Center for Molecular and Translational Human Infectious Diseases Research, Department of Pathology and Genomic Medicine, Houston Methodist Research Institute and Houston Methodist Hospital, Houston, Texas, USA.
Department of Pathology and Laboratory Medicine, Weill Cornell Medical College, New York, New York, USA.
mBio. 2017 May 16;8(3):e00489-17. doi: 10.1128/mBio.00489-17.
is a major human pathogen responsible for high morbidity and mortality rates. The emergence and spread of strains resistant to multiple antimicrobial agents and documented large nosocomial outbreaks are especially concerning. To develop new therapeutic strategies for , it is imperative to understand the population genomic structure of strains causing human infections. To address this knowledge gap, we sequenced the genomes of 1,777 extended-spectrum beta-lactamase-producing strains cultured from patients in the 2,000-bed Houston Methodist Hospital system between September 2011 and May 2015, representing a comprehensive, population-based strain sample. Strains of largely uncharacterized clonal group 307 (CG307) caused more infections than those of well-studied epidemic CG258. Strains varied markedly in gene content and had an extensive array of small and very large plasmids, often containing antimicrobial resistance genes. Some patients with multiple strains cultured over time were infected with genetically distinct clones. We identified 15 strains expressing the New Delhi metallo-beta-lactamase 1 (NDM-1) enzyme that confers broad resistance to nearly all beta-lactam antibiotics. Transcriptome sequencing analysis of 10 phylogenetically diverse strains showed that the global transcriptome of each strain was unique and highly variable. Experimental mouse infection provided new information about immunological parameters of host-pathogen interaction. We exploited the large data set to develop whole-genome sequence-based classifiers that accurately predict clinical antimicrobial resistance for 12 of the 16 antibiotics tested. We conclude that analysis of large, comprehensive, population-based strain samples can assist understanding of the molecular diversity of these organisms and contribute to enhanced translational research. causes human infections that are increasingly difficult to treat because many strains are resistant to multiple antibiotics. Clonal group 258 (CG258) organisms have caused outbreaks in health care settings worldwide. Using a comprehensive population-based sample of extended-spectrum beta-lactamase (ESBL)-producing strains, we show that a relatively uncommon clonal type, CG307, caused the plurality of ESBL-producing infections in our patients. We discovered that CG307 strains have been abundant in Houston for many years. As assessed by experimental mouse infection, CG307 strains were as virulent as pandemic CG258 strains. Our results may portend the emergence of an especially successful clonal group of antibiotic-resistant .
是一种主要的人类病原体,可导致高发病率和死亡率。出现并传播对多种抗菌药物具有耐药性的菌株,以及有记录的大型医院内暴发,尤其令人担忧。为了开发针对的新治疗策略,了解引起人类感染的菌株的群体基因组结构至关重要。为了解决这一知识空白,我们对 2011 年 9 月至 2015 年 5 月期间在休斯顿卫理公会医院系统的 2000 张病床中培养的 1777 株产超广谱β-内酰胺酶的进行了基因组测序,这代表了一个全面的、基于人群的菌株样本。大量特征不明确的克隆群 307(CG307)菌株引起的感染比研究较多的流行 CG258 菌株引起的感染更多。菌株在基因组成上差异显著,并且具有广泛的小型和大型质粒,这些质粒通常含有抗菌药物耐药基因。一些随着时间推移培养出多种菌株的患者感染了遗传上不同的克隆。我们鉴定出 15 株表达新德里金属β-内酰胺酶 1(NDM-1)酶的菌株,该酶对几乎所有β-内酰胺类抗生素具有广泛的耐药性。对 10 株具有不同系统发育的菌株进行的转录组测序分析表明,每个菌株的全球转录组都是独特的且高度可变的。实验性小鼠感染提供了宿主-病原体相互作用的免疫参数的新信息。我们利用大量数据集开发了基于全基因组序列的分类器,可准确预测 16 种测试抗生素中的 12 种的临床抗菌药物耐药性。我们的结论是,对大型、全面、基于人群的菌株样本进行分析有助于了解这些生物体的分子多样性,并有助于加强转化研究。引起的人类感染越来越难以治疗,因为许多菌株对多种抗生素具有耐药性。克隆群 258(CG258)生物体已在全球卫生保健环境中引起暴发。使用产超广谱β-内酰胺酶(ESBL)的菌株的全面人群样本,我们表明,一种相对不常见的克隆类型 CG307 引起了我们患者中大多数产 ESBL 的感染。我们发现 CG307 菌株在休斯顿已经存在多年了。如通过实验性小鼠感染评估的,CG307 菌株与大流行的 CG258 菌株一样具有毒力。我们的结果可能预示着一种特别成功的抗生素耐药的克隆群的出现。
