Your search keyword '"Bloemen, Bram"' showing total 2 results

1. Towards facilitated interpretation of shotgun metagenomics long-read sequencing data analyzed with KMA for the detection of bacterial pathogens and their antimicrobial resistance genes.

Author

Gand, Mathieu, Navickaite, Indre, Bartsch, Lee-Julia, Grützke, Josephine, Overballe-Petersen, Søren, Rasmussen, Astrid, Otani, Saria, Michelacci, Valeria, Rodríguez Matamoros, Bosco, González-Zorn, Bruno, Brouwer, Michael S. M., Di Marcantonio, Lisa, Bloemen, Bram, Vanneste, Kevin, Roosens, Nancy H. C. J., AbuOun, Manal, and De Keersmaecker, Sigrid C. J.

Subjects

DRUG resistance in microorganisms, METAGENOMICS, BACTERIAL chromosomes, GENES, POPULAR literature, SWINE farms

Abstract

Metagenomic sequencing is a promising method that has the potential to revolutionize the world of pathogen detection and antimicrobial resistance (AMR) surveillance in food-producing environments. However, the analysis of the huge amount of data obtained requires performant bioinformatics tools and databases, with intuitive and straightforward interpretation. In this study, based on long-read metagenomics data of chicken fecal samples with a spike-in mock community, we proposed confidence levels for taxonomic identification and AMR gene detection, with interpretation guidelines, to help with the analysis of the output data generated by KMA, a popular k-mer read alignment tool. Additionally, we demonstrated that the completeness and diversity of the genomes present in the reference databases are key parameters for accurate and easy interpretation of the sequencing data. Finally, we explored whether KMA, in a two-step procedure, can be used to link the detected AMR genes to their bacterial host chromosome, both detected within the same long-reads. The confidence levels were successfully tested on 28 metagenomics datasets which were obtained with sequencing of real and spiked samples from fecal (chicken, pig, and buffalo) or food (minced beef and food enzyme products) origin. The methodology proposed in this study will facilitate the analysis of metagenomics sequencing datasets for KMA users. Ultimately, this will contribute to improvements in the rapid diagnosis and surveillance of pathogens and AMR genes in food-producing environments, as prioritized by the EU. [ABSTRACT FROM AUTHOR]

Published

2024

2. Development of a portable on-site applicable metagenomic data generation workflow for enhanced pathogen and antimicrobial resistance surveillance.

Author

Bloemen, Bram, Gand, Mathieu, Vanneste, Kevin, Marchal, Kathleen, Roosens, Nancy H. C., and De Keersmaecker, Sigrid C. J.

Subjects

*DRUG resistance in microorganisms, *METAGENOMICS, *PATHOGENIC microorganisms, *WORKFLOW software, *LABORATORY equipment & supplies, *DNA, *WORKFLOW

Abstract

Rapid, accurate and comprehensive diagnostics are essential for outbreak prevention and pathogen surveillance. Real-time, on-site metagenomics on miniaturized devices, such as Oxford Nanopore Technologies MinION sequencing, could provide a promising approach. However, current sample preparation protocols often require substantial equipment and dedicated laboratories, limiting their use. In this study, we developed a rapid on-site applicable DNA extraction and library preparation approach for nanopore sequencing, using portable devices. The optimized method consists of a portable mechanical lysis approach followed by magnetic bead-based DNA purification and automated sequencing library preparation, and resulted in a throughput comparable to a current optimal, laboratory-based protocol using enzymatic digestion to lyse cells. By using spike-in reference communities, we compared the on-site method with other workflows, and demonstrated reliable taxonomic profiling, despite method-specific biases. We also demonstrated the added value of long-read sequencing by recovering reads containing full-length antimicrobial resistance genes, and attributing them to a host species based on the additional genomic information they contain. Our method may provide a rapid, widely-applicable approach for microbial detection and surveillance in a variety of on-site settings. [ABSTRACT FROM AUTHOR]

Published

2023