High-Capacity Storage of Digital Information in DNA

Abstract

A method for storage of an item of information (210) is disclosed. The method comprises encoding bytes (720) in the item of information (210), and representing using a schema the encoded bytes by a DNA nucleotide to produce a DNA sequence (230). The DNA sequence (230) is broken into a plurality of overlapping DNA segments (240) and indexing information (250) added to the plurality of DNA segments. Finally, the plurality of DNA segments (240) is synthesized (790) and stored (795).

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. patent application Ser. No. 14/556,213 filed on Nov. 30, 2014, which is a continuation of PCT Application No. PCT/EP2013/061300 filed on May 31, 2013, which claims the benefit of the filing date of U.S. Provisional Patent Application Ser. No. 61/654,295, filed on Jun. 1, 2012. The above-referenced applications are hereby incorporated by reference.

SEQUENCE LISTING

The instant application contains a Sequence Listing which has been submitted electronically in ASCII format and is hereby incorporated by reference in its entirety. Said ASCII copy, created on Jun. 1, 2015, is named 4091.91216USC1_SL.txt and is 1,592 bytes in size.

BACKGROUND OF THE INVENTION

Field of the Invention

The disclosure relates to a method and apparatus for the storage of digital information in DNA.

Brief Description of the Related Art

DNA has the capacity to hold vast amounts of information, readily stored for long periods in a compact form. Bancroft, C., Bowler, T., Bloom, B. & Clelland, C. T. Long-term storage of information in DNA. Science 293, 1763-1765 (2001) and Cox, J. P. L. Long-term data storage in DNA. TRENDS Biotech. 19, 247-250 (2001). The idea of using DNA as a store for digital information has existed since 1995. Baum, E. B. Building an associative memory vastly larger than the brain. Science 268, 583-585 (1995). Physical implementations of DNA storage have to date stored only trivial amounts of information—typically a few numbers or words of English text. Clelland, C. T., Risca, V. & Bancroft, C. Hiding messages in DNA microdots. Nature 399, 533-534 (1999); Kac, E. Genesis (1999) http://www.ekac.org/geninfo.html accessed online, 2 Apr. 2012; Wong, P. C., Wong, K.-K. & Foote, H. Organic data memory. Using the DNA approach. Comm. ACM 46, 95-98 (2003); Ailenberg, M. & Rotstein, O. D. An improved Huffman coding method for archiving text, images, and music characters in DNA. Biotechniques 47, 747-754 (2009); Gibson, D. G. et al. Creation of a bacterial cell controlled by a chemically synthesized genome. Science 329, 52-56 (2010). The inventors are unaware of large-scale storage and recovery of arbitrarily sized digital information encoded in physical DNA, rather than data storage on magnetic substrates or optical substrates.

Currently the synthesis of DNA is a specialized technology focused on biomedical applications. The cost of the DNA synthesis has been steadily decreasing over the past decade. It is interesting to speculate at what timescale data storage in a DNA molecule, as disclosed herein, would be more cost effective than the current long term archiving process of data storage on tape with rare but regular transfer to new media every 3 to 5 years. Current “off the shelf” technology for DNA synthesis equates to a price of around 100 bytes per U.S. dollar. Newer technology commercially available from Agilent Technologies (Santa Clara, Calif.) may substantially decrease this cost. However, account also needs to be made for regular transfer of data between tape media. The questions are both the costs for this transfer of data and whether this cost is fixed or diminishes over time. If a substantial amount of the cost is assumed to be fixed, then there is a time horizon at which use of DNA molecules for data storage is more cost effective than regular data storage on the tape media. After 400 years (at least 80 media transfers), it is possible that this data storage using DNA molecules is already cost effective.

The high capacity of DNA to store information stably under easily achieved conditions has made DNA an attractive target for information storage since 1995. In addition to information density, DNA molecules have a proven track record as an information carrier, longevity of the DNA molecule is known and the fact that, as a basis of life on Earth, methods for manipulating, storing and reading the DNA molecule will remain the subject of continual technological innovation while there remains DNA-based intelligent life. Data storage systems based on both living vector DNA (in vivo DNA molecules) and on synthesized DNA (in vitro DNA) have been proposed. The in vivo data storage systems have several disadvantages. Such disadvantages include constraints on the quantity, genomic elements and locations that can be manipulated without affecting viability of the DNA molecules in the living vector organisms. Examples of such living vector organisms include but are not limited to bacteria. The reduction in viability includes decreasing capacity and increasing the complexity of information encoding schemes. Furthermore, germline and somatic mutation will cause fidelity of the stored information and decoded information to be reduced over time and possibly a requirement for storage conditions of the living DNA to be carefully regulated.

In contrast, the “isolated DNA” (i.e., in vitro DNA) is more easily “written” and routine recovery of examples of the non-living DNA from samples that are tens of thousands of years old indicates that a well-prepared non-living DNA sample should have an exceptionally long lifespan in easily-achieved low-maintenance environments (i.e. cold, dry and dark environments). See, Shapiro, B. et al. Rise and fall of the Beringian steppe bison. Science 306, 1561-1565 (2004); Poinar, H. K. et al. Metagenomics to paleogenomics: large-scale sequencing of mammoth DNA. Science 311, 392-394 (2005); Willerslev, E. et al. Ancient biomolecules from deep ice cores reveal a forested southern Greenland. Science 317, 111-114 (2007); Green, R. E. et al. A draft sequence of the Neanderthal genome. Science 328, 710-722 (2010); Anchordoquy, T. J. & Molina, M. C. Preservation of DNA. Cell Preservation Tech. 5, 180-188 (2007); Bonnet, J. et al. Chain and conformation stability of solid-state DNA: implications for room temperature storage. Nucl. Acids Res. 38, 1531-1546 (2010); Lee, S. B., Crouse, C. A. & Kline, M. C. Optimizing storage and handling of DNA extracts. Forensic Sci. Rev. 22, 131-144 (2010).

