Chemical probing studies of variants of the genomic hepatitis delta virus ribozyme by primer extension analysis

A Two-Metal-Ion-Mediated Conformational Switching Pathway for HDV Ribozyme Activation

RNA enzymes serve as a potentially powerful platform from which to design catalysts and engineer new biotechnology. A fundamental understanding of these systems provides insight to guide design. The hepatitis delta virus ribozyme (HDVr) is a small, self-cleaving RNA motif widely distributed in nature, that has served as a paradigm for understanding basic principles of RNA catalysis. Nevertheless, questions remain regarding the precise roles of divalent metal ions and key nucleotides in catalysis. In an effort to establish a reaction mechanism model consistent with available experimental data, we utilize molecular dynamics simulations to explore different conformations and metal ion binding modes along the HDVr reaction path. Building upon recent crystallographic data, our results provide a dynamic model of the HDVr reaction mechanism involving a conformational switch between multiple non-canonical G25:U20 base pair conformations in the active site. These local nucleobase dynamics play an important role in catalysis by modulating the metal binding environments of two Mg²⁺ ions that support catalysis at different steps of the reaction pathway. The first ion plays a structural role by inducing a base pair flip necessary to obtain the catalytic fold in which C75 moves towards to the scissile phosphate in the active site. Ejection of this ion then permits a second ion to bind elsewhere in the active site and facilitate nucleophile activation. The simulations collectively describe a mechanistic scenario that is consistent with currently available experimental data from crystallography, phosphorothioate substitutions, and chemical probing studies. Avenues for further experimental verification are suggested.

Mapping of RNA-protein interactions

RNA-protein interactions are important biological events that perform multiple functions in all living organisms. The wide range of RNA interactions demands diverse conformations to provide contacts for the selective recognition of proteins. Various analytical procedures are presently available for quantitative analyses of RNA-protein complexes, but analytical-based mapping of these complexes is essential to probe specific interactions. In this overview, interactions of functional RNAs and RNA-aptamers with target proteins are discussed by means of mapping strategies.

DMS footprinting of structured RNAs and RNA-protein complexes

We describe a protocol in which dimethyl sulfate (DMS) modification of the base-pairing faces of unpaired adenosine and cytidine nucleotides is used for structural analysis of RNAs and RNA-protein complexes (RNPs). The protocol is optimized for RNAs of small to moderate size (< or = 500 nt). The RNA or RNP is first exposed to DMS under conditions that promote formation of the folded structure or complex, as well as 'control' conditions that do not allow folding or complex formation. The positions and extents of modification are then determined by primer extension, polyacrylamide gel electrophoresis and quantitative analysis. From changes in the extent of modification upon folding or protein binding (appearance of a 'footprint'), it is possible to detect local changes in the secondary and tertiary structure of RNA, as well as the formation of RNA-protein contacts. This protocol takes 1.5-3 d to complete, depending on the type of analysis used.

Design of a highly reactive HDV ribozyme sequence uncovers facilitation of RNA folding by alternative pairings and physiological ionic strength

The hepatitis delta virus (HDV) ribozyme is a self-cleaving RNA that resides in the HDV genome and regulates its replication. The native fold of the ribozyme is complex, having two pseudoknots. Earlier work implicated four non-native pairings in slowing pseudoknot formation: Alt 1, Alt 2, Alt 3, and Alt P1. The goal of the present work was design of a kinetically simplified and maximally reactive construct for in vitro mechanistic and structural studies. The initial approach chosen was site-directed mutagenesis in which known alternative pairings were destabilized while leaving the catalytic core intact. Based on prior studies, the G11C/U27Delta double mutant was prepared. However, biphasic kinetics and antisense oligonucleotide response trends opposite those of the well-studied G11C mutant were observed suggesting that new alternative pairings with multiple registers, termed Alt X and Alt Y, had been created. Enzymatic structure mapping of oligonucleotide models supported this notion. This led to a model wherein Alt 2 and the phylogenetically conserved Alt 3 act as "folding guides", facilitating folding of the major population of the RNA molecules by hindering formation of the Alt X and Alt Y registers. Attempts to eliminate the strongest of the Alt X pairings by rational design of a quadruple mutant only resulted in more complex kinetic behavior. In an effort to simultaneously destabilize multiple alternative pairings, studies were carried out on G11C/U27Delta in the presence of urea or increased monovalent ion concentration. Inclusion of physiological ionic strength allowed the goal of monophasic, fast-folding (kobs approximately 60 min(-1)) kinetics to be realized. To account for this, a model is developed wherein Na+, which destabilizes secondary and tertiary structures in the presence of Mg2+, facilitates native folding by destabilizing the multiple alternative secondary structures with a higher-order dependence.

