Structure-function analysis of D9N and N291S mutations in human lipoprotein lipase using molecular modelling
Autor: | M. Ilyas Kamboh, Richard J. McClure, Billy W. Day, Hamid Razzaghi |
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Rok vydání: | 2001 |
Předmět: |
Models
Molecular Molecular Sequence Data Cofactor Structure-Activity Relationship Materials Chemistry Humans Computer Simulation Amino Acid Sequence Physical and Theoretical Chemistry Apolipoproteins C Pancreas Spectroscopy chemistry.chemical_classification Lipoprotein lipase biology Sequence Homology Amino Acid digestive oral and skin physiology Wild type nutritional and metabolic diseases Lipid metabolism Computer Graphics and Computer-Aided Design In vitro Lipoprotein Lipase Enzyme Biochemistry chemistry Docking (molecular) Mutagenesis biology.protein lipids (amino acids peptides and proteins) Apolipoprotein C-II Two-dimensional nuclear magnetic resonance spectroscopy |
Zdroj: | Journal of molecular graphicsmodelling. 19(6) |
ISSN: | 1093-3263 |
Popis: | Lipoprotein lipase (LPL) plays a central role in lipid metabolism. The D9N and N291S mutations in the LPL gene are associated with elevated triglyceride and decreased HDL-cholesterol levels. Published in vitro expression studies suggest that these two mutations are associated with reduced LPL enzymatic activity. We sought to gain further insight on the impact of these two mutations on the LPL structure and function by molecular modelling techniques. Homology modelling was used to develop a three-dimensional (3D) structure of LPL from human pancreatic lipase. Two separate LPL models for the D9N and N291S substitutions were constructed and compared with the wild type LPL for differences in hydrophobicity, atomic burial, hydrogen bond pattern, and atomic mobility. In comparison to the wild type model, the 9N model was associated with significantly increased atomic mobility of its neighboring residues, but the catalytic site was not affected. The region near residue 9 in the upper part of the N-domain was considered a candidate site for protein–protein interaction. In the N291S model, alterations in H-bonds and constrained atomic mobility were among conformational changes in the region where the substitution had occurred. These are hypothesized to cause an increase in the rate of dissociation in LPL dimerization, subsequently affecting the LPL enzymatic activity. We also modelled the C-domain of apoCII, the obligatory cofactor of LPL, from 2D NMR data and docked the model with LPL to explore their interaction site. These docking experiments suggest that the C-domain of apoCII interacts with the interface of N- and C-domains of LPL and part of the lid structure that covers the catalytic site. In summary, we provide molecular modelling data on two well-known mutations in the LPL gene to help explain the published in vitro expression findings and propose a possible LPL-apoCII interaction site. Our data indicate that molecular modelling of LPL mutations could provide a valuable tool to understand the effects of a mutation on the structure–function of this important enzyme. |
Databáze: | OpenAIRE |
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