Previous work on the storage of information (also termed data) in the DNA has typically focused on “writing” a human-readable message into the DNA in encoded form, and then “reading” the encoded human-readable message by determining the sequence of the DNA and decoding the sequence. Work in the field of DNA computing has given rise to schemes that in principle permit large-scale associative (content-addressed) memory, but there have been no attempts to develop this work as practical DNA-storage schemes. Baum, E. B. Building an associative memory vastly larger than the brain. Science 268, 583-585 (1995); Tsaftaris, S. A. & Katsaggelos, A. K. On designing DNA databases for the storage and retrieval of digital signals. Lecture Notes Comp. Sci. 3611, 1192-1201 (2005); Yamamoto, M., Kashiwamura, S., Ohuchi, A. & Furukawa, M. Large-scale DNA memory based on the nested PCR. Natural Computing 7, 335-346 (2008); Kari, L. & Mahalingam, K. DNA computing: a research snapshot. In Atallah, M. J. & Blanton, M. (eds.) Algorithms and Theory of Computation Handbook, vol. 2. 2nd ed. pp. 31-1-31-24 (Chapman & Hall, 2009). FIG. 1 shows the amounts of information successfully encoded and recovered in 14 previous studies (note the logarithmic scale on the y-axis). Points are shown for 14 previous experiments (open circles) and for the present disclosure (solid circle). The largest amount of human-readable messages stored this way is 1280 characters of English language text⁸, equivalent to approximately 6500 bits of Shannon information. Gibson, D. G. et al. Creation of a bacterial cell controlled by a chemically synthesized genome. Science 329, 52-56 (2010); MacKay, D. J. C. Information Theory, Inference, and Learning Algorithms. (Cambridge University Press, 2003).

The Indian Council of Scientific and Industrial Research has filed a U.S. Patent Application Publication No. 2005/0053968 (Bharadwaj et al) that teaches a method for storing information in DNA. The method of U.S. '968 comprises using an encoding method that uses 4-DNA bases representing each character of an extended ASCII character set. A synthetic DNA molecule is then produced, which includes the digital information, an encryption key, and is flanked on each side by a primer sequence. Finally, the synthesized DNA is incorporated in a storage DNA. In the event that the amount of DNA is too large, then the information can be fragmented into a number of segments. The method disclosed in U.S. '968 is able to reconstruct the fragmented DNA segments by matching up the header primer of one of the segments with the tail primer on the subsequent one of the segments.

Other patent publications are known which describe techniques for storing information in DNA. For example, U.S. Pat. No. 6,312,911 teaches a steganographic method for concealing coded messages in DNA. The method comprises concealing a DNA encoded message within a genomic DNA sample followed by further concealment of the DNA sample to a microdot. The application of this U.S. '911 patent is in particular for the concealment of confidential information. Such information is generally of limited length and thus the document does not discuss how to store items of information that are of longer length. The same inventors have filed an International Patent Application published as International Publication No. WO 03/025123.

SUMMARY OF THE INVENTION

A practical encoding-decoding procedure that stores more information than previously handled is described in this disclosure. The inventors have encoded five computer files—totaling 757051 bytes (739 kB) of hard disk storage and with an estimated Shannon information of 5.2×10⁶ bits—into a DNA code. The inventors subsequently synthesized this DNA, transported the synthesized DNA from the USA to Germany via the UK, sequenced the DNA and reconstructed all five computer files with 100% accuracy.

The five computer files included an English language text (all 154 of Shakespeare's sonnets), a PDF document of a classic scientific paper, a JPEG colour photograph and an MP3 format audio file containing 26 seconds of speech (from Martin Luther King's “I Have A Dream” speech). Watson, J. D. & Crick, F. H. C. Molecular structure of nucleic acids. Nature 171, 737-738 (1953). This data storage represents approximately 800 times as much information as the known previous DNA-based storage and covers a much greater variety of digital formats. The results demonstrate that DNA storage is increasingly realistic and could, in future, provide a cost-effective means of archiving digital information and may already be cost effective for low access, multi-decade archiving tasks.

A method for storage of an item of information is disclosed. The method comprises encoding bytes in the item of information. The encoded bytes are represented using a schema by a DNA nucleotide to produce a DNA sequence in-silico. In a next step, the DNA sequence is split into a plurality of overlapping DNA segments and indexing information is added to the plurality of DNA segments. Finally, the plurality of DNA segments is synthesized and stored.

The addition of the indexing information to the DNA segments means that the position of the segments in the DNA sequence representing the item of information can be uniquely identified. There is no need to rely on a matching of a head primer with a tail primer. This makes it possible to recover almost the entire item of information, even if one of the segments has failed to reproduce correctly. If no indexing information were present, then there is a risk that it might not be possible to correctly reproduce the entire item of information if the segments could not be matched to each other due to “orphan” segments whose position in the DNA sequence cannot be clearly identified.

The use of overlapping DNA segments means that a degree of redundancy is built into the storage of the items of information. If one of the DNA segments cannot be decoded, then the encoded bytes can still be recovered from neighboring ones of the DNA segments. Redundancy is therefore built into the system.

Multiple copies of the DNA segments can be made using known DNA synthesis techniques. This provides an additional degree of redundancy to enable the item of information to be decoded, even if some of copies of the DNA segments are corrupted and cannot be decoded.

In one aspect of the invention, the representation schema used for encoding is designed such that adjacent ones of the DNA nucleotides are different. This is to increase the reliability of the synthesis, reproduction and sequencing (reading) of the DNA segments

In a further aspect of the invention, a parity-check is added to the indexing information. This parity check enables erroneous synthesis, reproduction or sequencing of the DNA segments to be identified. The parity-check can be expanded to also include error correction information.

Alternate ones of the synthesized DNA segments are reverse complemented.

These provide an additional degree of redundancy in the DNA and means that there is more information available if any of the DNA segment is corrupted.

