Kraig Biocraft Laboratories, Inc. is an American biotechnology company headquartered in Ann Arbor, Michigan. It develops and manufactures recombinant spider silks and other high-performance polymers using spider silk gene sequences.[1] Their most notable fiber is dragon silk which has been demonstrated to be tougher than many fibers used in bullet proof vests.[2]
Company type | Public |
---|---|
Industry | Biotechnology |
Founded | 2006 |
Founder | Kim Thompson |
Headquarters | Ann Arbor, Michigan |
Key people | |
Website | www |
History
editKim Kraig Thompson, a retired lawyer, invented the protein expression platform in 2002, which would become the basis for Kraig Lab's work with spider silk.[3] He founded Kraig Biocraft Laboratories in April 2006 to develop and commercialize spider silks and other high-performance polymers gene and sequences using platform technology in combination with genetic engineering concepts.[4]
The original scientific work to reduce Thompson's invention to practice was performed in the biological laboratories of the University of Notre Dame. The University of Notre Dame was chosen in large part because the co-inventor of the PiggyBac transposon system, Malcom Fraser, was in residence there. This transposon was utilized by Kraig Labs and the University of Notre Dame to create the world's first transgenic silkworm producing recombinant spider silk. This work was subsequently the subject of a peer-reviewed article in the publication of the National Academy of Sciences (PNAS).[5]
In 2011, Sigma-Aldrich started developing genetically modified silkworms in partnership with Kraig Biocraft Laboratories in order to produce spider silk.[1]
In 2019, the company's wholly owned subsidiary, Prodigy Textiles LLC, established production facility in Vietnam for the production of spider silk.[6][7]
Research
editThe company's production platform is based upon genetic modification of the domesticated silk worm, Bombyx mori.
In 2020, the firm successfully developed a significantly more advanced technology platform. This utilized a non-CRISPR gene editing, large plasmid knock-in knock-out technology. The new platform allows for the creation of essentially pure spider silk. Other than the silkworm's remaining specifically desired native silk protein elements, Kraig Labs is now able to produce nearly pure spider silk.[8] The knock-in knock-out technology allows Kraig Labs to work with very complex protein sequences in the silkworms, which are about four times more complex than published technologies. The company's Generation III Spider Silk Technology is purposed for specific customization.[8]
Kraig Labs originally used the PiggyBac Transposon plasmid vector that was developed in collaboration with the University of Notre Dame.[9] In all methods, specific sequences of spider DNA are inserted into the genetic makeup of the silkworm to create a silkworm that produces spider silk. That transgenic silkworm is then used as the basis for establishing a genetic line silkworms that also produce spider silk.[10] The firm is able to customize the sequences that it inserts into the silkworm, thus giving them the ability to customize the resulting silk thread's strength, flexibility and possibly other properties.[11]
References
edit- ^ a b Kelsey Volkmann (April 11, 2012). "Sigma-Aldrich to make modified silk worms". St. Louis Business Journal. (subscription required)
- ^ "Spider Silk Production Breakthrough from Kraig Biocraft Laboratories | Kraig Biocraft Laboratories". 30 May 2019.
- ^ "Original Provisional Patent | Kraig Biocraft Laboratories". 8 May 2020.
- ^ "Kraig Biocraft Laboratories Announces Patent Filing on Artificial Spider Silk Breakthrough | Kraig Biocraft Laboratories". 30 September 2010.
- ^ Teulé, Florence; Miao, Yun-Gen; Sohn, Bong-Hee; Kim, Young-Soo; Hull, J. Joe; Fraser, Malcolm J.; Lewis, Randolph V.; Jarvis, Donald L. (17 January 2012). "Silkworms transformed with chimeric silkworm/spider silk genes spin composite silk fibers with improved mechanical properties". Proceedings of the National Academy of Sciences. 109 (3): 923–928. Bibcode:2012PNAS..109..923T. doi:10.1073/pnas.1109420109. PMC 3271896. PMID 22215590.
- ^ "Full speed ahead in Vietnam".
- ^ Friedman, Arthur (July 27, 2021). "Kraig Biocraft Hits Vietnam Covid Snag".
- ^ a b "Kraig Biocraft Laboratories achieves Knock-in Knock-out Success to create nearly Pure Spider Silk | Kraig Biocraft Laboratories". 17 April 2020.
- ^ "Kraig Biocraft Laboratories, Inc. Gears Up to Double the Number of Genetic Insertions Performed | Kraig Biocraft Laboratories". 12 May 2009.
- ^ Grossman, Lisa (October 4, 2010). "Mutant Worms Produce Piles of Spider Silk". Wired – via www.wired.com.
- ^ "Transgenic Worms Make Tough Fibers". MIT Technology Review.
External links
edit- Kraig Biocraft Laboratories Achieves Production Goal to Create Nearly Pure Spider Silk
- Kraig Labs claims spider silk breakthrough
- Kraig scales up breeding silkworms for super-strong ‘spider silk’
- Meet the Transgenic Silkworms That Are Spinning Out Spider Silk
- Silkworms transformed with chimeric silkworm/spider silk genes spin composite silk fibers with improved mechanical properties
- Quality Fabric Of The Month: Spider Silk — Potential Unleashed | Textile World
- University of Notre Dame | College of Science
- Notre Dame and University of Wyoming scientists genetically engineer silkworms to produce artificial spider silk
- Scientists Compare Rat Genome With Human, Mouse
- Mutant Worms Produce Piles of Spider Silk
- Wayback Machine