Rewritable digital data storage in live cells via engineered control of recombination directionality

The use of synthetic biological systems in research, healthcare, and manufacturing often requires autonomous history-dependent behavior and therefore some form of engineered biological memory. For example, the study or reprogramming of aging, cancer, or development would benefit from genetically encoded counters capable of recording up to several hundred cell division or differentiation events. Although genetic material itself provides a natural data storage medium, tools that allow researchers to reliably and reversibly write information to DNA in vivo are lacking. Here, we demonstrate a rewriteable recombinase addressable data (RAD) module that reliably stores digital information within a chromosome. RAD modules use serine integrase and excisionase functions adapted from bacteriophage to invert and restore specific DNA sequences. Our core RAD memory element is capable of passive information storage in the absence of heterologous gene expression for over 100 cell divisions and can be switched repeatedly without performance degradation, as is required to support combinatorial data storage. We also demonstrate how programmed stochasticity in RAD system performance arising from bidirectional recombination can be achieved and tuned by varying the synthesis and degradation rates of recombinase proteins. The serine recombinase functions used here do not require cell-specific cofactors and should be useful in extending computing and control methods to the study and engineering of many biological systems.

[1]  Polar mutations in lac, gal and phage lambda consist of a few IS-DNA sequences inserted with either orientation. , 1972, Molecular & general genetics : MGG.

[2]  S. Adhya,et al.  Formation of lambda lysogens by IS2 recombination: gal operon--lambda pR promoter fusions. , 1979, Virology.

[3]  M. Gellert,et al.  DNA gyrase action involves the introduction of transient double-strand breaks into DNA. , 1980, Proceedings of the National Academy of Sciences of the United States of America.

[4]  H. Nash Integration and Excision of Bacteriophage λ: The Mechanism of Conservative Site Specific Recombination , 1981 .

[5]  N. Lee,et al.  Mechanism of araC autoregulation and the domains of two overlapping promoters, Pc and PBAD, in the L-arabinose regulatory region of Escherichia coli. , 1981, Proceedings of the National Academy of Sciences of the United States of America.

[6]  J. Sulston,et al.  The embryonic cell lineage of the nematode Caenorhabditis elegans. , 1983, Developmental biology.

[7]  H. Nash,et al.  Knotting of DNA caused by a genetic rearrangement. Evidence for a nucleosome-like structure in site-specific recombination of bacteriophage lambda. , 1983, Journal of molecular biology.

[8]  M. Radman,et al.  A system for detection of genetic and epigenetic alterations in Escherichia coli induced by DNA-damaging agents. , 1985, Journal of molecular biology.

[9]  W Szybalski,et al.  Control of cloned gene expression by promoter inversion in vivo: construction of the heat-pulse-activated att-nutL-p-att-N module. , 1985, Gene.

[10]  M. Ptashne A Genetic Switch , 1986 .

[11]  B. Sauer Site-specific recombination: developments and applications. , 1994, Current opinion in biotechnology.

[12]  H. Bujard,et al.  Independent and tight regulation of transcriptional units in Escherichia coli via the LacR/O, the TetR/O and AraC/I1-I2 regulatory elements. , 1997, Nucleic acids research.

[13]  R. Wade,et al.  Comparative kinetic analysis of FLP and cre recombinases: mathematical models for DNA binding and recombination. , 1998, Journal of molecular biology.

[14]  L. Poulsen,et al.  New Unstable Variants of Green Fluorescent Protein for Studies of Transient Gene Expression in Bacteria , 1998, Applied and Environmental Microbiology.

[15]  R. Hendrix,et al.  Evolutionary relationships among diverse bacteriophages and prophages: all the world's a phage. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[16]  J. Collins,et al.  Construction of a genetic toggle switch in Escherichia coli , 2000, Nature.

[17]  Chris Hanson,et al.  Amorphous computing , 2000, Commun. ACM.

