Department of Large Animal Clinical Sciences, Western College of Veterinary Medicine, University of Saskatchewan, 52 Campus Drive, Saskatoon, SK, S7N 5B4, Canada.
Department of Agricultural, Food, and Nutritional Science, Faculty of Agricultural, Life, and Environmental Sciences, University of Alberta, 2-31 General Services Building, Edmonton, AB, T6G 2H1, Canada.
BMC Vet Res. 2022 Jun 2;18(1):211. doi: 10.1186/s12917-022-03269-6.
Bovine respiratory disease (BRD) is an important cause of morbidity and mortality and is responsible for most of the injectable antimicrobial use in the feedlot industry. Traditional bacterial culture can be used to diagnose BRD by confirming the presence of causative pathogens and to support antimicrobial selection. However, given that bacterial culture takes up to a week and early intervention is critical for treatment success, culture has limited utility for informing rapid therapeutic decision-making. In contrast, metagenomic sequencing has the potential to quickly resolve all nucleic acid in a sample, including pathogen biomarkers and antimicrobial resistance genes. In particular, third-generation Oxford Nanopore Technology sequencing platforms provide long reads and access to raw sequencing data in real-time as it is produced, thereby reducing the time from sample collection to diagnostic answer. The purpose of this study was to compare the performance of nanopore metagenomic sequencing to traditional culture and sensitivity methods as applied to nasopharyngeal samples from segregated groups of chronically ill feedlot cattle, previously treated with antimicrobials for nonresponsive pneumonia or lameness.
BRD pathogens were isolated from most samples and a variety of different resistance profiles were observed across isolates. The sequencing data indicated the samples were dominated by Moraxella bovoculi, Mannheimia haemolytica, Mycoplasma dispar, and Pasteurella multocida, and included a wide range of antimicrobial resistance genes (ARGs), encoding resistance for up to seven classes of antimicrobials. Genes conferring resistance to beta-lactams were the most commonly detected, while the tetH gene was detected in the most samples overall. Metagenomic sequencing detected the BRD pathogens of interest more often than did culture, but there was limited concordance between phenotypic resistance to antimicrobials and the presence of relevant ARGs.
Metagenomic sequencing can reduce the time from sampling to results, detect pathogens missed by bacterial culture, and identify genetically encoded determinants of resistance. Increasing sequencing coverage of target organisms will be an essential component of improving the reliability of this technology, such that it can be better used for the surveillance of pathogens of interest, genetic determinants of resistance, and to inform diagnostic decisions.
牛呼吸道疾病(BRD)是发病率和死亡率的重要原因,也是饲料加工厂中大多数注射用抗生素使用的原因。传统的细菌培养可通过确认致病病原体的存在来诊断 BRD,并支持抗生素的选择。但是,由于细菌培养需要一周的时间,并且早期干预对于治疗成功至关重要,因此培养对于快速治疗决策的信息有限。相比之下,宏基因组测序有可能快速解析样本中的所有核酸,包括病原体生物标志物和抗生素耐药基因。特别是,第三代牛津纳米孔技术测序平台提供了长读长,并实时访问实时产生的原始测序数据,从而减少了从样本采集到诊断答案的时间。本研究的目的是比较纳米孔宏基因组测序与传统培养和药敏方法在先前用抗生素治疗无反应性肺炎或跛行的慢性患病牛隔离组的鼻拭子样本中的性能。
从大多数样本中分离出 BRD 病原体,并观察到分离株具有多种不同的耐药谱。测序数据表明,样品主要由莫拉氏菌属、曼海姆氏菌属、支原体属和多杀巴斯德氏菌属,包括广泛的抗生素耐药基因(ARGs),编码对多达七种类别的抗生素的耐药性。检测到的耐药基因赋予对β-内酰胺类抗生素的耐药性,而 tetH 基因在大多数样品中总体上的检测率最高。宏基因组测序比培养更频繁地检测到 BRD 病原体,但表型对抗生素的耐药性与相关 ARGs 的存在之间的一致性有限。
宏基因组测序可以减少从采样到结果的时间,检测到细菌培养遗漏的病原体,并鉴定出遗传编码的耐药决定因素。增加目标生物的测序覆盖率将是提高该技术可靠性的重要组成部分,以便更好地用于监测感兴趣的病原体、耐药基因的遗传决定因素,并为诊断决策提供信息。
