* Astronomy

New study sheds light on how and when vision evolved

Opsins, the light-sensitive proteins key to vision, may have evolved earlier and undergone fewer genetic changes than previously believed, according to a new study from the National University of Ireland Maynooth and the University of Bristol published today in Proceedings of the National Academy of Sciences (PNAS) .
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New fossils provide evidence of powerful eyes

Palaeontologists have uncovered half-a-billion-year-old fossils demonstrating that primitive animals had excellent vision.
An international team led by scientists from the South Australian Museum and the University of Adelaide found the exquisite fossils, which look like squashed eyes from a recently swatted fly.
This discovery will be published today in the prestigious journal Nature.
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New Fossils Demonstrate That Powerful Eyes Evolved in a Twinkling

Title: A Chiton Uses Aragonite Lenses to Form Images
Authors: Daniel I. Speiser, Douglas J. Eernisse, Sönke Johnsen

Hundreds of ocelli are embedded in the dorsal shell plates of certain chitons. These ocelli each contain a pigment layer, retina, and lens, but it is unknown whether they provide chitons with spatial vision. It is also unclear whether chiton lenses are made from proteins, like nearly all biological lenses, or from some other material. Electron probe X-ray microanalysis and X-ray diffraction revealed that the chiton Acanthopleura granulata has the first aragonite lenses ever discovered. We found that these lenses allow A. granulata's ocelli to function as small camera eyes with an angular resolution of about 9° - 12°. Animals responded to the sudden appearance of black, overhead circles with an angular size of 9°, but not to equivalent, uniform decreases in the downwelling irradiance. Our behavioural estimates of angular resolution were consistent with estimates derived from focal length and receptor spacing within the A. granulata eye. Behavioural trials further indicated that A. granulata's eyes provide the same angular resolution in both air and water. We propose that one of the two refractive indices of the birefringent chiton lens places a focused image on the retina in air, whereas the other does so in water.

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It's hard to miss the huge eye of a squid. But now it appears that certain squids can detect light through an organ other than their eyes as well.
That's what researchers at the University of Wisconsin-Madison report in the current issue (June 2) of the Proceedings of the National Academy of Sciences.
The study shows that the light-emitting organ some squids use to camouflage themselves to avoid being seen by predators - usually fish sitting on the ocean floor - also detects light.
The findings may lead to future studies that provide insight into the mechanisms of controlling and perceiving light.

"Evolution has a 'toolkit' and when it needs to do a particular job, such as see light, it uses the same toolkit again and again. In this case, the light organ, which comes from different tissues than the eye during development, uses the same proteins as the eye to see light" - lead author Margaret McFall-Ngai, a professor of medical microbiology and immunology at the UW-Madison School of Medicine and Public Health (SMPH).

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