Mantis shrimps have a unique way of seeing
Eagles may be famous for their vision, but the most incredible eyes of any animal belong to the mantis shrimp. Neither mantises nor shrimps, these small, pugilistic invertebrates are already renowned for their amazingly complex vision. Now, a group of scientists have found that they use a visual system that’s never been seen before in another animal, and it allows them to exchange secret messages.
Mantis shrimps are no stranger to world records. They are famous for their powerful forearms, which can throw the fastest punch on the planet. The arm can accelerate through water at up to 10,000 times the force of gravity, creating a pressure wave that boils the water in front of it, and eventually hits its prey with the force of a rifle bullet. Both crab shells and aquarium glass shatter easily.
Amazing eyes
As impressive as their arms are, the eyes of a mantis shrimp are even more incredible. They are mounted on mobile stalks and can move independently of each other. Mantis shrimps can see objects with three different parts of the same eye, giving them ‘trinocular vision’ so unlike humans who perceive depth best with two eyes, these animals can do it perfectly well with either one of theirs.
Their colour vision far exceeds our too. The middle section of each eye, the midband, consists of six parallel strips. The first four are loaded with eight different types of light-sensitive cells (photoreceptors), containing pigments that respond to different wavelengths of light. With these, the mantis shrimp’s visible spectrum extends into the infrared and the ultraviolet. They can even use filters to tune each individual photoreceptor according to local light conditions.
The fifth and six rows of the midband contain photoreceptors that are specialised for detecting polarised light. Normally, light behaves like a wave that vibrates in every possible direction as it moves along. In comparison, polarised light vibrates in just one direction – think of attaching a piece of string to a wall and shaking it up and down. While we are normally oblivious to it, it’s present in the glare that reflects off water and glass and we use polarising filters in sunglasses and cameras to screen it out.
Light can also travel in a the shape of a helix, moving as a spiralling beam that spins either clockwise (right-handed) or anti-clockwise (left-handed). This phenomenon is called ‘circular polarisation’. Tsyr-Huei Chiou from the University of Maryland found that the mantis shrimp’s eye contains the only known cells in the animal kingdom that can detect it. Our technology can do the same, but the mantis shrimps beat us to it by as much as 400 million years.
Eye for detail
Each of the mantis shrimp’s photoreceptors contains seven cells called rhabdoms arranged in a cylinder, and each of these contains thousands of tiny projections called microvilli. In receptors that are sensitive to polarised light, the microvilli are all arranged in one direction, creating a narrow gap that only light vibrating in a certain plane can pass through. Three of the seven rhabdoms are sensitive to one plane of polarised light and the other four are sensitive to a plane that’s perpendicular to it.
Sitting atop these seven cells is an eighth rhabdom. In the fifth and sixth rows of the midband, the microvilli in this eighth cell are precisely aligned and everywhere else (and indeed in all other crustaceans), they are randomly arranged. It’s this key innovation that allows the mantis shrimp to see circular polarised light.
The eighth rhabdom creates a slit that’s angled at 45 degrees to those created by the seven cells underneath, precisely the precise angle that converts circularly polarised light into its linear version. The light is converted differently depending on whether it spins left or right, and this activates different groups of rhabdoms. When Chiou recorded the electrical activity of the seven underlying rhabdoms, he found that some were only sensitive to right-handed circularly polarised light, while others only responded to the left-handed variety. So in theory, mantis shrimps can not only detect circularly polarised light, they can also tell which direction it’s spinning in.
Benefits to behaviour
Chiou provided further evidence of this ability by training mantis shrimps to associate either left-handed or right-handed circularly polarised light with a food reward. After the lessons, he gave them a choice between two food containers that reflected circularly polarised light spinning in different directions. As expected, the animals were more likely to choose the container whose reflections matched those that they had been trained to prefer.
How does this unique visual system benefit a mantis shrimp? For a start, water is replete with circularly polarised reflections and being able to see these could help the animals to see their world in a higher contrast. But Chiou found that the parts of the shells of three species of mantis shrimps also reflect circularly polarised light. See, for example, how different the tail of a mantis shrimp looks under a right-handed circular polarising filter and a left-handed one.
Tellingly, males and females produce these reflections from different body parts that are commonly used for signalling during courtship. Chiou speculates that amorous mantis shrimps use circularly polarised light as a secret communication channel. Mantis shrimps use linearly polarised light for this purpose too and while many predators can’t see these codes, they are all too visible to cuttlefish, squid and octopus that prey on mantis shrimps. The animals avoid that risk by using a signalling method that their eyes and theirs alone can see.
Chiou also noted that some species, including the beautiful peacock mantis shrimp, are more sensitive to circularly polarised light than others. Their communications may be so secret that even other mantis shrimps can’t see them.
Reference: CHIOU, T., KLEINLOGEL, S., CRONIN, T., CALDWELL, R., LOEFFLER, B., SIDDIQI, A., GOLDIZEN, A., MARSHALL, J. (2008). Circular Polarization Vision in a Stomatopod Crustacean. Current Biology DOI: 10.1016/j.cub.2008.02.066.
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