Abstract
Several naturally occuring mutations in the human insulin gene are associated with diabetes mellitus. The three known mutant molecules, Wakayama, Los Angeles and Chicago were evaluated using molecular docking and molecular dynamics (MD) to analyse mechanisms of deprived binding affinity for insulin receptor (IR). Insulin Wakayama, is a variant in which valine at position A3 is substituted by leucine, while in insulin Los Angeles and Chicago, phenylalanine at positions B24 and B25 is replaced by serine and leucine, respectively. These mutations show radical changes in binding affinity for IR. The ZDOCK server was used for molecular docking, while AMBER 14 was used for the MD study. The published crystal structure of IR bound to natural insulin was also used for MD. The binding interactions and MD trajectories clearly explained the critical factors for deprived binding to the IR. The surface area around position A3 was increased when valine was substituted by leucine, while at positions B24 and B25 aromatic amino acid phenylalanine replaced by non-aromatic serine and leucine might be responsible for fewer binding interactions at the binding site of IR that leads to instability of the complex. In the MD simulation, the normal mode analysis, rmsd trajectories and prediction of fluctuation indicated instability of complexes with mutant insulin in order of insulin native insulin < insulin Chicago < insulin Los Angeles < insulin Wakayama molecules which corresponds to the biological evidence of the differing affinities of the mutant insulins for the IR.
Highlights
Diabetes mellitus (DM) is a heterogeneous group of metabolic diseases characterized by chronic hyperglycaemia resulting from decreased insulin secretion and/or increased insulin resistance
Results Crystal complex of insulin receptor (IR) and native insulin The crystal structure (PDB insert domain (ID): 3W14) of IR bound with native insulin is depicted in Figure 2a, which explains that helix of in case of B chain (InsB) (B7-B19) engages with the C-terminal end of L1 domain but InsA has no interaction with domain L1
In this study we examined the binding of mutant insulins Wakayama, Los Angeles and Chicago using pharmacoinformatics analysis of the reduced binding affinity to the IR
Summary
Diabetes mellitus (DM) is a heterogeneous group of metabolic diseases characterized by chronic hyperglycaemia resulting from decreased insulin secretion and/or increased insulin resistance. There are several naturally occurring mutations in the insulin molecule which have been described in humans and are associated with diabetes mellitus These include insulin Wakayama (Val3A → Leu3A) where valine is mutated to leucine at A3, insulin Los Angeles (Phe24B → Ser24B) and insulin Chicago (Phe25B→Leu25B) in which phenylalanine is substituted by serine and leucine at B24 and B25 respectively. These substitutions occur within the crevice adjoining the IR binding surface and impair receptor binding by many-fold in affected individuals(Wan et al, 2005; Wollmer et al, 1981).
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