Ribozyme motif structure mapped using random recombination and selection

Isolating the core functional elements of an RNA is normally performed during the characterization of a new RNA in order to simplify further biochemical analysis. The removal of extraneous sequence is challenging and can lead to biases that result from the incomplete sampling of deletion variants. An impartial solution to this problem is to construct a library containing a large number of deletion constructs and to select functional RNA isolates that are at least as efficient as their full-length progenitors. Here, we use nonhomologous recombination and selection to isolate the catalytic core of a pyrimidine nucleotide synthase ribozyme. A variable-length pool of approximately 10(8) recombinant molecules that included deletions, inversions, and translocations of a 271-nucleotide-long ribozyme isolate was constructed by digesting and randomly religating its DNA genome. In vitro selection for functional ribozymes was then performed in a size-dependent and a size-independent manner. The final pools had nearly equivalent catalytic rates even though their length distributions were completely different, indicating that a diverse range of deletion constructs were functionally active. Four short sequence islands, requiring as little as 81 nt of sequence, were found within all of the truncated ribozymes and could be folded into a secondary structure consisting of three helix-loops. Our findings suggest that nonhomologous recombination is a highly efficient way to isolate a ribozyme's core motif and could prove to be a useful method for evolving new ribozyme functions from pre-existing sequences in a manner that may have played an important role early in evolution.     

Engineered RNase P ribozymes increase their cleavage activities and efficacies in inhibiting viral gene expression in cells by enhancing the rate of cleavage and binding of the target mRNA

Engineered RNase P ribozymes are promising gene-targeting agents that can be used in both basic research and clinical applications. We have previously selected ribozyme variants for their activity in cleaving an mRNA substrate from a pool of ribozymes containing randomized sequences. In this study, one of the variants was used to target the mRNA encoding thymidine kinase (TK) of herpes simplex virus 1 (HSV-1). The variant exhibited enhanced cleavage and substrate binding and was at least 30 times more efficient in cleaving TK mRNA in vitro than the ribozyme derived from the wild type sequence. Our results provide the first direct evidence to suggest that a point mutation at nucleotide 95 of RNase P catalytic RNA from Escherichia coli (G(95) --> U(95)) increases the rate of cleavage, whereas another mutation at nucleotide 200 (A(200) --> C(200)) enhances substrate binding of the ribozyme. A reduction of about 99% in TK expression was observed in cells expressing the variant, whereas a 70% reduction was found in cells expressing the ribozyme derived from the wild type sequence. Thus, the RNase P ribozyme variant is highly effective in inhibiting HSV-1 gene expression. Our study demonstrates that ribozyme variants increase their cleavage activity and efficacy in blocking gene expression in cells through enhanced substrate binding and rate of cleavage. These results also provide insights into the mechanism of how RNase P ribozymes efficiently cleave an mRNA substrate and, furthermore, facilitate the development of highly active RNase P ribozymes for gene-targeting applications.     

Revitalization of six abandoned catalytic DNA species reveals a common three-way junction framework and diverse catalytic cores

A library containing as many as 10(16) nucleic acid candidates is typically used to isolate artificial ribozymes and deoxyribozymes (DNAzymes) in an in vitro selection experiment, with only a handful of sequences surviving many rounds of stringent selection steps. These winning species are generally the focus of interest whereas the less competitive contenders are usually not examined. Nevertheless, molecular species abandoned during the selection process might still represent a rich pool of catalytic motifs that are useful for the examination of DNA's inherent catalytic ability, and for the design of molecular tools for practical applications. Here we report a study of six RNA-cleaving, fluorescence-signaling deoxyribozymes that appeared in the early generations of a previous in vitro selection experiment, using the combined approaches of reselection, rational structural analysis, and reaction condition optimization. All six deoxyribozymes were found to use a three-way junction as a common structural framework for catalysis. However, disparities observed in the conserved nucleotide allocations, methylation interference patterns and metal-ion selectivities, pointed to distinct catalytic cores. The rate constants of the optimized deoxyribozymes fell in the range of approximately 0.2 to 1.6 min(-1), which are comparable to those of similar ribozymes. Our findings indicate that deoxyribozymes eliminated by harsh selection criteria are structurally simple molecules that can be tailored into efficient catalysts.     

