RNA cleaving '10-23' DNAzymes with enhanced stability and activity

‘10-23’ DNAzymes can be used to cleave any target RNA in a sequence-specific manner. For applications in vivo, they have to be stabilised against nucleolytic attack by the introduction of modified nucleotides without obstructing cleavage activity. In this study, we optimise the design of a DNAzyme targeting the 5′-non-translated region of the human rhinovirus 14, a common cold virus, with regard to its kinetic properties and its stability against nucleases. We compare a large number of DNAzymes against the same target site that are stabilised by the use of a 3′-3′-inverted thymidine, phosphorothioate linkages, 2′-O-methyl RNA and locked nucleic acids, respectively. Both cleavage activity and nuclease stability were significantly enhanced by optimisation of arm length and content of modified nucleotides. Furthermore, we introduced modified nucleotides into the catalytic core to enhance stability against endonucleolytic degradation without abolishing catalytic activity. Our findings enabled us to establish a design for DNAzymes containing nucleotide modifications both in the binding arms and in the catalytic core, yielding a species with up to 10-fold enhanced activity and significantly elevated stability against nucleolytic cleavage. When transferring the design to a DNAzyme against a different target, only a slight modification was necessary to retain activity.     

Efficient silencing of gene expression by an ASON-bulge-DNAzyme complex

Background

DNAzymes are DNA molecules that can directly cleave cognate mRNA, and have been developed to silence gene expression for research and clinical purposes. The advantage of DNAzymes over ribozymes is that they are inexpensive to produce and exhibit good stability. The “10-23 DNA enzyme” is composed of a catalytic domain of 15 deoxynucleotides, flanked by two substrate-recognition domains of approximately eight nucleotides in each direction, which provides the complementary sequence required for specific binding to RNA substrates. However, these eight nucleotides might not afford sufficient binding energy to hold the RNA substrate along with the DNAzyme, which would interfere with the efficiency of the DNAzyme or cause side effects, such as the cleavage of non-cognate mRNAs.

Methodology

In this study, we inserted a nonpairing bulge at the 5′ end of the “10–23 DNA enzyme” to enhance its efficiency and specificity. Different sizes of bulges were inserted at different positions in the 5′ end of the DNAzyme. The non-matching bulge will avoid strong binding between the DNAzyme and target mRNA, which may interfere with the efficiency of the DNAzyme.

Conclusions

Our novel DNAzyme constructs could efficiently silence the expression of target genes, proving a powerful tool for gene silencing. The results showed that the six oligo bulge was the most effective when the six oligo bulge was 12–15 bp away from the core catalytic domain.     

Locked nucleoside analogues expand the potential of DNAzymes to cleave structured RNA targets

Background  

DNAzymes cleave at predetermined sequences within RNA. A prerequisite for cleavage is that the DNAzyme can gain access to its target, and thus the DNAzyme must be capable of unfolding higher-order structures that are present in the RNA substrate. However, in many cases the RNA target sequence is hidden in a region that is too tightly structured to be accessed under physiological conditions by DNAzymes.     

DNAzyme-mediated silencing of ornithine decarboxylase

The value of reducing the activity of ornithine decarboxylase (ODC), a key enzyme in the biosynthesis of polyamines, is well-appreciated. Polyamines are necessary components for cell growth, and manipulation of polyamine homeostasis may be an effective strategy for the treatment of a number of disorders, including neoplastic diseases. An approach to develop an effective DNAzyme, using the 10-23 model, against ODC is described in these studies. DNAzymes able to cleave the target ODC RNA were identified in vitro and further characterized by the effect each had on ODC protein and activity levels using in vitro translated ODC RNA. ODC protein levels and activity correlated well with the RNA cleavage activity of the DNAzyme. One of the DNAzymes, DZ IV, which exhibited good activity, was optimized for use in cell culture studies. The DNAzyme hybridization arms were altered from equal length arms varying in length (8, 9, 10, or 11 nucleotides) or to unequal length arms (7/11 nucleotides), and kinetic analyses were performed to identify the most catalytically efficient configuration. DZ IV with equal arms nine nucleotides in length proved to be the most catalytically efficient. In HEK 293 cells, DZ IV was able to reduce the amount of translated ODC protein, resulting in approximately 80% reduction in ODC activity-a statistically significant enhancement over the apparent antisense effect of a catalytically inactive DNAzyme. These results indicate that this DNAzyme may be a useful tool to study the function of ODC and may have potential therapeutic uses.     

