12:38am Monday 11 December 2017

Shrimp vision, communication and cancer detection

A mantis shrimp in a defensive position, on its back with its legs, head and heavily-armoured tail closed over. The red colour indicates areas of reflected circular polarising light. Credit Yakir Gagnon/QBI
 Credit Yakir Gagnon/QBI

The ocean is lighting up with secret forms of communication between marine animals that may have applications in satellite remote sensing, biomedical imaging, cancer detection and computer data storage, a team of Australian and international researchers has found.

The University of Queensland Queensland Brain Institute’s (QBI) Dr Yakir Gagnon said the team had already shown that mantis shrimp (Gonodactylaceus falcatus) could reflect and detect circular polarising light.

“This is extremely rare in nature and, until now, no-one has shown what they use it for,” he said.

“This study shows that the shrimp use circular polarisation as a means to covertly advertise their presence to aggressive competitors.”

QBI’s Professor Justin Marshall, who heads the Australian part of the polarisation team, said it was more common for animals to communicate with colour.

“In birds, coloured feathers advertise gender and territory and in the ocean, reef fish display with colour – this is a form of communication we almost understand,” he said.

“What we’re now discovering is that there’s a completely new language of communication.

“Linear polarised light oscillates in only one plane, whereas circular polarised light travels in a spiral – clockwise or anti-clockwise – direction.

“We’ve now determined that mantis shrimp display circular polarised patterns on the body, particularly on the legs, head and heavily armoured tail, which are the regions most visible when they curl up during conflict.

“These shrimp live in holes in the reef and they like to hide away. They’re secretive and don’t like to be in the open.”

Dr Gagnon said that researchers dropped a mantis shrimp into a tank with two burrows to hide in – one reflecting unpolarised light and the other reflecting circular polarised light.

“We found that the shrimp chose the unpolarised burrow 68 per cent of the time – suggesting the circular polarised burrow was perceived as being occupied by another mantis shrimp,” he said.

“If you essentially label holes with circular polarising light, by shining circular polarising light out of them, shrimps won’t go near it.

“They know – or they think they know – there’s another shrimp there.”

Professor Marshall said the findings could help doctors to better detect cancer.

“Cancerous cells do not reflect polarised light, in particular circular polarising light, in the same way as healthy cells,” he said.

“Cameras, designed by our US collaborators in Washington University in St Louis under Associate Professor Viktor Gruev, have been equipped with polarising sensors inspired by mantis shrimps and may detect cancer cells long before the human eye can see them.”

Professor Marshall was also part of a second study with QBI alumni Dr Martin How, which showed that linear polarised light was used as a form of communication by fiddler crabs.

“These animals seem to have evolved in-built sun glasses to help them survive and communicate on the mudflats,” he said.

Both the mantis shrimp study and the fiddler crab study  are available online in the journal Current Biology.

Media: QBI media and communications manager Bernadette Condren, b.condren@uq.edu.au, +61 7 3346 6353; Dr Yakir Gagnon, y.gagnon@uq.edu.au, 0424 393 332; Professor Justin Marshall, justin.marshall@uq.edu.au, +61 7 3365 1397.


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