AI Article Synopsis
- Aldose reductase inhibitors are important for preventing diabetes complications, and new derivatives of rhodanine-3-hippuric acid-pyrazole were developed and tested for their effectiveness.
- The synthesized compounds showed strong inhibitory activity against ALR2, with some being significantly more potent than the currently used drug, epalrestat.
- Molecular docking studies indicated that these compounds effectively bind to the active site of ALR2, blocking its activity by disrupting essential interactions in the protein.
Article Abstract
Inhibitors of aldose reductase are rate-limiting enzymes and could play a key role to prevent the complications of diabetes. In our attempt to develop novel inhibitors of aldose reductase, the derivatives of rhodanine-3-hippuric acid-pyrazole hybrid were synthesized and characterised by spectral data. The biological studies reveal that all the compounds show an excellent activity against ALR2 with IC values ranging from 0.04 to 1.36 µM. Among these the synthesised compounds 6a-m, 6g and 6e showed specific inhibitory activity with IC values of 0.04 and 0.06 µM respectively against ALR2 and found to be more potent than epalrestat (IC = 0.87 μM), the only aldose reductase inhibitor currently used in the therapy. Molecular docking analysis using the AR-NADP complex as a receptor was performed with all the synthesized compounds. All the compounds exhibit a well-defined binding mode within the AR active site, similarly to previous described AR inhibitors, with the anion head group bound to the catalytic center, blocking thus its activity. By forming hydrogen bonds with Tyr48 and His110 of the protein from ALR2 (PDB ID: 2FZD), the compounds 6g and 6e interrupt the proton donation mechanism, which is necessary for the catalytic activity of ALR2.
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| http://dx.doi.org/10.1016/j.bioorg.2020.103640 | DOI Listing |
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