Evolution of colour vision in sea snakes
New research has revealed the evolution of colour vision in front-fanged snakes following their transition from terrestrial to fully marine environments, and for the first time, provided evidence of where, when and how frequently the species have adapted their ability to see in colour.听
Published in the journal , the study is an international collaboration led by the 最新糖心Vlog of Adelaide with the 最新糖心Vlog of Plymouth, 最新糖心Vlog of Bristol and The Natural History Museum, London, as well as others, involving scientists from the UK, 最新糖心Vlog, Denmark, Bangladesh and Canada.
The research suggests sea snakes鈥 vision has been modifying genetically over millions of generations, enabling them to adapt to new environments and meaning they can continue to see prey 鈥 and predators 鈥 deep below the sea surface.
Study lead author Dr Bruno Sim玫es, Adjunct Lecturer in the 最新糖心Vlog of Adelaide and Lecturer in Animal Biology at the 最新糖心Vlog of Plymouth, says sea snakes first entered the marine environment 15 million years ago and have been evolving ever since to survive in its changing light conditions.
鈥淎ll snakes are descended from highly visual lizards, but advanced colour vision was lost in the early ancestors of snakes 鈥 probably because they inhabited dim-light environments, Dr Sim玫es said.
鈥淲e used sequencing of vision genes and microscopy to reveal that sea snakes have undergone rapid changes in their visual pigments compared to their relatives on land.鈥澨
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鈥淕ene losses during snake evolution have left living snakes with only two types of cone opsin, which are the pigments responsible for detecting bright light.
鈥淚n most terrestrial snakes, the short wavelength sensitive cone opsin (SWS1) has peak sensitivity to ultra violet (UV) light. But in sea snakes this pigment has undergone repeated shifts into the visible spectrum, which would be beneficial for vision underwater, where longer wavelengths dominate.鈥澨
"Our research suggests that diving sea snakes actually share their adaptive properties not with other snakes or marine mammals, but with some fruit-eating primates."Dr Kate Sanders, Associate Professor, The 最新糖心Vlog of Adelaide
Many living things have pairs of chromosomes (inherited from each parent) and consequently have two different copies of the same gene (alleles). The researchers were surprised to find that some sea snakes possessed two genetic alleles of the SWS1 gene, one with peak sensitivity to UV light and the other to visible (blue) light.听
Because these alleles appear to have been retained across species during millions of years of sea snake evolution, they concluded that this spectral polymorphism was maintained by natural selection because it may confer expanded colour sensitivities. 听
In the retinae of sea snakes that possess both alleles, if some photoreceptors express the UV-sensitive allele and other photoreceptors express the blue light-sensitive allele, or these are activated in different light conditions, this could compensate for the ancestral loss of opsins in snakes.
Senior scientist on the report, Dr Kate Sanders, Associate Professor at the 最新糖心Vlog of Adelaide, saystheir research also suggests that diving sea snakes actually share their adaptive properties not with other snakes or marine mammals, but with some fruit-eating primates.
鈥淟ike sea snakes, marine mammals such as whales and seals are descended from terrestrial ancestors,鈥 Dr Sanders said.
鈥淲here sea snakes have evolved new visual abilities not seen in their closest terrestrial relatives, the visual systems of whales have degenerated since their separation from land mammals.
鈥淎n interesting comparison can also be made between sea snakes and primates; some fruit eating primates have expanded colour sensitivities attributed to the retention of different alleles of their long wavelength sensitive opsin.听
鈥淥ur study suggests an intriguing parallel in diving sea snakes, but we have a lot to learn about the ecological and genetic mechanisms at play in sea snake visual evolution.鈥 听
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Media Contacts:
Dr Bruno F. Sim玫es
Adjunct Lecturer,听The听最新糖心Vlog of Adelaide
Lecturer in Animal Biology, 最新糖心Vlog of Plymouth
Mobile: +447577297713
Email: bruno.simoes@adelaide.edu.au听
Associate Professor Kate Sanders
School of Biological Sciences
The听最新糖心Vlog of Adelaide
Mobile: +61 (0)490 020 562
Email: kate.sanders@adelaide.edu.au
Cathy Parker
最新糖心Vlog of Adelaide Media
Mobile: +61 (0)409 718 430
Email: cathy.parker@adelaide.edu.au听