Abstract
Tuberculosis exerts a tremendous burden on global health, with ∼9 million new infections and ∼2 million deaths annually. The Mycobacterium tuberculosis complex (MTC) was initially regarded as a highly homogeneous population; however, recent data suggest the causative agents of tuberculosis are more genetically and functionally diverse than appreciated previously. The impact of this natural variation on the virulence and clinical manifestations of the pathogen remains largely unknown. This report examines the effect of genetic diversity among MTC clinical isolates on global gene expression and survival within macrophages. We discovered lineage-specific transcription patterns in vitro and distinct intracellular growth profiles associated with specific responses to host-derived environmental cues. Strain comparisons also facilitated delineation of a core intracellular transcriptome, including genes with highly conserved regulation across the global panel of clinical isolates. This study affords new insights into the genetic information that M. tuberculosis has conserved under selective pressure during its long-term interactions with its human host.
Highlights
Mycobacterium tuberculosis represents a unique opportunity to explore the impact of evolution and genetic diversity on bacterial host adaptation and pathogenesis
Genetic variations occur under selective pressures imposed by the human host, leading to variation amongst clinical isolates
Tuberculosis (TB) is an ancient disease caused by Mycobacterium tuberculosis that still exerts a tremendous burden on global health
Summary
Mycobacterium tuberculosis represents a unique opportunity to explore the impact of evolution and genetic diversity on bacterial host adaptation and pathogenesis. M. tuberculosis is the most prominent member of the Mycobacterium tuberculosis complex (MTC), comprised of seven closely related species with distinct host tropisms including the human pathogens M. africanum and M. canettii and the animal adapted species M. bovis (bovine), M. caprae (goats), M. pinnipedii (seals), and M. microti (rodents). Members of the MTC are considered genetically monomorphic with a high level of genomic sequence similarity (.99.95%), limited horizontal gene transfer, and a clonal population structure [4], [5]. This apparent homogeneity led to the assumption that genetic diversity among MTC strains would not be of clinical significance. It is becoming apparent that the genetic diversity of the MTC has been underestimated
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