Abstract
AbstractOutbreaks of tuberculosis- such as the large isoniazid-resistant outbreak centered on London, United Kingdom, which originated in 1995- provide excellent opportunities to model transmission of this devastating disease. Transmission chains for tuberculosis are notoriously difficult to ascertain, but mathematical modelling approaches, combined with whole-genome sequencing (WGS) data, have strong potential to contribute to transmission analyses. Using such data, we aimed to reconstruct transmission histories for the outbreak using a Bayesian approach, and to use machine learning techniques with patient-level data to identify the key covariates associated with transmission. By using our transmission reconstruction method that accounts for phylogenetic uncertainty, we are able to identify 24 transmission events with reasonable confidence, 11 of which have zero single nucleotide polymorphism (SNP) distance, and as maximum distance of 3. Patient age, alcohol abuse and history of homelessness were found to be the most important predictors of being credible tuberculosis transmitters.
Publisher
Cold Spring Harbor Laboratory
Reference20 articles.
1. Diepreye Ayabina , Janne O Ronning , Kristian Alfsnes , Nadia Debech , Ola B Brynildsrud , Trude Arnesen , Gunnstein Norheim , Anne-Torunn Mengshoel , Rikard Rykkvin , Ulf R Dahle , Caroline Colijn , and Vegard Eldholm . Genome-based transmission modelling separates imported tuberculosis from recent transmission within an immigrant population. Microbial Genomics, September 2018.
2. Marcel A Behr , Paul H Edelstein , and Lalita Ramakrishnan . Revisiting the timetable of tuberculosis. BMJ, 362, 2018.
3. Beast 2: A software platform for bayesian evolutionary analysis;PLOS Computational Biology,2014
4. When are pathogen genome sequences informative of transmission events?
5. Whole genome sequence analysis of a large isoniazid-resistant tuberculosis outbreak in london: a retrospective observational study;PLoS medicine,2016