TY - JOUR
T1 - Halogenated ligands and their interactions with amino acids
T2 - Implications for structure-activity and structure-toxicity relationships
AU - Kortagere, Sandhya
AU - Ekins, Sean
AU - Welsh, William J.
N1 - Funding Information:
The authors acknowledge access to the computational facilities at the Informatics Institute of UMDNJ and the academic computing services. Support for this work has been provided primarily by the US-EPA funded Environmental Bioinformatics and Computational Toxicology Center (ebCTC), under STAR Grant number GAD R 832721-010 to WJW. A similar analysis on an older PDB data set was presented as a poster at the 49th Annual Biophysical Society meeting by one of the authors (SK).
PY - 2008/9
Y1 - 2008/9
N2 - The properties of chemicals are rooted in their molecular structure. It follows that structural analysis of specific interactions between ligands and biomolecules at the molecular level is invaluable for defining structure-activity relationships (SARs) and structure-toxicity relationships (STRs). This study has elucidated the structural and molecular basis of interactions of biomolecules with alkyl and aryl halides that are extensively used as components in many commercial pesticides, disinfectants, and drugs. We analyzed the protein structures deposited in Protein Data Bank (PDB) for structural information associated with interactions between halogenated ligands and proteins. This analysis revealed distinct patterns with respect to the nature and structural characteristics of halogen interactions with specific types of atoms and groups in proteins. Fluorine had the highest propensity of interactions for glycine, while chlorine for leucine, bromine for arginine, and iodine for lysine. Chlorine, bromine and iodine had the lowest propensity of interactions for cysteine, while fluorine had a lowest propensity for proline. These trends for highest propensity shifted towards the hydrophobic residues for all the halogens when only interactions with the side chain were considered. Halogens had equal propensities of interaction for the halogen bonding partners (nitrogen and oxygen atoms), albeit with different geometries. The optimal angle for interactions with halogens was ∼120° for oxygen atoms, and ∼96° for nitrogen atoms. The distance distributions of halogens with various amino acids were mostly bimodal, and the angle distributions were unimodal. Insights gained from this study have implications for the rational design of safer drugs and commercially important chemicals.
AB - The properties of chemicals are rooted in their molecular structure. It follows that structural analysis of specific interactions between ligands and biomolecules at the molecular level is invaluable for defining structure-activity relationships (SARs) and structure-toxicity relationships (STRs). This study has elucidated the structural and molecular basis of interactions of biomolecules with alkyl and aryl halides that are extensively used as components in many commercial pesticides, disinfectants, and drugs. We analyzed the protein structures deposited in Protein Data Bank (PDB) for structural information associated with interactions between halogenated ligands and proteins. This analysis revealed distinct patterns with respect to the nature and structural characteristics of halogen interactions with specific types of atoms and groups in proteins. Fluorine had the highest propensity of interactions for glycine, while chlorine for leucine, bromine for arginine, and iodine for lysine. Chlorine, bromine and iodine had the lowest propensity of interactions for cysteine, while fluorine had a lowest propensity for proline. These trends for highest propensity shifted towards the hydrophobic residues for all the halogens when only interactions with the side chain were considered. Halogens had equal propensities of interaction for the halogen bonding partners (nitrogen and oxygen atoms), albeit with different geometries. The optimal angle for interactions with halogens was ∼120° for oxygen atoms, and ∼96° for nitrogen atoms. The distance distributions of halogens with various amino acids were mostly bimodal, and the angle distributions were unimodal. Insights gained from this study have implications for the rational design of safer drugs and commercially important chemicals.
KW - DDT
KW - Halogen bonds
KW - Halogenated ligands
KW - PCB
KW - PDB analysis
KW - Propensity
KW - Protein-ligand interactions
KW - Structure-activity relationship and structure-toxicity relationship
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U2 - 10.1016/j.jmgm.2008.04.001
DO - 10.1016/j.jmgm.2008.04.001
M3 - Article
C2 - 18524655
AN - SCOPUS:52049106111
SN - 1093-3263
VL - 27
SP - 170
EP - 177
JO - Journal of Molecular Graphics and Modelling
JF - Journal of Molecular Graphics and Modelling
IS - 2
ER -