Genomics and Machine Learning for Taxonomy Consensus: The Mycobacterium tuberculosis Complex Paradigm

Infra-species taxonomy is a prerequisite to compare features such as virulence in different pathogen lineages. Mycobacterium tuberculosis complex taxonomy has rapidly evolved in the last 20 years through intensive clinical isolation, advances in sequencing and in the description of fast-evolving loc...

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Bibliographic Details
Published in:PloS one 2015-07, Vol.10 (7), p.e0130912-e0130912
Main Authors: Azé, Jérôme, Sola, Christophe, Zhang, Jian, Lafosse-Marin, Florian, Yasmin, Memona, Siddiqui, Rubina, Kremer, Kristin, van Soolingen, Dick, Refrégier, Guislaine
Format: Article
Language:English
Subjects:
Algorithms
Bacterial Typing Techniques - methods
Biology
Biotechnology
Classification
Clinical isolates
Cluster Analysis
Computational Biology
Computer Science
CRISPR
Databases, Genetic
Deoxyribonucleic acid
DNA
DNA, Bacterial - genetics
Epidemiology
Genetic engineering
Genomes
Genomics
Genotype
Genotyping
Hybridization
Internet
Learning algorithms
Machine Learning
Metabolism
Molecular Epidemiology
Mycobacterium tuberculosis
Mycobacterium tuberculosis - classification
Organisms
Polymerase Chain Reaction
Polymorphism, Restriction Fragment Length
Polymorphism, Single Nucleotide
Prevalence
Public health
Single nucleotide polymorphisms
Studies
Taxonomy
Tuberculosis
Tuberculosis - microbiology
Virulence
Virulence (Microbiology)
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Summary:Infra-species taxonomy is a prerequisite to compare features such as virulence in different pathogen lineages. Mycobacterium tuberculosis complex taxonomy has rapidly evolved in the last 20 years through intensive clinical isolation, advances in sequencing and in the description of fast-evolving loci (CRISPR and MIRU-VNTR). On-line tools to describe new isolates have been set up based on known diversity either on CRISPRs (also known as spoligotypes) or on MIRU-VNTR profiles. The underlying taxonomies are largely concordant but use different names and offer different depths. The objectives of this study were 1) to explicit the consensus that exists between the alternative taxonomies, and 2) to provide an on-line tool to ease classification of new isolates. Genotyping (24-VNTR, 43-spacers spoligotypes, IS6110-RFLP) was undertaken for 3,454 clinical isolates from the Netherlands (2004-2008). The resulting database was enlarged with African isolates to include most human tuberculosis diversity. Assignations were obtained using TB-Lineage, MIRU-VNTRPlus, SITVITWEB and an algorithm from Borile et al. By identifying the recurrent concordances between the alternative taxonomies, we proposed a consensus including 22 sublineages. Original and consensus assignations of the all isolates from the database were subsequently implemented into an ensemble learning approach based on Machine Learning tool Weka to derive a classification scheme. All assignations were reproduced with very good sensibilities and specificities. When applied to independent datasets, it was able to suggest new sublineages such as pseudo-Beijing. This Lineage Prediction tool, efficient on 15-MIRU, 24-VNTR and spoligotype data is available on the web interface "TBminer." Another section of this website helps summarizing key molecular epidemiological data, easing tuberculosis surveillance. Altogether, we successfully used Machine Learning on a large dataset to set up and make available the first consensual taxonomy for human Mycobacterium tuberculosis complex. Additional developments using SNPs will help stabilizing it.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0130912