TY - JOUR
T1 - Unexpected relative aqueous solubilities of a phosphotyrosine analogue and two phosphonate derivatives
AU - Boresch, Stefan
AU - Leitgeb, Martin
AU - Beselman, Aleksandra
AU - MacKerell, Alexander D.
N1 - Coden: JACSA
Affiliations: Biomolecular Simulation Group, Inst. fur Biomolek. Strukturchemie, Universität Wien, Währingerstraße 17, 1090 Wien, Austria; Dept. of Pharmaceutical Sciences, School of Pharmacy, University of Maryland, 20 Penn Street, Baltimore, MD 21201, United States
Adressen: Boresch, S.; Biomolecular Simulation Group; Inst. fur Biomolek. Strukturchemie; Universität Wien; Währingerstraße 17 1090 Wien, Austria; email: [email protected]
Source-File: BioStruktChemScopus.csv
Import aus Scopus: 2-s2.0-16844363790
Importdatum: 21.12.2006 12:03:22
22.10.2007: Datenanforderung 1935 (Import Sachbearbeiter)
22.10.2007: Datenanforderung 1936 (Import Sachbearbeiter)
09.02.2010: Datenanforderung UNIVIS-DATEN-DAT.RA-2 (Import Sachbearbeiter)
PY - 2005
Y1 - 2005
N2 - Phosphotyrosine (pTyr) is an essential component of biological signaling, often being a determinant of protein-protein interactions. Accordingly, a number of drug discovery efforts targeting signal transduction pathways have included phosphotyrosine and analogues as essential components of the lead compounds. Toward the goal of improved biological efficacy, the phosphonate and difluoro phosphonate analogues of pTyr have been employed in inhibitor design because of their stability to hydrolysis and enhanced binding affinity in certain cases. To quantitate the contribution of aqueous solubility of pTyr, phosphonomethyl phenylalanine (Pmp), and difluorophosphonomethyl phenylalanine (F 2Pmp) to their relative binding affinities, free energy perturbation calculations were undertaken on the mimetics phenol phosphate (PP), benzyl phosphonate (BP), and difluorobenzyl phosphonate (F2BP), including development of empirical force field parameters compatible with the CHARMM all-atom force fields. Notably, it is shown that the most favorably solvated compound of the series is BP, followed by PP, with F2BP the least favorably solvated for both the mono- and dianionic forms of the compounds. The molecular origin of this ordering is shown to be due to changes in charge distribution, in the comparatively larger size of the fluorine atoms, as well as in differences of local solvation between PP and BP. The implications of the differences in aqueous solubility toward the relative binding potencies of pTyr-, Pmp-, and F2Pmp-containing peptide ligands are discussed. Our results indicate that one general principle explaining the efficacy of selective fluorination to enhance binding affinities may lie in the ability of fluorine atoms to increase the hydrophobicity of a ligand while maintaining its capability to form hydrogen bonds. Œ 2005 American Chemical Society.
AB - Phosphotyrosine (pTyr) is an essential component of biological signaling, often being a determinant of protein-protein interactions. Accordingly, a number of drug discovery efforts targeting signal transduction pathways have included phosphotyrosine and analogues as essential components of the lead compounds. Toward the goal of improved biological efficacy, the phosphonate and difluoro phosphonate analogues of pTyr have been employed in inhibitor design because of their stability to hydrolysis and enhanced binding affinity in certain cases. To quantitate the contribution of aqueous solubility of pTyr, phosphonomethyl phenylalanine (Pmp), and difluorophosphonomethyl phenylalanine (F 2Pmp) to their relative binding affinities, free energy perturbation calculations were undertaken on the mimetics phenol phosphate (PP), benzyl phosphonate (BP), and difluorobenzyl phosphonate (F2BP), including development of empirical force field parameters compatible with the CHARMM all-atom force fields. Notably, it is shown that the most favorably solvated compound of the series is BP, followed by PP, with F2BP the least favorably solvated for both the mono- and dianionic forms of the compounds. The molecular origin of this ordering is shown to be due to changes in charge distribution, in the comparatively larger size of the fluorine atoms, as well as in differences of local solvation between PP and BP. The implications of the differences in aqueous solubility toward the relative binding potencies of pTyr-, Pmp-, and F2Pmp-containing peptide ligands are discussed. Our results indicate that one general principle explaining the efficacy of selective fluorination to enhance binding affinities may lie in the ability of fluorine atoms to increase the hydrophobicity of a ligand while maintaining its capability to form hydrogen bonds. Œ 2005 American Chemical Society.
U2 - 10.1021/ja044935h
DO - 10.1021/ja044935h
M3 - Article
VL - 127
SP - 4640
EP - 4648
JO - Journal of the American Chemical Society
JF - Journal of the American Chemical Society
SN - 0002-7863
IS - 13
ER -