[18]  W. Jacobs,et al.  Genome organization and characterization of mycobacteriophage Bxb1 , 2000, Molecular microbiology.

[19]  C Bancroft,et al.  Long-Term Storage of Information in DNA , 2001, Science.

[20]  J. Lewis,et al.  Control of directionality in integrase-mediated recombination: examination of recombination directionality factors (RDFs) including Xis and Cox proteins. , 2001, Nucleic acids research.

[21]  Frank Buchholz,et al.  Alteration of Cre recombinase site specificity by substrate-linked protein evolution , 2001, Nature Biotechnology.

[22]  Margaret C. M. Smith,et al.  Diversity in the serine recombinases , 2002, Molecular microbiology.

[23]  Shruti Jain,et al.  Mycobacteriophage Bxb1 integrates into the Mycobacterium smegmatis groEL1 gene , 2003, Molecular microbiology.

[24]  G. Hatfull,et al.  The orientation of mycobacteriophage Bxb1 integration is solely dependent on the central dinucleotide of attP and attB. , 2003, Molecular cell.

[25]  C. Branda,et al.  Talking about a revolution: The impact of site-specific recombinases on genetic analyses in mice. , 2004, Developmental cell.

[26]  Michele P Calos,et al.  Phage integrases: biology and applications. , 2004, Journal of molecular biology.

[27]  M. Malamy,et al.  Polar mutations in lac, gal and phage λ consist of a few IS-DNA sequences inserted with either orientation , 2004, Molecular and General Genetics MGG.

[28]  Graham F Hatfull,et al.  Synapsis in phage Bxb1 integration: selection mechanism for the correct pair of recombination sites. , 2005, Journal of molecular biology.

[29]  Uriel Feige,et al.  Genomic Variability within an Organism Exposes Its Cell Lineage Tree , 2005, PLoS Comput. Biol..

[30]  G. Hatfull,et al.  Control of Phage Bxb1 Excision by a Novel Recombination Directionality Factor , 2006, PLoS biology.

[31]  N. Grindley,et al.  Mechanisms of site-specific recombination. , 2003, Annual review of biochemistry.

[32]  Jason J. Hoyt,et al.  A diversity of serine phage integrases mediate site-specific recombination in mammalian cells , 2006, Molecular Genetics and Genomics.

[33]  D. Baker,et al.  Computational redesign of endonuclease DNA binding and cleavage specificity , 2006, Nature.

[34]  Timothy S. Ham,et al.  A tightly regulated inducible expression system utilizing the fim inversion recombination switch. , 2006, Biotechnology and bioengineering.

[35]  David A. Drubin,et al.  Rational design of memory in eukaryotic cells. , 2007, Genes & development.

[36]  G. Hatfull,et al.  Two-step site selection for serine-integrase-mediated excision: DNA-directed integrase conformation and central dinucleotide proofreading , 2008, Proceedings of the National Academy of Sciences.

[37]  D. Endy,et al.  Refinement and standardization of synthetic biological parts and devices , 2008, Nature Biotechnology.

[38]  Timothy S. Ham,et al.  Design and Construction of a Double Inversion Recombination Switch for Heritable Sequential Genetic Memory , 2008, PloS one.

[39]  B. Kennedy,et al.  Replicative aging in yeast: the means to the end. , 2008, Annual review of cell and developmental biology.

[40]  G. Church,et al.  Synthetic Gene Networks That Count , 2009, Science.

[41]  Russell M Gordley,et al.  Structure-guided reprogramming of serine recombinase DNA sequence specificity , 2010, Proceedings of the National Academy of Sciences.

[42]  Pamela A. Silver,et al.  Making Cellular Memories , 2010, Cell.

[43]  The Bxb1 gp47 recombination directionality factor is required not only for prophage excision, but also for phage DNA replication. , 2012, Gene.

[44]  Barry Kelly,et al.  Memories , 1997, The Ulster medical journal.