Bei Speculative Evolution haben wir ausgehend von wissenschaftlichen Publikationen über synthetische Biologie, Gentechnik und Robotik überlegt, wie Arten weiterentwickelt werden könnten, um ihre Widerstandsfähigkeit zu erhöhen. Daraufhin haben wir Textanweisungen formuliert, um mit DALL-E KI-generierte Bilder zu erstellen. Jede spekulative Art in der Simulation hat so eine Hintergrundgeschichte, die in realen Szenarien verwurzelt ist.
| Mourning Geckos | |
| 2021 | gene edited stem cells help regrow more perfect tails Laboratory research by Lozito, University of Southern California (UCLA), 2021 |
| 2054 | gene edited to grow an additional head |
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Gene-edited stem cells help geckos regrow more perfect tails
Science News, NOVEMBER 1, 2021, by Freda Kreier
https://www.sciencenews.org/article/gecko-tail-regrow-regeneration-gene-editing-stem-cells
Abstract
Gene-edited stem cells help geckos regrow more perfect tails
Regenerating body parts is never easy. For instance, some lizards can grow back their tails, but these new appendages are pale imitations of the original. Now, genetically modified stem cells are helping geckos grow back better tails.
Tweaking and implanting embryonic stem cells on the tail stumps of mourning geckos (Lepidodactylus lugubris) allowed the reptiles to grow tails that are more like the original than ever before, researchers report October 14 in Nature Communications. These findings are a stepping-stone to developing regenerative therapies in humans that may one day treat hard-to-heal wounds.
A gecko’s tail is an extension of its spine — with the vertebrae to prove it. Regenerated tails, however, are simpler affairs. “It’s just a bunch of concentric tubes of fat, muscle and skin,” says Thomas Lozito, a biologist at the University of Southern California in Los Angeles.
That’s because stem cells in adult geckos produce a molecular signal that encourages the formation of cartilage in new tails, but not bone or nervous tissues (SN: 8/17/18). Lozito and his colleagues used embryonic stem cells, which can develop into a wider range of tissues than adult stem cells, modified them to ignore this signal and then implanted them on the tail stumps of geckos that had their tails surgically removed. The tails that grew from these modified stem cells had bonelike grooves in the cartilage and generated new neural tissue at the top of the tail.
These modified tails still lack a spinal cord, making them a far cry from the original. “We fixed one problem, but there are still many imperfections,” Lozito says. “We’re still on the hunt for the perfect tail.”
Regenerating body parts is never easy. For instance, some lizards can grow back their tails, but these new appendages are pale imitations of the original. Now, genetically modified stem cells are helping geckos grow back better tails.
Tweaking and implanting embryonic stem cells on the tail stumps of mourning geckos (Lepidodactylus lugubris) allowed the reptiles to grow tails that are more like the original than ever before, researchers report October 14 in Nature Communications. These findings are a stepping-stone to developing regenerative therapies in humans that may one day treat hard-to-heal wounds.
A gecko’s tail is an extension of its spine — with the vertebrae to prove it. Regenerated tails, however, are simpler affairs. “It’s just a bunch of concentric tubes of fat, muscle and skin,” says Thomas Lozito, a biologist at the University of Southern California in Los Angeles.
That’s because stem cells in adult geckos produce a molecular signal that encourages the formation of cartilage in new tails, but not bone or nervous tissues (SN: 8/17/18). Lozito and his colleagues used embryonic stem cells, which can develop into a wider range of tissues than adult stem cells, modified them to ignore this signal and then implanted them on the tail stumps of geckos that had their tails surgically removed. The tails that grew from these modified stem cells had bonelike grooves in the cartilage and generated new neural tissue at the top of the tail.
These modified tails still lack a spinal cord, making them a far cry from the original. “We fixed one problem, but there are still many imperfections,” Lozito says. “We’re still on the hunt for the perfect tail.”
Mourning geckos (one shown) are an all-female species of lizard capable of regrowing their tails.
BRIAN GRATWICKE/FLICKR (CC BY 4.0)