In silico-based repositioning of phosphinothricin as a novel technetium-99m imaging probe with potential anti-cancer activity

Abstract

L-Phosphinothricin (glufosinate or 2-amino-4-((hydroxy(methyl) phosphinyl) butyric acid ammonium salt (AHPB)), which is a structural analog of glutamate, is a recognized herbicide that acts on weeds through inhibition of glutamine synthetase. Due to the structural similarity between phosphinothricin and some bisphosphonates (BPs), this study focuses on investigating the possibility of repurposing phosphinothricin as a bisphosphonate analogue, particularly in two medicine-related activities: image probing and as an anti-cancer drug. As BP is a competitive inhibitor of human farnesyl pyrophosphate synthase (HFPPS), in silico molecular docking and dynamic simulations studies were established to evaluate the binding and stability of phosphinothricin with HFPPS, while the results showed good binding and stability in the active site of the enzyme in relation to alendronate. For the purpose of inspecting bone-tissue accumulation of phosphinothricin, a technetium (99mTc)�phosphinothricin complex was developed and its stability and tissue distribution were scrutinized. The radioactive complex showed rapid, high and sustained uptake into bone tissues. Finally, the cytotoxic activity of phosphinothricin was tested against breast and lung cancer cells, with the results indicating cytotoxic activity in relation to alendronate. All the above results provide support for the use of phosphinothricin as a potential anti-cancer drug and of its technetium complex as an imaging probe. � 2018 by the authors.

Description

Scopus
MSA Google Scholar

Keywords

October University for Modern Sciences and Arts, جامعة أكتوبر للعلوم الحديثة والآداب, University of Modern Sciences and Arts, MSA University, Cancer imaging, In-silico, Molecular docking, Phosphinothricin, Repositioning, Technetium-99m, alendronic acid, aminobutyric acid derivative, antineoplastic agent, phosphinothricin, radiopharmaceutical agent, technetium, Technetium-99, animal, binding site, cell proliferation, chemical structure, chemistry, diagnostic imaging, drug effect, drug repositioning, drug stability, human, molecular docking, molecular dynamics, mouse, pH, structure activity relation, tissue distribution, tumor cell line, Alendronate, Aminobutyrates, Animals, Antineoplastic Agents, Binding Sites, Cell Line, Tumor, Cell Proliferation, Diagnostic Imaging, Drug Repositioning, Drug Stability, Humans, Hydrogen-Ion Concentration, Mice, Molecular Docking Simulation, Molecular Dynamics Simulation, Molecular Structure, Radiopharmaceuticals, Structure-Activity Relationship, Technetium, Tissue Distribution

Citation

Full Text link