For clues into how Myrmoteras executes its power-amplified strike, scientists examined the ants first under a microscope, then using micro computed tomography (micro-CT), a three-dimensional imaging system that uses X-rays to visualize the internal structures of small specimens. Their observations allowed them to piece together a model of how the jaws likely works. Researchers detected a feature of the ant’s mandible joint that allows its jaws to lock open. Before the strike, a lobe on the back of the ant’s head compresses, likely acting as a spring loaded with potential energy. Then a fast-contracting trigger muscle releases the jaws and the stored energy, executing the strike.
Credit: Fredrick Larabee, Smithsonian
Few potential victims stand a chance against the formidable mandibles of a trap-jaw ant. In conflicts between predators and prey, speed is a decided advantage, and evolution has given these insects an edge with spring-loaded jaws that snap shut — often on their next meal — with astonishing speed
“It’s a very interesting example of convergent evolution,” said Fredrick Larabee, a postdoctoral researcher at the museum who led the research. “Different trap-jaw ants have very fast jaws to accomplish similar tasks, but this group has evolved them in a completely independent way.”
Myrmoteras ants live in the tropics of Southeast Asia, where they feed primarily on springtails — tiny arthropods that launch themselves into the air like fleas when they detect a threat. Until they encounter their prey, the ants hold their long, slender jaws at the ready, opened to a 280-degree angle. Latched into this position, the jaws store elastic energy. When they are released, they snap shut in a fraction of a second. “These ants are rarely seen in nature and almost impossible to keep alive in the lab,” said University of Illinois entomology professor Andy Suarez, who conducted the research with Larabee.
No one knew previously just how fast Myrmoteras jaws move, but according to the new study, the ant’s predatory strike takes only about half a millisecond. That’s 700 times faster than the blink of an eye. To watch the action, Larabee and his colleagues filmed the ants with a high-speed camera, capturing 50,000 frames per second. By measuring the mandibles’ movements between different frames of the videos, they calculated that the closing jaws of Myrmoteras reach a peak speed of about 50 miles an hour.
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That is faster than the jaws could move if they were powered by muscles alone, Larabee said. Still, it is considerably slower than the jaws of other known trap-jaw ants. The ant mandibles of the distantly related Odontomachus reach speeds twice that of Myrmoteras, making their strikes among the fastest animal movements ever recorded. Those faster ants are known to use their spring-loaded jaws not just to catch their prey, but also to leap away from danger. But Myrmoteras ants do not seem to need that much speed. “They just need to be faster than the critters they’re trying to eat, and their jaws are plenty fast for capturing springtails,” he said.
For clues into how Myrmoteras executes its power-amplified strike, Larabee examined the ants first under a microscope, then using micro-computed tomography (micro-CT), a three-dimensional imaging system that uses X-rays to visualize the internal structures of small specimens. His observations allowed him to piece together a model of how the jaws likely works.
Larabee detected a feature of the ant’s mandible joint that allows its jaws to lock open. Before the strike, a lobe on the back of the ant’s head compresses, likely acting as a spring loaded with potential energy. Then a fast-contracting trigger muscle releases the jaws and the stored energy, executing the strike.
“What’s interesting is that the arrangement of the muscles and how the jaws are locked open are completely different from other trap-jaws ants that have been studied,” Larabee said. “It seems like it’s a completely unique evolution of this system.”
Last year, Smithsonian scientists discovered a trap-jaw system in an unusual group of spiders that live in South America and New Zealand. Spring-loaded systems are also responsible for the lightning-fast hops and leaps of grasshoppers, crickets and fleas. These systems are diverse and have evolved through a variety of structural adaptations — highlighting just how advantageous high-speed movements can be. In future studies, Larabee will continue to investigate the diversity of these systems, exploring how the structure of different ants’ trap-jaw mechanisms correlate to their speed and performance. A new high-resolution micro-CT scanner at the museum will enable its scientists to conduct even more detailed anatomical analyses.
Larabee studied the Myrmoteras ants as a Peter Buck Postdoctoral Research Fellow at the museum. The Peter Buck Fellowship Program trains the next generation of scientists by supporting graduate students and postdoctoral researchers in pursuing their research vision to understand nature and culture with the museum’s research staff, collections and facilities.
Larabee collaborated with scientists with the University of Arizona and colleagues with the University of Illinois in conducting this research.
Story Source: Materials provided by Smithsonian Original written by Whitney Clavin.Note: Content may be edited for style and length.
Fredrick J. Larabee, Wulfila Gronenberg, Andrew V. Suarez. Performance, morphology and control of power-amplified mandibles in the trap-jaw ant Myrmoteras (Hymenoptera: Formicidae). The Journal of Experimental Biology, 2017; 220 (17): 3062 DOI: 10.1242/jeb.156513