Site-specific modification of functional groups in genomic hepatitis delta virus (HDV) ribozyme

Human hepatitis delta (HDV) ribozyme is one of small ribozymes, such as hammerhead and hairpin ribozymes, etc. Its secondary structure shows pseudoknot structure composed of four stems (I to IV) and three single-stranded regions (SSrA, -B and -C). The 3D structure of 3'-cleaved product of genomic HDV ribozyme provided extensive information about tertiary hydrogen bonding interactions between nucleotide bases, phosphate oxygens and 2'OHs including new stem structure P1.1. To analyze the role of these hydrogen bond networks in the catalytic reaction, site-specific atomic-level modifications (such as deoxynucleotides, deoxyribosyl-2-aminopurine, deoxyribosylpurine, 7-deaza-ribonucleotide and inosine) were incorporated in the smallest trans-acting HDV ribozyme (47-mer). Kinetic analysis of these ribozyme variants demonstrated the importance of the two W-C base pairs of P1.1 for cleavage; in addition, the results suggest that all hydrogen bond interactions detected in the crystal structure involving 2'-OH and N7 atoms are present in the active ribozyme structure. In most of the variants, the relative reduction in kobs caused by substitution of the 2'-OH group correlated with the number of hydrogen bonds affected by the substitution. However G74 and C75 may have more than one hydrogen bond involving the 2'-OH in both the trans- and cis-acting HDV ribozyme. Moreover, in variants in which N7 was deleted, kobs was reduced 5- to 15-fold, it may suggest that N7 assists in coordinating Mg2+ ions or water molecules which bind with weak affinity in the active structure.

Inhibition of Hepatitis Delta Virus Genomic Ribozyme Self-Cleavage by Aminoglycosides

Subgenomic regions of hepatitis delta virus (HDV) RNA contains ribozyme whose activities are important to viral life cycles and depend on a unique pseudoknot structure. To explore the characters of HDV ribozyme, antibiotics of the aminoglycoside, which has been shown inhibiting self-splicing of group I intron and useful in elucidating its structure, were tested for their effect on HDV genomic ribozyme. Aminoglycosides, including tobramycin, netromycin, neomycin and gentamicin effectively inhibited HDV genomic ribozyme self-cleavage in vitro at a concentration comparable to that inhibiting group I intron self-splicing. The extent of inhibition depended upon the concentration of magnesium ion. Chemical modification mapping of HDV ribozyme RNA indicated that the susceptibility of nucleotide 703 to the modifying agent was enhanced in the presence of tobramycin, suggesting a conformational shift of HDV ribozyme, probably due to an interaction with the aminoglycoside. Finally, we examined the effect of aminoglycoside on HDV cleavage and replication in cell lines, however, none of the aminoglycoside effective in vitro exerted suppressive effects in vivo. Our results represented as an initial effort in utilizing aminoglycoside to probe the structure of HDV ribozyme and to compare its reaction mechanism with those of other related ribozymes.

Kinetic and binding analysis of the catalytic involvement of ribose moieties of a trans-acting delta ribozyme

We have identified ribose 2'-hydroxyl groups (2'-OHs) that are critical for the activity of a trans-cleaving delta ribozyme derived from the antigenomic strand of the hepatitis delta virus. Initially, an RNA-DNA mixed ribozyme composed of 26 deoxyribo- (specifically the nucleotides forming the P2 stem and the P4 stem-loop) and 31 ribonucleotides (those forming the catalytic center) was engineered. This mixed ribozyme catalyzed the cleavage of a small substrate with kinetic parameters virtually identical to those of the all-RNA ribozyme. The further substitution of deoxyribose for ribose residues permitted us to investigate the contribution of all 2'-OHs to catalysis. Determination of the kinetic parameters for the cleavage reaction of the resulting ribozymes revealed (i) 10 2'-OH groups appear to be important in supporting the formation of several hydrogen bonds within the catalytic core, (ii) none of the important 2'-OHs seem to coordinate a magnesium cation, and (iii) 1 of the tested RNA-DNA mixed polymers appeared to stabilize the ribozyme-substrate transition-state complex, resulting in an improvement over the all-RNA counterpart. The contribution of the 2'-OHs to the catalytic mechanism is discussed, and differences with the crystal structure of a genomic delta self-cleaved product are explained. Clearly, the 2'-OHs are essential components of the network of interactions involved in the formation of the catalytic center of the delta ribozyme.