DESCRIPTION OF THE FIGURES

For a more complete understanding of the present invention and the advantages thereof, reference is now made to the following description and the accompanying drawings, in which:

FIG. 1 is a graph of amounts of information stored in DNA and successfully recovered, as a function of time.

FIG. 2 shows an example of the method of the present disclosure. FIG. 2 discloses SEQ ID NO: 4.

FIG. 3 shows a graph of the cost effectiveness of storage over time.

FIG. 4 shows a motif with a self-reverse complementary pattern.

FIG. 5 shows the encoding efficiency.

FIG. 6 shows error rates.

FIG. 7 shows a flow diagram of the encoding of the method.

FIG. 8 shows a flow diagram of the decoding of the method.

DETAILED DESCRIPTION

One of the main challenges for a practical implementation of DNA storage to date has been the difficulty of creating long sequences of DNA to a specified design. The long sequences of DNA are required to store large data files, such as long text items and videos. It is also preferable to use an encoding with a plurality of copies of each designed DNA. Such redundancy guards against both encoding and decoding errors, as will be explained below. It is not cost-efficient to use a system based on individual long DNA chains to encode each (potentially large) message. The inventors have developed a method that uses ‘indexing’ information associated with each one of the DNA segments to indicate the position of the DNA segment in a hypothetical longer DNA molecule that encodes the entire message.

The inventors used methods from code theory to enhance the recoverability of the encoded messages from the DNA segment, including forbidding DNA homopolymers (i.e. runs of more than one identical base) that are known to be associated with higher error rates in existing high throughput technologies. The inventors further incorporated a simple error-detecting component, analogous to a parity-check bit⁹ into the indexing information in the code. More complex schemes, including but not limited to error-correcting codes and, indeed, substantially any form of digital data security (e.g. RAID-based schemes) currently employed in informatics, could be implemented in future developments of the DNA storage scheme. See, Baum, E. B. Building an associative memory vastly larger than the brain. Science 268, 583-585 (1995) and Chen, P. M., Lee, E. K., Gibson, G. A., Katz, R. H. & Patterson, D. A. RAID: high-performance, reliable secondary storage. ACM Computing Surveys 26, 145-185 (1994).

The inventors selected five computer files to be encoded as a proof-of-concept for the DNA storage of this disclosure. Rather than restricting the files to human-readable information, files using a range of common formats were chosen. This demonstrated the ability of the teachings of the disclosure to store arbitrary types of digital information. The files contained all 154 of Shakespeare's sonnets (in TXT format), the complete text and figure of ref 10 (in PDF format), a medium-resolution color photograph of the EMBL-European Bioinformatics Institute (JPEG 2000 format), a 26 second extract from Martin Luther King's “I Have A Dream” speech (MP3 format) and a file defining the Huffman code used in this study to convert bytes to base-3 digits (as a human-readable text file).

The five files selected for DNA-storage were as follows:

• • wssnt10.txt—107738 bytes—ASCII text format all 154 Shakespeare sonnets (from Project Gutenberg, http://www.gutenberg.org/ebooks/1041)
  • watsoncrick.pdf—280864 bytes—PDF format document Watson and Crick's (1953) publication¹⁰ describing the structure of DNA (from the Nature website, http://www.nature.com/nature/dna50/archive.html, modified to achieve higher compression and thus smaller file size).
  • EBI.jp2—184264 bytes—JPEG 2000 format image file color photograph (16.7M colors, 640×480 pixel resolution) of the EMBL-European Bioinformatics Institute (own picture).
  • MLK_excerpt_VBR_45-85.mp3—168539 bytes—MP3 format sound file 26 second-long extract from Martin Luther King's “I Have A Dream” speech (from http://www.americanrhetoric.com/speeches/mlkihaveadream.htm, modified to achieve higher compression: variable bit rate, typically 48-56 kbps; sampling frequency 44.1 kHz)
  • View huff3.cd.new—15646 bytes—ASCII file human-readable file defining the Huffman code used in this study to convert bytes to base-3 digits (trits)

The five computer files comprise a total of 757051 bytes, approximately equivalent to a Shannon information of 5.2×10⁶ bits or 800 times as much encoded and recovered human-designed information as the previous maximum amount known to have been stored (see FIG. 1).

The DNA encoding of each one of the computer files was computed using software and the method is illustrated in FIG. 7. In one aspect of the invention 700 described herein, the bytes comprising each computer file 210 were represented in step 720 as a DNA sequence 230 with no homopolymers by an encoding scheme to produce an encoded file 220 that replaces each byte by five or six bases (see below) forming the DNA sequence 230. The code used in the encoding scheme was constructed to permit a straightforward encoding that is close to the optimum information capacity for a run length-limited channel (i.e., no repeated nucleotides). It will, however, be appreciated that other encoding schemes may be used.

The resulting in silico DNA sequences 230 are too long to be readily produced by standard oligonucleotide synthesis. Each of the DNA sequences 230 was therefore split in step 730 into overlapping segments 240 of length 100 bases with an overlap of 75 bases. To reduce the risk of systematic synthesis errors introduced to any particular run of bases, alternate ones of the segments were then converted in step 740 to their reverse complement, meaning that each base is “written” four times, twice in each direction. Each segment was then augmented in step 750 with an indexing information 250 that permitted determination of the computer file from which the segment 240 originated and its location within that computer file 210, plus simple error-detection information. This indexing information 250 was also encoded in step 760 as non-repeating DNA nucleotides, and appended in step 770 to the 100 information storage bases of the DNA segments 240. It will be appreciated that the division of the DNA segments 240 into lengths of 100 bases with an overlap of 75 bases is purely arbitrary. It would be possible for other lengths and overlaps to be used and this is not limiting of the invention.

In total, all of the five computer files were represented by 153335 strings of DNA. Each one of the strings of DNA comprised 117 nucleotides (encoding original digital information plus indexing information). The encoding scheme used had various features of the synthesized DNA (e.g. uniform segment lengths, absence of homopolymers) that made it obvious that the synthesized DNA did not have a natural (biological) origin. It is therefore obvious that the synthesized DNA has a deliberate design and encoded information. See, Cox, J. P. L. Long-term data storage in DNA. TRENDS Biotech. 19, 247-250 (2001).

