School of Cellular and Molecular Medicine, University of Bristol, Biomedical Sciences Building, University Walk, Bristol BS8 1TD, U.K.
Instituto de Química de Rosario (IQUIR, CONICET-UNR), Suipacha 570, S2002LRK Rosario, Argentina.
ACS Infect Dis. 2021 Sep 10;7(9):2697-2706. doi: 10.1021/acsinfecdis.1c00194. Epub 2021 Aug 6.
Metallo-β-lactamase (MBL) production in Gram-negative bacteria is an important contributor to β-lactam antibiotic resistance. Combining β-lactams with β-lactamase inhibitors (BLIs) is a validated route to overcoming resistance, but MBL inhibitors are not available in the clinic. On the basis of zinc utilization and sequence, MBLs are divided into three subclasses, B1, B2, and B3, whose differing active-site architectures hinder development of BLIs capable of "cross-class" MBL inhibition. We previously described 2-mercaptomethyl thiazolidines (MMTZs) as B1 MBL inhibitors (e.g., NDM-1) and here show that inhibition extends to the clinically relevant B2 (Sfh-I) and B3 (L1) enzymes. MMTZs inhibit purified MBLs (e.g., Sfh-I, 0.16 μM) and potentiate β-lactam activity against producer strains. X-ray crystallography reveals that inhibition involves direct interaction of the MMTZ thiol with the mono- or dizinc centers of Sfh-I/L1, respectively. This is further enhanced by sulfur-π interactions with a conserved active site tryptophan. Computational studies reveal that the stereochemistry at chiral centers is critical, showing less potent MMTZ stereoisomers (up to 800-fold) as unable to replicate sulfur-π interactions in Sfh-I, largely through steric constraints in a compact active site. Furthermore, replacement of the thiazolidine sulfur with oxygen (forming an oxazolidine) resulted in less favorable aromatic interactions with B2 MBLs, though the effect is less than that previously observed for the subclass B1 enzyme NDM-1. In the B3 enzyme L1, these effects are offset by additional MMTZ interactions with the protein main chain. MMTZs can therefore inhibit all MBL classes by maintaining conserved binding modes through different routes.
金属β-内酰胺酶(MBL)在革兰氏阴性菌中的产生是β-内酰胺类抗生素耐药性的一个重要因素。将β-内酰胺类药物与β-内酰胺酶抑制剂(BLIs)联合使用是克服耐药性的有效途径,但临床上尚未有 MBL 抑制剂。根据锌的利用和序列,MBLs 分为三个亚类,B1、B2 和 B3,它们不同的活性位点结构阻碍了能够“跨类”抑制 MBL 的 BLIs 的开发。我们之前描述了 2-巯基甲基噻唑烷(MMTZs)作为 B1 MBL 抑制剂(例如,NDM-1),并在此表明抑制作用扩展到了临床相关的 B2(Sfh-I)和 B3(L1)酶。MMTZs 抑制纯化的 MBLs(例如,Sfh-I,0.16 μM)并增强了产酶株对β-内酰胺类药物的活性。X 射线晶体学显示,抑制涉及 MMTZ 硫醇与 Sfh-I/L1 的单核或双核锌中心的直接相互作用。这进一步通过与保守活性位点色氨酸的硫-π 相互作用得到增强。计算研究表明,手性中心的立体化学是关键的,表现出较弱的 MMTZ 立体异构体(高达 800 倍)无法在 Sfh-I 中复制硫-π 相互作用,主要是由于紧凑的活性位点中的空间位阻。此外,将噻唑烷的硫用氧(形成恶唑烷)取代导致与 B2 MBLs 的芳香相互作用不太有利,尽管这种影响小于先前观察到的亚类 B1 酶 NDM-1 的影响。在 B3 酶 L1 中,这些影响被 MMTZ 与蛋白质主链的额外相互作用所抵消。因此,MMTZs 可以通过不同途径保持保守的结合模式来抑制所有 MBL 类。
