Public Engagement
ßÏßÏÊÓƵ Neuroscience public engagement activities
We use some essential cookies to make this website work.
We'd like to set additional cookies to understand how you use our site so we can improve it for everyone. Also, we'd like to serve you some cookies set by other services to show you relevant content.
View our privacy policy.ßÏßÏÊÓƵ Neuroscience public engagement activities
Local contacts and activities
News from the Open Research Technologies Hub
By: Stephanie Allen
Last updated: Thursday, 14 October 2021
Researchers have revealed that non-mammalian vertebrates might have a much more simple and effective way of deciphering between colour and greyscale information than humans.
and others from his at the ßÏßÏÊÓƵ were investigating how zebrafish respond and decipher between different wavelengths, or colours of light.
Prof Baden said: “Zebrafish, unlike humans, have four types of cone-photoreceptors, specialised neurons in the retina which respond to light. These four types are often called red, green, blue and UV. The assumption is that each should do what it says on the tin – red should respond to red light, green to green light, and so on. However, we found that this isn’t the case.”
In the first ever direct in-vivo measurements of ‘colour tuning’ from a vertebrate photoreceptor, Prof Baden and his team, collaborating with researchers at the University of Tübingen, Germany and Baylor College of Medicine in Texas, USA, found that zebrafish can decipher colour in a much simpler way to humans. Their study, published by , describes how ‘red cones’ responded to brightness, i.e. black or white information, while ‘green cones’ responded to colour information.
Prof Baden explained: “In basic principles, colour vision requires visual circuits to disentangle brightness from colour information. In nature, these are fundamentally entwined so to disentangle them is no trivial task, which in some cases can require quite a lot of neurons.
“In humans, some of these are distributed all over the eyes and brain in ways that are still far from understood. In contrast, zebrafish solve this basic problem themselves at the earliest possible site, in the synapse of the photoreceptors themselves.”
From an evolutionary perspective, Prof Baden explains that this “fish strategy” is probably much closer to the ‘origin of vision’ in vertebrates.
In contrast, during the age of the dinosaurs, humans’ early mammalian ancestors are thought to have escaped to the forests and adopted a nocturnal lifestyle. In the process, they lost all but two of their cone-photoreceptor types, resulting in most mammals being dichromatic – only able to see in two colours. Dogs, cats, horses, even hamsters and mice, can all distinguish blues from greens, but none of them can readily distinguish greens from reds. Accordingly, we imagine them to see the world in colours that may be similar to what a red-green colour-blind human might experience.
Unlike other mammals, humans and the evolutionary lineage of gorillas and chimpanzees, much later evolved to become trichromatic, regaining some of the lost abilities in colour vision. However, this occurs in a much more complicated way, which requires a lot of computation, thought to be performed by the brain rather than within the eye. This is a complex process and means that distinguishing between some colours has to be learnt in early infancy through the developing cortex.
Prof Baden said: “Our study essentially shows that vertebrates like zebrafish, and presumably most non mammalian vertebrates like other fish, birds, reptiles and amphibians, can actually solve this fundamental ‘colour puzzle’ right at the first synapse of vision. In comparison, humans are stuck with this overly complicated ‘knock-off’ strategy because of early mammalian ancestry!”
The study also references links to insects, as flies also have four such ‘colour vision photoreceptors’, determining colour in exactly the same way as the zebrafish despite evolving completely independently.
In a follow-up paper, due to be published in soon (Bartel et al. Curr Biol, in press), the researchers use the same technique to investigate the second layer of processing in the retina, the so-called bipolar cells. Expanding on the above results, they show that at this second layer of processing, zebrafish represent three (rather than the previous two) types of colour contrast. This “third” is built by comparing UV- to all other wavelength, and it bears striking resemblance to one of the two colour channels that humans use – the so called “blue-yellow” system.
Together, the papers imply that the human blue-yellow system is truly ancient, predating the split of tetrapods from fish almost 400 million years ago. It seems that when it comes to seeing colour, we do at least share some traits with essentially all vertebrates that see colour.