Improved accumulation and activity of ribozymes expressed from a tRNA-based RNA polymerase III promoter.

RNA polymerase III (pol III) transcripts are abundant in all cells. Therefore, pol III promoters may be ideal for expressing high levels of exogenous RNAs, such as antisense RNAs, decoy RNAs and ribozymes, in many different cell types. We have improved accumulation of recombinant RNAs expressed from a human meti tRNA-derived pol III promoter > 100-fold by modifying the 3' terminus of the transcripts to hybridize to the 5' terminus. This terminal duplex includes the 8 nt leader sequence present in the primary wild-type meti tRNA transcript that is normally removed during processing to the mature tRNA. Expression of an anti-HIV ribozyme was analyzed in cells stably transduced with retroviral vectors encoding pol III transcription units containing this modification. High accumulation of recombinant pol III ribozyme transcripts was observed in all cell lines tested. Due to the enhanced transcript accumulation, ribozyme cleavage activity was readily detectable in total RNA extracted from stably transduced human T cell lines. One pol III transcription unit, termed 'TRZ', was optimized further for ribozyme cleavage activity. The improved pol III transcription units reported here may be useful for expressing a variety of functional and therapeutic RNAs.

Novel system for analysis of group I 3' splice site reactions based on functional trans-interaction of the P1/P10 reaction helix with the ribozyme's catalytic core.

A group I intron from a bacterial tRNA precursor has been converted into an RNA enzyme that catalyzes the efficient polymerization of oligoribonucleotide analogs of tRNA exons using a reaction scheme consisting of multiple cycles of reverse and forward exon ligation reactions. Here, we present results showing that this system represents a novel and useful tool for the analysis of 3' splice site reactions of group I ribozymes. First, analysis of variant substrates containing base substitutions in group I secondary structure elements P1, P9.0 and P10 confirms that exon polymerization is dependent on these structures, and therefore constitutes an appropriate and relevant model system for studying the exon ligation step of splicing. Second, to probe interactions between the intron's catalytic core and the bases and backbone of the P1/P10 reaction helix, two successful strategies for separating the internal guide sequence from the intron core were devised. One such strategy uses a construct in which the reaction helix interacts functionally with the catalytic core using only tertiary contacts. Further stabilization of this interaction through the inclusion of a 7 bp intermolecular P2 helix generates increased reaction efficiency. Third, when provided with two reaction helices, the ribozyme synthesizes mixed polymers through a mechanism that involves sequential binding and release of the duplexes. Fourth, in these reactions, turnover of the external guide sequence requires unwinding and annealing of the P2 helix, suggesting that P2 unwinding may occur during group I splicing. These results provide novel experimental tools to probe the relatively poorly understood 3' splice site reactions of group I introns, and may be relevant to ribozyme-catalyzed assembly and recombination of oligomers in prebiotic scenarios.

In vitro and in vivo comparison of hammerhead, hairpin, and hepatitis delta virus self-processing ribozyme cassettes.

Ribozyme expression cassettes were constructed which generate trimmed, trans-acting ribozymes from longer transcripts through the action of a downstream cis-acting ribozyme. This self-processing system produces small, well-defined trans-acting ribozymes with minimal, nonproductive, intramolecular structure. These cassettes also permit direct comparison of different ribozyme expression vectors without the need to compensate for different transcription initiation and termination sequences. Expression cassettes were created that contain a T7 promoter and that encode a single trans-acting ribozyme followed by either a hammerhead, hairpin, or hepatitis delta virus cis-acting ribozyme. All three ribozyme motifs function efficiently when transcribed in vitro, although slight differences are observed in the efficiency of self-processing for the different motifs. When transiently expressed in cultured mouse cells, the same specific cleavage products are observed. In addition, the relative efficiencies of in vitro self-processing between the three ribozyme constructs was maintained in vivo. Thus, the cellular milieu does not differentially alter the activity of the three ribozyme motifs. Detection of ribozyme-catalyzed RNA cleavage products from cultured cells is direct proof of ribozyme action in vivo.

Four ribose 2'-hydroxyl groups essential for catalytic function of the hairpin ribozyme.

