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R&D: Research Overcomes Key Obstacles to Scaling Up DNA Data Storage

With techniques for labeling and retrieving data files

From Matt Shipman, North Carolina State University

Researchers from North Carolina State University have developed new techniques for labeling and retrieving data files in DNA-based information storage systems, addressing two of the key obstacles to widespread adoption of DNA data storage technologies.

Keung Dna Memory 2019 Header

(Image credit: DataBase Center for Life Science)
Shared under a Creative Commons license.

DNA systems are attractive because of their potential information storage density; they could theoretically store a billion times the amount of data stored in a conventional electronic device of comparable size,” says James Tuck, co-corresponding author of a paper on the work, and associate professor, electrical and computer engineering, NC State.

But two of the big challenges here are, how do you identify the strands of DNA that contain the file you are looking for? And once you identify those strands, how do you remove them so that they can be read – and do so without destroying the strands?

Previous work had come up with a system that appends short, 20-monomer long sequences of DNA called primer-binding sequences to the ends of DNA strands that are storing information,” says Albert Keung, co-corresponding author of the paper, and assistant professor, chemical and biomolecular engineering, NC State. “You could use a small DNA primer that matches the corresponding primer-binding sequence to identify the appropriate strands that comprise your desired file. However, there are only an estimated 30,000 of these binding sequences available, which is insufficient for practical use. We wanted to find a way to overcome this limitation.

To address these problems, the researchers developed two techniques that, taken together, they call DNA Enrichment and Nested Separation, or DENSe.

The researchers tackled the file identification challenge by using two, nested primer-binding sequences. The system first identifies all of the strands containing the initial binder sequence. It then conducts a second ‘search’ of that subset of strands to single out those strands that contain the second binder sequence.

This increases the number of estimated file names from approximately 30,000 to approximately 900 million,” Tuck says.

Once identified, the file still needs to be extracted. Existing techniques use polymerase chain reaction (PCR) to make lots (and lots) of copies of the relevant DNA strands, then sequence the entire sample. Because there are so many copies of the targeted DNA strands, their signal overwhelms the rest of the strands in the sample, making it possible to identify the targeted DNA sequence and read the file.

That technique is not efficient, and it doesn’t work if you are trying to retrieve data from a high-capacity database – there’s just too much other DNA in the system,” says Kyle Tomek, Ph.D. Student, NC State, and co-lead author of the paper.

So the researchers took a different approach to data retrieval, attaching any of several small molecular tags to the primers being used to identify targeted DNA strands. When the primer finds the targeted DNA, it uses PCR to make a copy of the relevant DNA – and the copy is attached to the molecular tag.

The researchers also utilized magnetic microbeads coated with molecules that bind specifically to a given tag. These functionalized microbeads ‘grab’ the tags of targeted DNA strands. The microbeads can then be retrieved with a magnet, bringing the targeted DNA with them.

This system allows us to retrieve the DNA strands associated with a specific file without having to make many copies of each strand, while also preserving the original DNA strands in the database,” Keung says. We’ve implemented the DENSe system experimentally using sample files, and have demonstrated that it can be used to store and retrieve text and image files,

These techniques, when used in tandem, open the door to developing DNA-based data storage systems with modern capacities and file-access capabilities,” Tomek says.

Next steps include scaling this up and testing the DENSe approach with larger databases,” Tuck says. “ A big challenge there is cost.

The paper, Driving the Scalability of DNA-Based Information Storage Systems, is published in the journal ACS Synthetic Biology. Co-lead author of the paper is Kevin Volkel, Ph.D. Student, NC State. The paper was co-authored by Alexander Simpson, former graduate student, NC State; and Austin Hass and Elaine Indermaur, both undergraduates, NC State.

The work was done with support from the National Science Foundation under grant number 1650148.

Article: Driving the Scalability of DNA-Based Information Storage Systems

ACS Synthetic Biology has published an article written by Kyle J. Tomek, Department of Chemical and Biomolecular Engineering, North Carolina State University, Raleigh, North Carolina 27695, USA, Kevin Volkel, Alexander Simpson, Department of Electrical and Computer Engineering, North Carolina State University, Raleigh, North Carolina 27695, USA, Austin G. Hass, Department of Chemical and Biomolecular Engineering, North Carolina State University, Raleigh, North Carolina 27695, USA, and Department of Structural and Molecular Biochemistry, North Carolina State University, Raleigh, North Carolina 27695, USA, Elaine W. Indermaur, Department of Chemical and Biomolecular Engineering, North Carolina State University, Raleigh, North Carolina 27695, USA, James M. Tuck, Department of Electrical and Computer Engineering, North Carolina State University, Raleigh, North Carolina 27695, USA, and Albert J. Keung, Department of Chemical and Biomolecular Engineering, North Carolina State University, Raleigh, North Carolina 27695, USA.

North Carolina State University Sb 2019 00100b 0004

Abstract: “The extreme density of DNA presents a compelling advantage over current storage media; however, to reach practical capacities, new systems for organizing and accessing information are needed. Here, we use chemical handles to selectively extract unique files from a complex database of DNA mimicking 5TB of data and design and implement a nested file address system that increases the theoretical maximum capacity of DNA storage systems by five orders of magnitude. These advancements enable the development and future scaling of DNA-based data storage systems with modern capacities and file access capabilities.

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