Inferring evolutionary pathways and directed genotype networks of foodborne pathogens

Modelling the emergence of foodborne pathogens is a crucial step in the prediction and prevention of disease outbreaks. Unfortunately, the mechanisms that drive the evolution of such continuously adapting pathogens remain poorly understood. Here, we combine molecular genotyping with network science...

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Bibliographic Details
Published in:PLoS computational biology 2020-10, Vol.16 (10), p.e1008401
Main Authors: Cliff, Oliver M, McLean, Natalia, Sintchenko, Vitali, Fair, Kristopher M, Sorrell, Tania C, Kauffman, Stuart, Prokopenko, Mikhail
Format: Article
Language:English
Subjects:
Antimicrobial agents
Australia
Bayes Theorem
Bayesian analysis
Biology and Life Sciences
Causes of
Computer and Information Sciences
Datasets
Engineering
Epidemics
Evolution
Evolution, Molecular
Exploitation
Foodborne diseases
Foodborne pathogens
Funding
Genome, Bacterial - genetics
Genomics
Genotype
Genotype & phenotype
Genotypes
Genotyping
Health aspects
Humans
Identification and classification
Infections
Infectious diseases
Medical research
Medicine and Health Sciences
Microorganisms
Models, Genetic
Natural history
Networks
Outbreaks
Pathogenic microorganisms
Pathogens
Pathology
Pathways
Population
Public health
Salmonella
Salmonella Food Poisoning - microbiology
Salmonella Typhimurium
Salmonella typhimurium - classification
Salmonella typhimurium - genetics
Salmonella typhimurium - pathogenicity
Software
Statistical inference
Strains (organisms)
Structure-function relationships
Transition points
Virulence
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Description
Summary:Modelling the emergence of foodborne pathogens is a crucial step in the prediction and prevention of disease outbreaks. Unfortunately, the mechanisms that drive the evolution of such continuously adapting pathogens remain poorly understood. Here, we combine molecular genotyping with network science and Bayesian inference to infer directed genotype networks-and trace the emergence and evolutionary paths-of Salmonella Typhimurium (STM) from nine years of Australian disease surveillance data. We construct networks where nodes represent STM strains and directed edges represent evolutionary steps, presenting evidence that the structural (i.e., network-based) features are relevant to understanding the functional (i.e., fitness-based) progression of co-evolving STM strains. This is argued by showing that outbreak severity, i.e., prevalence, correlates to: (i) the network path length to the most prevalent node (r = -0.613, N = 690); and (ii) the network connected-component size (r = 0.739). Moreover, we uncover distinct exploration-exploitation pathways in the genetic space of STM, including a strong evolutionary drive through a transition region. This is examined via the 6,897 distinct evolutionary paths in the directed network, where we observe a dominant 66% of these paths decrease in network centrality, whilst increasing in prevalence. Furthermore, 72.4% of all paths originate in the transition region, with 64% of those following the dominant direction. Further, we find that the length of an evolutionary path strongly correlates to its increase in prevalence (r = 0.497). Combined, these findings indicate that longer evolutionary paths result in genetically rare and virulent strains, which mostly evolve from a single transition point. Our results not only validate our widely-applicable approach for inferring directed genotype networks from data, but also provide a unique insight into the elusive functional and structural drivers of STM bacteria.
ISSN:1553-7358
1553-734X
1553-7358
DOI:10.1371/journal.pcbi.1008401