Ants are neat: when they move into a new nest box, they spend the first days cleaning it thoroughly, like us humans getting out the cleaning bucket when moving into a new home. Despite keeping the nest clean, using poison within the nest is dangerous and can kill unprotected brood. However, the silk cocoon that surrounds the ant's sensitive pupae protects them from any harmful effects, as Sylvia Cremer from the Institute of Science and Technology Austria (IST Austria), and her team, including first author doctoral student Christopher Pull - now a postdoc at the Royal Holloway University London (RHUL) - show in today's edition of Current Biology.
Many ants produce highly acidic chemicals from specialized glands in their body. For a long time, researchers assumed that ants only spray this poison, which is made mostly of formic acid, to fight other ants and would-be predators. But in two studies published in 2013 and 2018, Sylvia Cremer and her team showed that ants use acidic chemicals to disinfect nest-mates contaminated and infected with pathogens. In the current study, published by Pull et al., Cremer's research team show that Lasius neglectus ants also spray their nests prophylactically with their acidic poison, likely ensuring that the nest is clean for first-time occupancy. But, given the poison doubles-up as a chemical weapon, the use of the poison within the nest raises further questions, as Sylvia Cremer explains: "How can ants spray this aggressive acid in their nest, whilst leaving their sensitive brood in the acidic fog?" Whilst adult ants are protected from the poison by a thick skin (the cuticle) and eggs by a protective "shell" (the corion), the cuticle of the pupae is thin and fragile, and so very susceptible to damage. However, pupae of the Lasius neglectus species are also covered in a silk cocoon, which Pull et al hypothesized may offer them protection.
Through a series of experiments, the research team searched for the answer. First, they removed the protective silk cocoon from some pupae and found that these nude pupae survived just as well alone as pupae wrapped in a cocoon. But when they placed nude pupae and worker ants into a nest together, more nude pupae died than cocooned pupae. Is the increased death a result of the acidic poison? To test this, the researchers glued shut the poison glands of the worker ants with superglue. "We created a 'functional knock-out' ant by creating animals that could not spray formic acid," explains Cremer. In a nest with ants unable to spray their acid, nude and wrapped pupae had the same chance of survival. "So it is the formic acid that kills nude pupae, but pupae in a cocoon are protected from it," Cremer concludes - and we behave similarly: "When we use harmful cleaning products, we protect ourselves with gloves. The cocoon has a similar function to protective gloves."
The current study provides the first example at colony level of so-called immunopathology, a phenomenon also known from the human immune system. The immune system often fights pathogens with toxic substances, but at the same time, it must limit damage to its own body cells. The immune system, therefore, faces the challenge of fighting pathogens as aggressively as possible, while protecting the body's own cells and organs from collateral damage. The same happens in ants on the colony level: they protect the most sensitive parts of their colony from the harmful side effects of cleaning with a caustic poison.
The study could also explain why some species of ants have lost the original cocoon and other species have kept it, explains Christopher Pull: "Constructing a cocoon is costly for ants, for example, it may mean a longer development time for the pupae. Why some species of ants have a cocoon whereas others have lost it is still unclear. Here, we show that the cocoon protects ants in a sensitive phase of their development. It remains to be seen whether species of ants without cocoon clean their nests with less aggressive chemicals."
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About IST Austria
The Institute of Science and Technology (IST Austria) is a PhD-granting research institution located in Klosterneuburg, 18 km from the center of Vienna, Austria. Inaugurated in 2009, the Institute is dedicated to basic research in the natural and mathematical sciences. IST Austria employs professors on a tenure-track system, postdoctoral fellows, and doctoral students. While dedicated to the principle of curiosity-driven research, the Institute owns the rights to all scientific discoveries and is committed to promote their use. The first president of IST Austria is Thomas A. Henzinger, a leading computer scientist and former professor at the University of California in Berkeley, USA, and the EPFL in Lausanne, Switzerland. The graduate school of IST Austria offers fully-funded PhD positions to highly qualified candidates with a bachelor's or master's degree in biology, neuroscience, mathematics, computer science, physics, and related areas. http://www.ist.ac.at
Journal
Current Biology