As noted above, other encoding schemes for the DNA segments 240 could be used, for example to provide enhanced error-correcting properties. It would also be straightforward to increase the amount of indexing information in order to allow more or larger files to be encoded. It has been suggested that the Nested Primer Molecular Memory (NPMM) scheme reaches its practical maximum capacity at 16.8M unique addresses, and there appears to be no reason why the method of the disclosure could not be extended beyond this to enable the encoding of almost arbitrarily large amounts of information. See, Yamamoto, M., Kashiwamura, S., Ohuchi, A. & Furukawa, M. Large-scale DNA memory based on the nested PCR. Natural Computing 7, 335-346 (2008) and Kari, L. & Mahalingam, K. DNA computing: a research snapshot. In Atallah, M. J. & Blanton, M. (eds.) Algorithms and Theory of Computation Handbook, vol. 2. 2nd ed. pp. 31-1-31-24 (Chapman & Hall, 2009)

One extension to the coding scheme in order to avoid systematic patterns in the DNA segments 240 would be to add change the information. Two ways of doing this were tried. A first way involved the “shuffling” of information in the DNA segments 240, the information can be retrieved if one knows the pattern of shuffling. In one aspect of the disclosure different patterns of shuffles were used for different ones of the DNA segments 240.

A further way is to add a degree of randomness into the information in each one of the DNA segments 240. A series of random digits can be used for this, using modular addition of the series of random digits and the digits comprising the information encoded in the DNA segments 240. The information can easily be retrieved by modular subtraction during decoding if one knows the series of random digits used. In one aspect of the disclosure, different series of random digits were used for different ones of the DNA segments 240.

The digital information encoding in step 720 was carried out as follows. The five computer files 210 of digital information (represented in FIG. 2A) stored on a hard-disk drive were encoded using software. Each byte of each one of the five computer files 210 to be encoded in step 720 was represented as a sequence of DNA bases via base-3 digits (‘trits’ 0, 1 and 2) using a purpose-designed Huffman code listed in Table 1 (below) to produce the encoded file 220. This exemplary coding scheme is shown in outline in FIG. 2B. Each of the 256 possible bytes was represented by five or six trits. Subsequently, each one of the trits was encoded as a DNA nucleotide 230 selected from the three nucleotides different from the previous nucleotide (FIG. 2C). In other words, in the encoding scheme chosen for this aspect of the disclosure, each one of the three nucleotides was different from the previous one used to ensure no homopolymers. The resulting DNA sequence 230 was split in step 730 to DNA segments 240 of length 100 bases, as shown in FIG. 2D. Each one of the DNA segments overlapped the previous DNA segment by 75 bases, to give DNA segments of a length that was readily synthesized and to provide redundancy. Alternate ones of the DNA segments were reverse complemented.

The indexing information 250 comprised two trits for file identification (permitting 3²=9 files to be distinguished, in this implementation), 12 trits for intra-file location information (permitting 3¹²=531441 locations per file) and one ‘parity-check’ trit. The indexing information 250 was encoded in step 760 as non-repeating DNA nucleotides and was appended in step 770 to the 100 information storage bases. Each indexed DNA segment 240 had one further base added in step 780 at each end, consistent with the ‘no homopolymers’ rule, that would indicate whether the entire DNA segment 240 were reverse complemented during the ‘reading’ stage of the experiment.

In total, the five computer files 210 were represented by 153335 strings of DNA, each comprising 117 (1+100+2+12+1+1) nucleotides (encoding original digital information and indexing information).

The data-encoding component of each string in the aspect of the invention described herein can contain Shannon information at 5.07 bits per DNA base, which is close to the theoretical optimum of 5.05 bits per DNA base for base-4 channels with run length limited to one. The indexing implementation 250 permits 3¹⁴=4782969 unique data locations. Increasing the number of indexing trits (and therefore bases) used to specify file and intra-file location by just two, to 16, gives 3¹⁶=43046721 unique locations, in excess of the 16.8M that is the practical maximum for the NPMM scheme. See, Yamamoto, M., Kashiwamura, S., Ohuchi, A. & Furukawa, M. Large-scale DNA memory based on the nested PCR. Natural Computing 7, 335-346 (2008) and Kari, L. & Mahalingam, K. DNA computing: a research snapshot. In Atallah, M. J. & Blanton, M. (eds.) Algorithms and Theory of Computation Handbook, vol. 2. 2nd ed. pp. 31-1-31-24 (Chapman & Hall, 2009)

The DNA synthesis process of step 790 was also used to incorporate 33 bp adapters to each end of each one of the oligonucleotides (oligo) to facilitate sequencing on Illumina sequencing platforms:

5′ adapter:
(SEQ ID NO: 1)
ACACTCTTTCCCTACACGACGCTCTTCCGATCT
3′ adapter:
(SEQ ID NO: 2)
AGATCGGAAGAGCGGTTCAGCAGGAATGCCGAG

The 153335 DNA segment designs 240 were synthesized in step 790 in three distinct runs (with the DNA segments 240 randomly assigned to runs) using an updated version of Agilent Technologies' OLS (Oligo Library Synthesis) process described previously^{22, 23} to create approx. 1.2×10⁷ copies of each DNA segment design. Errors were seen to occur in only about one error per 500 bases and independently in different copies of the DNA segments 240. Agilent Technologies adapted the phosphoramidite chemistry developed previously²⁴ and employed inkjet printing and flow cell reactor technologies in Agilent's SurePrint in situ microarray synthesis platform. The inkjet printing within an anhydrous chamber allows the delivery of very small volumes of phosphoramidites to a confined coupling area on a 2D planar surface, resulting in the addition of hundreds of thousands of bases in parallel. Subsequent oxidation and detritylation are carried out in a flow cell reactor. Once the DNA synthesis has been completed, the oligonucleotides are then cleaved from the surface and deprotected. See, Cleary, M. A. et al. Production of complex nucleic acid libraries using highly parallel in situ oligonucleotide synthesis. Nature Methods 1, 241-248 (2004).

