Abstract
U.S. public health agencies have employed next-generation sequencing (NGS) as a tool to quickly identify foodborne pathogens during outbreaks. Although established short-read NGS technologies are known to provide highly accurate data, long-read sequencing is still needed to resolve highly-repetitive genomic regions and genomic arrangement, and to close the sequences of bacterial chromosomes and plasmids. Here, we report the use of long-read nanopore sequencing to simultaneously sequence the entire chromosome and plasmid of Salmonella enterica subsp. enterica serovar Bareilly and Escherichia coli O157:H7. We developed a rapid and random sequencing approach coupled with de novo genome assembly within a customized data analysis workflow that uses publicly-available tools. In sequencing runs as short as four hours, using the MinION instrument, we obtained full-length genomes with an average identity of 99.87% for Salmonella Bareilly and 99.89% for E. coli in comparison to the respective MiSeq references. These nanopore-only assemblies provided readily available information on serotype, virulence factors, and antimicrobial resistance genes. We also demonstrate the potential of nanopore sequencing assemblies for rapid preliminary phylogenetic inference. Nanopore sequencing provides additional advantages as very low capital investment and footprint, and shorter (10 hours library preparation and sequencing) turnaround time compared to other NGS technologies.
Highlights
U.S public health agencies have employed next-generation sequencing (NGS) as a tool to quickly identify foodborne pathogens during outbreaks
Utilizing publicly-available tools, we report a reproducible bioinformatics workflow which assembled the circularized bacterial genomes and associated plasmids with the lowest error rate reported to date
This study shows that long-read nanopore sequencing can be used as a low-cost method to sequence the whole microbial genomes of foodborne pathogens
Summary
U.S public health agencies have employed next-generation sequencing (NGS) as a tool to quickly identify foodborne pathogens during outbreaks. WGS is a routine procedure in epidemiologic investigation and surveillance of foodborne pathogens, short-read sequencing technology faces challenges such as resolving repetitive regions, which introduce ambiguities that lead to inaccurate sequence reconstruction and incomplete and fragmented de novo assemblies[6,7,8,9]. These gaps can lead to the inability to determine accurate genome organization or architecture, which can be important in determining if genes are co-regulated or co-transmissible in the case of genes associated with. Present address: BASE2BIO, Oshkosh, WI, USA. 3Present address: Office of Public Health Services, Food Safety and Inspection Services, USDA, 950 College Station Road, Athens, GA, USA. 4Present address: Texas A&M Veterinary
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