Dependent Deoxyribozymes Research Articles

Self-cleavage of genetically encoded Zn2+-dependent deoxyribozymes for low-cost biotechnological production of programable responsive DNA hydrogels

Despite the emergence of sequence-programable responsive DNA hydrogels, their further development is still hampered by the limited availability of chemically synthesized nucleic acid constituents. We herein developed a cost-efficient biotechnological approach for general production of programable responsive DNA hydrogels by harnessing bacteria as cell factories. Programmable pseudogenes of responsive DNA hydrogels were designed by interleaving Y-unit strand sequences with Zn2+-dependent self-cleaving deoxyribozymes. After in vivo amplification, self-cleavage of these deoxyribozymes in extracted precursor ssDNAs were systematically investigated. The versatility of this approach was demonstrated by preparing a unitary Y-unit system of pH-responsive DNA hydrogel and a binary Y-unit system of Cas12a-responsive hydrogel. This low-cost biotechnological approach requires only standard molecular biology equipment and inexpensive consumables, which may encourage further exploration of responsive DNA hydrogels.

An isothermal, non-enzymatic, and dual-amplified fluorescent sensor for highly sensitive DNA detection

Abstract Sensitive DNA assays are of importance in life science and biomedical engineering, but they are heavily dependent on thermal cycling programs or enzyme-assisted schemes, which require the utilization of bulky devices and costly reagents. To circumvent such requirements, we developed an isothermal enzyme-free DNA sensing method with dual-stage signal amplification ability based on the coupling use of catalytic hairpin assembly (CHA) and Mg2+-dependent deoxyribozyme (DNAzyme). In this study, the sensing system involves a set of hairpin DNA probes for CHA (ensuring the first stage of signal amplification) as well as ribonucleobase-modified molecular beacons that serve as activatable substrates for DNAzymes (warranting the second stage of signal amplification). An experimentally determined detection limit of about 0.5 pM is achieved with a good linear range from 0.5 to 10 pM. The results from spiked fetal bovine serum samples further confirm the reliability for practical applications. The non-thermal cycling, enzyme-free, and dual-amplified features make it a powerful sensing tool for effective nucleic acid assay in a variety of biomedical applications.

Highly Efficient Cofactors of Cu2+‐Dependent Deoxyribozymes

AbstractDeoxyribozymes can catalyze various types of reactions mostly with metal ions as their cofactors. Here we demonstrate that three copper compounds with thiosemicarbazide or semicarbazide ligands, are highly active cofactors of Cu2+‐dependent deoxyribozymes without any additional reagents. The maximum catalytic rate constant of the deoxyribozyme with dichloro(di‐thiosemicarbazide)copper as a cofactor is ∼25‐fold faster than Cu2+ cofactor under the same reaction condition. Using a variety of spectroscopies, electrochemistry, and mutagenesis, we demonstrate that both the three‐dimensional structure and redox potential of the copper center of the cofactors are essential to the catalysis of deoxyribozymes. The cofactor interacts with the enzyme‐substrate complex forming a ternary enzyme‐substrate‐cofactor complex, which is confirmed by changing the structure of the enzyme‐substrate complex through varying the temperature, or mutating the active site of the enzyme and conserved site of the substrate. The result suggests that Cu2+‐dependent deoxyribozyme requires a well‐defined active site to carry out the catalysis proficiently.

DNA-catalyzed glycosylation using aryl glycoside donors.

We report the identification by in vitro selection of Zn(2+)/Mn(2+)-dependent deoxyribozymes that glycosylate the 3'-OH of a DNA oligonucleotide. Both β and α anomers of aryl glycosides can be used as the glycosyl donors. Individual deoxyribozymes are each specific for a particular donor anomer.

