AUTHOR=Simcox Breven S. , Tomlinson Brooke R. , Shaw Lindsey N. , Rohde Kyle H. 

TITLE=Mycobacterium abscessus DosRS two-component system controls a species-specific regulon required for adaptation to hypoxia

JOURNAL=Frontiers in Cellular and Infection Microbiology

VOLUME=13

YEAR=2023

URL=https://www.frontiersin.org/journals/cellular-and-infection-microbiology/articles/10.3389/fcimb.2023.1144210

DOI=10.3389/fcimb.2023.1144210

ISSN=2235-2988

ABSTRACT=<p><italic>Mycobacterium abscessus</italic> (<italic>Mab</italic>), an emerging opportunistic pathogen, predominantly infects individuals with underlying pulmonary diseases such as cystic fibrosis (CF). Current treatment outcomes for <italic>Mab</italic> infections are poor due to <italic>Mab’s</italic> inherent antibiotic resistance and unique host interactions that promote phenotypic tolerance and hinder drug access. The hypoxic, mucus-laden airways in the CF lung and antimicrobial phagosome within macrophages represent hostile niches <italic>Mab</italic> must overcome <italic>via</italic> alterations in gene expression for survival. Regulatory mechanisms important for the adaptation and long-term persistence of <italic>Mab</italic> within the host are poorly understood, warranting further genetic and transcriptomics study of this emerging pathogen. DosRS<italic><sub>Mab</sub></italic>, a two-component signaling system (TCS), is one proposed mechanism utilized to subvert host defenses and counteract environmental stress such as hypoxia. The homologous TCS of <italic>Mycobacterium tuberculosis</italic> (<italic>Mtb</italic>), DosRS<italic><sub>Mtb</sub></italic>, is known to induce a ~50 gene regulon in response to hypoxia, carbon monoxide (CO) and nitric oxide (NO) <italic>in vitro</italic> and <italic>in vivo</italic>. Previously, a small DosR<italic><sub>Mab</sub></italic> regulon was predicted using bioinformatics based on DosR<italic><sub>Mtb</sub></italic> motifs however, the role and regulon of DosRS<italic><sub>Mab</sub></italic> in <italic>Mab</italic> pathogenesis have yet to be characterized in depth. To address this knowledge gap, our lab generated a <italic>Mab dosRS</italic> knockout strain (<italic>Mab<sub>ΔdosRS</sub>)</italic> to investigate differential gene expression, and phenotype in an <italic>in vitro</italic> hypoxia model of dormancy. qRT-PCR and lux reporter assays demonstrate <italic>Mab_dosR</italic> and 6 predicted downstream genes are induced in hypoxia. In addition, RNAseq revealed induction of a much larger hypoxia response comprised of &gt;1000 genes, including 127 differentially expressed genes in a <italic>dosRS</italic> mutant strain. Deletion of DosRS<italic><sub>Mab</sub></italic> led to attenuated growth under low oxygen conditions, a shift in morphotype from smooth to rough, and down-regulation of 216 genes. This study provides the first look at the global transcriptomic response of <italic>Mab</italic> to low oxygen conditions encountered in the airways of CF patients and within macrophage phagosomes. Our data also demonstrate the importance of DosRS<italic><sub>Mab</sub></italic> for adaptation of <italic>Mab</italic> to hypoxia, highlighting a distinct regulon (compared to <italic>Mtb)</italic> that is significantly larger than previously described, including both genes conserved across mycobacteria as well as <italic>Mab</italic>-specific genes.</p>