Antigenic variation impacts gonococcal lifestyle and antibiotic tolerance by modulating interbacterial forces

Abstract

AbstractType 4 pili (T4P) are multifunctional filaments involved in adhesion, surface motility, colony formation, and horizontal gene transfer. These extracellular polymers are surface-exposed and, therefore, act as antigens. The human pathogenNeisseria gonorrhoeaeuses pilin antigenic variation to escape immune surveillance, yet it is unclear how antigenic variation impacts other functions of T4P. Here, we addressed this question by replacing the major pilin of a laboratory strain ofN. gonorrhoeaewith pilins from clinical isolates. Structural predictions reveal filament features that vary from one strain to the next, with the potential to impact pilus:pilus interactions. Using a combination of laser tweezers, electron microscopy, and advanced image analysis, we explore the phenotypic consequences of these structural changes. We reveal that strains differing only in their major pilin sequence vary substantially in their attractive forces, which we attribute to variations in the stereochemistry of the T4P filament. In liquid culture, strongly interacting bacteria form colonies while weakly interacting bacteria retain a planktonic lifestyle. We show that lifestyle strongly affects growth kinetics and antibiotic tolerance. In the absence of external stresses, planktonic bacteria grow faster than colony-forming bacteria. In the presence of the antibiotics ceftriaxone and ciprofloxacin, the killing kinetics indicate strongly increased tolerance of colony-forming strains. We propose that pilin antigenic variation produces a mixed population containing variants optimized for growth, colonization, or survivability under external stress. Different environments select different variants, ensuring the survival and reproduction of the population as a whole.Significance statementNeisseriaare highly successful human pathogens that continuously vary their surface structures to escape immune surveillance. Antigenic variation of the major pilin subunit causes variations of the structure of the Type 4 pilus, a surface exposed virulence factor. Here, we investigate the effect of pilin antigenic variation on bacterial lifestyle and tolerance against antibiotics. We find that pilin antigenic variation causes changes in the physical interactions between the bacteria, resulting in distinct aggregating and planktonic phenotypes. During treatment with antibiotics, aggregating strains are more tolerant than planktonic strains by an order of magnitude. Since tolerance tends to facilitate resistance development, pilin antigenic variation reduces the efficiency of antibiotic treatment.