Global Phylogeny of Treponema Pallidum Lineages Reveals Recent Expansion and Spread of Contemporary Syphilis

Overview

Journal Nat Microbiol

Specialties Microbiology
Parasitology

Date 2021 Nov 25

PMID 34819643

Citations 38

Authors

Mathew A Beale

Michael Marks

Michelle J Cole

Min-Kuang Lee

Rachel Pitt

Christopher Ruis

Eszter Balla

Tania Crucitti

Michael Ewens

Candela Fernandez-Naval

Anna Grankvist

Malcolm Guiver

Chris R Kenyon

Rafil Khairullin

Ranmini Kularatne

Maider Arando

Barbara J Molini

Andrey Obukhov

Emma E Page

Fruzsina Petrovay

Cornelis Rietmeijer

Dominic Rowley

Sandy Shokoples

Erasmus Smit

Emma L Sweeney

George Taiaroa

Jaime H Vera

Christine Wenneras

David M Whiley

Deborah A Williamson

Gwenda Hughes

Prenilla Naidu

Magnus Unemo

Mel Krajden

Sheila A Lukehart

Muhammad G Morshed

Helen Fifer

Nicholas R Thomson

Affiliations

Soon will be listed here.

Abstract

Syphilis, which is caused by the sexually transmitted bacterium Treponema pallidum subsp. pallidum, has an estimated 6.3 million cases worldwide per annum. In the past ten years, the incidence of syphilis has increased by more than 150% in some high-income countries, but the evolution and epidemiology of the epidemic are poorly understood. To characterize the global population structure of T. pallidum, we assembled a geographically and temporally diverse collection of 726 genomes from 626 clinical and 100 laboratory samples collected in 23 countries. We applied phylogenetic analyses and clustering, and found that the global syphilis population comprises just two deeply branching lineages, Nichols and SS14. Both lineages are currently circulating in 12 of the 23 countries sampled. We subdivided T. p. pallidum into 17 distinct sublineages to provide further phylodynamic resolution. Importantly, two Nichols sublineages have expanded clonally across 9 countries contemporaneously with SS14. Moreover, pairwise genome analyses revealed examples of isolates collected within the last 20 years from 14 different countries that had genetically identical core genomes, which might indicate frequent exchange through international transmission. It is striking that most samples collected before 1983 are phylogenetically distinct from more recently isolated sublineages. Using Bayesian temporal analysis, we detected a population bottleneck occurring during the late 1990s, followed by rapid population expansion in the 2000s that was driven by the dominant T. pallidum sublineages circulating today. This expansion may be linked to changing epidemiology, immune evasion or fitness under antimicrobial selection pressure, since many of the contemporary syphilis lineages we have characterized are resistant to macrolides.

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Insights into Treponema pallidum genomics from modern and ancient genomes using a novel mapping strategy.

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