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Atomic and residue hydrophilicity in the context of folded protein structures (1995)

Kuhn, Leslie A. ; Swanson, Craig A. ; Pique, Michael E. ; [et al.]

New York, NY : Wiley-Blackwell

Proteins: Structure, Function, and Genetics 23 (1995), S. 536-547

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ISSN: 0887-3585

Keywords: water ; hydrophobicity ; hydration ; X-ray crystallography ; solvation ; ordered solvent ; molecular recognition ; water-protein interactions ; drug and inhibitor design ; protein surface analysis ; Chemistry ; Biochemistry and Biotechnology

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Medicine

Notes: Water-protein interactions drive protein folding, stabilize the folded structure, and influence molecular recognition and catalysis. We analyzed the closest protein contacts of 10,837 water molecules in crystallographic structures to define a specific hydrophilicity scale reflecting specific rather than bulk solvent interactions. The tendencies of different atom and residue types to be the nearest protein neighbors of bound water molecules correlated with other hydrophobicity scales, verified the relevance of crystallographically determined water positions, and provided a direct experimental measure of water affinity in the context of the folded protein. This specific hydrophilicity was highly correlated with hydrogen-bonding capacity, and correlated better with experimental than computationally derived measures of partitioning between aqueous and organic phases. Atoms with related chemistry clustered with respect to the number of bound water molecules. Neutral and negatively charged oxygen atoms were the most hydrophilic, followed by positively-charged then neutral nitrogen atoms, followed by carbon and sulfur atoms. Agreement between observed side-chain specific hydrophilicity values and values derived from the atomic hydrophilicity scale showed that hydrophilicity values can be synthesized for different functional groups, such as unusual side or main chains, discontinuous epitopes, and drug molecules. Two methods of atomic hydrophilicity analysis provided a measure of complementarity in the interfaces of trypsin:pancreatic trypsin inhibitor and HIV protease:U-75875 inhibitor complexes. © 1995 Wiley-Liss, Inc.

Additional Material: 6 Ill.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1002/prot.340230408

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Screening a peptidyl database for potential ligands to proteins with side-chain flexibilityVolker Schnecke and Craig A. Swanson contributed equally to the research. (1998)

Schnecke, Volker ; Swanson, Craig A. ; Getzoff, Elizabeth D. ; [et al.]

New York, NY : Wiley-Blackwell

Proteins: Structure, Function, and Genetics 33 (1998), S. 74-87

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ISSN: 0887-3585

Keywords: docking ; distance geometry ; drug design ; peptidyl inhibitors ; protein-peptide interactions ; inducible complementarity ; aspartic proteinase ; glycosyltransferase ; serine protease ; DNA repair enzyme ; Chemistry ; Biochemistry and Biotechnology

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Medicine

Notes: The three key challenges addressed in our development of SPECITOPE, a tool for screening large structural databases for potential ligands to a protein, are to eliminate infeasible candidates early in the search, incorporate ligand and protein side-chain flexibility upon docking, and provide an appropriate rank for potential new ligands. The protein ligand-binding site is modeled by a shell of surface atoms and by hydrogen-bonding template points for the ligand to match, conferring specificity to the interaction. SPECITOPE combinatorially matches all hydrogen-bond donors and acceptors of the screened molecules to the template points. By eliminating molecules that cannot match distance or hydrogen-bond constraints, the transformation of potential docking candidates into the ligand-binding site and the shape and hydrophobic complementarity evaluations are only required for a small subset of the database. SPECITOPE screens 140,000 peptide fragments in about an hour and has identified and docked known inhibitors and potential new ligands to the free structures of four distinct targets: a serine protease, a DNA repair enzyme, an aspartic proteinase, and a glycosyltransferase. For all four, protein side-chain rotations were critical for successful docking, emphasizing the importance of inducible complementarity for accurately modeling ligand interactions. SPECITOPE has a range of potential applications for understanding and engineering protein recognition, from inhibitor and linker design to protein docking and macromolecular assembly. Proteins 33:74-87, 1998. © 1998 Wiley-Liss, Inc.

Additional Material: 5 Ill.

Type of Medium: Electronic Resource

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