Lanthanide ions as required cofactors for DNA catalysts

We report that micromolar concentrations of lanthanide ions can be required cofactors for DNA-hydrolyzing deoxyribozymes. Previous work identified deoxyribozymes that simultaneously require both Zn(2+) and Mn(2+) to achieve DNA-catalyzed DNA hydrolysis (10(12) rate enhancement); a mutant of one such DNA catalyst requires only Zn(2+). Here we show that in vitro selection in the presence of 10 µM lanthanide ion (Ce(3+), Eu(3+), or Yb(3+)) along with 1 mM Zn(2+) leads to numerous DNA-hydrolyzing deoxyribozymes that strictly require the lanthanide ion as well as Zn(2+) for catalytic activity. These DNA catalysts have a range of lanthanide dependences, including some deoxyribozymes that strongly favor one particular lanthanide ion (e.g., Ce(3+) >> Eu(3+) >> Yb(3+)) and others that function well with more than one lanthanide ion. Intriguingly, two of the Yb(3+)-dependent deoxyribozymes function well with Yb(3+) alone (K(d,app) ~10 µM, in the absence of Zn(2+)) and have little or no activity with Eu(3+) or Ce(3+). In contrast to these selection outcomes when lanthanide ions were present, new selections with Zn(2+) or Mn(2+) alone, or Zn(2+) with Mg(2+)/Ca(2+), led primarily to deoxyribozymes that cleave DNA by deglycosylation and β-elimination rather than by hydrolysis, including several instances of depyrimidination. We conclude that lanthanide ions warrant closer attention as cofactors when identifying new nucleic acid catalysts, especially for applications in which high concentrations of polyvalent metal ion cofactors are undesirable.

Probing Essential Nucleobase Functional Groups in Aptamers and Deoxyribozymes by Nucleotide Analogue Interference Mapping of DNA

Nucleotide analogue interference mapping of DNA (dNAIM) is here introduced as a new nonenzymatic interference-based approach that enables high-throughput identification of essential nucleobase functional groups in DNA aptamers and in the catalytic core of deoxyribozymes. Nucleobase-modified ribonucleotides are statistically incorporated into DNA by solid-phase synthesis, employing the 2'-OH group as a chemical tag for analysis of interference effects. This method is exemplified on an AMP-binding DNA aptamer and was further used to identify indispensable nucleobase functional groups for DNA-catalyzed RNA-ligation by the Mg(2+)-dependent deoxyribozymes 7S11 and 9DB1. dNAIM should prove broadly useful for facile structural probing of functional DNA for which active and inactive variants can be separated based on catalytic or ligand-binding activities.

Controlling the direction of site-selectivity and regioselectivity in RNA ligation by Zn2+-dependent deoxyribozymes that use 2′,3′-cyclic phosphate RNA substrates

Our previous efforts have used in vitro selection to identify numerous Zn(2+)-dependent deoxyribozymes that ligate two RNA substrates with reaction at a 2',3'-cyclic phosphate. Each deoxyribozyme creates one of several different RNA linkages, including native 3'-5' and non-native 2'-5' phosphodiester bonds as well as many unnatural linkages. In this report, we describe experiments to reveal design aspects of the selection strategy that favor site-selective and regioselective synthesis of native 3'-5' RNA linkages. The results also reveal that an explicit selection pressure for RNA substrate sequence generality must be developed if the deoxyribozymes are to have practical generality.

General Deoxyribozyme-Catalyzed Synthesis of Native 3‘−5‘ RNA Linkages

An elusive goal for nucleic acid enzymology has been deoxyribozymes that ligate RNA rapidly, sequence-generally, with formation of native 3'-5' linkages, and in preparatively useful yield. Using in vitro selection, we have identified Mg2+- and Zn2+-dependent deoxyribozymes that simultaneously fulfill all four of these criteria. The new deoxyribozymes operate under practical incubation conditions and have modest RNA substrate sequence requirements, specifically D downward arrowRA for 9DB1 and A downward arrowR for 7DE5 (D = A, G, or U; R = A or G). These requirements are comparable to those of deoxyribozymes such as 10-23 and 8-17, which are already widely used as biochemical tools for RNA cleavage. We anticipate that the 9DB1 and 7DE5 deoxyribozymes will find immediate practical application for RNA ligation.