The folding pathway of the genomic hepatitis delta virus ribozyme is dominated by slow folding of the pseudoknots

Hepatitis delta virus (HDV) replicates by a double rolling-circle mechanism that requires self-cleavage by closely related genomic and antigenomic versions of a ribozyme. We have previously shown that the uncleaved genomic ribozyme is subject to a variety of alternative (Alt) pairings. Sequence upstream of the ribozyme can regulate self-cleavage activity by formation of an Alt 1 ribozyme-containing structure that severely inhibits self-cleavage, or a P(-1) self-structure that permits rapid self-cleavage. Here, we test three other alternative pairings: Alt P1, Alt 2, and Alt 3. Alt P1 and Alt 3 contain primarily ribozyme-ribozyme interactions, while Alt 2 involves ribozyme-flanking sequence interaction. A number of single and double mutant ribozymes were prepared to increase or decrease the stability of the alternative pairings, and rates of self-cleavage were determined. Results of these experiments were consistent with the existence of the proposed alternative pairings and their ability to inhibit the overall rate of native ribozyme folding. Local misfolds are treated as internal equilibrium constants in a binding polynomial that modulates the intrinsic rate of cleavage. This model of equilibrium effects of misfolds should be general and apply to other ribozymes. All of the alternative pairings sequester a pseudoknot-forming strand. Folding of ribozymes containing Alt P1 and Alt 2 was accelerated by urea as long as the native ribozyme fold was sufficiently stable, while folding of mutants in which both of these alternative pairings had been removed were not stimulated by urea. This behavior suggests that the pseudoknots form by capture of an unfolded or appropriately rearranged alternative pairing by its complementary native strand. Fast-folding mutants were prepared by either weakening alternative pairings or by strengthening native pairings. A kinetic model was developed that accommodates these features and explains the position of the rate-limiting step for the G11C mutant. Implications of these results for structural and dynamic studies of the uncleaved HDV ribozyme are discussed.

Requirement for canonical base pairing in the short pseudoknot structure of genomic hepatitis delta virus ribozyme

The tertiary structure of the 3'-cleaved product of the genomic hepatitis delta virus (HDV) ribozyme was solved by X-ray crystallographic analysis. In this structure, three single-stranded regions (SSrA, -B and -C) interact intricately with one another via hydrogen bonds between nucleotide bases, phosphate oxygens and 2'-OHs to form a nested double pseudoknot structure. Among these interactions, two Watson-Crick (W-C) base pairs, 726G-710C and 727G-709C, that form between SSrA and SSrC (P1.1) seem to be especially important for compact folding. To characterize the importance of these base pairs, ribozymes were subjected to in vitro selection from a pool of RNA molecules randomly substituted at positions 709, 710, 726 and 727. The results establish the importance of the two W-C base pairs for activity, although some mutants are active with one G-C base pair. In addition, the kinetic parameters were analyzed in all 16 combinations with two canonical base pairs. Comparison of variant ribozymes with the wild-type ribozyme reveals that the difference in reaction rates for these variants (DeltaDelta G (double dagger)) is not simply accounted for by the differences in the stability of P1.1 (DeltaDelta G (0)(37)). The role played by Mg(2+)ions in formation of the P1.1 structure is also discussed.

Sequential folding of the genomic ribozyme of the hepatitis delta virus: structural analysis of RNA transcription intermediates

