Some bacteria deploy tiny spearguns to retaliate against rival attacks. Researchers at the University of Basel have mimicked attacks by poking bacteria with an ultra-sharp tip. Using this approach, they have uncovered that bacteria assemble their nanoweapons in response to cell envelope damage and rapidly strike back with high precision.
The research is published in the journal Science Advances.
In the world of microbes, peaceful coexistence goes hand in hand with fierce competition for nutrients and space. Certain bacteria outcompete rivals and fend off attackers by injecting them with a lethal cocktail using tiny, nano-sized spearguns, known as type VI secretion systems (T6SS).
Bacteria respond to cell envelope damage
The research group led by Professor Marek Basler at the Biozentrum, University of Basel, has been studying the T6SS of different bacterial species for many years.
“We knew that Pseudomonas aeruginosa uses its T6SS to fire back when attacked,” explains Basler. “But we did not know what exactly triggers the assembly of the nano-speargun: contact with neighbors, toxic molecules, or simply cell damage?”
In close collaboration with Roderick Lim, Argovia Professor for Nanobiology at the Biozentrum and the Swiss Nanoscience Institute (SNI), the researchers have now demonstrated: Pseudomonas aeruginosa responds to ruptures in the outer membrane—initiated by mechanical force, such as poking with a sharp tip.
Puncturing a bacterial envelope with a tiny ‘needle’
Roderick Lim’s lab has long-standing expertise in atomic force microscopy (AFM) technology.
“Using AFM, we have been able to mimic a bacterial T6SS attack,” says Mitchell Brüderlin, Ph.D. student at the SNI Ph.D. School and first-author of the study. “With the needle-like, ultra-sharp AFM tip, we can touch the bacterial surface, and by gradually increasing the pressure, puncture the outer and the inner membranes in a controlled manner.”
In combination with fluorescence microscopy, the researchers revealed that the bacteria respond to outer membrane damage.
“Within ten seconds the bacteria assemble their T6SS, often repeatedly, at the site of damage and fire back with pinpoint accuracy,” adds Basler. “Our work clearly shows that breaking the outer membrane is necessary and sufficient to trigger T6SS assembly.”
New insights into bacterial defense mechanisms
The biggest challenge for the researchers was the size and the shape of the bacteria.
“So far, we have only used the AFM to study eukaryotic cells, including human cells,” explains Lim. “But Pseudomonas bacteria are more than ten times smaller than human cells, so it was demanding to poke them at a specific site.”
In the microbial ecosystem, survival is all about strategy, and Pseudomonas aeruginosa has certainly mastered the art of defense.
“The targeted and swift retaliation against local attacks minimizes misfiring and optimizes the cost-benefit ratio,” says Basler.
This clever tactic gives Pseudomonas a survival advantage, enabling it to incapacitate attackers and thrive in diverse and often challenging environments.
