Department of Chemistry and Biochemistry, University of Oklahoma, 101 Stephenson Parkway, Norman, Oklahoma 73019, United States.
Department of Pharmacological and Physiological Science, Saint Louis University School of Medicine, St. Louis, Missouri 63104, United States.
Acc Chem Res. 2021 Feb 16;54(4):930-939. doi: 10.1021/acs.accounts.0c00843. Epub 2021 Feb 4.
Antibiotics are miracle drugs that can cure infectious bacterial diseases. However, their utility is challenged by antibiotic-resistant bacteria emerging in clinics and straining modern medicine and our ways of life. Certain bacteria such as Gram-negative (Gram(-)) and Mycobacteriales species are intrinsically resistant to most clinical antibiotics and can further gain multidrug resistance through mutations and plasmid acquisition. These species stand out by the presence of an additional external lipidic membrane, the outer membrane (OM), that is composed of unique glycolipids. Although formidable, the OM is a passive permeability barrier that can reduce penetration of antibiotics but cannot affect intracellular steady-state concentrations of drugs. The two-membrane envelopes are further reinforced by active efflux transporters that expel antibiotics from cells against their concentration gradients. The major mechanism of antibiotic resistance in Gram(-) pathogens is the active efflux of drugs, which acts synergistically with the low permeability barrier of the OM and other mutational and plasmid-borne mechanisms of antibiotic resistance.The synergy between active efflux and slow uptake offers Gram(-) bacteria an impressive degree of protection from potentially harmful chemicals, but it is also their Achilles heel. Kinetic studies have revealed that even small changes in the efficiency of either of the two factors can have dramatic effects on drug penetration into the cell. In line with these expectations, two major approaches to overcome this antibiotic resistance mechanism are currently being explored: (1) facilitation of antibiotic penetration across the outer membranes and (2) avoidance and inhibition of clinically relevant multidrug efflux pumps. Herein we summarize the progress in the latter approach with a focus on efflux pumps from the resistance-nodulation-division (RND) superfamily. The ability to export various substrates across the OM at the expense of the proton-motive force acting on the inner membrane and the engagement of accessory proteins for their functions are the major mechanistic advantages of these pumps. Both the RND transporters and their accessory proteins are being targeted in the discovery of efflux pump inhibitors, which in combination with antibiotics can potentiate antibacterial activities. We discuss intriguing relationships between substrates and inhibitors of efflux pumps, as these two types of ligands face similar barriers and binding sites in the transporters and accessory proteins and both types of activities often occur with the same chemical scaffold. Several distinct chemical classes of efflux inhibitors have been discovered that are as structurally diverse as the substrates of efflux pumps. Recent mechanistic insights, both empirical and computational, have led to the identification of features that distinguish OM permeators and efflux pump avoiders as well as efflux inhibitors from substrates. These findings suggest a path forward for optimizing the OM permeation and efflux-inhibitory activities in antibiotics and other chemically diverse compounds.
抗生素是能治愈感染性细菌疾病的神奇药物。然而,在临床中出现的抗生素耐药细菌对它们提出了挑战,使现代医学和我们的生活方式都受到了影响。某些细菌,如革兰氏阴性(Gram(-))和分枝杆菌科,对大多数临床抗生素天然具有耐药性,并且可以通过突变和质粒获得进一步获得多药耐药性。这些物种的特点是存在额外的外部脂质膜,即外膜(OM),它由独特的糖脂组成。尽管 OM 是一个令人生畏的被动渗透屏障,可以降低抗生素的穿透性,但它不能影响细胞内药物的稳态浓度。两层膜包膜进一步由主动外排转运蛋白加固,这些转运蛋白将抗生素从细胞中排出,逆浓度梯度进行。革兰氏阴性病原体中抗生素耐药的主要机制是药物的主动外排,它与 OM 的低渗透性屏障以及其他突变和质粒介导的抗生素耐药机制协同作用。主动外排和摄取缓慢之间的协同作用使革兰氏阴性细菌免受潜在有害化学物质的侵害,但这也是它们的阿喀琉斯之踵。动力学研究表明,即使这两个因素中的任何一个的效率发生微小变化,都会对药物穿透细胞产生巨大影响。根据这些预期,目前正在探索两种克服这种抗生素耐药机制的主要方法:(1)促进抗生素穿透外膜,(2)避免和抑制临床相关的多药外排泵。本文总结了后一种方法的进展,重点介绍了耐药-结节-分裂(RND)超家族的外排泵。这些泵的主要机制优势是能够在质子动力的作用下,将各种底物穿过 OM 进行运输,同时还利用辅助蛋白来发挥其功能。这些泵的 RND 转运蛋白及其辅助蛋白都成为了外排泵抑制剂的靶标,这些抑制剂与抗生素联合使用可以增强抗菌活性。我们讨论了外排泵的底物和抑制剂之间的有趣关系,因为这两种类型的配体在转运蛋白和辅助蛋白中面临着相似的障碍和结合位点,并且这两种类型的活性通常都发生在相同的化学支架上。已经发现了几种不同的化学类别的外排抑制剂,它们的结构与外排泵的底物一样多样化。最近的经验和计算机制研究结果,确定了区分 OM 渗透剂和外排泵回避物以及外排抑制剂与底物的特征。这些发现为优化抗生素和其他化学多样性化合物的 OM 穿透和外排抑制活性提供了前进的道路。