Gibson Assembly® Advances Field of DNA Digital Data Storage
Gibson Assembly strategy successfully employed to significantly increase the throughput of DNA data storage and retrieval
SAN DIEGO--(BUSINESS WIRE)-- Researchers from the University of Washington and Microsoft announced a DNA assembly strategy for nanopore data storage, reporting that the Gibson Assembly® method was exceptionally effective in retrieving information stored in DNA. The strategy successfully decoded a picture of a space shuttle, the Earth, and Leonardo da Vinci’s Vitruvian Man.
Todd R. Nelson Ph.D., CEO of SGI-DNA, stated, “We are excited to see SGI-DNA’s technologies being applied across multiple disciplines and will continue to expand our BioXp™ Gene Builder and reagents portfolio to include next generation tools for DNA data storage.”
A paper describing this research, “DNA assembly for nanopore data storage readout,” was published July 3rd in the journal Nature Communications by authors Randolph Lopez, Yuan-Jyue Chen, Siena Dumas Ang, Sergey Yekhanin, Konstantin Makarychev, Miklos Z. Racz, Georg Seelig, Karin Strauss, and Luis Ceze.
“Applying Gibson Assembly to information retrieval from DNA was instrumental in addressing nanopore readout bottlenecks by producing long DNA constructs and significantly increasing data output. This leads to higher readout performance and better resource usage,” said Dr. Luis Ceze, Professor at University of Washington, and senior author of the Nature Communications manuscript.
DNA storage has been a growing area of interest due to its encoding power with a capacity to store more than 200 petabytes (million gigabytes) of data per gram of DNA. The Gibson Assembly Method enables the creation of DNA that’s easily accessed, decoded and read, overcoming the challenges of retrieving information from DNA. In their manuscript, the team at University of Washington demonstrated that using the Gibson Assembly method, in combination with the compact nanopore sequencing platform, allowed them to retrieve and decode a total of 1.67 megabytes of data stored in short sections of synthetic DNA. This accomplishment represents the power of combining big data with DNA storage miniaturization.
Daniel Gibson, Ph.D., CTO of SGI-DNA and inventor of Gibson Assembly, commented, “It’s incredible to see the revolutionary developments in DNA storage that have emerged from recent advances in reading and writing DNA. Gibson Assembly is being widely adopted and is on the forefront of many exciting new technologies, everywhere from personalized medicine to big data. Our continued and aggressive development of fully automated applications for the BioXp Gene Builder, such as Multi-Tile Assembly and Cloning (MTAC), place these capabilities into the hands of scientists for the first time.”
SGI-DNA’s landmark discoveries in DNA storage began in 2008 with the creation of the first synthetic genome designed to have its architect’s names stored in it. Later in 2010, the genome of the first synthetic cell was designed to include the names of its authors and some famous quotations. In the latter work, a new code was designed and implemented to be biologically innocuous to an organism carrying that DNA. Unique sequences allow signatures, “barcodes” and other information to be tracked within the DNA sequences of any synthetic sequence or organism, providing nano-level quality control of DNA products.
For more information on the BioXp™ 3200 Gene Builder and its applications, visit www.sgidna.com.
The Gibson Assembly® Method is also available under commercial license. For more information, contact us at email@example.com.
At SGI-DNA, our mission is to develop revolutionary synthetic genomics platforms that accelerate advances in drug discovery, precision medicine, DNA data storage and industrial design; bridging the gap between the digital and biological worlds. For more information, please visit www.sgidna.com.
SOURCE SGI-DNA Corporation
Ruth Petersen, 858-754-2979
Source: SGI-DNA Corporation