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Scientists reveal secrets of flashlight fish

By Leonard Ho - Posted Feb 10, 2017 09:00 AM
Flashlight fish are very cool reef fish, but they're cave-dwellers so humans rarely get a glimpse into their cryptic world. They possess bioluminescent sacks under their eyes. Researchers now know how flashlight fish use their flashlights.
Scientists reveal secrets of flashlight fish

Anomalops katoptron. Photo by the California Academy of Sciences

From Ruhr-University Bochum:


The firefly among fish

Thanks to glowing bacteria in special organs below their eyes, flashlight fish send out flashing signals at night. Biologists from Bochum have researched their purpose.

The flashlight fish Anomalops katoptron, which inhabits the coral reefs of the Pacific, uses flashing signals to forage for food at night. The moment it finds food, the flashing signal changes to a permanent glow while the fish is feeding. In addition to the lighting conditions in its surroundings, the presence of food also determines the bioluminescence of the fish. This fact was discovered by behavioural biologists headed by Prof Dr Stefan Herlitze and Dr Jens Hellinger. The researchers thus identified the purposes of bioluminescence in this fish species. The same question still remains open for many other glowing marine creatures. The researchers published their report in the Plos One edition from February 8, 2017.

Light organs rotate backwards

Flashlight fish, also referred to as lantern-eye fish, live in swarms of eight to 50 animals that hunt plankton on coral reef roofs at night. During the day, the fish withdraw to a depth of up to 400 metres, where they presumably rest in underwater caves. They have light organs below their eyes which can be rotated backwards and which contain bioluminescent symbiotic bacteria. By rotating their light organs, the fish generate flash patterns in different frequencies. To date, researchers could only speculate about the light organs' function.

“Deploying methods of behavioural biology, we have now successfully demonstrated that Anomalops katoptron uses its light organs while foraging, and it adjusts the flash frequency to the context in which it operates,” as Stefan Herlitze and Jens Hellinger explain. For their analysis, the researchers utilised watertight infrared spotlights, developed in collaboration with the faculty workshop for this specific purpose.

Constant glow during feeding

They observed that the fish blink 90 times per minute on average during the night. Once the researchers add zooplankton to the water, the animals promptly reduce their flash frequency and emit an almost continuous glow while feeding. Non-glowing control animals of the same species hardly ever caught any prey. They didn’t exhibit any changes to blink frequency in the presence of zooplankton, either. The blink frequency in non-glowing fish can be determined by monitoring light organ rotation. “The results clearly indicate that Anomalops katoptron relies on its light organs while foraging for food,” conclude Stefan Herlitze and Jens Hellinger.

Moreover, the researchers have demonstrated that the animals’ blink frequency is also regulated by the lighting conditions in their environment. During the day, the animals rest in the reef aquarium in a dimly lit cave, keeping their light organs closed for the most part, interrupted only by brief blinks. During their active phase at night, on the other hand, the fish exhibit a high blink frequency. The precise function of that blink pattern is not yet fully understood. Additional analyses will reveal whether the fish use blink patterns to communicate or whether they confuse predators by blinking in a swarm.

Close symbiosis

Anatomical thin-section analyses that the researchers performed on  light organs of luminescent and non-luminescent fish have revealed marked differences in the macroscopic and microscopic structures:  light organs of luminescent fish contain tightly packed tubules which house living, glowing bacteria; once the  light organs stop glowing and lose the bacteria, holes form in the tubule structure. The structural transformation following the loss of luminescence suggests a close symbiosis between fish and bacteria. The loss of luminescence is caused by food shortage.

 


Journal Reference:

  1. Jens Hellinger, Peter Jägers, Marcel Donner, Franziska Sutt, Melanie D. Mark, Budiono Senen, Ralph Tollrian, Stefan Herlitze. The Flashlight Fish Anomalops katoptron Uses Bioluminescent Light to Detect Prey in the Dark. PLOS ONE, 2017; 12 (2): e0170489 DOI: 10.1371/journal.pone.0170489

Author: Leonard Ho
Location: Southern California

I'm a passionate aquarist of over 30 years, a coral reef lover, and the blog editor for Advanced Aquarist. While aquarium gadgets interest me, it's really livestock (especially fish), artistry of aquariums, and "method behind the madness" processes that captivate my attention.

Website: http://www.advancedaquarist.com.

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