Synthetic shuffling and in vitro selection reveal the rugged adaptive fitness landscape of a kinase ribozyme

The relationship between genotype and phenotype is often described as an adaptive fitness landscape. In this study, we used a combination of recombination, in vitro selection, and comparative sequence analysis to characterize the fitness landscape of a previously isolated kinase ribozyme. Point mutations present in improved variants of this ribozyme were recombined in vitro in more than 10¹⁴ different arrangements using synthetic shuffling, and active variants were isolated by in vitro selection. Mutual information analysis of 65 recombinant ribozymes isolated in the selection revealed a rugged fitness landscape in which approximately one-third of the 91 pairs of positions analyzed showed evidence of correlation. Pairs of correlated positions overlapped to form densely connected networks, and groups of maximally connected nucleotides occurred significantly more often in these networks than they did in randomized control networks with the same number of links. The activity of the most efficient recombinant ribozyme isolated from the synthetically shuffled pool was 30-fold greater than that of any of the ribozymes used to build it, which indicates that synthetic shuffling can be a rich source of ribozyme variants with improved properties.     

In vitro selection of hammerhead ribozymes containing a bulged nucleotide in stem II.

Hammerhead ribozymes were transcribed from a dsDNA template containing four random nucleotides between stems II and III, which replace the naturally occurring GAA nucleotides. In vitro selection was used to select hammerhead ribozymes capable of in cis cleavage using denaturing polyacrylamide gels for the isolation of cleaving sequences. Self-cleaving ribozymes were cloned after the first and second rounds of selection, sequenced and characterised. Only sequences containing 5'-HGAA-3', where H is A, C or U, between stems II and III were active; G was clearly not tolerated at this position. Thus, only three sequences out of the starting pool of 256 (4(4)) were active. The Michaelis-Menten parameters were determined for the in trans cleaving versions of these ribozymes and indicate that selected ribozymes are less efficient than the native sequence. We propose that the selected ribozymes accommodate the extra nucleotide as a bulge in stem II.     

New catalytic structures from an existing ribozyme

Although protein enzymes with new catalytic activities can arise from existing scaffolds, less is known about the origin of ribozymes with new activities. Furthermore, mechanisms by which new macromolecular folds arise are not well characterized for either protein or RNA. Here we investigate how readily ribozymes with new catalytic activities and folds can arise from an existing ribozyme scaffold. Using in vitro selection, we isolated 23 distinct kinase ribozymes from a pool of sequence variants of an aminoacylase parent ribozyme. Analysis of these new kinases showed that ribozymes with new folds and biochemical activities can be found within a short mutational distance of a given ribozyme. However, the probability of finding such ribozymes increases considerably as the mutational distance from the parental ribozyme increases, indicating a need to escape the fold of the parent.     

In vitro evolution of the hammerhead ribozyme to a purine-specific ribozyme using mutagenic PCR with two nucleotide analogues

The conventional hammerhead ribozyme cleaves RNA 3' to nucleotide triplets with the general formula NUH, where N is any nucleotide, U is uridine and H is any nucleotide except guanosine. In order to isolate hammerhead ribozyme sequences capable of cleaving 3' to the GUG triplet, we performed a mutagenic selection protocol starting with the conventional sequence of an NUH-cleaving ribozyme. The 22 nucleotides in the core and the stem-loop II region were subjected to mutagenic PCR using the two nucleotide analogues 6-(2-deoxy-beta-d-ribofuranosyl)-3,4-dihydro-8H-pyrimido-[4,5-C)][1, 2] oxazin-7-one and of 8-oxo-2'-deoxyguanosine. After five repetitions of the selection cycle, several clones showed cleavage activity. One sequence, having one deletion, showed at least a 90 times higher in trans cleavage rate than the starting ribozyme. It cleaved 3' to GUG and GUA. The sequence of this ribozyme is essentially identical with that obtained previously by selection for AUG cleavage starting with a randomised core and stem-loop II region. This identical result of two independent selection procedures supports the notion that sequences for NUR cleavage, where R is a purine nucleotide, are not compatible with the classical hammerhead structure, and that the sequence space for this cleavage specificity is very limited. The cleavage of NUR triplets is not restricted to the sequence of the substrate that was used for selection but is sequence-independent for in trans cleavage, although the sequence context influences the value for the cleavage rate somewhat. Analysis of cleavage activities indicates the importance of A at position L2.5 in loop II.     