Parallel Selections In Vitro Reveal a Preference for 2′–5′ RNA Ligation upon Deoxyribozyme-Mediated Opening of a 2′,3′-Cyclic Phosphate

We previously used in vitro selection to identify Mg(2+)-dependent deoxyribozymes that mediate the ligation reaction of an RNA 5'-hydroxyl group with a 2',3'-cyclic phosphate. In these efforts, all of the deoxyribozymes were identified via a common in vitro selection strategy, and all of the newly formed RNA linkages were non-native 2'-5' phosphodiester bonds rather than native 3'-5' linkages. Here we performed several new selections in which the relative arrangements of RNA and DNA were different as compared with the earlier studies. In all cases, we again find deoxyribozymes that create only 2'-5' linkages. This includes deoxyribozymes with an arrangement that favors 3'-5' linkages for a different chemical reaction, that of a 2',3'-diol plus 5'-triphosphate. These data indicate a strong and context-independent chemical preference for creating 2'-5' RNA linkages upon opening of a 2',3'-cyclic phosphate with a 5'-hydroxyl group. Preliminary assays show that some of the newly identified deoxyribozymes have promise for ligating RNA in a sequence-general fashion. Because 2',3'-cyclic phosphates are the products of uncatalyzed RNA backbone cleavage, their ligation reactions may be of direct relevance to the RNA World hypothesis.

Zn2+-Dependent Deoxyribozymes That Form Natural and Unnatural RNA Linkages

We report Zn(2+)-dependent deoxyribozymes that ligate RNA. The DNA enzymes were identified by in vitro selection and ligate RNA with k(obs) up to 0.5 min(-)(1) at 1 mM Zn(2+) and 23 degrees C, pH 7.9, which is substantially faster than our previously reported Mg(2+)-dependent deoxyribozymes. Each new Zn(2+)-dependent deoxyribozyme mediates the reaction of a specific nucleophile on one RNA substrate with a 2',3'-cyclic phosphate on a second RNA substrate. Some of the Zn(2+)-dependent deoxyribozymes create native 3'-5' RNA linkages (with k(obs) up to 0.02 min(-)(1)), whereas all of our previous Mg(2+)-dependent deoxyribozymes that use a 2',3'-cyclic phosphate create non-native 2'-5' RNA linkages. On this basis, Zn(2+)-dependent deoxyribozymes have promise for synthesis of native 3'-5'-linked RNA using 2',3'-cyclic phosphate RNA substrates, although these particular Zn(2+)-dependent deoxyribozymes are likely not useful for this practical application. Some of the new Zn(2+)-dependent deoxyribozymes instead create non-native 2'-5' linkages, just like their Mg(2+) counterparts. Unexpectedly, other Zn(2+)-dependent deoxyribozymes synthesize one of three unnatural linkages that are formed upon the reaction of an RNA nucleophile other than a 5'-hydroxyl group. Two of these unnatural linkages are the 3'-2' and 2'-2' linear junctions created when the 2'-hydroxyl of the 5'-terminal guanosine of one RNA substrate attacks the 2',3'-cyclic phosphate of the second RNA substrate. The third unnatural linkage is a branched RNA that results from attack of a specific internal 2'-hydroxyl of one RNA substrate at the 2',3'-cyclic phosphate. When compared with the consistent creation of 2'-5' linkages by Mg(2+)-dependent ligation, formation of this variety of RNA ligation products by Zn(2+)-dependent deoxyribozymes highlights the versatility of transition metals such as Zn(2+) for mediating nucleic acid catalysis.

Structure-function correlations derived from faster variants of a RNA ligase deoxyribozyme.

We previously reported the in vitro selection of several Mg2+-dependent deoxyribozymes (DNA enzymes) that synthesize a 2'-5' RNA linkage from a 2',3'-cyclic phosphate and a 5'-hydroxyl. Here we subjected the 9A2 deoxyribozyme to re-selection for improved ligation rate. We found two new DNA enzymes (7Z81 and 7Z48) that contain the catalytic core of 7Q10, a previously reported small deoxyribozyme that is unrelated in sequence to 9A2. A third new DNA enzyme (7Z101) is unrelated to either 7Q10 or 9A2. The new 7Z81 and 7Z48 DNA enzymes have ligation rates over an order of magnitude higher than that of 7Q10 itself and they have additional sequence elements that correlate with these faster rates. Our findings provide insight into structure-function relationships of catalytic nucleic acids.

Novel biomaterials derived from deoxyribozyme and NAPzyme

AbstractWe report the potential of a small Ca2+‐dependent deoxyribozyme as a novel biomaterial to distinguish RNA foldings. It is found that an immobilized deoxyribozyme using avidin‐biotin interaction cleaves the target site within only single‐stranded RNAs. The RNA cleavage reaction is also detected using the deoxyribozyme SPR sensor chip. Furthermore, we develop a novel NAPzyme (nucleic acid peptide deoxyribozyme) with its RNA cleavage function in the absence of divalent metal ions.