The structures of the model oligoribonucleotides that mimic the consecutive stages in the transcription of genomic HDV ribozyme have been analyzed by the Pb(2+)-induced cleavage method, partial digestion with specific nucleases and chemical probing. In the transcription intermediates, the P1 and P4 helical segments are found to be present in the final folded forms in which they exist in the full-length transcript. However, the region corresponding to the central hairpin forms another thermodynamically stable hairpin structure. Its correct folding requires the presence of a ribozyme 3'-terminal sequence and the formation of helix P2. This confirms the ribozyme structure of the pseudoknot type and points to the crucial role of helix P2 in its overall folding. Moreover, we show that the J4/2 region can be specifically cleaved in the presence of selected divalent metal ions in the full-length transcript, but not in a shorter one lacking six 3'-terminal nucleotides, which cannot form the pseudoknotted structure. Thus, a particular RNA conformation around that cleavage site is required for specific hydrolysis, and the J4/2 region seems to be involved in the formation of a general metal ion binding site. Recently, it has been proposed that, in the antigenomic ribozyme, a four nucleotide sequence within the J1/2 region may contribute to the folding pathway, being part of a mechanism responsible for controlling ribozyme cleavage activity. Our study shows that in the genomic ribozyme the central hairpin region may contribute to a similar mechanism, providing a barrier to the formation of an active structure in the ribozyme folding pathway.

Mimicry of the hepatitis delta virus replication cycle mediated by synthetic circular oligodeoxynucleotides

BACKGROUND

Hepatitis delta virus (HDV) is a circular single-stranded RNA pathogen whose monomeric form results from self-processing. Although studies have examined minimal HDV ribozyme activities, the mechanism for forming the circular virus remains unclear, and the trans catalytic properties of self-processed forms of HDV ribozymes have not been studied. In addition, HDV ribozymes have not previously been engineered to cleave a non-HDV sequence.

RESULTS

Long repeating RNAs have been produced from in vitro rolling-circle transcription of synthetic circular oligodeoxynucleotides encoding catalytically active subsets of the entire antigenomic RNA virus. Like full-length HDV, these multimeric RNAs undergo self-processing to monomer length; importantly, cyclization is found to occur efficiently, but only in the presence of the circular template. Linear and circular monomer ribozymes and engineered variants are shown to be active in cleaving HDV and HIV RNA targets in trans, despite having self-binding domains.

CONCLUSIONS

Mimicry of the rolling-circle replication pathway for HDV replication has led to a new proposal for cyclization of HDV RNA. Under these conditions, cyclization is mediated by the complementary circular template. In addition, it has been shown that self-processed HDV ribozymes can be catalytically active in trans despite the presence of antisense sequences built into their structure.

Presence of a coordinated metal ion in a trans-acting antigenomic delta ribozyme

We have investigated the cleavage induced by metal ions in an antigenomic form of a trans-acting delta ribozyme. A specific Mg(2+)-induced cleavage at position G(52)at the bottom of the P2 stem was observed to occur solely within catalytically active ribozyme-substrate complexes (i.e. those that performed the essential conformational transition step). Only the divalent cations which support catalytic activity permitted the detection of specific induced cleavages in this region. Using various mutant ribozymes and substrates, we demonstrated a correlation between enzymatic activity and the Mg(2+)-induced cleavage pattern. We show that the efficiency of the coordination of the magnesium to its binding site is related to the nature of the base pair in the middle of the P1 stem (i.e. Rz(23)-S(8)). Together with additional evidence from nuclease probing experiments that indicates the occurrence of a structural rearrangement involving the bottom of the P2 stem upon formation of the P1 helix, these results show that an intimate relationship exists between the folding and the catalytic activity of the delta ribozyme.

Crystal structure of a hepatitis delta virus ribozyme

The self-cleaving ribozyme of the hepatitis delta virus (HDV) is the only catalytic RNA known to be required for the viability of a human pathogen. We obtained crystals of a 72-nucleotide, self-cleaved form of the genomic HDV ribozyme that diffract X-rays to 2.3 A resolution by engineering the RNA to bind a small, basic protein without affecting ribozyme activity. The co-crystal structure shows that the compact catalytic core comprises five helical segments connected as an intricate nested double pseudoknot. The 5'-hydroxyl leaving group resulting from the self-scission reaction is buried deep within an active-site cleft produced by juxtaposition of the helices and five strand-crossovers, and is surrounded by biochemically important backbone and base functional groups in a manner reminiscent of protein enzymes.

