5jmx Citations

Structure activity relationship studies on rhodanines and derived enethiol inhibitors of metallo-β-lactamases.
Fig. 1
Scheme 1
Zhang D, Markoulides MS, Stepanovs D, Rydzik AM, El-Hussein A, Bon C, Kamps JJAG, Umland KD, Collins PM, Cahill ST, Wang DY, von Delft F, Brem J, McDonough MA, Schofield CJ
OpenAccess logo Bioorg Med Chem 26 2928-2936 (2018)
Related entries: 6eum, 6ew3, 6ewe, 6f2n

Cited: 8 times
EuropePMC logo PMID: 29655609

Abstract

Metallo-β-lactamases (MBLs) enable bacterial resistance to almost all classes of β-lactam antibiotics. We report studies on enethiol containing MBL inhibitors, which were prepared by rhodanine hydrolysis. The enethiols inhibit MBLs from different subclasses. Crystallographic analyses reveal that the enethiol sulphur displaces the di-Zn(II) ion bridging 'hydrolytic' water. In some, but not all, cases biophysical analyses provide evidence that rhodanine/enethiol inhibition involves formation of a ternary MBL enethiol rhodanine complex. The results demonstrate how low molecular weight active site Zn(II) chelating compounds can inhibit a range of clinically relevant MBLs and provide additional evidence for the potential of rhodanines to be hydrolysed to potent inhibitors of MBL protein fold and, maybe, other metallo-enzymes, perhaps contributing to the complex biological effects of rhodanines. The results imply that any medicinal chemistry studies employing rhodanines (and related scaffolds) as inhibitors should as a matter of course include testing of their hydrolysis products.

Articles - 5jmx mentioned but not cited (1)

  1. Structure activity relationship studies on rhodanines and derived enethiol inhibitors of metallo-β-lactamases. Zhang D, Markoulides MS, Stepanovs D, Rydzik AM, El-Hussein A, Bon C, Kamps JJAG, Umland KD, Collins PM, Cahill ST, Wang DY, von Delft F, Brem J, McDonough MA, Schofield CJ. Bioorg Med Chem 26 2928-2936 (2018)


Reviews citing this publication (4)

  1. β-lactam/β-lactamase inhibitor combinations: an update. Tehrani KHME, Martin NI. Medchemcomm 9 1439-1456 (2018)
  2. Metallo-β-lactamases in the Age of Multidrug Resistance: From Structure and Mechanism to Evolution, Dissemination, and Inhibitor Design. Bahr G, González LJ, Vila AJ. Chem Rev 121 7957-8094 (2021)
  3. Metallo-β-Lactamase Inhibitors Inspired on Snapshots from the Catalytic Mechanism. Palacios AR, Rossi MA, Mahler GS, Vila AJ. Biomolecules 10 E854 (2020)
  4. Approaches for the discovery of metallo-β-lactamase inhibitors: A review. Shi C, Chen J, Kang X, Shen X, Lao X, Zheng H. Chem Biol Drug Des 94 1427-1440 (2019)

Articles citing this publication (3)

  1. Three-Dimensional Structure and Optimization of the Metallo-β-Lactamase Inhibitor Aspergillomarasmine A. Koteva K, Sychantha D, Rotondo CM, Hobson C, Britten JF, Wright GD. ACS Omega 7 4170-4184 (2022)
  2. Molecular mechanisms underlying the renoprotective effects of 1,4,7-triazacyclononane: a βeta-lactamase inhibitor. Tsotetsi N, Amoako DG, Somboro AM, Khumalo HM, Khan RB. Cytotechnology 72 785-796 (2020)
  3. Towards combating antibiotic resistance by exploring the quantitative structure-activity relationship of NDM-1 inhibitors. Yu T, Ahmad Malik A, Anuwongcharoen N, Eiamphungporn W, Nantasenamat C, Piacham T. EXCLI J 21 1331-1351 (2022)


Quick links