Deoxyribozymes with 2'-5' RNA ligase activity.

In vitro selection was used to identify deoxyribozymes that ligate two RNA substrates. In the ligation reaction, a 2'-5' RNA phosphodiester linkage is created from a 2',3'-cyclic phosphate and a 5'-hydroxyl group. The new Mg(2+)-dependent deoxyribozymes provide 50-60% yield of ligated RNA in overnight incubations at pH 7.5 and 37 degrees C, and they afford 40-50% yield in 1 h at pH 9.0 and 37 degrees C. Various RNA substrate sequences may be joined by simple Watson-Crick covaration of the DNA binding arms that interact with the two RNA substrates. The current deoxyribozymes have some RNA substrate sequence requirements at the nucleotides immediately surrounding the ligation junction (either UAUA GGAA or UAUN GGAA, where the arrow denotes the ligation site and N equals any nucleotide). One of the new deoxyribozymes was used to prepare by ligation the Tetrahymena group I intron RNA P4-P6 domain, a representative structured RNA. Nondenaturing gel electrophoresis revealed that a 2'-5' linkage between nucleotides A233 and G234 of P4-P6 does not disrupt its Mg(2+)-dependent folding (DeltaDeltaG degrees ' < 0.2 kcal/mol). This demonstrates that a 2'-5' linkage does not necessarily interfere with structure in a folded RNA. Therefore, these non-native linkages may be acceptable in modified RNAs when structure/function relationships are investigated. Deoxyribozymes that ligate RNA should be particularly useful for preparing site-specifically modified RNAs for studies of RNA structure, folding, and catalysis.

Factors that contribute to efficient catalytic activity of a small Ca2+-dependent deoxyribozyme in relation to its RNA cleavage function.

Recently, we found a small Ca(2+)-dependent deoxyribozyme (unmodified), d(GCCTGGCAG(1)G(2)C(3)T(4)A(5)C(6)A(7)A(8)C(9)G(10)A(11)GTCCCT), with cleavage activity for its RNA substrate, r(AGGGACA downward arrow UGCCAGGC) ( downward arrow denotes the RNA cleavage site), in the presence of Ca(2+) and developed a functional SPR sensor chip with this deoxyribozyme [Okumoto, Y., Ohmichi, T., and Sugimoto, N. (2002) Biochemistry 41, 2769-2773]. In the study presented here, to clarify the factors contributing to the efficient catalytic activity of the unmodified deoxyribozyme, RNA cleavage reactions were carried out using 24 mutant deoxyribozymes containing one unnatural DNA nucleotide, such as dI (2'-deoxyinosine), 7-deaza-dG, 2-aminopurine, 7-deaza-dA, 2-amino-dA, dm(5)C (5-methyl-2'-deoxycytosine), or d(P)C (5-propynyl-2'-deoxycytosine). The K(m) values (Michaelis constants) with the mutants that lacked N7 and O6 of G(1) and O6 of G(2) were 4.5 and 6.6 times that of the unmodified one, respectively. The k(cat) value (cleavage rate constant) with the mutants that lacked O6 of G(10) was 0.025 times that of the unmodified one. The results of UV melting curves, SPR kinetics, and CD spectra supported the quantitative idea that the catalytic activity of the unmodified form was achieved using Ca(2+). On the basis of these results, a preliminary model for two G(1) x A(8) and G(2) x A(7) mismatched base pairs such as G(anti) x A(anti) formed in the catalytic loop is proposed. The factor of 10 increase in the k(cat)/K(m) value of the mutant deoxyribozyme, which has C(9) substituted with d(P)C, suggests that the base stacking interaction between the substituted propynyl group in dC and the nearest-neighbor base grew stronger. Thus, substituting d(P)C for dC in the catalytic loop would be one of the best ways to increase the catalytic activity of the deoxyribozyme.

