Shumyatsky Gabriella, Burrell Aszia, Chaney Hollis, Sami Iman, Koumbourlis Anastassios C, Freishtat Robert J, Crandall Keith A, Zemanick Edith T, Hahn Andrea
Jefferson Biotechnology Program, Thomas Jefferson University, Philadelphia, PA, United States.
Center for Genetic Medicine Research, Children's National Research Institute, Washington, DC, United States.
Front Med (Lausanne). 2023 Jan 9;9:1082125. doi: 10.3389/fmed.2022.1082125. eCollection 2022.
Pulmonary exacerbations (PEx) in persons with cystic fibrosis (CF) are primarily related to acute or chronic inflammation associated with bacterial lung infections, which may be caused by several bacteria that activate similar bacterial genes and produce similar by-products. The goal of our study was to perform a stratified functional analysis of bacterial genes at three distinct time points in the treatment of a PEx in order to determine the role that specific airway microbiome community members may play within each clinical state (i.e., PEx, end of antibiotic treatment, and follow-up). Our secondary goal was to compare the change between clinical states with the metabolic activity of specific airway microbiome community members.
This was a prospective observational study of persons with CF treated with intravenous antibiotics for PEx between 2016 and 2020 at Children's National Hospital. Demographic and clinical information as well as respiratory samples were collected at hospital admission for PEx, end of antibiotic treatment, and follow-up. Metagenomic sequencing was performed; MetaPhlAn3 and HUMANn3 were used to assign sequences to bacterial species and bacterial metabolic genes, respectively.
Twenty-two persons with CF, with a mean age of 14.5 (range 7-23) years, experienced 45 PEx during the study period. Two-hundred twenty-one bacterial species were identified in the respiratory samples from the study cohort. Ten bacterial species had differential gene abundance across changes in the clinical state including , , and (all padj < 0.01 and log2FoldChange > |2|). These corresponded to a differential abundance of bacterial genes, with accounting for 81% of the genes more abundant in PEx and accounting for 83% of the genes more abundant in follow-up, all compared to the end of treatment. Lastly, 8,653 metabolic pathways were identified across samples, with again and contributing to the differential abundance of pathways (106 in PEx vs. 66 in follow-up, respectively). was associated with a single metabolic pathway (UDP--acetyl-D-glucosamine biosynthesis) increased in follow-up compared to PEx.
Taken together, these data suggest that the metabolic potential of bacterial species can provide more insight into changes across clinical states than the relative abundance of the bacteria alone.
囊性纤维化(CF)患者的肺部加重期(PEx)主要与细菌肺部感染相关的急性或慢性炎症有关,这些感染可能由几种激活相似细菌基因并产生相似副产物的细菌引起。我们研究的目的是在PEx治疗的三个不同时间点对细菌基因进行分层功能分析,以确定特定气道微生物群落成员在每种临床状态(即PEx、抗生素治疗结束和随访)中可能发挥的作用。我们的次要目标是比较临床状态之间的变化与特定气道微生物群落成员的代谢活性。
这是一项对2016年至2020年期间在儿童国家医院接受静脉抗生素治疗PEx的CF患者进行的前瞻性观察研究。在因PEx入院、抗生素治疗结束和随访时收集人口统计学和临床信息以及呼吸道样本。进行宏基因组测序;分别使用MetaPhlAn3和HUMANn3将序列分配给细菌物种和细菌代谢基因。
22名CF患者,平均年龄14.5岁(范围7 - 23岁),在研究期间经历了45次PEx。在研究队列的呼吸道样本中鉴定出221种细菌物种。10种细菌物种在临床状态变化时基因丰度存在差异,包括 、 和 (所有padj < 0.01且log2倍变化 > |2|)。这些对应于细菌基因丰度的差异,与治疗结束相比, 占PEx中丰度更高基因的81%, 占随访中丰度更高基因的83%。最后,在所有样本中鉴定出8653条代谢途径,同样 和 导致途径丰度的差异(PEx中为106条,随访中为66条)。 与一条代谢途径(UDP - N - 乙酰 - D - 葡糖胺生物合成)相关,与PEx相比,该途径在随访中增加。
综上所述,这些数据表明,细菌物种的代谢潜力比单独细菌的相对丰度能更深入地洞察临床状态之间的变化。