The hairpin ribozyme catalyzes site-specific cleavage of an RNA substrate using a magnesium-dependent transphosphorylation mechanism. Here, we describe experiments designed to test the importance of ribose 2'-hydroxyl groups for ribozyme function. Ribozymes for this work were synthesized in two segments using solid-phase RNA phosphoramidite chemistry. 2'-Deoxyribonucleotides were systematically introduced at each of the 50 positions within the ribozyme, and the catalytic activity of the resulting mixed RNA-DNA polymers was measured. Deletion of the 2'-hydroxyl group at each of four sites (A10, G11, A24, and C25) was found to result in severe inhibition of cleavage activity (kcat/KM decreased by 100- to 1000-fold), although KM measurements and mobility-shift assays showed that substrate binding was not affected. Identical results were obtained upon substitution of these ribonucleotides with 2'-O-methyl derivatives. Inhibition by 2'-modified sugars at G11 or A24 was rescued by increased Mg2+ concentrations, suggesting that these 2'-hydroxyls may function in magnesium binding. Our results demonstrate that the 2'-hydroxyl groups at A10, G11, A24, and C25 provide essential functions for catalysis, possibly forming important tertiary contacts or magnesium coordination sites that are necessary for active site architecture.

2'-Hydroxyl groups important for exon polymerization and reverse exon ligation reactions catalyzed by a group I ribozyme.

The functional importance of ribose moieties in both exons and in intron sequences proximal to the 3' splice site of a group I intron has been analyzed using a novel exon polymerization reaction. The ribozyme is a modified version of a self-splicing bacterial tRNA intron (I) that attacks a 20-nucleotide synthetic ligated exon substrate (E1.E2), yielding E1 and I.E2 by reverse exon ligation. A series of repetitive reactions then polymerize E2 on the 3' end of the intron; attack by E1 subsequently generates E1.(E2)n. Systematic deoxyribonucleotide substitution within E1.E2 was used to probe the function of 2'-hydroxyl groups in each exon and the 3'-terminal nucleotides of the intron. We find that ribose at the splice junction (U-1) and at the two adjacent positions with E1 (A-2, C-3) is important for reverse exon ligation. Within E2, deletion of 2'-hydroxyl groups of the nucleotides that form P10 does not affect reactivity. In contrast, ribose at the 3' end of the intron is essential for reverse exon ligation, and the presence of a 2'-OH group in each of the nucleotides comprising P9.0[3'] contributes to reaction efficiency. These results support a model in which specific 2'-hydroxyl groups at and adjacent to the reaction sites form tertiary contacts that serve to stabilize interactions with the catalytic core of the ribozyme. Furthermore, they suggest that the mechanism by which guanosine at the 3' end of the intron is activated for reverse exon ligation is the same as that by which guanosine mononucleotide is activated in the first step of splicing.

Novel RNA polymerization reaction catalyzed by a group I ribozyme.

We have converted a bacterial tRNA precursor containing a 205 nt self-splicing group I intron into a RNA enzyme that catalyzes polymerization of an external RNA substrate. The reaction involves transesterification steps analogous to both the forward and reverse exon ligation steps of group I splicing; as such it depends entirely on 3' splice site reactions. The RNA substrate is a 20 nt analogue of the ligated exons (E1.E2), whose 3' end resembles the 3' terminus of the intron RNA enzyme (IVS). The splice junction of the substrate is attacked by the 3' end of the intron, then the molecule displaces the original 3' terminal guanosine so that the new 3' terminus is brought into the active site and used as the attacking nucleophile in the next reaction. Polymerization occurs via a series of covalent enzyme-linked intermediates of the structure IVS.(E2)n, where n = 1 to > or = 18. The 5' exon accumulates during the course of the reaction and can attack the covalent intermediates to produce elongation products of structure E1.(E2)n, regenerating the intron RNA enzyme in unchanged form. In this manner, the enzyme converts 20 nt oligoribonucleotides into polyribonucleotides up to at least 180 nt by 10 nt increments. These results have significant implications for the evolution of RNA-based self-replicating systems.

Essential nucleotide sequences and secondary structure elements of the hairpin ribozyme.

In vitro selection experiments have been used to isolate active variants of the 50 nt hairpin catalytic RNA motif following randomization of individual ribozyme domains and intensive mutagenesis of the ribozyme-substrate complex. Active and inactive variants were characterized by sequencing, analysis of RNA cleavage activity in cis and in trans, and by substrate binding studies. Results precisely define base-pairing requirements for ribozyme helices 3 and 4, and identify eight essential nucleotides (G8, A9, A10, G21, A22, A23, A24 and C25) within the catalytic core of the ribozyme. Activity and substrate binding assays show that point mutations at these eight sites eliminate cleavage activity but do not significantly decrease substrate binding, demonstrating that these bases contribute to catalytic function. The mutation U39C has been isolated from different selection experiments as a second-site suppressor of the down mutants G21U and A43G. Assays of the U39C mutation in the wild-type ribozyme and in a variety of mutant backgrounds show that this variant is a general up mutation. Results from selection experiments involving populations totaling more than 10(10) variants are summarized, and consensus sequences including 16 essential nucleotides and a secondary structure model of four short helices, encompassing 18 bp for the ribozyme-substrate complex are derived.

