Gentamicin induction of the gonococcal toxin-antitoxin-encoding system and impact on gene expression influencing biofilm formation and fitness in a strain-specific manner.

UNLABELLED

The continued emergence of (Ng) isolates resistant to first-line antibiotics has focused efforts on understanding how alternative therapies, such as the expanded use of gentamicin (Gen), might counteract this global public health problem. Focusing on Gen as a viable alternative antibiotic for the treatment of gonorrheal infections, we used RNA-seq to determine if sub-lethal levels of Gen might impact gonococci on a transcriptional level. We found that sub-lethal Gen levels altered the expression of 23 genes in Ng strain FA19. Many of the differentially regulated genes were associated with known stress responses elaborated by Ng under different harmful conditions. We found that the transcripts of the operon, which encodes a putative HicA-HicB toxin-antitoxin system that is encoded by tandem genes with the prophage Ngo φ3, were increased in response to Gen. Although the loss of did not impact gonococcal susceptibility to a variety of antimicrobial agents or harmful environmental conditions, it did reduce biofilm formation in Ng strains F62, FA1090, WHO X, and CDC200 but not that of strain FA19. Furthermore, in strain F62, but not FA19, loss of reduced the fitness of Ng during experimental lower genital tract infection of female mice. Furthermore, we found that expression of can influence levels of the transcript which encodes the nitrate reductase shown previously to be upregulated in gonococcal biofilms. We propose that sub-lethal Gen has the capacity to influence gonococcal pathogenesis through the action of the HicAB toxin-antitoxin system.

IMPORTANCE

During antibiotic treatment, bacteria can be exposed to sub-lethal levels that could serve as a stress signal, resulting in changes in gene expression. The continued emergence of multi-drug-resistant strains of Ng has rekindled interest in expanded use of gentamicin (Gen) for the treatment of gonorrheal infections. We report that sub-lethal levels of Gen can influence levels of Ng transcripts, including that of the gonococcal -encoded toxin-antitoxin (TA) locus, which is embedded within an integrated prophage. Although the loss of this TA locus did not impact Ng susceptibility to Gen, it reduced the biofilm-forming ability of four of five Ng strains. Furthermore, in an examined strain in this group, we found that Ng fitness during experimental infection was negatively impacted. We propose that levels of the transcripts can be increased by sub-lethal levels of an antibiotic used in the treatment of gonorrhea and that this could influence pathogenicity.