyleneglycol dimer yields results in poor agreement with the crystal structure; excellent agreement is obtained if the ethyleneglycol dimer is included. Many proteins display structural elements in which precipitants like PEG might lodge. It will be important to investigate presence of precipitants in published crystal structures, and whether it has resulted in misinterpretation of electron density maps, thus adversely affecting drug design. | ||
| - | Crystal structure of TcAChE <scene name='72/725874/Cv/2'>shows its two subdomains</scene> (residues 4-305, purple, and residues 306-535, red). The <scene name='72/725874/Cv/3'>entrance to the active-site gorge</scene> located between the two sub-domains. There are several of the conserved aromatic residues: <scene name='72/725874/Cv/4'>Trp279</scene>, in the peripheral anionic site (PAS) at the top of the gorge; Tyr121, mid-way down the gorge, and | + | Crystal structure of TcAChE <scene name='72/725874/Cv/2'>shows its two subdomains</scene> (residues 4-305, purple, and residues 306-535, red). The <scene name='72/725874/Cv/3'>entrance to the active-site gorge</scene> located between the two sub-domains. There are several of the conserved aromatic residues: <scene name='72/725874/Cv/4'>Trp279</scene>, in the peripheral anionic site (PAS) at the top of the gorge; <scene name='72/725874/Cv/7'>Tyr121</scene>, mid-way down the gorge, and <scene name='72/725874/Cv/7'>Trp84</scene>, the principal element of the catalytic ‘anionic’ sub-site (CAS), near the bottom. Also |
| - | Trp84, the principal element of the catalytic ‘anionic’ sub-site (CAS), near the bottom. Also | + | |
shown are two members of the catalytic triad, Ser200 and His440. | shown are two members of the catalytic triad, Ser200 and His440. | ||
Revision as of 09:34, 23 February 2016
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