Garfish have the slowest rate of molecular evolution of all jawed vertebrates. This tells us something not only about its evolution, but also about possible modifications in the future.
In the new research from Yale University Scientists have revealed the genetic secrets of gar, an ancient group of ray-finned fish that have remained virtually unchanged for millions of years. The seven living species are structurally nearly identical to the oldest fossil fossils from the Jurassic period, about 150 million years ago. The research shows that this is due to an extremely low mutation rate, up to 10 times lower than that of mammals. This means that their DNA changes less than that of other animals, causing their genes and proteins to evolve significantly more slowly.
This is remarkable. Mutations can be very beneficial to the survival of a species. While most mutations provide relatively few benefits, some changes can allow species to better adapt to their environment. Especially when living environments change. “We were surprised at how slowly traction evolved at the molecular level,” says John Lundberg. This is confirmed by co-author Chase Brownstein. “This is a unique phenomenon among vertebrates. Living fossils such as the laurel plant show that some species can adapt over long periods of time with minimal genetic change.
DNA repairs
Researchers believe there is an explanation for this. In fact, gars appear to be unusually good at repairing their own DNA, allowing them to correct somatic and germline mutations (changes in DNA that occur before and after pregnancy) more efficiently than most other vertebrates. Since they also have a fairly long lifespan (they can live up to a hundred years), there is also plenty of time to repair DNA damage and remove mutations in their bodies.
This is not only good for them, but perhaps for us as well, says researcher Thomas Near. “Most cancers are mutations in the body that represent a failure of an individual's DNA repair mechanisms. If further research shows that DNA repair mechanisms are highly effective, and discovers what makes them so, we can begin to think about potential applications for human health.”
Hybrid offspring
The researchers also discovered that two species (alligator gar and long-nosed gar) that were separated by more than 100 million years of evolution still produce viable and fertile offspring. This makes it the oldest known mixture of all animals, plants and fungi that produce fertile and viable hybrids. Two species of fern that previously held the 60 million-year-old record have been defeated. So slow evolution also has advantages, as Brownstein explains: “The slower a species mutates, the more likely it is that it will be able to interbreed with a distinct species from which it has been genetically isolated for a long period of time.”
Living environment
A final explanation for the slow evolution is that the Jarat had a very constant living environment all these years. They have lived in relatively stable freshwater habitats for millions of years, which means there is less pressure to adapt quickly. “These factors may have worked together to reduce the rate of traction mutations and stabilize their genomes,” Brownstein says. “Which allowed them to survive for millions of years with little change.”
Therefore, the rate of evolution is far from equal between species. This insight affects not only our interpretation of fossil records, but also our expectations about how species will respond to future changes in their environment, such as those caused by climate change. “This research helps us understand the diversity of life on Earth and the factors that influence its evolution,” Lundberg said. “It is an important step forward in our knowledge of the history of life.”
At the other end of the spectrum are bacteria and phages. After researchers at the University of San Diego put the two species together in a small, sealed laboratory beaker, they evolved within three weeks (!). Viruses infected their bacterial hosts while at the same time bacteria developed new ways to defend themselves against these attacks. Viruses then made new evolutionary changes, bypassing the bacteria's newly acquired defense mechanisms. The researcher on this study, Josh Boren, can easily explain why this happened so quickly. “Microorganisms such as bacteria and viruses are very numerous and reproduce rapidly,” he explains. “In the space of a single day, they can go through more than seven generations (the equivalent of about 200 years in human generations).” This means that bacterial and viral populations undergo many genetic changes. If new mutations work better, they soon take over and become dominant.
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