The secondary structure and sequence optimization of an RNA ligase ribozyme.

In vitro selection can generate functional sequence variants of an RNA structural motif that are useful for comparative analysis. The technique is particularly valuable in cases where natural variation is unavailable or non-existent. We report the extension of this approach to a new extreme--the identification of a 112 nt ribozyme secondary structure imbedded within a 186 nt RNA. A pool of 10(14) variants of an RNA ligase ribozyme was generated using combinatorial chemical synthesis coupled with combinatorial enzymatic ligation such that 172 of the 186 relevant positions were partially mutagenized. Active variants of this pool were enriched using an in vitro selection scheme that retains the sequence variability at positions very close to the ligation junction. Ligases isolated after four rounds of selection catalyzed self-ligation up to 700 times faster than the starting sequence. Comparative analysis of the isolates indicated that when complexed with substrate RNAs the ligase forms a nested, double pseudo-knot secondary structure with seven stems and several important joining segments. Comparative analysis also suggested the identity of mutations that account for the increased activity of the selected ligase variants; designed constructs incorporating combinations of these changes were more active than any of the individual ligase isolates.     

A ribozyme selected from variants of U6 snRNA promotes 2',5'-branch formation

In vitro selection was used to sample SnRNA-related sequences for ribozyme activities, and several 2',5'-branch-forming ribozymes were isolated. One such ribozyme is highly dependent upon an 11-nt motif that contains a conserved U6 snRNA sequence (ACAGAGA-box) known to be important for pre-mRNA splicing. The ribozyme reaction is similar to the first step of splicing in that an internal 2'-hydroxyl of an unpaired adenosine attacks at the 5'-phosphate of a guanosine. It differs in that the leaving group is diphosphate rather than a 5' exon. The finding that lariat formation can be accomplished by a small RNA with sequences related to U6 snRNA indicates that the RNA available in the spliceosome may be involved in RNA-catalyzed branch formation.     

High-throughput assay and engineering of self-cleaving ribozymes by sequencing

Self-cleaving ribozymes are found in all domains of life and are believed to play important roles in biology. Additionally, self-cleaving ribozymes have been the subject of extensive engineering efforts for applications in synthetic biology. These studies often involve laborious assays of multiple individual variants that are either designed rationally or discovered through selection or screening. However, these assays provide only a limited view of the large sequence space relevant to the ribozyme function. Here, we report a strategy that allows quantitative characterization of greater than 1000 ribozyme variants in a single experiment. We generated a library of predefined ribozyme variants that were converted to DNA and analyzed by high-throughput sequencing. By counting the number of cleaved and uncleaved reads of every variant in the library, we obtained a complete activity profile of the ribozyme pool which was used to both analyze and engineer allosteric ribozymes.     

Selection of tetracycline inducible self-cleaving ribozymes as synthetic devices for gene regulation in yeast

Synthetic regulatory devices are key components for the development of complex biological systems and the reprogramming of cellular functions and networks. Here we describe the selection of tetracycline inducible hammerhead ribozymes. A tetracycline aptamer was fused to the full-length hammerhead ribozyme via a variable linker region. 11 rounds of in vitro selection were applied to isolate linker sequences that mediate tetracycline dependent hammerhead cleavage. We identified allosteric ribozymes that cleave in the presence of 1 μM tetracycline as fast as the full-length ribozyme whereas cleavage is inhibited up to 333-fold in the absence of tetracycline. Reporter gene assays indicate that the allosteric ribozymes can be employed to control gene expression in yeast.     