The effect of structure in a long target RNA on ribozyme cleavage efficiency.

Inhibition of gene expression by catalytic RNA (ribozymes) requires that ribozymes efficiently cleave specific sites within large target RNAs. However, the cleavage of long target RNAs by ribozymes is much less efficient than cleavage of short oligonucleotide substrates because of higher order structure in the long target RNA. To further study the effects of long target RNA structure on ribozyme cleavage efficiency, we determined the accessibility of seven hammerhead ribozyme cleavage sites in a target RNA that contained human immunodeficiency virus type 1 (HIV-1) vif - vpr . The base pairing-availability of individual nucleotides at each cleavage site was then assessed by chemical modification mapping. The ability of hammerhead ribozymes to cleave the long target RNA was most strongly correlated with the availability of nucleotides near the cleavage site for base pairing with the ribozyme. Moreover, the accessibility of the seven hammerhead ribozyme cleavage sites in the long target RNA varied by up to 400-fold but was directly determined by the availability of cleavage sites for base pairing with the ribozyme. It is therefore unlikely that steric interference affected hammerhead ribozyme cleavage. Chemical modification mapping of cleavage site structure may therefore provide a means to identify efficient hammerhead ribozyme cleavage sites in long target RNAs.     

Characterization of two distinct RNA domains that regulate translation of the Drosophila gypsy retroelement

The genomic RNA of the gypsy retroelement from Drosophila melanogaster exhibits features similar to other retroviral RNAs because its 5' untranslated (5' UTR) region is unusually long (846 nucleotides) and potentially highly structured. Our initial aim was to search for an internal ribosome entry site (IRES) element in the 5' UTR of the gypsy genomic RNA by using various monocistronic and bicistronic RNAs in the rabbit reticulocyte lysate (RRL) system and in cultured cells. Results reported here show that two functionally distinct and independent RNA domains control the production of gypsy encoded proteins. The first domain corresponds to the 5' UTR of the env subgenomic RNA and exhibits features of an efficient IRES (IRES(E)) both in the reticulocyte lysate and in cells. The second RNA domain that encompasses the gypsy insulator can function as an IRES in the rabbit reticulocyte lysate but strongly represses translation in cultured cells. Taken together, these results suggest that expression of the gypsy encoded proteins from the genomic and subgenomic RNAs can be regulated at the level of translation.     

Hairpin DNAzymes: a new tool for efficient cellular gene silencing

BACKGROUND: RNA-based gene silencing is potentially a powerful therapeutic strategy. Catalytic 10-23 DNAzymes bind to target RNA by complimentary sequence arms on a Watson-Crick basis and thus can be targeted to effectively cleave specific mRNA species. However, for in vivo applications it is necessary to stabilise DNAzymes against nucleolytic attack. Chemical modifications can be introduced into the binding arms to increase stability but these may alter catalytic activity and in some cases increase cell toxicity. METHODS: We designed novel 10-23 DNAzyme structures that incorporate stem-loop hairpins at either end on the DNAzyme binding arms. The catalytic activity of hairpin DNAzymes (hpDNAzyme) were tested in vitro against 32P-labelled cRNA encoding the muscle acetylcholine receptor (AChR) alpha-subunit. Resistance of hpDNAzymes to nucleolytic degradation was tested by incubation of the hpDNAzymes with Bal-31, DNase1 or HeLa cell extract. Gene silencing by hpDNAzymes was assessed by measuring reduced fluorescence from DsRed2 and EGFP reporters in cell culture systems, and reduced 125I-alpha-bungarotoxin binding in cells transfected with cDNA encoding the AChR. RESULTS: We show that hpDNAzymes show remarkable resistance to nucleolytic degradation, and demonstrate that in cell culture systems the hpDNAzymes are far more effective than standard 10-23 DNAzymes in down-regulating protein expression from target mRNA species. CONCLUSION: hpDNAzymes provide new molecular tools that, without chemical modification, give highly efficient gene silencing in cells, and may have potential therapeutic applications.     

