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.
| Joro Spiders | |
| 2020 | genetically modified marine bacteria to mass produce synthetic spider silk Laboratory research by Numata et al., RIKEN, 2020 |
| 2054 | genetically modified hyper-resistant Joro spiders optimized for opiate extraction |
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Genetically-modified marine bacteria able to produce synthetic spider silk
BBC Science Focus Magazine, July 12, 2020, Amy Arthur
https://www.sciencefocus.com/news/genetically-modified-marine-bacteria-able-to-produce-synthetic-spider-silk
Abstract
The biocompatible silk is not attacked by immune systems, making it useful for drug delivery systems, implant devices, and scaffolds for tissue engineering.
A marine bacterium has been genetically engineered to produce spider’s silk, a material with many applications, including in the medical, aerospace and clothing industries.
The silk that spiders use to form the spokes of their web is called dragline silk, and it’s tough, lightweight and biodegradable. It’s also biocompatible, which means it is compatible with living tissue and is not attacked by an animal’s immune system.
“This makes it safe for use in biomedical applications such as drug delivery systems, implant devices, and scaffolds for tissue engineering,” said Choon Pin Foong, who was involved in the study to mass-produce the silk.
These properties make it widely used and sought after, so teams around the world have tried to find a way to generate large quantities in the lab. One spider can only produce trace amounts, and because the arachnids are too territorial and often cannibalistic, it’s not possible to breed large groups for this purpose.
Instead, researchers have successfully used plants, animal cell cultures, yeasts, and other insects to produce silk similar to that found in nature. However, these methods are expensive on a large scale.
By using the purple-coloured marine bacteria, Rhodovulum sulfidophilumm, scientists at the RIKEN Center for Sustainable Resource Science have created a ‘microbial cell factory’ that needs only seawater and a source of sunlight, carbon dioxide and nitrogen to survive. This process is carbon-neutral, said Keiji Numata, who led the research team, making it eco-friendly and sustainable.
The bacteria are photosynthetic, which means it uses sunlight to produce its own nutrients in nature. In the study, R. sulfidophilumm was genetically modified to instead produce a small amount of the protein chain that makes up dragline silk.
“We are now working to mass-produce spider-silk dragline proteins at higher molecular weights in our photosynthetic system,” said Numata.
A marine bacterium has been genetically engineered to produce spider’s silk, a material with many applications, including in the medical, aerospace and clothing industries.
The silk that spiders use to form the spokes of their web is called dragline silk, and it’s tough, lightweight and biodegradable. It’s also biocompatible, which means it is compatible with living tissue and is not attacked by an animal’s immune system.
“This makes it safe for use in biomedical applications such as drug delivery systems, implant devices, and scaffolds for tissue engineering,” said Choon Pin Foong, who was involved in the study to mass-produce the silk.
These properties make it widely used and sought after, so teams around the world have tried to find a way to generate large quantities in the lab. One spider can only produce trace amounts, and because the arachnids are too territorial and often cannibalistic, it’s not possible to breed large groups for this purpose.
Instead, researchers have successfully used plants, animal cell cultures, yeasts, and other insects to produce silk similar to that found in nature. However, these methods are expensive on a large scale.
By using the purple-coloured marine bacteria, Rhodovulum sulfidophilumm, scientists at the RIKEN Center for Sustainable Resource Science have created a ‘microbial cell factory’ that needs only seawater and a source of sunlight, carbon dioxide and nitrogen to survive. This process is carbon-neutral, said Keiji Numata, who led the research team, making it eco-friendly and sustainable.
The bacteria are photosynthetic, which means it uses sunlight to produce its own nutrients in nature. In the study, R. sulfidophilumm was genetically modified to instead produce a small amount of the protein chain that makes up dragline silk.
“We are now working to mass-produce spider-silk dragline proteins at higher molecular weights in our photosynthetic system,” said Numata.
Spiders produce amazingly strong and lightweight threads made from silk proteins, which can be used to manufacture useful materials. Researchers succeeded in producing the spider silk using photosynthetic bacteria © RIKEN