Nijhuis R H T, Oueslati S, Zhou K, Bosboom R W, Rossen J W A, Naas T
Laboratory for Medical Microbiology and Immunology, Rijnstate, Velp, The Netherlands
Bactériologie-Virologie, AP-HP, LabEx LERMIT, Univ. Paris-Sud, Paris, France.
J Antimicrob Chemother. 2015 May;70(5):1429-33. doi: 10.1093/jac/dkv002. Epub 2015 Jan 27.
Klebsiella oxytoca is a member of the family of Enterobacteriaceae and often contains the β-lactamase blaOXY gene. Although this β-lactamase does not naturally hydrolyse ceftazidime, this study describes possible in vivo selection of a clinical K. oxytoca isolate showing increased MICs of ceftazidime.
To reveal the molecular mechanism underlying this unusual resistance phenotype, WGS, cloning, overexpression, MIC and steady-state kinetic studies were performed.
A patient was treated for a septic episode with ceftazidime (4 g/day). This therapy was based on earlier culture results in which, amongst others, a K. oxytoca (Velp-1) isolate was identified. After 11 days of treatment, K. oxytoca Velp-2 was isolated from a pus sample drained from the wound. The isolate showed increased resistance to ceftazidime (MIC ≥64 mg/L) compared with the original K. oxytoca isolate (Velp-1). WGS revealed the presence of a novel blaOXY-2 allele, designated blaOXY-2-15, with a two amino acid deletion at Ambler positions 168 and 169 compared with OXY-2-2. Cloning blaOXY-2-15 into Escherichia coli TOP10 resulted in increased MICs of ceftazidime, but reduced MICs of most other β-lactams compared with OXY-2-2. Steady-state kinetics confirmed the results of the MIC data, showing clearly significant ceftazidime hydrolysis.
This report shows the risk of in vivo selection of ceftazidime-resistant K. oxytoca isolates after prolonged ceftazidime treatment. Furthermore, it is the first known report of a K. oxytoca isolate conferring resistance to ceftazidime by a two amino acid deletion in the omega loop of OXY-2-2.
产酸克雷伯菌是肠杆菌科的成员,通常含有β-内酰胺酶blaOXY基因。虽然这种β-内酰胺酶不会自然水解头孢他啶,但本研究描述了临床分离的产酸克雷伯菌体内可能出现头孢他啶MIC升高的情况。
为揭示这种异常耐药表型背后的分子机制,进行了全基因组测序(WGS)、克隆、过表达、MIC及稳态动力学研究。
一名患者因败血症用头孢他啶(4g/天)治疗。该治疗基于早期培养结果,其中鉴定出一株产酸克雷伯菌(Velp-1)。治疗11天后,从伤口引流的脓液样本中分离出产酸克雷伯菌Velp-2。与原始的产酸克雷伯菌分离株(Velp-1)相比,该分离株对头孢他啶的耐药性增加(MIC≥64mg/L)。WGS显示存在一个新的blaOXY-2等位基因,命名为blaOXY-2-15,与OXY-2-2相比,在Ambler位置168和169处有两个氨基酸缺失。将blaOXY-2-15克隆到大肠杆菌TOP10中导致头孢他啶的MIC增加,但与OXY-2-2相比,大多数其他β-内酰胺类药物的MIC降低。稳态动力学证实了MIC数据的结果,显示出明显的头孢他啶水解。
本报告显示了长期使用头孢他啶治疗后体内选择耐头孢他啶产酸克雷伯菌分离株的风险。此外,这是首次报道产酸克雷伯菌分离株通过OXY-2-2的ω环中两个氨基酸缺失而对头孢他啶产生耐药性。
