Biologist Belinda Chang鈥檚 lab offers insight on how animals see
Humans sometimes describe eyes as the window to the soul, but for most animals, eyes are all about survival.
Evolutionary biologist Belinda Chang leads a lab that is devoted to understanding how animals see, and how their vision evolves and changes based on their need to adapt to the environment.
One area of particular focus for the lab is the visual pigments in the retina鈥檚 photoreceptor cells that absorb light and enable vision. The activation of a visual pigment is the first step in a chain of events that sends a signal to the brain that light, and therefore an image, has been perceived. When there is a change in the properties of visual pigments, it can have profound consequences on an animal鈥檚 ability to see and survive.
鈥淢ost animals, including humans, have two types of photoreceptor cells 鈥 rods and cones 鈥 in their retinas,鈥 said Chang, an associate professor in the departments of ecology & evolutionary biology and cell & systems biology. 鈥淩ods contain a visual pigment called rhodopsin and are sensitive to dim light, while cones differ in their molecular machinery, including different opsins, that allow them to operate under bright conditions.
鈥淭his combination of visual pigments allows animals to see in both bright and dim conditions. However, there are unusual exceptions. In some animals, only one type is present.鈥
This is the case, for example, with the Western ribbon garter snake, the subject of a paper by Chang鈥檚 group published in . This animal, whose habitat stretches from the central United States south to Central America, is active only in daylight and has previously been found to have only cones in its retinas.
Photo below, left to right: Associate Professor Belinda Chang; PhD students Sarah Dungan and Nihar Bhattacharya; and James Morrow, a postdoctoral fellow. Seated at computer: PhD student Ryan Schott. Photo by Diana Tyszko.
Chang鈥檚 group 鈥 which comprises a combination of undergraduate and graduate students and postdoctoral researchers 鈥 had been intrigued by a 70-year-old theory that through evolution, rods could transform into cones and vice versa in a process known as 鈥渢ransmutation.鈥 They wondered if such a process led to the absence of rods in the snakes, hypothesizing that somewhere along the line they sacrificed their ability to see well in dim light in order to improve their daylight vision. Given that the origin of all-cone retinas in this particular snake was still a mystery, Chang decided to test that theory.
鈥淎t some point in its evolution, this garter snake lost two of four ancestral cones,鈥 said Ryan Schott, a PhD candidate in Chang鈥檚 lab. 鈥淭his likely happened during an early, possibly burrowing underground phase of snake evolution, long before they came to have all-cone retinas. Living in dim light, they would have been more reliant on rhodopsin found in their rod cells.鈥
Using a variety of experimental approaches, Chang and her team tested two competing hypotheses to determine what had happened to those rods when the snake later evolved into an above-ground creature. They found two surprising things. First, rhodopsin, which is only supposed to be found in rods, was indeed present in some of the snake鈥檚 cone cells. Second, those cone cells had structural features that were remarkably similar to those found in rods.
鈥淭he results suggest that they are not true cones, but are in fact modified rods.鈥 said Nihar Bhattacharya, a PhD candidate in Chang鈥檚 lab.
But there was another twist: the modified cone-like rods may have enabled snakes to see colour in daylight, restoring a functionality that disappeared with the loss of some ancestral cones during an early burrowing phase.
Chang says the rare transformation has implications for how complex cellular types can arise in sensory systems.
鈥淧hysiological constraints imposed by historical losses can actually be shaped by selective forces to produce remarkable evolutionary benefits.鈥
Chang is known for being especially adept at recreating the ancestral genes of an animal. This enables her to get the picture of a genetic structure at a specific point in time and so better understand how evolutionary changes contribute to an animal鈥檚 overall fitness and survival.
The snake eyes study was only one in a series of successive advances by Chang and her colleagues in understanding the evolution of vision across the animal kingdom. In another studypublished in , the team described how the rhodopsin protein evolved in killer whales to improve their ability to see underwater in the predominantly blue-tinted light.
Sarah Dungan, another PhD candidate in Chang鈥檚 lab and lead author of the paper elaborates: 鈥渨hales are particularly reliant on rhodopsin because light fades very quickly as they swim deeper. But the majority of light in the ocean is also blue, so for a diving animal, the fact that rhodopsin is extra-sensitive in the blue part of the spectrum enables the eyes to make the most of the scarce light.
鈥And being able to see well means the difference between catching your prey and going hungry.鈥
Sean Bettam is a writer with the Faculty of Arts & Science