Ionic requirements for RNA binding, cleavage, and ligation by the hairpin ribozyme.

Metal ion requirements for RNA binding, cleavage, and ligation by the hairpin ribozyme have been analyzed. RNA cleavage is observed when Mg2+, Sr2+, or Ca2+ are added to a 40 mM Tris-HCl buffer, indicating that these divalent cations were capable of supporting the reaction. No reaction was observed when other ions (Mn2+, Co2+, Cd2+, Ni2+, Ba2+, Na+, K+, Li+, NH4+, Rb+, and Cs+) were tested. In the absence of added metal ions, spermidine can induce a very slow ribozyme-catalyzed cleavage reaction that is not quenched by chelating agents (EDTA and EGTA) that are capable of quenching the metal-dependent reaction. Addition of Mn2+ to a reaction containing 2 mM spermidine increases the rate of the catalytic step by at least 100-fold. Spermidine also reduces the magnesium requirement for the reaction and strongly stimulates activity at limiting Mg2+ concentrations. There are no special ionic requirements for formation of the initial ribozyme-substrate complex--analysis of complex formation using native gels and kinetic assays shows that the ribozyme can bind substrate in 40 mM Tris-HCl buffer. Complex formation is inhibited by both Mn2+ and Co2+. Ionic requirements for the ribozyme-catalyzed ligation reaction are very similar to those for the cleavage reaction. We propose a model for catalysis by the hairpin ribozyme that is consistent with these findings. Formation of an initial ribozyme-substrate complex occurs without the obligatory involvement of divalent cations. Ions (e.g., Mg2+) can then bind to form a catalytically proficient complex, which reacts and dissociates.(ABSTRACT TRUNCATED AT 250 WORDS)

Substrate selection rules for the hairpin ribozyme determined by in vitro selection, mutation, and analysis of mismatched substrates.

Substrate recognition by the hairpin ribozyme has been proposed to involve two short intermolecular helices, termed helix 1 and helix 2. We have used a combination of three methods (cleavage of mismatched substrates, in vitro selection, and site-specific mutational analysis) to systematically determine the substrate recognition rules for this RNA enzyme. Assays measuring substrate cleavage in trans under multiple turnover conditions were conducted using the wild-type ribozyme and substrates containing mismatches in all sites potentially recognized by the ribozyme. Molecules containing single- and multiple-base mismatches in helix 2 at sites distant from the cleavage site (g-4c, u-5a, g-4c: u-5a) were cleaved with reduced efficiency, whereas those with mismatches proximal to the cleavage site (c-2a, a-3c, c-2a: a-3c) were not cut. Analogous results were obtained for helix 1, where mismatches distal from the cleavage site (u+7a, u+8a, u+9a, u+7a: u+8a: u+9a) were used much more efficiently than those proximal to the cleavage site (c+4a, u-5a, g+6c, c+4a: u+5a: g+6c). In vitro selection experiments were carried out to identify active variants from populations of molecules in which either helix 1 or helix 2 was randomized. Results constitute an artificial phylogenetic data base that proves base-pairing of nucleotides at five positions within helix 1 and three positions within helix 2 and reveals a significant sequence bias at 3 bp (c+4.G6, c-2.G11, and a-3.U12). This sequence bias was confirmed at two sites by measuring relative cleavage rates of all 16 possible dinucleotide combinations at base pairs c+4.G6 and c-2.G11.(ABSTRACT TRUNCATED AT 250 WORDS)

Extensive phosphorothioate substitution yields highly active and nuclease-resistant hairpin ribozymes.

