A machine learning-based typing scheme refinement for Listeria monocytogenes core genome multilocus sequence typing with high discriminatory power for common source outbreak tracking

• Published in: PloS one Vol. 16; no. 11; p. e0260293
• Main Authors: Liu, Yen-Yi, Chen, Chih-Chieh
• Format: Journal Article
• Language: English
• Published: United States Public Library of Science 19.11.2021; Public Library of Science (PLoS)
• Subjects: Algorithms; Alleles; Analysis; Artificial Intelligence; Biology and Life Sciences; Computer and Information Sciences; Datasets; Diagnostic Tests, Routine - methods; Disease Outbreaks; Epidemiology; Feature selection; Gene sequencing; Genetic Techniques; Genome, Bacterial - genetics; Genomes; Genomics - methods; Humans; Learning algorithms; Listeria; Listeria monocytogenes; Listeria monocytogenes - genetics; Listeriosis - epidemiology; Listeriosis - microbiology; Loci; Machine Learning; Medicine and Health Sciences; Molecular Epidemiology - methods; Multilocus sequence typing; Multilocus Sequence Typing - methods; Nucleotide sequence; Outbreaks; Pathogens; Research and Analysis Methods; Whole genome sequencing; Whole Genome Sequencing - methods; Taiwan
• ISSN: 1932-6203; 1932-6203
• DOI: 10.1371/journal.pone.0260293

As whole-genome sequencing for pathogen genomes becomes increasingly popular, the typing methods of gene-by-gene comparison, such as core genome multilocus sequence typing (cgMLST) and whole-genome multilocus sequence typing (wgMLST), are being routinely implemented in molecular epidemiology. However, some intrinsic problems remain. For example, genomic sequences with varying read depths, read lengths, and assemblers influence the genome assemblies, introducing error or missing alleles into the generated allelic profiles. These errors and missing alleles might create "specious discrepancy" among closely related isolates, thus making accurate epidemiological interpretation challenging. In addition, the rapid growth of the cgMLST allelic profile database can cause problems related to storage and maintenance as well as long query search times. We attempted to resolve these issues by decreasing the scheme size to reduce the occurrence of error and missing alleles, alleviate the storage burden, and improve the query search time. The challenge in this approach is maintaining the typing resolution when using fewer loci. We achieved this by using a popular artificial intelligence technique, XGBoost, coupled with Shapley additive explanations for feature selection. Finally, 370 loci from the original 1701 cgMLST loci of Listeria monocytogenes were selected. Although the size of the final scheme (LmScheme_370) was approximately 80% lower than that of the original cgMLST scheme, its discriminatory power, tested for 35 outbreaks, was concordant with that of the original cgMLST scheme. Although we used L. monocytogenes as a demonstration in this study, the approach can be applied to other schemes and pathogens. Our findings might help elucidate gene-by-gene-based epidemiology.