A Lung-specific Mutational Signature Enables Inference of Viral and Bacterial Respiratory Niche

Overview

Journal Microb Genom

Specialties Genetics
Microbiology

Date 2023 May 15

PMID 37185044

Authors

Christopher Ruis

Thomas P Peacock

Luis M Polo

Diego Masone

Maria Soledad Alvarez

Angie S Hinrichs

Yatish Turakhia

Ye Cheng

Jakob McBroome

Russell Corbett-Detig

Julian Parkhill

R Andres Floto

Affiliations

Soon will be listed here.

Abstract

Exposure to different mutagens leaves distinct mutational patterns that can allow inference of pathogen replication niches. We therefore investigated whether SARS-CoV-2 mutational spectra might show lineage-specific differences, dependent on the dominant site(s) of replication and onwards transmission, and could therefore rapidly infer virulence of emergent variants of concern (VOCs). Through mutational spectrum analysis, we found a significant reduction in G>T mutations in the Omicron variant, which replicates in the upper respiratory tract (URT), compared to other lineages, which replicate in both the URT and lower respiratory tract (LRT). Mutational analysis of other viruses and bacteria indicates a robust, generalizable association of high G>T mutations with replication within the LRT. Monitoring G>T mutation rates over time, we found early separation of Omicron from Beta, Gamma and Delta, while mutational patterns in Alpha varied consistent with changes in transmission source as social restrictions were lifted. Mutational spectra may be a powerful tool to infer niches of established and emergent pathogens.

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