The catalytic function of the hairpin ribozyme has been investigated by modification-interference analysis of both ribozyme and substrate, using ribonucleoside phosphorothioates. Thiophosphate substitutions in two ribozyme domains were examined by using a novel and highly efficient two-piece ribozyme assembled from two independently synthesized oligoribonucleotides. The catalytic proficiency of the two-piece construct (KM = 48 nM, kcat = 2.3 min-1) is nearly identical to that of the one-piece ribozyme. The two-piece ribozyme is essentially unaffected by substitution with thiophosphates 5' to all guanosines, cytidines, and uridines. In contrast, incorporation of multiple adenosine phosphorothioates in the 5' domain of the ribozyme decreases ribozyme activity by a factor of 25. Modification-interference experiments using ribozymes partially substituted with adenosine phosphorothioate suggest that thiophosphates 5' to A7, A9 and A10 interfere with cleavage to a greater extent than substitutions at other sites within the molecule, but the effect is modest. Within the substrate, phosphorothioate substitution does not directly interfere with cleavage, rather, increasing thiophosphate content decreases the stability of the ribozyme-substrate complex. We describe the construction of a hairpin ribozyme containing dinucleotide extensions at its 5' and 3' ends. Full substitution of this molecule with G and C phosphorothioates results in a ribozyme with greatly enhanced stability against cellular ribonucleases without significant loss of catalytic efficiency.

Novel guanosine requirement for catalysis by the hairpin ribozyme.

THERE is much interest in the development of 'designer ribozymes' to target destruction of RNAs in vitro and in vivo. Engineering of ribozymes with novel specificities requires detailed knowledge of the ribozyme-substrate interaction, and a rigorous evaluation of sequence specificity. The hairpin ribozyme catalyses an efficient and reversible site-specific cleavage reaction. We have used mutagenesis and in vitro selection strategies to show that RNA cleavage and ligation has an absolute requirement for guanosine immediately 3' to the cleavage-ligation site. This G is not required for efficient substrate binding, rather, its 2-amino group is an essential component of the active site required for catalysis.

Binding and cleavage of nucleic acids by the "hairpin" ribozyme.

The "hairpin" ribozyme derived from the minus strand of tobacco ringspot virus satellite RNA [(-)sTRSV] efficiently catalyzes sequence-specific RNA hydrolysis in trans (Feldstein et al., 1989; Hampel & Triz, 1989; Haseloff & Gerlach, 1989). The ribozyme does not cleave DNA. An RNA substrate analogue containing a single deoxyribonucleotide residue 5' to the cleavage site (A-1) binds to the ribozyme efficiently but cannot be cleaved. A DNA substrate analogue with a ribonucleotide at A-1 is cleaved; thus A-1 provides the only 2'-OH required for cleavage. These results support cleavage via a transphosphorylation mechanism initiated by attack of the 2'-OH of A-1 on the scissile phosphodiester. The ribozyme discriminates between DNA and RNA in both binding and cleavage. Results indicate that the 2'-OH of A-1 functions in complex stabilization as well as cleavage. The ribozyme efficiently cleaves a phosphorothioate diester linkage, suggesting that the pro-Rp oxygen at the scissile phosphodiester does not coordinate Mg2+.

Formation in vitro of the pTP-dCMP initiation complex of human adenovirus type 12.

We report the covalent addition of [32P]dCMP to a protein from group A adenovirus 12 (Ad12)-infected human (KB) cells in vitro, using crude extracts. Synthesis of the 60K protein-dCMP complex required a DNA template containing a terminally located adenovirus replication origin; the protein-dCMP bond was alkali-labile but acid-stable. We therefore conclude that this product is the Ad12 terminal protein precursor (pTP)-dCMP initiation complex for DNA replication. Synthesis of Ad12 pTP-dCMP was specific for dCTP but was stimulated by dATP. In contrast to Ad2, the Ad12 initiation reaction required ATP. Antipeptide antiserum targeted to Ad DNA polymerase inhibited Ad12 pTP-dCMP synthesis in vitro, providing evidence that Ad DNA polymerase catalyse dCMP addition to pTP during initiation.

Extracts of hamster cells abortively infected with human adenovirus type 12 are competent to support initiation of viral DNA replication.

Baby hamster kidney (BHK-21) cells do not allow replication of human adenovirus type 12 (Ad12) DNA during abortive infection by this virus. However, we have determined that crude extracts of BHK-21 cells abortively infected with Ad12 support in vitro the initiation reaction of Ad12 DNA replication. Synthesis of the Ad12 pTP-dCMP initiation complex by BHK extracts is two- to five-fold less than when crude infected human (KB) cell extracts are used in the reaction. Combining infected KB cytoplasmic and uninfected BHK nuclear extracts in the reaction indicates that the decreased efficiency is probably due to a lesser ability of hamster nuclear extracts to support the initiation reaction, rather than to decreased synthesis of Ad12 pTP and DNA polymerase during abortive infection, or to the presence of an inhibitor in BHK cells.