Phylogeographic Variation in Recombination Rates Within a Global Clone of Methicillin-resistant Staphylococcus Aureus

Overview

Journal Genome Biol

Specialties Biology
Genetics

Date 2012 Dec 29

PMID 23270620

Citations 69

Authors

Santiago Castillo-Ramirez

Jukka Corander

Pekka Marttinen

Mona Aldeljawi

William P Hanage

Henrik Westh

Kit Boye

Zeynep Gulay

Stephen D Bentley

Julian Parkhill

Matthew T Holden

Edward J Feil

Affiliations

Soon will be listed here.

Abstract

Background: Next-generation sequencing (NGS) is a powerful tool for understanding both patterns of descent over time and space (phylogeography) and the molecular processes underpinning genome divergence in pathogenic bacteria. Here, we describe a synthesis between these perspectives by employing a recently developed Bayesian approach, BRATNextGen, for detecting recombination on an expanded NGS dataset of the globally disseminated methicillin-resistant Staphylococcus aureus (MRSA) clone ST239.

Results: The data confirm strong geographical clustering at continental, national and city scales and demonstrate that the rate of recombination varies significantly between phylogeographic sub-groups representing independent introductions from Europe. These differences are most striking when mobile non-core genes are included, but remain apparent even when only considering the stable core genome. The monophyletic ST239 sub-group corresponding to isolates from South America shows heightened recombination, the sub-group predominantly from Asia shows an intermediate level, and a very low level of recombination is noted in a third sub-group representing a large collection from Turkey.

Conclusions: We show that the rapid global dissemination of a single pathogenic bacterial clone results in local variation in measured recombination rates. Possible explanatory variables include the size and time since emergence of each defined sub-population (as determined by the sampling frame), variation in transmission dynamics due to host movement, and changes in the bacterial genome affecting the propensity for recombination.

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