A three-nucleotide helix I is sufficient for full activity of a hammerhead ribozyme: advantages of an asymmetric design.

Trans-cleaving hammerhead ribozymes with long target-specific antisense sequences flanking the catalytic domain share some features with conventional antisense RNA and are therefore termed 'catalytic antisense RNAs'. Sequences 5' to the catalytic domain form helix I and sequences 3' to it form helix III when complexed with the target RNA. A catalytic antisense RNA of more than 400 nucleotides, and specific for the human immunodeficiency virus type 1 (HIV-1), was systematically truncated within the arm that constituted originally a helix I of 128 base pairs. The resulting ribozymes formed helices I of 13, 8, 5, 3, 2, 1 and 0 nucleotides, respectively, and a helix III of about 280 nucleotides. When their in vitro cleavage activity was compared with the original catalytic antisense RNA, it was found that a helix I of as little as three nucleotides was sufficient for full endonucleolytic activity. The catalytically active constructs inhibited HIV-1 replication about four-fold more effectively than the inactive ones when tested in human cells. A conventional hammerhead ribozyme having helices of just 8 nucleotides on either side failed to cleave the target RNA in vitro when tested under the conditions for catalytic antisense RNA. Cleavage activity could only be detected after heat-treatment of the ribozyme substrate mixture which indicates that hammerhead ribozymes with short arms do not associate as efficiently to the target RNA as catalytic antisense RNA. The requirement of just a three-nucleotide helix I allows simple PCR-based generation strategies for asymmetric hammerhead ribozymes. Advantages of an asymmetric design will be discussed.     

A cis and trans adenine-dependent hairpin ribozyme against Tpl-2 target

Ribozymes are catalytic RNAs that possess the property of cutting an RNA target via site-specific cleavage after sequence-specific recognition. Ribozymes can moreover cleave multiple substrate molecules. An increasing number of studies show that ribozymes are particularly well adapted tools against cancer, silencing or down-regulating gene expression at the RNA level. We have constructed an adenine-dependent hairpin ribozyme that cleaves the sequence at nucleotides A(225)(downward arrow)G(226) relative to the start codon of translation of the Tpl-2 kinase mRNA; this serine/threonine kinase activates the mitogen-activated protein kinase pathway implicated in cell proliferation in breast cancer. An adenine-dependent hairpin ribozyme 1 (ADHR1) was previously isolated using the Systematic Evolution of Ligands by EXponential enrichment procedure. Switch on/switch off ribozymes are particularly useful since high amounts of stable ribozyme can be produced in the absence of adenine and the ribozyme specifically cleaves its target in the presence of adenine. The ADHR1 target sequence was replaced by a sequence derived from the Tpl-2 kinase mRNA. The resulting Tpl-2 ribozyme is active in cis cleavage: kinetic studies have been performed as a function of Mg2+ concentration, adenine concentration, as well as at different pH and with various cofactors. Finally, the Tpl-2 ribozyme was shown to cleave its target in trans successfully. These findings demonstrate that a potential therapeutic ribozyme can be produced by simple sequence modification.     

Ribozyme mediated destruction of RNA in vivo.

Previous studies have demonstrated that high ribozyme to substrate ratios are required for ribozyme inhibitory function in nuclear extracts. To obtain high intracellular levels of ribozymes, tRNA genes, known to be highly expressed in most tissues, have been modified for use as ribozyme expression cassettes. Ribozyme coding sequences were placed between the A and the B box, internal promoter sequences of a Xenopus tRNAMet gene. When injected into the nucleus of frog oocytes, the ribozyme tRNA gene (ribtDNA) produces 'hammerhead' ribozymes which cleave the 5' sequences of U7snRNA, its target substrate, with high efficiency in vitro. Oocytes were coinjected with ribtDNA, U7snRNA and control substrate RNA devoid of a cleavage sequence. It was found that the ribtRNA remained localized mainly in the nucleus, whereas the substrate and the control RNA exited rapidly into the cytoplasm. However, sufficient ribtRNA migrated into the cytoplasm to cleave, and destroy, the U7snRNA. Thus, the action of targeted 'hammerhead' ribozymes in vivo is demonstrated.     

