DNAmoreDB - A Database of Deoxyribozymes

Published on 2011 in Nucleic Acids Res. volume 39 issue 1.

PubMed ID: 20739352

DOI:10.1093/nar/gkq753

Abstract:

A covalently branched nucleic acid can be synthesized by joining the 2'-hydroxyl of the branch-site ribonucleotide of a DNA or RNA strand to the activated 5'-phosphorus of a separate DNA or RNA strand. We have previously used deoxyribozymes to synthesize several types of branched nucleic acids for experiments in biotechnology and biochemistry. Here, we report in vitro selection experiments to identify improved deoxyribozymes for synthesis of branched DNA and RNA. Each of the new deoxyribozymes requires Mn²(+) as a cofactor, rather than Mg²(+) as used by our previous branch-forming deoxyribozymes, and each has an initially random region of 40 rather than 22 or fewer combined nucleotides. The deoxyribozymes all function by forming a three-helix-junction (3HJ) complex with their two oligonucleotide substrates. For synthesis of branched DNA, the best new deoxyribozyme, 8LV13, has k(obs) on the order of 0.1 min⁻¹, which is about two orders of magnitude faster than our previously identified 15HA9 deoxyribozyme. 8LV13 also functions at closer-to-neutral pH than does 15HA9 (pH 7.5 versus 9.0) and has useful tolerance for many DNA substrate sequences. For synthesis of branched RNA, two new deoxyribozymes, 8LX1 and 8LX6, were identified with broad sequence tolerances and substantial activity at pH 7.5, versus pH 9.0 for many of our previous deoxyribozymes that form branched RNA. These experiments provide new, and in key aspects improved, practical catalysts for preparation of synthetic branched DNA and RNA.



DNAzymes linked to this article:

Name Isolated sequence Length Reaction
8LX12 CCCCGAGGTGTGGACATAGCGGGCTGGTGTGGCGCGCAGTGAGCCTAGTG      50 RNA ligation
8LX13 CATCGGTGTAGCGATGCACGGGCAAAGATACATTCGCAGTGAGGGTGCGG      50 RNA ligation
8LX14 CCACGTGCGAGGTTAGACGTCAGTGGCTGGTGTTCGCAGTGAGCCTATTG      50 RNA ligation
8LX15 CCGACGCGTCCAGGAGGCAAGGGCTATATGCACCGCAGTGAGGGCTCGG      49 RNA ligation
8LX16 CACGAGGTAGGGAGGGGCACACTGCTATGCTCAGCGCAGTGAGAGTATGC      50 RNA ligation
8LX17 CACATGTCTAGCGGCGTGCGGGAGAAGTGCAAGCGCTGTGAGGGTGTG      48 RNA ligation
8LX18 CCAAGGCAGAGCGTAGCCAGACAGCCGGGAGGTTCGCAGTGAGTGAATGG      50 RNA ligation
8LX21 GTAGCCACATTAGTGCGCTGCAACTGCTATGCAACGCAGTGAGAGGGTGC      50 RNA ligation
8LV1 GCCGGTGGAAGGTTCTCTGCCAAAAGTGGTCGTCCGCAGTGAGACTTTAG      50 DNA ligation
8LV3 CCATGGACGTATGGTTTGGTATGCCGAACGCGGACGCAGGTGAGGCAGGGC      51 DNA ligation
8LV7 CAGGGTGAGAGGACCGTAAGTGTTAGTTGACACACGCAGTGAGCTTCGAT      50 DNA ligation
8LV9 GTCGGGCGTGTGGTTGCAAAGGACGTCTGGAGTGCGCAGTGAGACCGCCA      50 DNA ligation
8LV11 CCTAGGGAATGCGGAGGCTTGAGGTGTGTCTTGGCGCAGGAGCGTAACC      49 DNA ligation
8LV12 CAGTAGACGCCGCATAGGGCACTGTTTACTGCTCCGAAGTGAGAGGAGGG      50 DNA ligation
8LV13 CGAGAGCGTGAATGTTGGTTGAGACACAGTGTACGCAGTGAGAGGGAAC      49 DNA ligation
8LV15 CAGGGAGAGAGGCGTACGCGGAGATATACGCGGTCGCAGTGAGATTCGAT      50 DNA ligation
8LV17 CACGAGTAAGTGCTCGATTGGGTTACACTGAGGCCGCAGTGAGCAAGGAG      50 DNA ligation
8LV21 CAGGGTGAGAGGACGAAAGCATGGGGTTAGCTGCGCAGTGAGATTCGAT      49 DNA ligation
8LV22 CAGGGTGAAGTGGAAGCTACATTGTATGATTGCGCGCAGTGAGTTTCGAG      50 DNA ligation
8LX8 CCGACGAGGTGAGGGGCATGCGGTACACGCGCATATAGTGAGGGGTCCA      49 RNA ligation
8LX3 CCCACCGGTAGGGCTACGGGCAAGGTCAACATGCCGCAAGTGAGGGGTCGA      51 RNA ligation
8LX5 CAGGCCATGGATTATTGGAGGAATGGGCCGTCAGCGCGTGAGGTGTGGA      49 RNA ligation
8LV2 ATGACTGTAGGAGCGGACGCTAAGCCTTTAGACTCGCAGTGAGGTTCCG      49 DNA ligation
8LX1 GACGCCACCGAAGTCGCCATCTCCCGTAGGTGAAGGGCGTGAGGGTTCCA      50 RNA ligation
8LX6 CAGTGCAGGGCGTGAGGGCTCCATCCCCAGTGCAGGGCGTGAGGGCTCGG      50 RNA ligation
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