Oligonucleotides as modulators of cancer gene expression

The delineation of gene function has always been an intensive subject of investigations. Recent advances in the synthesis and chemistry of oligonucleotides have now made these molecules important tools to study and identify gene function and regulation. Modulation of gene expression using oligonucleotides has been targeted at different levels of the cellular machinery. Triplex forming oligonucleotides, as well as peptide nucleic acids, have been used to inhibit gene expression at the level of transcription; after binding of these specific oligonucleotides, conformational change of the DNA's helical structure prevents any further DNA/protein interactions necessary for efficient transcription. Gene regulation can also be achieved by targeting the translation of mRNAs. Antisense oligonucleotides have been used to down-regulate mRNA expression by annealing to specific and determined region of an mRNA, thus inhibiting its translation by the cellular machinery. The exact mechanism of this type of inhibition is still under intense investigation and is thought to be related to the activation of RNase H, a ribonuclease that is widely available that can cleave the RNA/DNA duplex, thus making it inactive. Another well-characterized means of interfering with the translation of mRNAs is the use of ribozymes. Ribozymes are small catalytic RNAs that possess both site specificity and cleavage capability for an mRNA substrate, inhibiting any further protein formation. This review describes how these different oligonucleotides can be used to define gene function and discusses in detail their chemical structure, mechanism of action, advantages and disadvantages, and their applications.

Analysis of the cleavage reaction of a trans-acting human hepatitis delta virus ribozyme

The cleavage reaction catalyzed by the trans -acting genomic ribozyme of human hepatitis delta virus (HDV) was analyzed with a 13mer substrate (R13) and thio-substituted [SR13(Rp) and SR13(Sp)] substrates under single-turnover conditions. The cleavage of RNA by the trans -acting HDV ribozyme proceeded as a first order reaction. The logarithm of the rate of cleavage (kclv) increased linearly (with a slope of approximately 1) between pH 4.0 and 6.0, an indication that a single deprotonation reaction occurred. This result suggests that kclv reflects the rate of the chemical cleavage step, at least around pH 5. The amount of active complex with the SR13(Sp) substrate was almost as large as with R13 (60-80%), whereas the amount of the corresponding active complex formed with the SR13(Rp) substrate was, at most, 20% of this value (with 0.5-100 mM Mg2+ions) at pH 5.0. Nonetheless, the value of kclv for all substrates was almost the same (0.4-0.5 min-1). Neither a 'thio effect' nor a 'Mn2+rescue effect' were observed. These results suggest that Mg2+ions do not interact with pro-R oxygen directly but are essential to the formation of the active complex of the ribozyme and its substrate.

Self-cleaving ribozymes of hepatitis delta virus RNA

Hepatitis delta virus (HDV) is a small single-stranded RNA satellite of hepatitis B virus. Although it is a human pathogen, it shares a number of features with a subset of the small plant satellite RNA viruses, including self-cleaving sequences in the genomic and antigenomic sequences of the viral RNA. The self-cleaving sequence is critical to viral replication and is thought to function as a ribozyme in vivo to process the products of rolling-circle replication to unit-length molecules. A divalent cation is required for cleavage and while a structural role is implicated for metal ions, a more direct role for a metal ion in catalysis has not yet been proven. A minimal natural ribozyme sequence with proficient in vitro self-cleavage activity is about 85 nucleotides long and adopts a secondary structure with four paired regions (P1-P4). The two pairings that define the 5' and 3' boundaries of the ribozyme, P1 and P2, form an atypical pseudoknot arrangement. This secondary structure places a number of constraints on the possible tertiary folding of the sequence, which together with chemical probing, photo-cross-linking, mutagenesis and computer-assisted modeling provides clues to the three-dimensional structure. The data are consistent with a model in which the cleavage site, located at the 5' end of P1, is in close proximity to three single-stranded regions, consisting of a hairpin loop at the end of P3 and two sequences joining P1 to P4 and P4 to P2. While the natural forms of the HDV ribozymes appear to be prone to misfolding, biochemical and mutagenesis studies from a number of laboratories has allowed the production of trans-acting ribozymes and smaller more active cis-acting ribozymes, both of which will aid in further mechanistic and structural studies of this RNA.

The structure of the isolated, central hairpin of the HDV antigenomic ribozyme: novel structural features and similarity of the loop in the ribozyme and free in solution

The structure of an RNA hairpin containing a seven-nucleotide loop that is present in the self-cleaving sequence of hepatitis delta virus antigenomic RNA was determined by high resolution NMR spectroscopy. The loop, which is composed of only one purine and six pyrimidines, has a suprisingly stable structure, mainly supported by sugar hydroxyl hydrogen bonds and base-base and base-phosphate stacking interactions. Compared with the structurally well-determined, seven-membered anticodon loop in tRNA, the sharp turn which affects the required 180 degrees change in direction of the sugar-phosphate backbone in the loop is shifted one nucleotide in the 3' direction. This change in direction can be characterized as a reversed U-turn. It is expected that the reversed U-turn may be found frequently in other molecules as well. There is evidence for a new non-Watson-Crick UC base pair formed between the first and the last residue in the loop, while most of the other bases in the loop are pointing outwards making them accessible to solvent. From chemical modification, mutational and photocrosslinking studies, a similar picture develops for the structure of the hairpin in the active ribozyme indicating that the loop structure in the isolated hairpin and in the ribozyme is very similar.