Selective cleavage of bcr-abl chimeric RNAs by a ribozyme targeted to non-contiguous sequences.

Conventionally designed ribozymes may be unable to cleave RNA at sites which are inaccessible due to secondary structure. In addition, it may also be difficult to specifically target a conventionally designed ribozyme to some chimeric RNA molecules. Novel approaches for ribozyme targeting were developed by using the L6 bcr-abl fusion RNA as a model. Using one approach, we successfully directed ribozyme nucleation to a site on the bcr-abl RNA that is distant from the GUA cleavage site. These ribozymes bound to the L6 substrate RNA via an anchor sequence that was complementary to bcr sequences. The anchor was necessary for efficient cleavage as the anchor minus ribozyme, a conventionally designed ribozyme, was inefficient at catalyzing cleavage at this same site. The effect of anchor sequences on catalytic rates was determined for two of these ribozymes. Ribozymes generated by a second approach were designed to cleave at a CUU site in proximity to the bcr-abl junction. Both approaches have led to the development of a series of ribozymes specific for both the L6 and K28 bcr-abl chimeric RNAs, but not normal abl or bcr RNAs. The specificity of the ribozyme correlated in part with the ability of the ribozyme to bind substrate as demonstrated by gel shift analyses. Secondary structure predictions for the RNA substrate support the experimental results and may prove useful as a theoretical basis for the design of ribozymes.     

An Efficient Catalytic DNA that Cleaves L-RNA

Many DNAzymes have been isolated from synthetic DNA pools to cleave natural RNA (D-RNA) substrates and some have been utilized for the design of aptazyme biosensors for bioanalytical applications. Even though these biosensors perform well in simple sample matrices, they do not function effectively in complex biological samples due to ubiquitous RNases that can efficiently cleave D-RNA substrates. To overcome this issue, we set out to develop DNAzymes that cleave L-RNA, the enantiomer of D-RNA, which is known to be completely resistant to RNases. Through in vitro selection we isolated three L-RNA-cleaving DNAzymes from a random-sequence DNA pool. The most active DNAzyme exhibits a catalytic rate constant ~3 min^-1 and has a structure that contains a kissing loop, a structural motif that has never been observed with D-RNA-cleaving DNAzymes. Furthermore we have used this DNAzyme and a well-known ATP-binding DNA aptamer to construct an aptazyme sensor and demonstrated that this biosensor can achieve ATP detection in biological samples that contain RNases. The current work lays the foundation for exploring RNA-cleaving DNAzymes for engineering biosensors that are compatible with complex biological samples.     

A general strategy for effector-mediated control of RNA-cleaving ribozymes and DNA enzymes

A novel and general approach is described for generating versions of RNA-cleaving ribozymes (RNA enzymes) and DNAzymes (DNA enzymes), whose catalytic activity can be controlled by the binding of activator molecules. Variants of the RNA-cleaving 10-23 DNAzyme and 8-17 DNAzyme were created, whose catalysis was activated by up to approximately 35-fold by the binding of the effector adenosine. The design of such variants was possible even though the tertiary folding of the two DNAzymes is not known. Variants of the hammerhead ribozyme were constructed, to respond to the effectors ATP and flavin mononucleotide. Whereas in conventional allosteric ribozymes, effector-binding modulates the chemical step of catalysis, here, effectors exercise their effect upon the substrate-binding step, by stabilizing the enzyme-substrate complex. Because such an approach for controlling the activity of DNAzymes/ribozymes requires no prior knowledge of the enzyme's secondary or tertiary folding, this regulatory strategy should be generally applicable to any RNA-cleaving ribozyme or DNAzyme, natural or in vitro selected, provided substrate-recognition is achieved by Watson-Crick base-pairing.     

Inhibition of HIV-1 replication by ribozymes that show poor activity in vitro.

