Department of Infectious Diseases, St. Jude Children's Research Hospital, Memphis, Tennessee, United States of America.
Department of Chemistry, Lomonosov State University, Moscow, Russian Federation.
PLoS Pathog. 2022 Jul 13;18(7):e1010698. doi: 10.1371/journal.ppat.1010698. eCollection 2022 Jul.
Baloxavir marboxil (BXM) is approved for treating uncomplicated influenza. The active metabolite baloxavir acid (BXA) inhibits cap-dependent endonuclease activity of the influenza virus polymerase acidic protein (PA), which is necessary for viral transcription. Treatment-emergent E23G or E23K (E23G/K) PA substitutions have been implicated in reduced BXA susceptibility, but their effect on virus fitness and transmissibility, their synergism with other BXA resistance markers, and the mechanisms of resistance have been insufficiently studied. Accordingly, we generated point mutants of circulating seasonal influenza A(H1N1)pdm09 and A(H3N2) viruses carrying E23G/K substitutions. Both substitutions caused 2- to 13-fold increases in the BXA EC50. EC50s were higher with E23K than with E23G and increased dramatically (138- to 446-fold) when these substitutions were combined with PA I38T, the dominant BXA resistance marker. E23G/K-substituted viruses exhibited slightly impaired replication in MDCK and Calu-3 cells, which was more pronounced with E23K. In ferret transmission experiments, all viruses transmitted to direct-contact and airborne-transmission animals, with only E23K+I38T viruses failing to infect 100% of animals by airborne transmission. E23G/K genotypes were predominantly stable during transmission events and through five passages in vitro. Thermostable PA-BXA interactions were weakened by E23G/K substitutions and further weakened when combined with I38T. In silico modeling indicated this was caused by E23G/K altering the placement of functionally important Tyr24 in the endonuclease domain, potentially decreasing BXA binding but at some cost to the virus. These data implicate E23G/K, alone or combined with I38T, as important markers of reduced BXM susceptibility, and such mutants could emerge and/or transmit among humans.
巴洛沙韦马索利(BXM)已获批准用于治疗单纯性流感。其活性代谢物巴洛沙韦酸(BXA)可抑制流感病毒聚合酶酸性蛋白(PA)的帽依赖性内切酶活性,该活性对病毒转录至关重要。已发现治疗中出现的 E23G 或 E23K(E23G/K)PA 取代与 BXA 敏感性降低有关,但它们对病毒适应性和传染性的影响、与其他 BXA 耐药标志物的协同作用以及耐药机制尚未得到充分研究。因此,我们生成了携带 E23G/K 取代的循环季节性甲型流感 A(H1N1)pdm09 和 A(H3N2)病毒的点突变体。这两种取代均使 BXA EC50 增加了 2 至 13 倍。与 E23G 相比,E23K 引起的 EC50 更高,当与 PA I38T(主要的 BXA 耐药标志物)联合使用时,EC50 急剧增加(138 至 446 倍)。E23G/K 取代的病毒在 MDCK 和 Calu-3 细胞中的复制能力略有受损,E23K 时更为明显。在雪貂传播实验中,所有病毒均传播至直接接触和空气传播动物,只有 E23K+I38T 病毒未能通过空气传播感染 100%的动物。在传播事件中和通过体外 5 次传代过程中,E23G/K 基因型均主要稳定。E23G/K 取代削弱了耐热性 PA-BXA 相互作用,当与 I38T 结合时进一步削弱。计算机模拟表明,这是由于 E23G/K 改变了内切酶结构域中功能重要的 Tyr24 的位置,可能降低了 BXA 的结合,但对病毒有一定的影响。这些数据表明,E23G/K 单独或与 I38T 联合使用,是 BXM 敏感性降低的重要标志物,此类突变体可能在人群中出现和/或传播。