Detailed analysis of base preferences at the cleavage site of a trans-acting HDV ribozyme: a mutation that changes cleavage site specificity

In our previous attempt at in vitro selection of a trans - acting human hepatitis delta virus (HDV) ribozyme, we found that one of the variants, G10-68-725G, cleaved a 13 nt substrate, HDVS1, at two sites [Nishikawa,F., Kawakami,J., Chiba,A., Shirai,M., Kumar,P.K.R. and Nishikawa,S. (1996) Eur. J. Biochem., 237, 712-718]. One site was the normal cleavage site and the other site was shifted 1 nt toward the 3'-end. To clarify the interactions between nucleotides around the cleavage site of the trans -acting HDV ribozyme, we analyzed the efficiency of the reaction for every possible base pair between the substrate and the ribozyme at positions -1 (-1N:726N) and +1 (+1N:725N) relative to the cleavage site using the genomic HDV ribozyme, TdS4(Xho), and derivatives of the most active variant, G10-68. These mutagenesis analyses revealed that the +1 base of the substrate affects the structure of the catalytic core in the complex with G10-68-725G, substrate and divalent metal ions, and it shifts the cleavage site. In a comparison with other variants of the trans -acting HDV ribozyme, we found that this cleavage site shift occurred only with G10-68-725G.

Constructing an efficient trans-acting genomic HDV ribozyme

We have engineered a genomic HDV ribozyme to construct several trans-acting ribozymes for use in trans to cleave target RNAs. Among the 10 different combinations attempted, only HDV88-Trans had cleavage activity on the 13-nucleotide substrate, R13, in vitro. To improve the cleavage efficiency, at least in vitro, of the HDV88-Trans ribozyme (kclv = 0.022 min(-1)), we have constructed several variants that differ in forming stem II (length) in the pseudoknot secondary structure model. When cleavage rate constants were analyzed and compared among variants of HDV88-Trans, HDV88-Trans-4 yielded kclv = 1.7 min(-1). HDV88-Trans-4 thus represents the highest active genomic HDV ribozyme that functions in trans thus far constructed, and has activity under physiological conditions (pH 7.1 at 37 degrees C with 1 mM of MgCl2).

Selection in vitro of trans-acting genomic human hepatitis delta virus (HDV) ribozymes

In an effort to identify the functional structure as well as new active variants of the trans-acting genomic ribozyme of human hepatitis delta virus (HDV), we applied an in vitro selection procedure. A total of 14 rounds of selection and amplification was repeated and various mutant ribozymes in G10 and G14 pools analyzed. Active ribozymes which were isolated in the present study (from G10 and G14) all possessed conserved bases (that were identified earlier) in the cis-acting molecule. A dominant clone G10-68 variant was accumulated in generation 14. Interestingly, when base substitutions were analyzed in G10-68 variant, we found that this variant appears to be close to antigenome-like HDV ribozyme molecule. Further investigations of G10-68 confirmed that each mutated base was the most appropriate nucleotide at every position of the HDV ribozyme.

3-D models of the antigenomic ribozyme of the hepatitis delta agent with eight new contacts suggested by sequence analysis of 188 cDNA clones

