Structure based design, synthesis and biological evaluation of amino phosphonate derivatives as human glucokinase activators

[Display omitted] •Novel biosenstive α-aminophosphonates were designed and synthesized as GK activators.•QSAR descriptors and ADME properties proved them as safer drugs.•Molecular docking studies of GKAs revealed their best binding affinities and orientations.•The in vitro evaluation of GKAs reveale...

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Bibliographic Details
Published in:Computational biology and chemistry 2017-06, Vol.68, p.118-130
Main Authors: Yellapu, Nanda Kumar, Kilaru, Ravendra Babu, Chamarthi, Nagaraju, PVGK, Sarma, Matcha, Bhaskar
Format: Article
Language:English
Subjects:
ADME
Drug Design
Enzyme Activation - drug effects
Enzyme Activators - chemical synthesis
Enzyme Activators - chemistry
Enzyme Activators - pharmacology
GK activators
Glucokinase
Glucokinase - metabolism
Humans
Liver - enzymology
Molecular docking
Molecular Structure
Organophosphonates - chemical synthesis
Organophosphonates - chemistry
Organophosphonates - pharmacology
QSAR
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Summary:[Display omitted] •Novel biosenstive α-aminophosphonates were designed and synthesized as GK activators.•QSAR descriptors and ADME properties proved them as safer drugs.•Molecular docking studies of GKAs revealed their best binding affinities and orientations.•The in vitro evaluation of GKAs revealed their potential GK activation. Glucokinase (GK) is a potential therapeutic target of type 2 diabetes and GK activators (GKAs) represent a promising class of small organic molecules which enhance GK activity. Based on the configuration and conformation of the allosteric site of GK, we have designed a novel class of amino phosphonate derivatives in order to develop potent GKAs. The QSAR model developed using numerous descriptors revealed its potential with the best effective statistical values of RMSE=1.52 and r2=0.30. Moreover, application of this model on the present test set GKAs proved to be worthy to predict their activities as a better linear relationship was observed with RMSE=0.14 and r2=0.88. ADME studies and Lipinski filters encouraged them as safer therapeutics. The molecular dynamics and docking studies against the GK allosteric site revealed that all GKAs bind with best affinities and the complexes are strengthened by H-bonding, phosphonate salt bridges, hydrophobic and arene cat ionic interactions. Finally, in vitro evaluation with human liver GK revealed their potential to increase the GK activity by different folds. The results from QSAR, ADME, molecular docking and in vitro assays strongly suggested that the present molecules could be used as effective and safer therapeutics to control and manage type 2 diabetes.
ISSN:1476-9271
1476-928X
DOI:10.1016/j.compbiolchem.2017.02.011