Selection of a novel class of RNA-RNA interaction motifs based on the ligase ribozyme with defined modular architecture

To develop molecular tools for the detection and control of RNA molecules whose functions rely on their 3D structures, we have devised a selection system to isolate novel RNA motifs that interact with a target RNA structure within a given structural context. In this system, a GAAA tetraloop and its specific receptor motif (11-ntR) from an artificial RNA ligase ribozyme with modular architecture (the DSL ribozyme) were replaced with a target structure and random sequence, respectively. Motifs recognizing the target structure can be identified by in vitro selection based on ribozyme activity. A model selection targeting GAAA-loop successfully identified motifs previously known as GAAA-loop receptors. In addition, a new selection targeting a C-loop motif also generated novel motifs that interact with this structure. Biochemical analysis of one of the C-loop receptor motifs revealed that it could also function as an independent structural unit.     

New ligase-derived RNA polymerase ribozymes

The search is underway for a catalytic RNA molecule capable of self-replication. Finding such a ribozyme would lend crucial support to the RNA World hypothesis, which holds that very early life-forms relied on RNA for both replicating and storing genetic information. We previously reported an RNA polymerase isolated from a pool of variants of an existing RNA ligase ribozyme. Here we report eight additional ligase-derived polymerase ribozymes isolated from this pool. Because each of them is a new potential starting point for further in vitro evolution and engineering, together they substantially enrich the set of candidates from which an RNA replicase ribozyme might eventually emerge.     

RNase P ribozymes selected in vitro to cleave a viral mRNA effectively inhibit its expression in cell culture

An in vitro selection procedure was used to select RNase P ribozyme variants that efficiently cleaved the sequence of the mRNA encoding thymidine kinase of herpes simplex virus 1. Of the 45 selected variants sequenced, 25 ribozymes carried a common mutation at nucleotides 224 and 225 of RNase P catalytic RNA from Escherichia coli (G(224)G(225) --> AA). These selected ribozymes exhibited at least 10 times higher cleavage efficiency (k(cat)/K(m)) than that derived from the wild type ribozyme. Our results suggest that the mutated A(224)A(225) are in close proximity to the substrate and enhance substrate binding of the ribozyme. When these ribozyme variants were expressed in herpes simplex virus 1-infected cells, the levels of thymidine kinase mRNA and protein were reduced by 95-99%. Our study provides the first direct evidence that RNase P ribozyme variants isolated by the selection procedure can be used for the construction of gene-targeting ribozymes that are highly effective in tissue culture. These results demonstrate the potential for using RNase P ribozymes as gene-targeting agents against any mRNA sequences, and using the selection procedure as a general approach for the engineering of RNase P ribozymes.     

The influence of imperfectly paired helices I and III on the catalytic activity of hammerhead ribozymes.

Several catalytic antisense RNAs directed against different regions of the genomic or antigenomic RNA of Sendai virus were constructed. All RNAs contained the same catalytic domain based on hammerhead ribozymes but some had deletions or mutations resulting in imperfect helices I and III. Pre-annealed substrate/ribozyme complexes were used to determine the rates of the cleavage process for the different ribozymes under single-turnover conditions. It was found that the sequence context surrounding the cleavable motif influenced the cleavage efficiencies. Deletions or mutations of nucleotides 2.1 or 15.1 and 15.2 according to the numbering system for hammerhead ribozymes of Hertel et al. destroyed catalytic activity. Deletions of nucleotide 2.2 or additional nucleotides in the helix I-forming region of the ribozyme did not destruct, but only reduced the cleavage efficiencies. Similar results were observed for a deletion of nucleotide 15.3. Simultaneous deletions within helices I and III resulted in alternative cleavage sites. The potential consequences for the specificity of the ribozyme reaction are discussed.     

Non-ribozyme sequences enhance self-cleavage of ribozymes derived from Hepatitis delta virus.

Analysis of the self-cleavage of ribozymes derived from the genomic RNA of Hepatitis delta virus (HDV) has revealed that certain co-transcribed vector sequences significantly affect the activity of the ribozyme. Specifically, the t1/2 of self-cleavage for a 135 nucleotide HDV RNA varied, at 42 degrees C, from 5 min to 88 min, depending on the vector-derived sequences flanking the 5' end of the ribozyme. Further analysis suggested that this phenomenon was most likely due to the interaction of vector-derived sequences with a 16 nucleotide region found at the 3' end of the ribozyme. These findings have implications for studies of ribozymes transcribed from cDNA templates, and may provide information regarding the catalytic structure of the HDV ribozyme.