Photon-directed Multiplexed Enzymatic DNA Synthesis for Molecular Digital Data Storage

Lee, Howon; Wiegand, Daniel J.; Griswold, Kettner; Punthambaker, Sukanya; Chun, Honggu; Kohman, Richie E.; Church, George M.

doi:10.1101/2020.02.19.956888

Cited by 5 publications

(4 citation statements)

References 24 publications

(35 reference statements)

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“…We demonstrated MDRAM’s capacity for conjugation of data-encoded oligonucleotides. Importantly, the chemistry itself is widely applicable for conjugation of other types of DNA onto the magnetic substrate – for example, we anticipate that longer strands of information-encoded DNA ( 6 ) or those from enzymatic synthesis ( 27, 28 ) would also be compatible with conjugation. Therefore, MDRAM is amenable for any type of biomolecule storage platform that is compatible with TCO-Tz labeling schemes.…”

Section: Discussionmentioning

confidence: 99%

Magnetic DNA random access memory with nanopore readouts and exponentially-scaled combinatorial addressing

Lau

Chandak

Roy

et al. 2021

Preprint

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The storage of data in DNA typically involves encoding and synthesizing data into short oligonucleotides, followed by reading with a sequencing instrument. Major challenges include the molecular consumption of synthesized DNA, issues with basecalling errors, and limitations with scaling up read access operations for individual data elements. Addressing these challenges, we describe a DNA storage system called MDRAM (Magnetic DNA-based Random Access Memory) that enables repetitive and efficient readouts of targeted files with nanopore-based sequencing. Through conjugation of synthesized DNA to magnetic beads, we enabled repeated readouts of data while preserving the original DNA analyte and maintaining data readout quality. MDRAM also utilizes an efficient convolutional coding scheme that leverages soft information in raw nanopore sequencing signals to achieve information reading costs comparable to Illumina sequencing despite substantially higher error rates. Finally, we demonstrate a proof-of-concept DNA-based proto-filesystem that enables an exponentially-scalable data address space using only small numbers of targeting primers for assembly and readout.

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Section: Discussionmentioning

confidence: 99%

Magnetic DNA random access memory with nanopore readouts and exponentially-scaled combinatorial addressing

Lau

Chandak

Roy

et al. 2021

Preprint

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“…Novel approaches focus on enzymatic DNA synthesis ( Lee et al, 2019 ; Lee et al, 2020a ). While oligonucleotides produced with this methodology currently remain shorter, experts expect lower error rates, higher speed and longer fragments with this upcoming technology.…”

Section: Technological Strategies Towards Implementationmentioning

confidence: 99%

Decoding DNA data storage for investment

Stanley¹,

Strittmatter²,

Vickers³

et al. 2020

Biotechnology Advances

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While DNA's perpetual role in biology and life science is well documented, its burgeoning digital applications are beginning to garner significant interest. As the development of novel technologies requires continuous research, product development, startup creation, and financing, this work provides an overview of each respective area and highlights current trends, challenges, and opportunities. These are supported by numerous interviews with key opinion leaders from across academia, government agencies and the commercial sector, as well as investment data analysis. Our findings illustrate the societal and economic need for technological innovation and disruption in data storage, paving the way for nature's own time-tested, advantageous, and unrivaled solution. We anticipate a significant increase in available investment capital and continuous scientific progress, creating a ripe environment on which DNA data storage-enabling startups can capitalize to bring DNA data storage into daily life.

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“…Molecular recording strategies write information into DNA by altering existing DNA sequences (5) or adding new sequences (6). For example, systems have been developed that use methods including differential CRISPR spacer acquisition (5,7,8), enzymatic synthesis (9)(10)(11) and others (1,8,12). By connecting these DNA modifications to a user input (in the case of data storage) or environmental signal of interest (in the case of recording events), these strategies enable post hoc recovery of signal dynamics over time by DNA sequencing.…”

Section: Introductionmentioning

confidence: 99%

Recording Temporal Signals with Minutes Resolution Using Enzymatic DNA Synthesis

Bhan

Castinado

Glaser

et al. 2021

Preprint

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Employing DNA as a high-density data storage medium has paved the way for next-generation digital storage and biosensing technologies. However, the multipart architecture of current DNA-based recording techniques renders them inherently slow and incapable of recording fluctuating signals with sub-hour frequencies. To address this limitation, we developed a simplified system employing a single enzyme, terminal deoxynucleotidyl transferase (TdT), to transduce environmental signals into DNA. TdT adds nucleotides to the 3 prime ends of single-stranded DNA (ssDNA) in a template-independent manner, selecting bases according to inherent preferences and environmental conditions. By characterizing TdT nucleotide selectivity under different conditions, we show that TdT can encode various physiologically relevant signals like Co2+, Ca2+, Zn2+ concentrations and temperature changes in vitro. Further, by considering the average rate of nucleotide incorporation, we show that the resulting ssDNA functions as a molecular ticker tape. With this method we accurately encode a temporal record of fluctuations in Co2+ concentration to within 1 minute over a 60-minute period. Finally, we engineer TdT to allosterically turn off in the presence of physiologically relevant concentration of calcium. We use this engineered TdT in concert with a reference TdT to develop a two-polymerase system capable of recording a single step change in Ca2+ signal to within 1 minute over a 60-minute period. This work expands the repertoire of DNA-based recording techniques by developing a novel DNA synthesis-based system that can record temporal environmental signals into DNA with minutes resolution.

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Photon-directed Multiplexed Enzymatic DNA Synthesis for Molecular Digital Data Storage

Cited by 5 publications

References 24 publications

Magnetic DNA random access memory with nanopore readouts and exponentially-scaled combinatorial addressing

Magnetic DNA random access memory with nanopore readouts and exponentially-scaled combinatorial addressing

Decoding DNA data storage for investment

Recording Temporal Signals with Minutes Resolution Using Enzymatic DNA Synthesis

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