Newswise — Planthopper bugs may be small, but they attract mates from afar by sending vibrational calls along plant stems and leaves using fast, rhythmic motions of their abdomen. In a new study publishing March 12 in the open-access journal PLOS Biology, researchers at the University of Oxford show how a newly-discovered “snapping organ” enables courting bugs of both sexes to produce this shaking motion through a combination of muscle action and elastic recoil.

 

Producing vibrations that will travel well along plant material requires the sudden release of mechanical energy – many times faster than could be achieved through direct action of the planthoppers’ tiny muscles.

 

The authors of the new study discovered that the secret lies in the fast release of stored elastic energy, rather like a catapult, but with the key difference that the stored energy is released cyclically, leading to a repetitive up-down motion of the abdomen. This is accomplished by a complex anatomical structure that the researchers call the “snapping organ”, because of the speed with which it snaps open and closed.

 

The discovery of the new organ was as unexpected as its mechanism. “I was studying 3D images of planthoppers that I had collected using X-ray imaging in a particle accelerator, trying to understand the evolutionary relationships between different groups,” said lead author of the study, Leonidas-Romanos Davranoglou. “But as I dissected the bugs in virtual reality on my computer, I immediately realised that I was looking at something entirely new, so decided to investigate further.”

 

The researchers collected hundreds of live planthoppers from the hills around Athens, which they brought back to their Oxford lab to conduct experiments. To understand the vibration generation mechanism of the new snapping organ, they used microtomography, laser vibrometry, confocal microscopy, and high-speed video recordings. The scientists then teamed up with the Vibration and Uncertainty Lab at Oxford’s Department of Engineering Science to build a theoretical model of the mechanism. The vibratory organ was found to be present in all of the many different families of planthoppers, showing that this entire group of bugs are specialists in this unusual form of communication.

 

“These insects include several economically important pest species, including the brown planthopper, which is one of the most serious pests on rice in the developing world,” said co-author Dr Beth Mortimer. “Understanding how these insects signal to each other may help in disrupting their communication channels or detecting their calls. Silent to the ear, the planthoppers have come up with their own novel way to communicate with potential mates. You could say it’s their form of Snapchat.”

 

While the discovery of the snapping organ is new, the bugs’ approach is an extremely old mechanism of communication, dating back at least 250 million years, to the dawn of planthopper evolution.

 

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In your coverage please use this URL to provide access to the freely available article in PLOS Biology http://journals.plos.org/plosbiology/article?id=10.1371/journal.pbio.3000155

 

Press-only preview: https://plos.io/2EpSZCY

 

Contact: Beth Mortimer, [email protected]

 

Citation: Davranoglou L-R, Cicirello A, Taylor GK, Mortimer B (2019) Planthopper bugs use a fast, cyclic elastic recoil mechanism for effective vibrational communication at small body size. PLoS Biol 17(3): e3000155. https://doi.org/10.1371/journal.pbio.3000155

 

Image Caption: The researchers experimented on tiny planthoppers (Agalmatium bilobum, pictured). [Note wings are removed].

 

Image Credit: L.-R. Davranoglou

 

Funding: For funding, BM thanks the Royal Commission for the Exhibition of 1851: https://www.royalcommission1851.org/. LRD is grateful to the Alexander S. Onassis Public Benefit Foundation Scholarships for Hellenes: https://www.onassis.org/en/scholarships-greeks.php and to Oxford-NaturalMotion: http://www.ox.ac.uk/admissions/graduate/fees-and-funding/graduate-scholarships for funding. GT was supported by a research grant from Jesus College, Oxford: https://www.jesus.ox.ac.uk/. AC is grateful to Balliol College for the Career Development Fellowship in Engineering: https://www.balliol.ox.ac.uk/. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

 

Competing Interests: The authors have declared that no competing interests exist.

Journal Link: PLOS Biology