Key Transitions in the Evolution of Rapid and Slow Growing Identified by Comparative Genomics

Overview

Journal Front Microbiol

Specialty Microbiology

Date 2020 Feb 11

PMID 32038518

Citations 20

Authors

Nathan L Bachmann

Rauf Salamzade

Abigail L Manson

Richard Whittington

Vitali Sintchenko

Ashlee M Earl

Ben J Marais

Affiliations

Soon will be listed here.

Abstract

Mycobacteria have been classified into rapid and slow growing phenotypes, but the genetic factors that underlie these growth rate differences are not well understood. We compared the genomes of 157 mycobacterial species, representing all major branches of the mycobacterial phylogenetic tree to identify genes and operons enriched among rapid and slow growing mycobacteria. Overlaying growth phenotype on a phylogenetic tree based on 304 core genes suggested that ancestral mycobacteria had a rapid growth phenotype with a single major evolutionary separation into rapid and slow growing sub-genera. We identified 293 genes enriched among rapid growing sub-genera, including genes encoding for amino acid transport/metabolism (e.g., operon) and transcription, as well as novel ABC transporters. Loss of the and ABC transporter operons among slow growing species suggests that reduced cellular amino acid transport may be growth limiting. Comparative genomic analysis suggests that horizontal gene transfer, from non-mycobacterial genera, may have contributed to niche adaptation and pathogenicity, especially among slow growing species. Interestingly, the mammalian cell entry () operon was found to be ubiquitous, irrespective of growth phenotype or pathogenicity, although protein sequence homology between rapid and slow growing species was low (<50%). This suggests that the operon was present in ancestral rapid growing species, but later adapted by slow growing species for use as a mechanism to establish an intra-cellular lifestyle.

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