The adapters were added to the DNA segments to enable a plurality of copies of the DNA segments to be easily made. A DNA segment with no adapter would require additional chemical processes to “kick start” the chemistry for the synthesis of the multiple copies by adding additional groups onto the ends of the DNA segments.

Up to ˜99.8% coupling efficiency is achieved by using thousands-fold excess of phosphoramidite and activator solution. Similarly, millions-fold excess of detritylation agent drives the removal of the 5′-hydroxyl protecting group to near completion. A controlled process in the flowcell reactor significantly reduced depurination, which is the most prevalent side reaction. See, Le Proust, E. M. et al. Synthesis of high-quality libraries of long (150mer) oligonucleotides by a novel depurination controlled process. Nucl. Acids Res. 38, 2522-2540 (2010). Up to 244000 unique sequences can be synthesized in parallel and delivered as ˜1-10 picomole pools of oligos.

The three samples of lyophilized oligos were incubated in Tris buffer overnight at 4° C., periodically mixed by pipette and vortexing, and finally incubated at 50° C. for 1 hour, to a concentration of 5 ng/ml. As insolubilized material remained, the samples were left for a further 5 days at 4° C. with mixing two-four times each day. The samples were then incubated at 50° C. for 1 hour and 68° C. for 10 minutes, and purified from residual synthesis by-products on Ampure XP paramagnetic beads (Beckman Coulter) and could be stored in step 795. Sequencing and decoding is shown in FIG. 8.

The combined oligo sample was amplified in step 810 (22 PCR cycles using thermocycler conditions designed to give even A/T vs. G/C processing²⁶) using paired-end Illumina PCR primers and high-fidelity AccuPrime reagents (Invitrogen), a combination of Taq and Pyrococcus polymerases with a thermostable accessory protein. The amplified products were bead purified and quantified on an Agilent 2100 Bioanalyzer, and sequenced using AYB software in paired-end mode on an Illumina HiSeq 2000 to produce reads of 104 bases.

The digital information decoding was carried out as follows. The central 91 bases of each oligo were sequenced in step 820 from both ends and so rapid computation of full-length (117 base) oligos and removal of sequence reads inconsistent with the designs was straightforward. The sequence reads were decoded in step 830 using computer software that exactly reverses the encoding process. The sequence reads for which the parity-check trit indicated an error or that at any stage could not be unambiguously decoded or assigned to a reconstructed computer file were discarded in step 840 from further consideration.

The vast majority of locations within every decoded file were detected in multiple different sequenced DNA oligos, and simple majority voting in step 850 was used to resolve any discrepancies caused by the DNA synthesis or the sequencing errors. On completion of this procedure 860, four of the five original computer files 210 were reconstructed perfectly. The fifth computer file required manual intervention to correct two regions each of 25 bases that were not recovered from any sequenced read.

During decoding in step 850, it was noticed that one file (ultimately determined to be watsoncrick.pdf) reconstructed in silico at the level of DNA (prior to decoding, via base-3, to bytes) contained two regions of 25 bases that were not recovered from any one of the sequenced oligos. Given the overlapping segment structure of the encoding, each region indicated the failure of four consecutive segments to be synthesized or sequenced, as any one of four consecutive overlapping segments would have contained bases corresponding to this location. Inspection of the two regions indicated that the non-detected bases fell within long repeats of the following 20-base motif:

(SEQ ID NO: 3
5′ GAGCATCTGCAGATGCTCAT 3′

It was noticed that repeats of this motif have a self-reverse complementary pattern. These are shown in FIG. 4.

It is possible that long, self-reverse complementary DNA segments might not be readily sequenced using the Illumina paired-end process, owing to the possibility that the DNA segments might form internal nonlinear stem-loop structures that would inhibit the sequencing-by-synthesis reaction used in the protocol used in the method described in this document. Consequently, the in silico DNA sequence was modified to repair the repeating motif pattern and then subjected to subsequent decoding steps. No further problems were encountered, and the final decoded file matched perfectly the file watsoncrick.pdf. A code that ensured that no long self-complementary regions existed in any of the designed DNA segments could be used in future.

Example of Huffman Coding Scheme

Table 1 shows an example of the exemplary Huffman coding scheme used to convert byte values (0-255) to base-3. For highly compressed information, each byte value should appear equally frequently and the mean number of trits per byte will be (239*5+17*6)/256=5.07. The theoretical maximum number of trits per byte is log(256)/log(3)=5.05.

