Nikola Kurbatfinski , Preston J. Hill , Noah Tobin , Cameron N. Kramer , Joseph Wickham , Steven D. Goodman , Luanne Hall-Stoodley , Lauren O. Bakaletz
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引用次数: 0
Abstract
Objectives
Structural or mucus hypersecretory pulmonary diseases such as cystic fibrosis (CF), wherein viscous mucus accumulates and clearance functions are impaired, predispose people to lung infection by inhaled bacteria that form biofilm aggregates. Nontuberculous mycobacteria (NTM), primarily Mycobacterium abscessus and Mycobacterium avium, are the growing cause of these lung infections and are extremely challenging to treat due to antibiotic recalcitrance. Better therapeutic approaches are urgently needed. We developed a humanized monoclonal antibody (HuTipMab) directed against a biofilm structural linchpin, the bacterial DNABII proteins, that rapidly disrupts biofilms and generates highly vulnerable newly released bacteria (NRel).
Methods
HuTipMab's ability to recognize HupB, NTM's DNABII homologue was determined by ELISA. Relative ability of HuTipMab to disrupt biofilms formed by lab-passaged and clinical isolates of NTM was assessed by CLSM. Relative sensitivity of NTM NRel to antibiotic killing compared to when grown planktonically was evaluated by plate count.
Results
HuTipMab recognized HupB and significantly disrupted NTM biofilms in a time- and dose-dependent manner. Importantly, NTM NRel of lab-passaged and clinical isolates were now highly sensitive to killing by amikacin and azithromycin.
Conclusions
If successful, this combinatorial treatment strategy would empower existing antibiotics to more effectively kill NTM newly released from a biofilm by HuTipMab and thereby both improve clinical outcomes and perhaps decrease length of antibiotic treatment for people that are NTM culture-positive.
结构性或粘液高分泌性肺部疾病,如囊性纤维化(CF),其中粘性粘液积聚和清除功能受损,易使人因吸入形成生物膜聚集体的细菌而感染肺部。非结核分枝杆菌(NTM),主要是脓肿分枝杆菌和鸟分枝杆菌,是这些肺部感染的日益增长的原因,由于抗生素的顽固性,治疗极具挑战性。迫切需要更好的治疗方法。我们开发了一种人源化单克隆抗体(HuTipMab),针对生物膜结构关键,细菌DNABII蛋白,快速破坏生物膜并产生高度脆弱的新释放细菌(NRel)。方法采用ELISA法检测shutipmab对HupB、NTM dna ii同源物的识别能力。通过CLSM评估HuTipMab破坏实验室传代和临床分离NTM形成的生物膜的相对能力。通过平板计数来评估NTM NRel与浮游生长时对抗生素杀伤的相对敏感性。结果shutipmab识别HupB,并以时间和剂量依赖的方式显著破坏NTM生物膜。重要的是,实验室传代和临床分离的NTM NRel现在对阿米卡星和阿奇霉素的杀伤高度敏感。结论如果成功,这种联合治疗策略将使现有抗生素能够更有效地杀死由HuTipMab从生物膜中释放的NTM,从而改善临床结果,并可能缩短NTM培养阳性患者的抗生素治疗时间。
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