We mapped 359 mutations at 25 positions in synthetic variants of the antigenomic ribozyme of the hepatitis delta agent by analyzing the sequences of 188 cDNA clones. These data were used to identify three features of the ribozyme: highly conserved nucleotides, positions with restricted nucleotide substitutions and three-dimensional relationships between nucleotides. The distribution of mutations at the 25 positions was as follows: G-11 (the eleventh nucleotide from the cleavage site) was mutated in 56 clones; G-12 in 36; U-15 in 33; C-13 in 26; G-28 in 23; C-27 in 21; C-29 in 19; U-26 in 17; C-18 in 14; A-14 in 13; C-16 in 13; C-19 in 12; U-17 in 11; A-20 in 10; G-42 in 9; G-40 in 7; G-41 in 7; C-24 in 6; U-32 in 6; U-23 in 5; C-25 in 4; C-21 in 3; G-30 in 3; G-31 in 3; C-22 in 1. All clones containing a mutation at C-25 had an A at this position, suggesting that the extra cyclic amino group present in adenine and cytosine may function during the cleavage event. Mutations at certain positions were common in simple clones (containing only one or two mutations), while mutations at other positions were over-represented in more complex clones. Both compensatory base changes and co-mutational frequencies were used to identify eight pairs of nucleotides which may interact with each other: G-11 and C-18, G-12 and C-27, C-13 and G-28, C-21 and U-23/C-24, C-21 and G-30, U-23 and G-31/U-32, C24 and G-30, C-27 and G-42. These pairs, which involve some of the most conserved positions in the molecule, suggest interactions among nucleotides previously depicted in open-loop structures. The newly proposed points of contact between pairs of nucleotides are compatible with both the axehead and pseudoknot secondary structural models and were combined with previously proposed Watson-Crick base paired helices to produce two three dimensional models. In both of these, C-25 and C-76 are placed near the cleavage site.

RNA folding

The number of known motifs for RNA folding and RNA tertiary organization is expanding rapidly as we learn more about the diverse biological functions of RNA. Problems in protein and RNA folding have melded in recent investigations of ribonucleoprotein folding. Theoretical and experimental models are rapidly being developed for the pathways and stabilizing forces involved in RNA folding.

RNA cleavage by small catalytic RNAs

Recent studies of the hammerhead ribozyme have provided an insight into its three-dimensional structure. In addition, studies using chemical probes, functional-group modification and mutational analysis, in combination with computer modelling, have led to proposals for the structure of both the hairpin and hepatitis delta virus ribozymes. Such structural elucidations will aid understanding of the mechanism of ribozyme catalysis. The discovery that certain RNA-binding proteins can increase the catalytic efficiency of ribozymes in encouraging for their use in the inhibition of gene expression in vivo.

Intracellular cleavage and ligation of hepatitis delta virus genomic RNA: regulation of ribozyme activity by cis-acting sequences and host factors

During replication, a ribozyme within the genomic RNA of hepatitis delta virus cleaves multimeric precursors to release a unit-length linear intermediate. Intramolecular ligation of this intermediate produces the circular genomic RNA. Although one copy of the ribozyme is reconstituted by such ligation, it does not subsequently cleave and destroy the circular conformation. We have identified cis-acting attenuator sequences that prevent self-cleavage of the circular product by base pairing with and inactivating the ribozyme. Furthermore, we have shown that during the initial processing of the multimeric precursor RNA, host-specific factors activate the ribozyme by preventing its association with the attenuator sequences. Thus, we demonstrate a novel switching mechanism that regulates ribozyme activity inside the cell.

Identification of phosphate oxygens that are important for self-cleavage activity of the HDV ribozyme by phosphorothioate substitution interference analysis

A phosphorothioate substitution interference assay was used to investigate the role of the pro-Rp oxygens of phosphate groups in the self-cleavage reaction of the genomic human hepatitis delta virus (HDV) ribozyme. Incorporation of several different phosphorothioates (NTP alpha S) into the HDV ribozyme inhibited the self-cleavage activity. Incorporation of uridine 5' phosphorothioate or adenosine 5' phosphorothioate maintained 72% of the original self-cleavage activity whereas incorporation of guanosine 5' phosphorothioate or cytosine 5' phosphorothioate into the precursor reduced self-cleavage activity to about 20% in each case. Using partially substituted phosphorothioate-modified transcripts, we identified the pro-Rp oxygens that are important for the ribozyme activity, and they are located at positions 0, 1, 4, 5, 21, 24, 25, 27, 28, 30-34, 40, 43 and 75. In particular, the pro-Rp oxygens at positions 0, 1 and 21 are appear to be critical for the self-cleavage activity of the HDV ribozyme.

RNA pseudoknots

Many new RNA pseudoknot structures have been detected and proposed in the past year. Although we are still waiting for the first detailed structure of a pseudoknot, their role in processes such as translational autoregulation or ribosomal frameshifting has been extensively studied and is now well established. Pseudoknot structures appear to play a pivotal role in small subunit ribosomal RNA and in the noncoding regions of viral RNAs. There are also strong indications that RNA pseudoknots are highly suitable structural motifs for the recognition and binding of proteins.