	TABLE 1
	Code	8-bit ASCII	Byte	Base 3 Coding
	Word No	Character	Value	(5 or 6 trits)
	0		0	22201
	1	U	85	22200
	2	™	170	22122
	3		127	22121
	4	″	253	22120
	5	4	52	22112
	6	ä	138	22111
	7	)	41	22110
	8	V	86	22102
	9	*	42	22101
	10	d	100	22100
	11	,	44	22022
	12	.	250	22020
	13	Ñ	132	22021
	14	°	161	22012
	15	b	98	22010
	16		8	22002
	17	″	34	22011
	18	[NL]	10	22001
	19	{umlaut over (1)}	149	22000
	20	W	87	21222
	21		21	21221
	22	J	74	21220
	23	$	36	21212
	24	E	69	21210
	25	±	177	21202
	26		20	21211
	27	’	213	21200
	28	£	163	21201
	29	Â	229	21121
	30	{hacek over ( )}	255	21122
	31	≈	197	21120
	32	Ö	133	21112
	33		252	21110
	34		26	21111
	35	≠	173	21101
	36	ó	151	21102
	37	R	82	21100
	38	K	75	21022
	39	%	37	21021
	40	¶	166	21011
	41	Ø	191	21020
	42	X	88	21012
	43	?	63	21010
	44	D	68	21001
	45	ñ	150	21002
	46	L	76	21000
	47		4	20222
	48	ö	154	20221
	49	Í	234	20212
	50		22	20220
	51	¢	162	20211
	52	i	105	20210
	53	f	102	20202
	54	{acute over ( )}	171	20201
	55	h	104	20200
	56	©	169	20122
	57	ƒ	196	20121
	58	-	208	20120
	59	T	84	20112
	60	Ç	130	20111
	61	{acute over (1)}	146	20102
	62	H	72	20110
	63		16	20101
	64	B	66	20100
	65		24	20022
	66	j	106	20012
	67	fl	223	20020
	68	:	58	20021
	69	â	137	20011
	70	I	73	20010
	71	e	101	20001
	72	®	168	20002
	73	μ	181	12221
	74	Ø	175	12222
	75	°	251	20000
	76	(	40	12220
	77	å	140	12212
	78		17	12211
	79	S	83	12210
	80		254	12202
	81		240	12201
	82	÷	214	12200
	83	5	53	12122
	84		202	12112
	85		25	12121
	86		18	12120
	87	{tilde over ( )}	247	12111
	88	Æ	174	12110
	89	p	112	12102
	90	Y	89	12101
	91	“	210	12100
	92	Ÿ	217	12012
	93	-	248	12020
	94	¬	194	12021
	95	∂	182	12022
	96	P	80	12011
	97	O	79	12002
	98	√	195	12010
	99		12	12001
	100	—	209	12000
	101	•	165	11222
	102	1	245	11221
	103		2	11220
	104	Q	81	11212
	105	&	38	11211
	106	ç	141	11202
	107	”	211	11210
	108	Ô	239	11200
	109	−	95	11201
	110	+	43	11122
	111	‡	224	11121
	112	À	203	11112
	113	ë	145	11120
	114	{grave over (1)}	147	11110
	115		19	11111
	116	2	50	11101
	117	à	136	11102
	118	k	107	11100
	119	Ü	134	11022
	120	m	109	11021
	121	ô	153	11020
	122	{circumflex over (1)}	148	11002
	123	Õ	205	11010
	124	‘	212	11011
	125	6	54	11012
	126	Ò	241	11000
	127	ú	156	11001
	128	s	115	10222
	129	t	116	10221
	130	N	78	10220
	131	C	67	10211
	132	F	70	10212
	133	≤	178	10210
	134	ü	159	10202
	135	é	142	10201
	136	\	92	10200
	137	0	48	10122
	138	Z	90	10120
	139	/	218	10121
	140	~	126	10112
	141	′	39	10111
	142	€	219	10102
	143	β	167	10110
	144	r	114	10101
	145	{umlaut over ( )}	172	10022
	146		14	10100
	147	x	120	10020
	148	ã	139	10021
	149	†	160	10012
	150	!	33	10011
	151	≥	179	10010
	152	u	117	10002
	153	.	225	10001
	154	Å	129	10000
	155	Σ	183	02222
	156	Ê	230	02220
	157	#	35	02221
	158	]	93	02210
	159		6	02211
	160		32	02212
	161	8	56	02201
	162	û	158	02202
	163	π	185	02121
	164	/	47	02122
	165	è	143	02200
	166	{	123	02111
	167	Ã	204	02120
	168	Ú	242	02112
	169	o	111	02110
	170	g	103	02102
	171	l	108	02101
	172	[TAB]	9	02100
	173	A	65	02022
	174	̆	249	02020
	175	[CR]	13	02021
	176	¥	180	02012
	177	,	226	02001
	178	ê	144	02002
	179		15	02010
	180	9	57	02011
	181	Ä	128	02000
	182	á	135	01220
	183	Û	243	01221
	184	æ	190	01222
	185	œ	207	01212
	186	M	77	01211
	187	-	45	01210
	188	[	91	01202
	189	¿	192	01201
	190	∫	186	01122
	191	ÿ	216	01200
	192	a	97	01112
	193	v	118	01120
	194	{circumflex over ( )}	246	01121
	195	⋄	215	01111
	196	3	51	01102
	197		206	01110
	198	Π	184	01100
	199	”	227	01101
	200	È	233	01022
	201	Ì	237	01021
	202	°	188	01020
	203	q	113	01012
	204	1	49	01011
	205	. . .	201	01010
	206	õ	155	01002
	207	fi	222	01000
	208	Á	231	01001
	209		5	00222
	210		27	00221
	211	É	131	00212
	212	§	164	00220
	213		3	00211
	214	.	46	00210
	215	w	119	00201
	216		28	00202
	217	∞	176	00200
	218		23	00122
	219	@	64	00121
	220	ù	157	00120
	221	ª	187	00112
	222	Ù	244	00110
	223	Ó	238	00111
	224	{grave over ( )}	96	00102
	225	Î	235	00101
	226	<	60	00022
	227		1	00100
	228	n	110	00021
	229		200	00011
	230		221	00020
	231	c	99	00012
	232		31	00010
	233	Δ	198	00002
	234	i	193	00001
	235	}	125	00000
	236	|	124	22222
	237	ò	152	22222
	238	z	122	22222
	239	G	71	222212
	240	{circumflex over ( )}	94	222211
	241		220	222210
	242		29	222202
	243		199	222201
	244	=	61	222200
	245		11	222122
	246	‰	228	222121
	247	>	62	222120
	248	7	55	222112
	249	y	121	222111
	250		7	222110
	251	-	30	222102
	252	Ë	232	222101
	253	Ω	189	222100
	254	;	59	222021
	255	Ï	236	222022

Encoding of the File

The arbitrary computer file 210 is represented as a string S_Ø of bytes (often interpreted as a number between Ø and 2⁸−1, i.e. a value in the set {0 . . . 255}). The string S_Ø is encoded using the Huffman code and converting to base-3. This generates a string S₁ of characters as the trit {0, 1, 2}.

