Department of Bacteria, Parasites and Fungi, Research Unit for Reproductive Tract Microbiology, Statens Serum Institut, Copenhagen, Denmark.
GlaxoSmithKline, Collegeville, Pennsylvania, USA.
Emerg Microbes Infect. 2020 Dec;9(1):1388-1392. doi: 10.1080/22221751.2020.1775498.
has developed resistance to first-line azithromycin and second-line moxifloxacin. Third-line pristinamycin is only 75% effective. Gepotidacin, a novel triazaacenaphthylene topoisomerase II inhibitor, blocks bacterial DNA replication. We determined the activity of gepotidacin alone and in combination with doxycycline against a diverse collection of isolates ( = 54). Minimum inhibitory concentrations (MICs) and minimum bactericidal concentrations (MBCs) were determined by a Vero-cell culture method. Macrolide resistance was present in 31 (57%) isolates, fluoroquinolone resistance in 18 (33%) isolates, and 17 (31%) had dual resistance. Synergy testing was performed for gepotidacin and doxycycline by checkerboard analysis for two macrolide- and two dual-resistant isolates. Gepotidacin was active against all 54 isolates with median and modal MICs of 0.125 mg/L and MIC of 0.25 mg/L (range ≤0.016-0.5 mg/L). No difference in gepotidacin MIC between macrolide-resistant and -susceptible isolates ( = 0.24) or between fluoroquinolone-, dual-resistant and -susceptible isolates ( = 0.2) was demonstrated. Gepotidacin MBCs were available for 44 isolates with median MIC of 0.064 mg/L and median MBC of 0.125 mg/L. All isolates had ≤4-fold difference between MIC and MBC, suggesting bactericidal effect for gepotidacin. Checkerboard analysis indicated synergistic effect for gepotidacin in combination with doxycycline [fractional inhibitory concentration index (ΣFICI) of 0.5] for two isolates and additive/indifference (ΣFICI at 0.62 and 0.75) for two isolates. Gepotidacin warrants further evaluation in clinical treatment trials for Combination therapy with doxycycline should be clinically studied to assess effect and potential protection against development and/or spread of gepotidacin resistance.
该菌株已对一线阿奇霉素和二线莫西沙星产生耐药性。三线普他霉素的有效率仅为 75%。新型三氮杂萘并乙二酮拓扑异构酶 II 抑制剂 gepotidacin 可阻断细菌 DNA 复制。我们测定了 gepotidacin 单独使用以及与强力霉素联合使用对不同 株分离株( = 54)的活性。通过 Vero 细胞培养法测定最小抑菌浓度(MIC)和最小杀菌浓度(MBC)。31 株(57%)分离株存在大环内酯耐药性,18 株(33%)分离株存在氟喹诺酮耐药性,17 株(31%)存在双重耐药性。通过棋盘分析对 2 株大环内酯和 2 株双重耐药分离株进行 gepotidacin 和强力霉素的协同试验。gpotidacin 对所有 54 株分离株均具有活性,中位和模态 MIC 为 0.125mg/L 和 MIC 为 0.25mg/L(范围为≤0.016-0.5mg/L)。大环内酯耐药和敏感分离株之间的 gepotidacin MIC 无差异( = 0.24),或氟喹诺酮耐药、双重耐药和敏感分离株之间的 MIC 无差异( = 0.2)。可获得 44 株分离株的 gepotidacin MBC,中位 MIC 为 0.064mg/L,中位 MBC 为 0.125mg/L。所有分离株的 MIC 和 MBC 之间的差异均不超过 4 倍,提示 gepotidacin 具有杀菌作用。棋盘分析表明,对于两种分离株,gpotidacin 与强力霉素联合使用具有协同作用(ΣFICI 为 0.5),对于两种分离株,具有相加/无关(ΣFICI 为 0.62 和 0.75)。gpotidacin 值得在临床治疗试验中进一步评估。与强力霉素联合使用的组合疗法应在临床上进行研究,以评估其疗效和对 gepotidacin 耐药性的发展和/或传播的潜在保护作用。