Self-cleaving RNAs (ribozymes) can be engineered to cleave target RNAs of choice in a sequence-specific manner (1). Consequently, they could be used to inhibit virus replication or to analyse host gene function in vivo. However, ribozymes that are catalytic in vitro are generally disappointing when analysed in cells unless expressed at high levels relative to their target RNAs (2, 3). Here we provide evidence that this can be overcome by optimizing ribozyme structure using cellular rather than cell-free assays. We show that ribozymes of relatively long flanking complementary regions (FCRs), while poor catalysts in vitro, can produce profound inhibition of HIV replication in cells. By examining a series of ribozymes in which the FCRs vary from 9 to 564 nucleotides, we establish that the optimum length for activity in the cell is > or = 33 nucleotides.     

Sequence-specific cleavage of RNA in the absence of divalent metal ions by a DNAzyme incorporating imidazolyl and amino functionalities

Two modified 2′-deoxynucleoside 5′-triphosphates have been used for the in vitro selection of a modified deoxyribozyme (DNAzyme) capable of the sequence-specific cleavage of a 12 nt RNA target in the absence of divalent metal ions. The modified nucleotides, a C5-imidazolyl-modified dUTP and 3-(aminopropynyl)-7-deaza-dATP were used in place of TTP and dATP during the selection and incorporate two extra protein-like functionalities, namely, imidazolyl (histidine analogue) and primary amino (lysine analogue) into the DNAzyme. The functional groups are analogous to the catalytic Lys and His residues employed during the metal-independent cleavage of RNA by the protein enzyme RNaseA. The DNAzyme requires no divalent metal ions or other cofactors for catalysis, remains active at physiological pH and ionic strength and can recognize and cleave a 12 nt RNA substrate with sequence specificity. This is the first example of a functionalized, metal-independent DNAzyme that recognizes and cleaves an all-RNA target in a sequence-specific manner. The selected DNAzyme is two orders of magnitude more efficient in its cleavage of RNA than an unmodified DNAzyme in the absence of metal ions and represents a rate enhancement of 10⁵ compared with the uncatalysed hydrolysis of RNA.     

The DNAzymes Rs6, Dz13, and DzF have potent biologic effects independent of catalytic activity

DNAzymes are catalytic DNA molecules capable of cleaving RNA substrates and therefore constitute a possible gene-suppression technology. We examined whether the previously reported potency of a DNAzyme targeting c-jun (Dz13) could be improved with judicious use of sequence and chemical modifications. Catalytic activity was measured to establish correlations between catalytic activity and biological potency. Surprisingly, Dz13 had significant cytotoxic activity against cells of rodent origin (IC(50) = 20-50 nM) despite having greatly reduced catalytic activity against a rodent target substrate (<25%), the latter being the result of a mismatch to the rodent c-jun sequence. In contrast, a modified Dz13 matching the rodent c-jun sequence (DT1501b) had no activity at similar concentrations against human or rodent cells despite being able to efficiently cleave the rodent c-jun sequence. Overall, catalytic activity against synthetic substrates did not correlate with cytotoxic activity and catalytically inactive mutants had in some cases equal or superior potency in cell cytotoxicity assays. Further examination of other previously published DNAzymes (Rs6 and DzF) revealed other occurrences of this anomalous behaviour. The active sequences all have G-rich 5 termini, suggesting that G-quadruplex formation might be involved. Consistent with this, deaza-guanosine substitutions abrogated cytotoxicity of Dz13. However, Dz13 did not show evidence of quadruplex formation as determined by circular dichroism studies and native electrophoresis. These data reveal that the biologic activity of several published DNAzymes is not mediated through the catalytic degradation of target mRNA.     

Deletion analysis in the catalytic region of the 10-23 DNA enzyme

In this study, the functional relevance of the core nucleotides of the RNA cleaving 10-23 DNA enzyme (DNAzyme) was investigated. Systematic deletion studies revealed that DNAzymes lacking thymine at position 8 (T8) retain catalytic activity comparable to that of the wild-type enzyme. Deletion of the adjacent cytosine at position 7 (C7) also resulted in a highly active enzyme and even the double deletion mutant C7/T8 displayed cleavage activity, although the catalytic rate under multiple turnover conditions was found to be reduced by one order of magnitude. The identification of non-essential nucleotides in the catalytic core might help to stabilize the DNAzyme against nucleolytic degradation and to overcome problems in elucidating its three-dimensional structure.