Let us now write len( ) for the function that computes the length (in characters) of the string S₁, and define n=len(S₁). Represent n in base-3 and prepend 0s to generate a string S₂ of trits such that len(S₂)=20. Form the string concatenation S₄=S₁. S₃. S₂, where S₃ is a string of at most 24 zeros is chosen so that len(S₄) is an integer multiple of 25.

S₄ is converted to the DNA string S₅ of characters in {A, C, G, T} with no repeated nucleotides (nt) using the scheme illustrated in the table below. The first trit of S4 is coded using the ‘A’ row of the table. For each subsequent trit, characters are taken from the row defined by the previous character conversion.

	previous	next trit to encode
	nt written	Ø	1	2
	A	C	G	T
	C	G	T	A
	G	T	A	C
	T	A	C	G

Table: Base-3 to DNA encoding ensuring no repeated nucleotides.

For each trit t to be encoded, select the row labeled with the previous nucleotide used and the column labeled t and encode using the nt in the corresponding table cell.

Define N=len (S₅), and let ID be a 2-trit string identifying the original file and unique within a given experiment (permitting mixing of DNA form different files S_Ø in one experiment. Split S₅ into the overlapping DNA segments 240 of length 100 nt, each of the DNA segments 240 being offset from the previous one of the DNA segments 240 by 25 nt. This means there will be ((N/25)−3) DNA segments 240, conveniently indexed i=Ø . . . (N/25)−4. The DNA segment i is denoted F_i and contains (DNA) characters 25i . . . 25_i+99 of S₅.

Each DNA segment F_i is further processed as follows:

If i is odd, reverse complement the DNA segment F_i.

Let i3 be the base-3 representation of i, appending enough leading zeros so that len(i3)=12. Compute P as the sum (mod 3) of the odd-positioned trits in ID and i3, i.e. ID₁+i3₁+i3₃+i3₅+i3₇+i3₉+i3₁₁. (P acts a ‘parity trit’—analogous to a parity bit—to check for errors in the encoded information about ID and 1.)

Form the indexing information 250 string IX=ID·i2·P (comprising 2+12+1=15 trits). Append the DNA-encoded (step 760) version of IX to F_i using the same strategy as shown in the above table, starting with the code table row defined by the last character of F_i to give indexed segment F′_i.

Form F″_i by prepending A or T and appending C or G to F′_i—choosing between A and T, and between C and G, randomly if possible but always such that there are no repeated nucleotides. This ensures that one can distinguish a DNA segment 240 that has been reverse complemented (step 240) during DNA sequencing from one that has not. The former will start with G|C and the end with T|A; the latter will start A|T and end C|G.

The segments F″_I are synthesized in step 790 as actual DNA oligonucleotides and stored in step 790 and may be supplied for sequencing in step 820.

Decoding

Decoding is simply reverse of the encoding in step 720, starting with the sequenced DNA segments 240 F″_I of length 117 nucleotides. Reverse complementation during the DNA sequencing procedure (e.g. during PCR reactions) can be identified for subsequent reversal by observing whether fragments start with A|T and end with C|G, or start with G|C and end T|A. With these two ‘orientation’ nucleotides removed, the remaining 115 nucleotide of each DNA segment 240 can be split into the first 100 ‘message’ nucleotides and the remaining fifteen ‘indexing information 250’ nucleotides. The indexing information nucleotide 250 can be decoded to determine the file identifier ID and the position index i3 and hence i, and errors may be detected by testing the parity trit P. Position indexing information 250 permits the reconstruction of the DNA-encoded file 230, which can then be converted to base-3 using the reverse of the encoding table above and then to the original bytes using the given Huffman code.

Discussion on Data Storage

The DNA storage has different properties from the traditional tape-based storage or disk-based storage. The ˜750 kB of information in this example was synthesized in 10 pmol of DNA, giving an information storage density of approximately one Terabyte/gram. The DNA storage requires no power and remains (potentially) viable for thousands of years even by conservative estimates.

DNA Archives can also be copied in a massively parallel manner by the application of PCR to the primer pairs, followed by aliquoting (splitting) the resulting DNA solution. In the practical demonstration of this technology in the sequencing process this procedure was done multiple times, but this could also be used explicitly for copying at large scale the information and then physically sending this information to two or more locations. The storage of the information in multiple locations would provide further robustness to any archiving scheme, and might be useful in itself for very large scale data copying operations between facilities.

The decoding bandwidth in this example was at 3.4 bits/second, compared to disk (approximately one Terabit/second) or tape (140 Megabit/second), and latency is also high (˜20 days in this example). It is expected that future sequencing technologies are likely to improve both these factors.

Modeling the full cost of archiving using either the DNA-storage of this disclosure or the tape storage shows that the key parameters are the frequency and fixed costs of transitioning between tape storage technologies and media. FIG. 3 shows the timescales for which DNA-storage is cost-effective. The upper bold curve indicates the break-even time (x-axis) beyond which the DNA storage as taught in this disclosure is less expensive than tape. This assumes that the tape archive has to be read and re-written every 3 years (f=⅓), and depends on the relative cost of DNA-storage synthesis and tape transfer fixed costs (y-axis). The lower bold curve corresponds to tape transfers every 5 years. The region below the lower bold curve indicates cases for which the DNA storage is cost-effective when transfers occur more frequently than every 5 years; between the two bold curves, the DNA storage is cost-effective when transfers occur from 3- to 5-yearly; and above the upper bold curve tape is less expensive when transfers occur less frequently than every 3 years. The dotted horizontal lines indicate ranges of relative costs of DNA synthesis to tape transfer of 125-500 (current values) and 12.5-50 (achieved if DNA synthesis costs reduce by an order of magnitude). Dotted vertical lines indicate corresponding break-even times. Note the logarithmic scales on all axes.

