DNAmoreDB - A Database of Deoxyribozymes

Published on 2003 in J. Am. Chem. Soc. volume 125 issue 25.

PubMed ID: 12812493

DOI:10.1021/ja035208+

Abstract:

We report a group of new DNA enzymes that possess a synchronized RNA-cleavage/fluorescence-signaling ability and exhibit wide-ranging metal-ion and pH dependences. These DNA catalysts were derived from a random-sequence DNA pool in a two-stage process:  (1) establishment of a catalytic DNA population through repetitive rounds of in vitro selection at pH 4.0, and (2) sequence-diversification and catalytic-activity optimization through five parallel paths of in vitro evolution conducted at pH 3.0, 4.0, 5.0, 6.0, and 7.0, respectively. The deoxyribozymes were evolved to cleave the phosphodiester bond of a single ribonucleotide embedded in DNA and flanked immediately by two deoxyribonucleotides modified with a fluorophore and a quencher, respectivelya setting that synchronizes catalysis with fluorescence signaling. The most dominant catalyst from each pool was examined for metal-ion specificity, catalytic efficiency, pH dependence, and fluorescence-signaling capability. Individual catalysts have different metal-ion requirements and can generate as much as a 12-fold fluorescence enhancement upon RNA cleavage. Most of the DNA enzymes have a pH optimum coinciding with the selection pH and exhibit a rate constant approximating 1 min-1 under optimal reaction conditions. The demonstration of DNA enzymes that are functional under extremely high acidity (such as pH 3 and 4) indicates that DNA has the ability to perform efficient catalysis even under harsh reaction conditions. The isolation of many new signaling DNA enzymes with broad pH optima and metal-ion specificities should facilitate the development of diverse deoxyribozyme-based biosensors.



DNAzymes linked to this article:

Name Isolated sequence Length Reaction
pH3DZ1 AGTTGGCGAAGATCGGTAGTACGAGGAAATAGGGGGTGAGTGGTGTAGGCTTGAAGGTGCCACGTCGAG      69 RNA cleavage
pH3DZ2 TGGTATAAGGGAGGCTAGAGAGGGTGTGGAAGAGCGGACAAAGGGTGGATTGTTAGGTATATTATTTG      68 RNA cleavage
pH3DZ4 TTGGGAGGAGGAGACTGATATTTGGTCCTTTTTAGCCGGTGCCGTTTTAGGTTGTGGGGTGGGTGGTA      68 RNA cleavage
pH3DZ5 TGGTGGAGGAAAGAAATAGCTTCGTCTTCCAtCGTGATGAGTGGGGAGGGAAAATGAGTAGGGGTCTGTA      70 RNA cleavage
pH3DZ6 CTAGAGTAGCTTTGTGCTGTAAGGCTAGTTTTGGTAAAGATAGGGCTCTATGGTACCGGTTTGGCTAT      68 RNA cleavage
pH3DZ7 GTGGTGTGTGATAGGGAGCCAACGAGTGACGAGATAGGTAGCCACGGTTAGGATTGGAAGGATTGTAC      68 RNA cleavage
pH3DZ8 GGCAAAAGGAAACGCAGTTTGGGTGGAAACAGGTGGAAGGGTGTCACGAGTTAGTGGAGTCGACCCCGTG      70 RNA cleavage
pH3DZ9 GGAAGTTGGAGGGTTCGTATTGCTACGTTGCCTTAGAGAGGTTGTGGAAGAGCGGCACATCATTGTTGGG      70 RNA cleavage
pH3DZ11 GAAGTGGGGGTCGGGGGAAGGGAGGCACGCGTAAAGGTAGGTGTGAGGGCGGGTGAGAGTTGGACAAT      68 RNA cleavage
pH4DZ1 TGTATGCTAGCTCGGGGAGAAACATCTTTGCGGGATAAGGCCGCCGATAGAGCGGAAGCGACTTGGTTGT      70 RNA cleavage
pH4DZ2 TGAATAGGGTCCTAGGCATAAATTACGAAAACGGCTTTAATCTTTTAGTGGAAAGGTCCGATAACGAGTG      70 RNA cleavage
pH4DZ3 TGGGTAAAAGGAAAAGATGGCGGAGCGAGTTGATGGCGTGATTAGGAGGAGGACTTAAAGGTGGTGGTTG      70 RNA cleavage
pH4DZ4 TGTACGGTAGGGAGGGTGCAAGGTGAATCGGATTAGTTTACGGAAGAGTGTGATTGAGTCCGATAGCT      68 RNA cleavage
pH4DZ5 CAGTAGGGCAATTTGGTTGGGTTTAATGTGATACGAAGAACCATATTTGCGGAGTTCTAGCCGGCCGAT      69 RNA cleavage
pH4DZ6 GAGGTGGGGGTCGGGGGAAGGGAGGCACGCGTAAAGGTAGGTGTGAGGGCGCATGAGGGAATTGGACGAT      70 RNA cleavage
pH4DZ7 GAGGTGGGGGTCGGGGGAAGGGAGGCACGCGTAAAGGTAGGTGTGAGGGCGCATGAGGGAATTGGACGAT      70 RNA cleavage
pH4DZ8 GGGAGTTGGAGGATCCGTACTGTTACGTTGTCTTAGAGAGGGTGTGGAAGAGCGGCACATTACTGTTGGG      70 RNA cleavage
pH5DZ1 TGAATAGGGTCTCGGGCATAAATTACGGAAACGGTTTTAATTTTCTAGTGGAAAGGTCCGATAACGAGGT      70 RNA cleavage
pH5DZ2 CTGTGGGAGGCTAAGAGAGGTTGTGGAAGAGCGGTAAACTAATATCAGTGTTATGACAGTGGTGATTGC      69 RNA cleavage
pH5DZ3 CGGAGTAGGGGGGGAAGGTTGGGTAAAGGAATTTTTATGCTGTTAGCAGGTCTAACGGCGGTGCAGGGG      69 RNA cleavage
pH5DZ4 GGCAGAGGAGGTGGGCGATGAGTAGTAGGGGGGGAAGGTTGGGTTCAGTTTAGTTGCGGTTGGTATAC      68 RNA cleavage
pH5DZ5 GAAGTGGGGGTCGGGGGAAGGGAGGCACGTGTAAAGGTAGGTGTGAGGGTGTATGGAAGAGTTGGACAAC      70 RNA cleavage
pH5DZ6 TCGTAGGGGGGGAAGGTTGGGTGGAAGGAGTTAGTAAGACGATTGTACTAGCGGTGAGGGCAGGGTGATG      70 RNA cleavage
pH6DZ1 ATCGGACAAGGGAGGCACTGGAGGTTGAGGTAGTGAGCGTTGGTTAACGCCGGACAAAGGGAAGCATGGT      70 RNA cleavage
pH6DZ2 TCGTAAGGGGGGAAGGTTGGGTGGAGGGAGTCAGTAAGACGATTGTACTAGTGGTGAGGGCAGGATGATG      70 RNA cleavage
pH7DZ1 GTGGAACCCATGATGAGCCGAGTTGGGGTGTGTCTCTCGTATATGGCGGAAGTGGGACAATAGTTGAGT      69 RNA cleavage
pH7DZ2 GTCGGACAAGGGAGGCACTGGGGATTGAGGTAGTGAGCGTTGGTTAACGCCGGACAAAGGGGAGCATGGT      70 RNA cleavage
pH7DZ3 TAACTCATTATGAGGTGACGGAGTACCGGAAGAGGGAGAGATGAAGGGATGGGCGGTTGTGCTGTGTTGG      70 RNA cleavage
pH7DZ4 CCCATGATGAGAGTGCTACTCGGAAGAGGGACATGATAGGGGAGGGATTAGATGGTGTTTATTGTGTAC      69 RNA cleavage
pH3DZ3 GAGGTGAACAAGCGGCTGAGCTTTTGGAAGAAGGCATAAGGAAAAGGTTAGATAAAGGTGCTGGTGCGAT      70 RNA cleavage
pH3DZ10 TGAATGAAACCTCGGGCATAAATTACGGAAACGGCTTTAATTTTTTAGTGGAAAGATCCGATAACGAGGT      70 RNA cleavage
pH6DZ3 GAGTGGGGGTCGGGGGAAGGGAGGCATGCGTAAAGGTAGGTGCGAGGGTGCATGAAAGGGTTGGGCAAC      69 RNA cleavage
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