Sequence Diversity, Metal Specificity, and Catalytic Proficiency of Metal-Dependent Phosphorylating DNA Enzymes

Although DNA has not been found responsible for biological catalysis, many artificial DNA enzymes have been created by “in vitro selection.” Here we describe a new selection approach to assess the influence of four common divalent metal ions (Ca 2+, Cu 2+, Mg 2+, and Mn 2+) on sequence diversity, metal specificity, and catalytic proficiency of self-phosphorylating deoxyribozymes. Numerous autocatalytic DNA sequences were isolated, a majority of which were selected using Cu 2+ or Mn 2+ as the divalent metal cofactor. We found that Cu 2+- and Mn 2+-derived deoxyribozymes were strictly metal specific, while those selected by Ca 2+ and Mg 2+ were less specific. Further optimization by in vitro evolution resulted in a Mn 2+-dependent deoxyribozyme with a k cat of 2.8 min −1. Our findings suggest that DNA has sufficient structural diversity to facilitate efficient catalysis using a broad scope of metal cofactor utilizing mechanisms.

Immobilized small deoxyribozyme to distinguish RNA secondary structures.

The RNA folding variation due to one or more mutations leads to different RNA splicing, RNA processing, and translational controls as a result of differences in the primary and higher-ordered structures that interact with other cellular molecules. Thus, distinguishing RNA folding is one of the guides to detect the gene functions related to disease and drug responses. We found, previously, a small Ca(2+)-dependent deoxyribozyme with its site-specific RNA cleavage [Sugimoto, N., Okumoto, Y., and Ohmichi, T. (1999) J. Chem. Soc., Perkin Trans. 2, 1382-1388]. In this study, we report the potential of this deoxyribozyme as a useful tool to distinguish RNA foldings. It is found that the immobilized deoxyribozyme using avidin-biotin interaction cleaves the target site within only single-stranded RNAs. The systematic design for the target RNA hairpin loops shows that the immobilized deoxyribozyme is able to cleave them with a > or =17 nucleotide loop size at only one site under single-turnover conditions. Furthermore, an RNA cleavage reaction is detected using the immobilized deoxyribozyme on a surface plasmon resonance (SPR) sensor chip. These results show that the immobilized deoxyribozymes on a column and on an SPR sensor chip become a novel and useful tool to distinguish the RNA foldings.

Effects of metal ions and catalytic loop sequences on the complex formation of a deoxyribozyme and its RNA substrate

A deoxyribozyme is a catalytic DNA that catalyzes a site-specific RNA cleavage activity and requires various divalent cations. Earlier we have reported that by downsizing the catalytic loop of a deoxyribozyme from 15-mer to 11-mer it resulted in a short and novel Ca 2+-dependent deoxyribozyme. In this paper, we investigate the complex formation of deoxyribozymes with their RNA substrates by using surface plasmon resonance (SPR) in order to determine quantitatively the effect of Ca 2+ or Mg 2+ on the recognition step between a deoxyribozyme and its RNA substrate. The results indicate that both the association and dissociation rate constants ( k a and k d) for the deoxyribozyme–RNA complex depends on metal ions as well as the loop size of the deoxyribozyme. Metal ions with high RNA cleavage activity induced an increase in k a and a decrease in k d. On the basis of the results, we propose that Ca 2+ ions may play a role in the rearrangement of the 11-mer catalytic loop of the short Ca 2+-dependent deoxyribozyme.

Development of a novel functional biosensor with a short Ca(2+)-dependent deoxyribozyme.

We develop a novel functional biosensor on a deoxyribozyme. A 5'-end-immobilized short Ca(2+)-dependent deoxyribozyme (dCGCTGGCAGGCTACAACGAGTCTTC) binds to a target RNA substrate (rGAAGACA decrease UGCCAGCG; decrease denotes an RNA cleavage site), and acts as an enzyme in the presence of Ca2+. It cleaves the target RNA substrate at one site of rAp decrease U in the asymmetric internal loop.

Development of a short Ca2+-dependent deoxyribozyme with RNA cleavage activity.

We developed a short Ca2+-dependent deoxyribozyme with 11 mer catalytic loop domain (dGGCTACAACGA) that catalyzed site-specific RNA cleavage reaction between rA and rU. The second-order rate constant of this short deoxyribozyme is 1.7 x 10(7) M(-1) min(-1) at 37 degrees C, and this value is very similar to that of the deoxyribozyme (dGGCTAGCTACAACGA) in the presence of Ca2+.