One issue for long-term digital archiving is how DNA-based storage scales to larger applications. The number of bases of the synthesized DNA needed to encode the information grows linearly with the amount of information to be stored. One must also consider the indexing information required to reconstruct full-length files from the short DNA segments 240. The indexing information 250 grows only as the logarithm of the number of DNA segments 240 to be indexed. The total amount of synthesized DNA required grows sub-linearly. Increasingly large parts of each ones of the DNA segments 240 are needed for indexing however and, although it is reasonable to expect synthesis of longer strings to be possible in future, the behavior of the scheme was modeled under the conservative constraint of a constant 114 nucleotides available for both the data and the indexing information 250.

As the total amount of information increases, the encoding efficiency decreases only slowly (FIG. 5). In the experiment (megabyte scale) the encoding scheme is 88% efficient. FIG. 5 indicates that efficiency remains >70% for data storage on petabyte (PB, 10¹⁵ bytes) scales and >65% on exabyte (EB, 10¹⁸ bytes) scales, and that DNA-based storage remains feasible on scales many orders of magnitude greater than current global data volumes. FIG. 5 also shows that costs (per unit information stored) rise only slowly as data volumes increase over many orders of magnitude. Efficiency and costs scale even more favourably if we consider the lengths of the synthesized DNA segments 240 available using the latest technology. As the amount of information stored increases, decoding requires more oligos to be sequenced. A fixed decoding expenditure per byte of encoded information would mean that each base is read fewer times and so is more likely to suffer decoding error. Extension of the scaling analysis to model the influence of reduced sequencing coverage on the per-decoded-base error rate revealed that error rates increase only very slowly as the amount of information encoded increases to a global data scale and beyond. This also suggests that the mean sequencing coverage of 1,308 times was considerably in excess of that needed for reliable decoding. This was confirmed by subsampling from the 79.6×310⁶ read-pairs to simulate experiments with lower coverage.

FIG. 5 indicates that reducing the coverage by a factor of 10 (or even more) would have led to unaltered decoding characteristics, which further illustrates the robustness of the DNA-storage method. Applications of the DNA-based storage might already be economically viable for long-horizon archives with a low expectation of extensive access, such as government and historical records. An example in a scientific context is CERN's CASTOR system, which stores a total of 80 PB of Large Hadron Collider data and grows at 15 PB yr⁻¹. Only 10% is maintained on disk, and CASTOR migrates regularly between magnetic tape formats. Archives of older data are needed for potential future verification of events, but access rates decrease considerably 2-3 years after collection. Further examples are found in astronomy, medicine and interplanetary exploration.

FIG. 5 shows the encoding efficiency and costs change as the amount of stored information increases. The x-axis (logarithmic scale) represents the total amount of information to be encoded. Common data scales are indicated, including the three zettabyte (3 ZB, 3×10²¹ bytes) global data estimate. The y-axis scale to left indicates encoding efficiency, measured as the proportion of synthesized bases available for data encoding. The y-axis scale to right indicate the corresponding effect on encoding costs, both at current synthesis cost levels (solid line) and in the case of a two-order-of magnitude reduction (dashed line).

FIG. 6 shows per-recovered-base error rate (y-axis) as a function of sequencing coverage, represented by the percentage of the original 79.6×10⁶ read-pairs sampled (x axis; logarithmic scale). One curve represents the four files recovered without human intervention: the error is zero when ≥2% of the original reads are used. Another curve is obtained by Monte Carlo simulation from our theoretical error rate model. The final curve represents the file (watsoncrick.pdf) that required manual correction: the minimum possible error rate is 0.0036%. The boxed area is shown magnified in the inset.

In addition to data storage, the teachings of this disclosure can also be used for steganography.

Claims

1. A method of storing information using nucleotides comprising:

converting an item of information comprising bytes into at least one DNA segment data;

synthesizing the at least one DNA segment data into at least one DNA segment, sequencing the at least one synthesized DNA segment; and

decoding the at least one sequenced DNA segment into the bytes of the item of information.

2. The method of claim 1, wherein the decoding further comprises decoding the at least one sequenced DNA segment into bit sequences, assembling the bit sequences into the bytes, and converting the bytes into a format of the item of information.

3. The method of claim 1, wherein the at least one DNA segment data comprises indexing information.

4. The method of claim 3, wherein the indexing information is configured to identify a source of the item of information.

5. The method of claim 3, wherein the indexing information is configured to identify the location of the at least one DNA segment data in the source of the item of information.

6. The method of claim 1, wherein the at least one DNA segment data comprises sequencing adapters.

7. The method of claim 1, wherein bytes are stored in a digital file.

8. The method of claim 7, wherein the digital file is stored on a hard disk.

9. The method of claim 1, wherein the at least one DNA segment data is at least 100 bases in length.

10. The method of claim 1, wherein the item of information comprises at least 15,646 bytes.

11. The method of claim 1, wherein the item of information comprises at least one of text, images, music, and video.

12. A method of retrieving an item of information from at least one synthesized DNA segment storing bytes of the item of information comprising:

sequencing the at least one synthesized DNA segment to generate DNA segment data; and

converting the DNA segment data into the bytes of the item of information.

13. The method of claim 12, wherein the converting comprises converting the DNA segment data into encoded ones of the bytes, and converting the encoded ones of the bytes into the item of information.

14. The method of claim 12, wherein the at least one synthesized DNA segment comprises indexing information.

15. The method of claim 14, wherein the indexing information is configured to identify a source of the item of information.

16. The method of claim 14, wherein the indexing information is configured to identify the location of the at least one synthesized DNA segment in the source of the item of information.

17. The method of claim 14, wherein the at least one DNA segment comprises sequencing adapters.

18. The method of claim 12, wherein the bytes are stored in a digital file.

19. The method of claim 18, wherein the digital file is stored on a hard disk.

20. The method of claim 12, wherein the at least one DNA segment is at least 100 bases in length.

21. The method of claim 12, wherein the item of information comprises at least 15,646 bytes.

22. The method of claim 12, wherein the item of information comprises at least one of text, images, music, and video.