DNAmoreDB - A Database of Deoxyribozymes

Published on 2012 in ACS Comb Sci volume 14 issue 12.

PubMed ID: 23088677

DOI:10.1021/co300111f

Abstract:

Functional nucleic acids are DNA and RNA aptamers that bind targets, or they are deoxyribozymes and ribozymes that have catalytic activity. These functional DNA and RNA sequences can be identified from random-sequence pools by in vitro selection, which requires choosing the length of the random region. Shorter random regions allow more complete coverage of sequence space but may not permit the structural complexity necessary for binding or catalysis. In contrast, longer random regions are sampled incompletely but may allow adoption of more complicated structures that enable function. In this study, we systematically examined random region length (N20 through N60) for two particular deoxyribozyme catalytic activities, DNA cleavage and tyrosine-RNA nucleopeptide linkage formation. For both activities, we previously identified deoxyribozymes using only N40 regions. In the case of DNA cleavage, here we found that shorter N20 and N30 regions allowed robust catalytic function, either by DNA hydrolysis or by DNA deglycosylation and strand scission via β-elimination, whereas longer N50 and N60 regions did not lead to catalytically active DNA sequences. Follow-up selections with N20, N30, and N40 regions revealed an interesting interplay of metal ion cofactors and random region length. Separately, for Tyr-RNA linkage formation, N30 and N60 regions provided catalytically active sequences, whereas N20 was unsuccessful, and the N40 deoxyribozymes were functionally superior (in terms of rate and yield) to N30 and N60. Collectively, the results indicate that with future in vitro selection experiments for DNA and RNA catalysts, and by extension for aptamers, random region length should be an important experimental variable.



DNAzymes linked to this article:

Name Isolated sequence Length Reaction
8VA2 GAACGTGGTGCGTGCTAACA      20 DNA cleavage
8VA5 CACCAACCGCGCGATGGATC      20 DNA cleavage
8VA6 TAGACGTAAACTGGAGTTG      19 DNA cleavage
8VA10 CGAATGTGGTGCGTGCTAAA      20 DNA cleavage
8VA23 AGGGGCGTGAGGGGTTCTTC      20 DNA cleavage
8VA25 TTAGGGAGGGCCACCAGCTT      20 DNA cleavage
7ZG5 GGATCATGGCGGTCTGGTTT      20 DNA cleavage
9ZH5 GCCCGGGAATGAGTCTTAGC      20 DNA cleavage
8VB1 ATGGGGCACAGTTCTCTCATACCCCTGGAA      30 DNA cleavage
8VB2 TGGTTCGCACTTTCCAGGACAGGTAACCAC      30 DNA cleavage
8VB4 CGGACCCGGGCTCGACCTCGTGCTGAGCAT      30 DNA cleavage
8VB5 TACAGCACAGGAGTTACGTCCGGGTAAGTG      30 DNA cleavage
8VB7 CCTTGGTGAGAACGCACCTCACGGACGTGG      30 DNA cleavage
8VB12 ACCGCGCGGAAGGCCTTTCTCGAAGGGCGA      30 DNA cleavage
8VB16 CCACTCCGTGCTCCTCTTGATGAGTAGGGC      30 DNA cleavage
8VB18 TACACTCATGGCGGTGTGATTCGATGCCGA      30 DNA cleavage
8VB21 ATCGGGTATTACGCGGACGGTTGCCCACCA      30 DNA cleavage
8VB22 CCGGCAGTGTGCTTGGGACAGCTTTGCTGG      30 DNA cleavage
8VB25 CAGGGGCGGTAGGCGTTACACTCAAATTGA      30 DNA cleavage
7ZJ7 GGATCATGGCGGTTTGGTTACGCTTTGCGT      30 DNA cleavage
9ZL1 GTGTGCTGGTAACATTAAAAAAGCTGGCTTCGGGGTTAGG      40 DNA cleavage
8TM3 GCGCTGGGAGGCACATGCTGGGTTGCACCG      30 Covalent Modification of Amino Acid Side Chains
8TM8 GCGCTGGGAGGCATGAAAGGGTCTGCACCG      30 Covalent Modification of Amino Acid Side Chains
8TM12 GCGCTGGGAGGCTAGTGCGGGGTTGCACCG      30 Covalent Modification of Amino Acid Side Chains
7TQ20 CAAGGAGAGCTGTACAAGCTCGGGTCGTGTTCAAAGGGATCATAGTGAGTACAAAACGG      59 Covalent Modification of Amino Acid Side Chains
7TQ2 CAAGGAGAGTTGTACAAGCTCGGGTCGTGTTCAAAGGGATCATAGTGAGTAGAAGGTCC      59 Covalent Modification of Amino Acid Side Chains
7TQ3 CAAGGAGAGTTGTACAAGCTCGGGTCGTGTTCAAAGGGATCATAGTGAGTAGGGAGC      57 Covalent Modification of Amino Acid Side Chains
7TQ11 CAAGGAGAGTTGTACAAGCTCGGGTCGTGTTCAAAGGTATCATAGTGAGGTAGTTAG      57 Covalent Modification of Amino Acid Side Chains
7TQ16 CAAGGAGAGTTGTACAAGCTCGGGTCGTGTTCAAAGGGATCATAGTGAGTAGATAACCT      59 Covalent Modification of Amino Acid Side Chains
7TQ53 CAAGGAGAGTTGTACAAGCTCGGGTCGTGTTCAAAGGTATCATAGTGAGTCGTGTCCAGT      60 Covalent Modification of Amino Acid Side Chains
7TQ46 CAAGGAGTGATCGTAGATCATGGGTCGTTCTGAAAGGCAGATAGTGAGTCATAAAACCACGG      62 Covalent Modification of Amino Acid Side Chains
8VA4 AGATGTGGTGCGTGCCAAAA      20 DNA cleavage
8VA11 GAACTGTGGTGCGTGCCAAA      20 DNA cleavage
7ZG2 CAGGATAATGGCGGTTTGGT      20 DNA cleavage
8VB9 CGGGGAATGGAGGCGTCCCAATGCAAATCG      30 DNA cleavage
8VB20 TCGCGGCACATTAGTGTGAGTGGATCACGT      30 DNA cleavage
8VB26 CCAGGATCAATGATAAGCCGAGTCAAAGGG      30 DNA cleavage
7ZJ12 GCCCACCAGGCTAGGGAGTGGTTACGAGGA      30 DNA cleavage
7TQ12 CAAGGAGAGTTGTACAAGCTCGGGTCGTGTTCAAAGGGATCATAGTGAGTAGACGATTT      59 Covalent Modification of Amino Acid Side Chains
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